AOP-Wiki

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<div id="title">
<h2>AOP ID and Title:</h2>
<div class="title">AOP 450: Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</div>
Short Title: Organo-Phosphate Chemicals leading to sensory axonal peripheral neuropathy and mortality
</div>
<h2>Graphical Representation</h2>
~~<img src="https://aopwiki.org/system/dragonfly/production/2022/05/17/4sct74h3nh_GA_AOP.png" height="500" width="700" alt=""/>~~
<img src="https://www.aopwiki.org/system/dragonfly/production/2022/05/17/4sct74h3nh_GA_AOP.png" height="500" width="700" alt=""/>
<div id="authors">
<h2>Authors</h2>
Saroj Kumar Amar and Kurt A. Gust*
U.S. Army Engineer Research and Development Center, Environmental Laboratory, 3909 Halls Ferry Road, Vicksburg, Mississippi 39180 Sarojkumaramar@gmail.com, Saroj.K.Amar@erdc.dren.mil *Corresponding Author: Kurt.A.Gust@usace.army.mil
</div>
<div id="status">
<h2>Status</h2>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Author status</th>
<th scope="col">OECD status</th>
<th scope="col">OECD project</th>
<th scope="col">SAAOP status</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Under development: Not open for comment. Do not cite</td>
<td></td>
<td></td>
<td></td>
</tr>
</tbody>
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</div>
</div>
<div id="abstract">
<h2>Abstract</h2>
Organophosphate compounds (OP) such as paraoxon, ethyl parathion, methyl parathion and others are widely used insecticides. OP compounds are also being developed as warfare nerve agents like soman, sarin and tabun etc. The present adverse outcome pathway (AOP) utilizing the existing key events (KEs) and describes the risk associated with a characteristics OP exposure via acetylcholinesterase (AChE) inhibition as molecular initiating event (MIE), which roots a series of KEs that ultimately manifest the adverse outcomes (AO) of sensory axonal peripheral neuropathy and mortality. The MIE of inhibited AChE triggers the KEs: activation of CYP2E1 (aopwiki.org/events/1508), oxidative stress in brain (aopwiki.org/events/1510), neurodegeneration (aopwiki.org/events/352), decreased neuronal network function in adult brain (aopwiki.org/events/618), sensory axonal peripheral neuropathy (aopwiki.org/events/1583) and increased mortality (aopwiki.org/events/351).  The OP insecticides inhibits AChE by inhibition of serine esterases and proteases via phosphorylation (Amitai G et al., 1998, Petroianu GA et al., 2001). Farm workers exposed with commonly used OP showed sharp decrease in blood AChE (MIE) level simultaneously over expression of CYP2E1 (KE1) at mRNA level (Sharma RK et al., 2013). CYP2E1-induced oxidative stress (KE2) by over activation of JNK signaling (Schattenberg JM et al., 2014). Literature further supported that oxidative stress causes neurodegeneration (KE3) by targeting different cellular macromolecules including membrane lipid peroxidation, mitochondrial dysfunction and oxidation of protein and nucleic acid (Gandhi S et al., 2012). Thus neurodegeneration and oxidative stress are inherently related phenomena, since microglia and astrocytes are the main sources of reactive oxygen species in CNS degenerative disorders consequently oxidative stress in brain caused neurodegeneration (Mendonca HR et al., 2020, Wakatsuki S et al., 2015, Mishra V et al., 2015, Kim M et al., 2019). Neurodegeneration leads to impairment of retrograde axonal transport that prohibits the growth factor supply to long-range projection neurons, causing synapse loss, and post-synaptic dendrite retraction that leads to decrease of the neuronal network in adult brain (KE 4) (aopwiki.org/relationships/647, Seeley WW et al., 2009). Palop et al (2006) also advocated that neurodegeneration leads to neural network dysfunction. Consequently, loss of neuronal network function in adult brain leads to an important adverse outcome sensory axonal peripheral neuropathy and symptoms include numbness, lack of coordination, impairment of motor nerve, dizziness, burning sensation etc. (Diantonio et al., 2019, Valek L et al., 2019, Persson AK et al., 2016, Topp KS et al., 2000). Thus this AO represents a disparate group of diseases where epidemiological features indicate the potential for a secondary AO of mortality as final adverse outcome (Taverner T et al., 2019, Martyn CN et al., 1997, Hughes RA et al., 1995). Thus this AOP established the connection between OP chemicals and sensory axonal peripheral neuropathy including mortality to endorse predictive toxicology.
Organophosphate compounds (OP) such as paraoxon, ethyl parathion, methyl parathion and others are widely used insecticides. OP compounds are also being developed as warfare nerve agents like soman, sarin and tabun etc. The present adverse outcome pathway (AOP) utilizing the existing key events (KEs) and describes the risk associated with a characteristics OP exposure via acetylcholinesterase (AChE) inhibition as molecular initiating event (MIE), which roots a series of KEs that ultimately manifest the adverse outcomes (AO) of sensory axonal peripheral neuropathy and mortality. The MIE of inhibited AChE triggers the KEs: activation of CYP2E1 (aopwiki.org/events/1508), oxidative stress (aopwiki.org/events/1392), neurodegeneration (aopwiki.org/events/352), decreased neuronal network function in adult brain (aopwiki.org/events/618), sensory axonal peripheral neuropathy (aopwiki.org/events/1583) and increased mortality (aopwiki.org/events/351).  The OP insecticides inhibits AChE by inhibition of serine esterases and proteases via phosphorylation (Amitai G et al., 1998, Petroianu GA et al., 2001). Farm workers exposed with commonly used OP showed sharp decrease in blood AChE (MIE) level simultaneously over expression of CYP2E1 (KE1) at mRNA level (Sharma RK et al., 2013). CYP2E1-induced oxidative stress (KE2) by over activation of JNK signaling (Schattenberg JM et al., 2014). Literature further supported that oxidative stress causes neurodegeneration (KE3) by targeting different cellular macromolecules including membrane lipid peroxidation, mitochondrial dysfunction and oxidation of protein and nucleic acid (Gandhi S et al., 2012). Thus neurodegeneration and oxidative stress are inherently related phenomena, since microglia and astrocytes are the main sources of reactive oxygen species in CNS degenerative disorders consequently oxidative stress in brain caused neurodegeneration (Mendonca HR et al., 2020, Wakatsuki S et al., 2015, Mishra V et al., 2015, Kim M et al., 2019). Neurodegeneration leads to impairment of retrograde axonal transport that prohibits the growth factor supply to long-range projection neurons, causing synapse loss, and post-synaptic dendrite retraction that leads to decrease of the neuronal network in adult brain (KE 4) (aopwiki.org/relationships/647, Seeley WW et al., 2009). Palop et al (2006) also advocated that neurodegeneration leads to neural network dysfunction. Consequently, loss of neuronal network function in adult brain leads to an important adverse outcome sensory axonal peripheral neuropathy and symptoms include numbness, lack of coordination, impairment of motor nerve, dizziness, burning sensation etc. (Diantonio et al., 2019, Valek L et al., 2019, Persson AK et al., 2016, Topp KS et al., 2000). Thus this AO represents a disparate group of diseases where epidemiological features indicate the potential for a secondary AO of mortality as final adverse outcome (Taverner T et al., 2019, Martyn CN et al., 1997, Hughes RA et al., 1995). Thus this AOP established the connection between OP chemicals and sensory axonal peripheral neuropathy including mortality to endorse predictive toxicology.
</div>
<div id="background">
</div>
<div id="aop_summary">
<h2>Summary of the AOP</h2>
<h3>Events</h3>
<h3>Molecular Initiating Events (MIE), Key Events (KE), Adverse Outcomes (AO)</h3>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sequence</th>
<th scope="col">Type</th>
<th scope="col">Event ID</th>
<th scope="col">Title</th>
<th scope="col">Short name</th>
</tr>
</thead>
<tbody>
<tr>
<td>1</td>
<td>MIE</td>
<td>12</td>
<td><a href="/events/12">Acetylcholinesterase (AchE) Inhibition</a></td>
<td>AchE Inhibition</td>
</tr>
<tr><td></td><td></td><td></td><td></td><td></td></tr>
<tr>
<td>2</td>
<td>KE</td>
<td>1391</td>
<td><a href="/events/1391">Activation of Cyp2E1</a></td>
<td>Activation of Cyp2E1</td>
</tr>
<tr>
~~<td>3</td>~~
<td></td>
<td>KE</td>
~~<td>1510</td>~~
~~<td><a href="/events/1510">Oxidative Stress in Brain</a></td>~~
~~<td>Oxidative Stress in Brain</td>~~
<td>1392</td>
<td><a href="/events/1392">Increase, Oxidative Stress </a></td>
<td>Increase, Oxidative Stress </td>
</tr>
<tr>
<td>4</td>
<td>KE</td>
<td>352</td>
<td><a href="/events/352">N/A, Neurodegeneration</a></td>
<td>N/A, Neurodegeneration</td>
</tr>
<tr>
<td>5</td>
<td>KE</td>
<td>618</td>
<td><a href="/events/618">Decreased, Neuronal network function in adult brain</a></td>
<td>Decreased, Neuronal network function in adult brain</td>
</tr>
<tr><td></td><td></td><td></td><td></td><td></td></tr>
<tr>
<td>6</td>
<td>AO</td>
<td>1583</td>
<td><a href="/events/1583">Sensory axonal peripheral neuropathy</a></td>
<td>Sensory axonal peripheral neuropathy</td>
</tr>
<tr>
<td>7</td>
<td>AO</td>
<td>351</td>
<td><a href="/events/351">Increased Mortality</a></td>
<td>Increased Mortality</td>
</tr>
</tbody>
</table>
</div>
<h3>Key Event Relationships</h3>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Upstream Event</th>
<th scope="col">Relationship Type</th>
<th scope="col">Downstream Event</th>
<th scope="col">Evidence</th>
<th scope="col">Quantitative Understanding</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/relationships/2653">Acetylcholinesterase (AchE) Inhibition</a></td>
<td>adjacent</td>
<td>Activation of Cyp2E1</td>
<td>Low</td>
<td>Moderate</td>
</tr>
<tr>
~~<td><a href="/relationships/2654">Activation of Cyp2E1</a></td>~~
<td><a href="/relationships/1512">Activation of Cyp2E1</a></td>
<td>adjacent</td>
~~<td>Oxidative Stress in Brain</td>~~
<td>Increase, Oxidative Stress </td>
<td>Moderate</td>
<td>Moderate</td>
</tr>
<tr>
~~<td><a href="/relationships/2655">Oxidative Stress in Brain</a></td>~~
<td><a href="/relationships/3312">Increase, Oxidative Stress </a></td>
<td>adjacent</td>
<td>N/A, Neurodegeneration</td>
<td>High</td>
<td>High</td>
</tr>
<tr>
<td><a href="/relationships/647">N/A, Neurodegeneration</a></td>
<td>adjacent</td>
<td>Decreased, Neuronal network function in adult brain</td>
<td>High</td>
<td>High</td>
</tr>
<tr>
<td><a href="/relationships/2656">Decreased, Neuronal network function in adult brain</a></td>
<td>adjacent</td>
<td>Sensory axonal peripheral neuropathy</td>
<td>Moderate</td>
<td>Low</td>
</tr>
<tr>
<td></td>
<td></td>
<td></td>
<td></td>
<td></td>
</tr>
<tr>
<td><a href="/relationships/2657">Sensory axonal peripheral neuropathy</a></td>
<td>non-adjacent</td>
<td>Increased Mortality</td>
<td>Low</td>
<td>Low</td>
</tr>
</tbody>
</table>
</div>
<h3>Stressors</h3>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Name</th>
<th scope="col">Evidence</th>
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</thead>
<tbody class="tbody-striped">
<tr>
<td>Paraoxon</td>
<td>Moderate</td>
</tr>
<tr>
<td>Methyl parathion</td>
<td>Moderate</td>
</tr>
<tr>
<td>Ethyl Parathion</td>
<td>Moderate</td>
</tr>
<tr>
<td>Organophosphates</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
<h4>Paraoxon</h4>
Paraoxon is an active metabolite of OP pesticide parathion which has been weaponized and used as a chemical-warfare agent that yields high mortality (Laxmikant 2014). Paraoxon is one of the most potent cholinesterase-inhibiting insecticides which is easily absorbed through skin and has been used to study acute and chronic effects of organophosphate intoxication (Deshpande LS et al., 2014). There is strong literature evidence demonstrating inhibition of AChE by paraoxon exposure leading to neurotoxicity. Paroxon inhibition of the enzyme AChE also potentially leads to enhanced glutamate release, diminished GABA uptake, oxidative damage, and neurodegeneration (Farizatto KLG et al., 2017). AChE inhibition and subsequent increased ACh levels can trigger seizures and cause neuronal and excitotoxic damage in the brain.  Asymptomatic low-level exposure to such anticholinesterase toxins can also leave the brain vulnerable or even cause it to exhibit neurological problems later in life. Paraoxon exposure initiates a pathogenic cascade involving seizure events and subsequent signs of damage including unique presynaptic vulnerability and associated behavioral deficits (Farizatto KLG et al., 2017).  Paraoxon-mediated synaptotoxicity is also associated with enhanced production of oxidative stress as well as integrin adhesion responses (Farizatto KLG et al., 2017).
<h4>Organophosphates</h4>
Attributes of OPs that produce the MIE and progression of the overall AOP.
</div>
<div id="overall_assessment">
<h2>Overall Assessment of the AOP</h2>
Exposure to OP toxicants is the major source of poisoning worldwide, which affecting approximately 3 million populations early, out of which nearly 15% die as a consequence of poisoning (Farizatto KLG et al., 2017; Eddleston et al., 2008). Exposure route of OP pesticide may be drinking contaminated water, breathing vapors of the toxicants, or direct exposure to a person’s skin with the toxicant. Stressor OPs causes inhibition of MIE (AChE) is well documented in literatures. OP pesticides like parathion and chlorpyrifos exercise their toxicity by irreversible inhibition of AChE (Amitai G et al., 1998). Irreversible inhibition of AChE by OPs in birds, insects, fish, and mammals causes neurotoxicity via characteristics cholinergic toxicity (Cao J et al., 2020; Pundir, C. S et al., 2012). AChE hydrolyses acetylcholine into acetic acid and choline, thus terminates the action of the neurotransmitter acetylcholine.  This hydrolysis is inhibited by OP pesticides as OP interfere with the breakdown of acetylcholine by binding to the AChE, which resulted in accumulation of acetylcholine in the nerve synapses and triggered interrupted neurotransmission (Thapa S et al., 2017). Thus OP-induced synaptotoxicity is directly associated with MIE (inhibition of AChE). Inhibition of AChE activates the expression of Cytochrome P450 2E1 i.e CYP2E1 (KE1) as reported in farm workers exposed with OP (Sharma RK et al., 2013). A correlation study between inhibited AChE and CYP2E1 induction in mouse brain is reported by Ma JQ et al., 2016. Enzymology study showed that AChE reactivator’s oxime were tested positive for their potential to inhibit CYP2E1 (Spicakova A et al., 2016; Veinlichova A et al., 2009). As previous study reported CYP2E1 a free enzyme with significant pro-oxidant activity is rich source of oxidative stress (Ma JQ, et al., 2016). Thus, in brain the expression of CYP2E1 results in the formation of oxygen radical intermediates and increased oxidative stress (KE2) in the astrocytes of CNS via JNK signaling (Schattenberg JM et al., 2014, Lu Y et al., 2008 Jin, M et al., 2013). Neurodegeneration are characterized by oxidative stress associated disorder with slow and gradual deterioration of structure and function of neurons (Uddin MS et al., 2020). Recent study reported that oxidative stress (KE2) mediated the neurodegeneration (KE3) via mitochondrial dysfunction and excitotoxicity (Uddin MS et al., 2020). Since the main source of oxidative stress in CNS is microglia and astrocytes thus oxidative stresses and neurodegeneration are associated together (Gandhi S et al., 2012). In vitro and in vivo study by Wakatsuki S, et al. (2015) revealed that oxidative stress induced two major pathways of neurodegeneration, neuronal apoptosis and axonal degeneration via phosphorylation dependent ZNFR1 signaling. Previous study suggested that in transgenic mouse model, neurological defects and network dysfunction are associated with neurological diseases (Palop et al., 2006). As per neuropathological inferences, neuroimaging technique, patients suffering from neurodegeneration and the supporting proof from transgenic animal models of neurodegeneration, it’s recommended that neurodegeneration is largely associated with decreased neural network function in adult brain. (aopwiki.org/relationships/647, Palop et al., 2007; Seeley WW et al., 2009). Thus neurodegeneration induced loss of neuronal network function in adult brain. Degeneration of injured axons is characteristics features of peripheral neuropathy as animal models demonstrated that blocking axon degeneration can prevent the development of peripheral neuropathy (DiAntonio. 2019). Axonal degeneration of peripheral sensory neurons is a main clinical index of peripheral sensory neuropathy (Liu H et al., 2017). Axonal degeneration induced peripheral neuropathy via self-destructive pathways and mechanistic study in mammalian model highlighted the three distinct pathways i.e wallerian degeneration, apoptosis-induced axon degeneration and pruning-induced axon degeneration (Geden MJ et al., 2016; DiAntonio et al., 2019). As per existing AOP relationship, impaired axonial transport leads to sensory axonal peripheral neuropathy (aopwiki.org/relationships/1835). The loss of neuronal network function in adult brain (KE4) leads to sensory axonal peripheral neuropathy (AO) with symptoms of numbness, lack of coordination, impairment of motor nerve, dizziness, burning sensation etc. (DiAntonio et al., 2019, Valek L et al., 2019, Persson AK et al., 2016,  Topp KS et al., 2000). Axonal neuropathy in childhood causes wasting, weakness and delayed development which impacts nervous system and other systemic manifestation, eventually causes mortality (Yiu EM et al., 2012). Peripheral neuropathy is generally irreversible disease with principle of treatment to prevent the progress of disease and related complications (Azhary H et al., 2010, Hicks CW et al., 2019). Since peripheral neuropathy is desperate group of diseases including several common and rare disease thus possess significant contribution in burden of disease and fatal disability in population (Martyn CN and Hughes RA, 1997). As per latest report Peripheral neuropathy was independently allied with mortality in the U.S. population, conclude that decreased sensation in the foot may be an unpredictable risk factor for death and the incident rate of mortality due to peripheral neuropathy is 34.3 % in the general population (Hicks CW et al., 2021). Consequently this evidence reveals the relation between AO (peripheral neuropathy) with enhanced mortality as terminal AO. Thus this AOP can open the route between MIE and AO that is important to scan the human health assessment specially the individual with potential pesticides exposure risk.
<h3>Domain of Applicability</h3>
Life Stage Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Life Stage</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Juvenile</td>
<td>High</td>
</tr>
<tr>
<td>Adults</td>
<td>Moderate</td>
</tr>
</tbody>
</table>
</div>
Taxonomic Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Term</th>
<th scope="col">Scientific Term</th>
<th scope="col">Evidence</th>
<th scope="col">Links</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Homo sapiens</td>
<td>Homo sapiens</td>
<td>Moderate</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=9606" target="_blank">NCBI</a></td>
</tr>
<tr>
<td>Rattus norvegicus</td>
<td>Rattus norvegicus</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=10116" target="_blank">NCBI</a></td>
</tr>
<tr>
<td>Mus musculus</td>
<td>Mus musculus</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=10090" target="_blank">NCBI</a></td>
</tr>
</tbody>
</table>
</div>
Sex Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sex</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Male</td>
<td>High</td>
</tr>
<tr>
<td>Female</td>
<td>Moderate</td>
</tr>
</tbody>
</table>
</div>
Life Stage Applicability
The key molecular target is the AChE enzyme, which appears to be available in all life stages of different species.
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<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:283px">
Life Stage
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:283px">
Evidence
</td>
</tr>
<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:none; vertical-align:top; width:283px">
Child
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:283px">
High
</td>
</tr>
<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:none; vertical-align:top; width:283px">
Adult
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:283px">
Moderate
</td>
</tr>
</tbody>
</table>
Taxonomic Applicability
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<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:148px">
Term
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:139px">
Scientific Term
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:139px">
Evidence
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:139px">
Links
</td>
</tr>
<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:none; vertical-align:top; width:148px">
Homo sapiens
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
Homo sapiens
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
Moderate
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
</td>
</tr>
<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:none; vertical-align:top; width:148px">
Rattus norvegicus
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
Rattus norvegicus
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
High
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
</td>
</tr>
<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:none; vertical-align:top; width:148px">
Mus musculus
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
Mus musculus
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
High
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:139px">
</td>
</tr>
</tbody>
</table>
Sex Applicability
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<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:283px">
Sex*
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:1px solid black; vertical-align:top; width:283px">
Evidence
</td>
</tr>
<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:none; height:25px; vertical-align:top; width:283px">
Female
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; height:25px; vertical-align:top; width:283px">
Moderate
</td>
</tr>
<tr>
<td style="border-bottom:1px solid black; border-left:1px solid black; border-right:1px solid black; border-top:none; vertical-align:top; width:283px">
Male
</td>
<td style="border-bottom:1px solid black; border-left:none; border-right:1px solid black; border-top:none; vertical-align:top; width:283px">
High
</td>
</tr>
</tbody>
</table>
*Study with 44 children for scanning the OP pesticide exposure risk witnessed differences for sex of the child, with male levels higher than female levels (Loewenherz C et al., 1997).
<h3>Essentiality of the Key Events</h3>
Rationale for essentiality calls:
<ul>
<li style="text-align:justify">MIE: Inhibition, AChE: AChE hydrolyses acetylcholine into acetic acid and choline, thus terminates the action of the neurotransmitter acetylcholine.  This hydrolysis is inhibited by OP pesticides as OP interfere with the breakdown of acetylcholine by binding to the AChE, which resulted in accumulation of acetylcholine in the nerve synapses and triggered interrupted neurotransmission (Thapa S et al., 2017). Previous studies with vertebrate and invertebrate validate the dependence of AChE activity to the dose of OP and increasing inhibition of AChE in dose dependent manner with OP as reported in fish, birds, nematodes, rodents and mollusk (<a href="https://aopwiki.org/events/12" style="color:blue; text-decoration:underline">https://aopwiki.org/events/12</a>). Inhibition of acetylcholine binding at the serine site results in an accumulation of acetylcholine in synapses with muscarinic and nicotinic receptors which resulting in unregulated excitation at junctions (https://aopwiki.org/events/10).</li>
<li style="text-align:justify">Key Event 1: Activation, CYP2E1: CYP2E1 can define as a P450 monooxygenase that activates the substrates by the addition of oxygen and producing an electrophilic metabolite (https://aopwiki.org/aops/220; Smith, et al. 2016). CYP2E1 in its catalytic cycle produce reactive oxygen species and expressed in the different part of human brain including cortex, cerebellum, hippocampus, thalamus and stratum and produce reactive oxygen species in its catalytic cycle. CYP2E1 is linked with oxidative damage of the brain (Jin, M et al., 2013). Activation of CYP2E1 is ultimately associated with the increase production of ROS (aopwiki.org/relationships/1726). Maneb and Paraquate a neurodegenerative pesticide enhanced the expression of CYP2E1 in male wistar rat which causes oxidative stress (Ahmad I et al., 2014). Activity of CYP2E1 is increasing with drugs, anesthetic agents, pesticides and related disorder (García-Suástegui WA et al., 2017) and linked with AChE inhibition as reported in farm worker (Sharma RK et al., 2013).  The highest level of CYP2E1 is found in the mitochondria and the endoplasmic reticulum of rat’s brain cells. Expression of CYP2E1 was found in the amygdala and prefrontal cortex in human brain (aopwiki.org/events/1508).</li>
<li style="text-align:justify">Key Event 2: Increased, oxidative stress in brain: The association between activation of CYP2E1 and the formation of ROS, which eventually leads to oxidative stress are well documented (<a href="https://aopwiki.org/relationships/1726" style="color:blue; text-decoration:underline">https://aopwiki.org/relationships/1726</a>). Study by Haorah et al. (2008) showed that CYP2E1 indeed produces ROS. Oxidative stress leads to neuronal apoptosis and neuronal degeneration by activating ZNRF1 via epidermal growth factor receptor (EGFR)–mediated phosphorylation (Wakatsuki S et al., 2015). ROS is closely associated to neuronal death in several neurological disorders including Parkinson’s and Alzheimer’s disease (Guglielmotto M et al., 2009). Acute injury of the brain including brain trauma and cerebral ischemia (Chen SD et al., 2011) or psychiatric disorders like autism, attention deficit, depression and schizophrenia (Michel TM et al., 2012) are also linked with ROS. ROS may target several different substrates and organelle of the cell like DNA, RNA oxidation, or lipid peroxidation (Gandhi S et al., 2012). ROS induced DNA mutation, DNA-protein crosslinks, DNA strand break and transformed purine and pyridine bases is documented (Gandhi S et al., 2012). </li>
<li style="text-align:justify">Key Event 3:  Neurodegeneration: Neurodegeneration is the loss of neuron cells in the brain and spinal cord. The loss of neurons can be define in term of ataxia and dementia i.e. functional loss and sensory dysfunction respectively. Each parts of the brain have their own individual function, thus the neurodegeneration is dependent to individual neuronal loss (Uttara, B et al., 2009). Neurodegeneration is a key aspect of a number of diseases called   “neurodegenerative diseases". All of these conditions lead to progressive brain damage and neurodegeneration due to decrease of neuronal function. Neurodegeneration and oxidative stress are inherently related phenomena, since microglia and astrocytes are the main sources of reactive oxygen species in CNS degenerative disorders thus oxidative stress in brain caused neurodegeneration (KE5) (Mendonca HR et al., 2020, Wakatsuki S et al., 2015, Mishra V et al., 2015, Kim M et al., 2019). Hence oxidative stress in brain is the requirement for downstream key event Neurodegeneration.</li>
<li style="text-align:justify">Key Event 2: Oxidative stress: The association between activation of CYP2E1 and the formation of ROS, which eventually leads to oxidative stress are well documented (<a href="https://aopwiki.org/relationships/1726" style="color:blue; text-decoration:underline">https://aopwiki.org/relationships/1726</a>). Study by Haorah et al. (2008) showed that CYP2E1 indeed produces ROS. Oxidative stress leads to neuronal apoptosis and neuronal degeneration by activating ZNRF1 via epidermal growth factor receptor (EGFR)–mediated phosphorylation (Wakatsuki S et al., 2015). ROS is closely associated to neuronal death in several neurological disorders including Parkinson’s and Alzheimer’s disease (Guglielmotto M et al., 2009). Acute injury of the brain including brain trauma and cerebral ischemia (Chen SD et al., 2011) or psychiatric disorders like autism, attention deficit, depression and schizophrenia (Michel TM et al., 2012) are also linked with ROS. ROS may target several different substrates and organelle of the cell like DNA, RNA oxidation, or lipid peroxidation (Gandhi S et al., 2012). ROS induced DNA mutation, DNA-protein crosslinks, DNA strand break and transformed purine and pyridine bases is documented (Gandhi S et al., 2012). </li>
<li style="text-align:justify">Key Event 3:  Neurodegeneration: Neurodegeneration is the loss of neuron cells in the brain and spinal cord. The loss of neurons can be define in term of ataxia and dementia i.e. functional loss and sensory dysfunction respectively. Each parts of the brain have their own individual function, thus the neurodegeneration is dependent to individual neuronal loss (Uttara, B et al., 2009). Neurodegeneration is a key aspect of a number of diseases called   “neurodegenerative diseases". All of these conditions lead to progressive brain damage and neurodegeneration due to decrease of neuronal function. Neurodegeneration and oxidative stress are inherently related phenomena, since microglia and astrocytes are the main sources of reactive oxygen species in CNS degenerative disorders thus oxidative stress in brain caused neurodegeneration (KE5) (Mendonca HR et al., 2020, Wakatsuki S et al., 2015, Mishra V et al., 2015, Kim M et al., 2019). Hence oxidative stress is the requirement for downstream key event Neurodegeneration.</li>
<li style="text-align:justify"> Key Event 4: Decreased, neuronal function in adult brain: The interaction of neurons is generally consists of a network of several axon terminals connected through synapses to dendrites on other neurons. Once neuron activated, resulted in firing of an electrochemical signal along the axon and it fires only if the total signal received is above firing threshold (aopwiki.org/events/618). In the brain, neurons create a network where the activity of one cell directly influences many others.  Neurotransmitters are released at synaptic transmission by presynaptic neuron which further activate the receptors of the postsynaptic neuron (aopwiki.org/events/618). Synaptic transmission relies on: the availability of the neurotransmitter and the binding of the postsynaptic receptor by the neurotransmitter. Once nerve impulse attains at the synapse, the neurotransmitters releases, which influence postsynaptic neuron. The postsynaptic neurons obtain inputs from both excitatory and inhibitory neurons. The excitatory and inhibitory stimuluses all together causing inhibition or "firing" and the inhibition of AChE resulted in decrease of neuronal function (Kolb and Whishaw, 2003). Previous study confirm the inhibition of AChE by OP pesticides paraoxon and chlorpyrifos and study further reported that environmental exposure of chlorpyrifos may leads to sensory peripheral neuropathy  in human (Amitai G et al., 1998). </li>
<li style="text-align:justify">Adverse Outcome: Sensory axonal peripheral neuropathy: The most common neurodegenerative syndrome affecting millions of patients worldwide is Peripheral neuropathy. Peripheral neuropathy affect the motor and autonomic systems are due to  axonal loss, consequently loss of neuronal function in adult brain leads to an important adverse outcome Sensory axonal peripheral neuropathy (DiAntonio et al., 2019, Valek L et al., 2019, Persson AK et al., 2016, Topp KS et al., 2000). Depending on the exposure level, some of the acute effects of OPs may leads to excessive secretions, cardiorespiratory depression and life threatening seizures. A number of long-term neurological and psychiatric consequences have been observed in survivors with acute OP exposure (Naughton SX et al., 2018). The symptoms may include sustained attention, motor impairments, psychotic episodes, depressed mood and cognitive flexibility (Steenland K et al., 1994; Pereira EF et al., 2014; Rosenstock et al., 1991; Dassanayake et al., 2007). Reversibility of neuropathy upon discontinuation of treatment is also reported (Brown, T et al., 1991). Peripheral neuropathies mostly affect sensory neurons in a length-dependent manner and therefore characterized by a stocking-and-glove distribution of the symptoms and numbness and paresthesia like   sensory symptoms (Forsyth, P.a., et al. 1997, aopwiki.org/events/1583). </li>
<li style="text-align:justify">Adverse Outcome Terminal: Increased, Mortality Increased mortality refers to an increase in the number of individuals dying in an experimental replicate group or in a population over a specific period of time (aopwiki.org/events/351). It has been estimated that there are 258,234 (plausible range 233,997 to 325,907) deaths from pesticide self-poisoning worldwide yearly, accounting for 30% (range 27% to 37%) of suicides globally (Gunnell D et al., 2007). Peripheral neuropathies are a disparate group of diseases their contribution to the burden of disease and disability is plausible, however there are limited epidemiological evidence that quantitatively connecting the previous AO to mortality rates with regard to the final adverse outcome (Taverner T et al., 2019, Martyn CN et al., 1997, Hughes RA et al., 1995). As per latest report Peripheral neuropathy was independently allied with mortality in the U.S. population, concluded that decreased sensation in the foot may be an unpredictable risk factor for death thus the incident rate of mortality due to peripheral neuropathy is 34.3 % in the general population (Hicks CW et al., 2021). Study in vertebrate and invertebrate showed that 70 to 80 % inhibition of AChE in brain leads to significant increase in mortality via accumulation of ACh (Russom CL et al., 2014). </li>
</ul>
<h3>Weight of Evidence Summary</h3>
"'Biological Plausibility"'
OP induced inhibition of AChE leads to accumulation of acetylcholine (ACh) at the cholinergic synaptic clefts, resulting in to long-term activation of the nicotinic and muscarinic ACh receptors (AChR) and overstimulation of cholinergic neurons with hyper excitation and seizures (Faria, M et al., 2015; Peña Llopis, S. & Pena, 2005). OP induced seizures can grow to status epilepticus causing severe damage of brain (Weissman, B. A. & Raveh, L et al., 2008). Inhibition of AChE is associated with wide range of adverse effect including fatality, hence it’s dependent to concentration and half-life of OP dose. Major adverse effects with accumulation of ACh in peripheral system includes glandular secretions, skeletal muscle twitching, smooth muscle contractions and flaccid paralysis, simultaneously centrally mediated impacts associated with learning, memory and behavioral impairments (<a href="https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf" style="color:blue; text-decoration:underline">https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf</a>).
Oxidative stress is the key mechanisms involved in OP induced neurotoxicity, which can caused by over-production of reactive oxygen species (ROS) in the electron transport system and metabolism of agents by cytochrome P450 (Farkhondeh T et al., 2020). Thus the oxidative stress is inducer of neuronal apoptosis and axonal degeneration. Since it activate the ZNRF1 by inducing epidermal growth factor receptor (EGFR)–mediated phosphorylation at the 103rd tyrosine residue thus the up-regulation of ZNRF1 activity by oxidative stress leads to neuronal apoptosis and Wallerian degeneration (Wakatsuki S et al., 2015). As per neuropathological outcomes and neuroimaging of patients suffering from neurodegeneration as well as complementary evidence from transgenic animal models of neurodegeneration, it has been recommended that neurodegeneration is related to neural network dysfunction (aopwiki.org/relationships/368; Palop et al., 2007b; Seeley WW et al., 2009). Neurodegeneration leads to impairment of retrograde axonal transport that prohibits the growth factor supply to long-range projection neurons, causing synapse loss and post-synaptic dendrite retraction that leads to decreases of the neuronal network (Seeley WW et al., 2009) (https://aopwiki.org/relationships/647). Defective axonal transport are the major cause for peripheral neuropathies as the length-dependent and distal neurologic deficits observed in patients with axonal loss, which are often linked to axonal transport defects ( https://aopwiki.org/relationships/1835 ; Rowinsky, E.K et al., 1995). Mutations linked to axonal transport are known cause of Charcot-Marie-Tooth disease (a peripheral neuropathy) (Zhao, C et al., 2001). Thus the function of axon survival and axon degeneration proteins play an important role in the mechanistic insight. Usually, the clinical presentation reflects an axonal peripheral neuropathy with glove-and-stocking distribution sensory loss, collective with the features indicative of nerve hyper excitability includes paresthesia, dysesthesia, and pain.  Symptoms like proprioceptive and motor effects may be prolonged, severe disabling and adversely affect activities of daily living and quality of life (Bhutani M et al., 2010).
"'Concordance of dose-response relationships:"'
Impairments in axonal transport could be detected even at concentrations that did not inhibit AChE activity and they were not blocked by cholinergic receptor antagonists (Naughton SX et al., 2018). Both neuronal culture and animal studies have reported that OP- induced axonal transport deficits as a potential non-cholinesterase mechanism for the long-term deleterious neurological effects (Naughton SX et al., 2021). Physostigmine was establish to strongly inhibit the purified eel AChE with an IC50 of 0.02 μM but not impaired axonal transport (Naughton SX et al., 2021).
"'Temporal concordance among the key events and adverse effect:"'
Sufficient literature evident that around 25 -32% of the US veterans deployed in Persian Gulf War was reported with chronic health symptoms like headache, respiratory problems, musculoskeletal pain and a number of neurological and neuropsychiatric illness including cognitive defects (Naughton SX et al., 2018; Sullivan et al., 2018), inline  with exposure of OP based inhibitors of AChE (Winkenwerder, 2003). Depending to exposure level, the effect of OP exposure may include cardiorespiratory depression, life threatening seizures and long term neurological and psychiatric consequences in survival including motor impairment (Naughton SX et al., 2018; Pereira et al., 2014). As per previous report the animal models have been largely appreciated to reveal the effects of anti- AChE abuses and their connection to brain damage in humans. <a href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5966299/#R14" style="color:blue; text-decoration:underline">Harrison et al., (2004)</a> establish that OP (Paraoxon) caused seizures in guinea pigs similar to those caused by the nerve gas soman in humans. Similarly, the anti-AChE strength of Paraoxon was similar in macaques and humans (<a href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5966299/#R41" style="color:blue; text-decoration:underline">Worek et al., 2011</a>). Moreover, <a href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5966299/#R33" style="color:blue; text-decoration:underline">Rosenberg et al., (2017)</a> showed that anti- AChE exposed macaques presented severe signs of toxicity such as fasciculations, miosis, salivation and convulsions including fatality in less than seven hours of application.
"'Consistency:"'
The cholinergic phase typically last within 48 hrs including medical emergency in intensive care unit (Senanayake N et al., 1987). OP induced inhibition of AChE caused accumulation of ACh at muscarinic sites and resulted in secretions, bronchoconstriction, blur vision and bradycardia. Accumulation of ACh at nicotinic sites triggered flaccid paralysis, insomnia, confusion, drowsiness convulsions, coma, and respiratory depression (PMCID: PMC6357250, EJIFCC. 1999). Peripheral neuropathy is the most common neurodegenerative disorder, caused by damaging to peripheral nerves and is an important cause of neuropathic pain including hyperalgesia, allodynia, and dysesthesias (DiAntonio et AL et al., 2019). Acute exposure of organophosphate induced delayed neuropathy is well reported which is characterized by distal degeneration of axons of CNS and PNS. Non excitability of the nerve with electromyographical signs of denervation has been noticed with progression of disease and the experimental date with human shows recovery in the young (Lotti M., 2005).  Transcutaneous intoxication with OP showed the nicotinic effect in young children (Pavlovic M., 2015). A study by Yonggang Li et al (2012) reported that Adult male Sprague Dawley rats treated with acute exposure of OP (diisopropylfluorophosphate) showed that almost all animals developed severe seizures and died within 30 minutes but with delayed neuronal injury model, animal survived and delayed neuronal injury was observed till 4-72 hrs (Li Y et al., 2011). Furthermore the role of oxidative stress in neuronal injury and oxidative stress-mediated protein damage in the brains of diisopropylfluorophosphate -intoxicated rats is also documented (Li Y et al., 2012).
"'Uncertainties, inconsistencies, and data gaps:"'
Cholinergic hyper stimulation which affect nervous system via AChE inhibition is very common mode of action of OP (Pope CN et al., 1999), simultaneously the mouse lacking AChE also showed hyper sensitive of OP via non AChE mechanisms of action (Duysen EG et al., 2001). Unfortunately, the very limited evidence are available for the measurement of AChE inhibition in peripheral neural tissues or neuro-effector junctions. Reductions in neural AChE activity may not always associated with obvious clinical signs because critical functions of those specific neurons may not be sufficiently evaluated to identify associated changes or tolerance developed. The time at which potential functional effects are evaluated may also contribute to an apparent lack of concordance between functional effects and cholinesterase inhibition. Thus it is difficult to determine, with accuracy or consistently, the degree of cholinesterase inhibition that will cause specific physiological or behavioral changes (<a href="https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf" style="color:blue; text-decoration:underline">https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf</a>). The existing evidence mostly focused on the whole brain AChE activity, but not usually regional brain measurements, or time-course data, mainly with acute exposures. Thus this is a major limitation, and  also the distribution of cholinergic pathways, their concentration and molecular form of AChE in different brain regions is not uniform. Thus, whole brain measurements of AChE inhibition may tell little or no change in activity, while masking significant changes in specific brain regions linked with particular cholinergically-mediated functions can tell more (<a href="https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf" style="color:blue; text-decoration:underline">https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf</a>).
<h3>Quantitative Consideration</h3>
OP is commonly used as insecticides because it inhibits the AChE of insects (Tomlin C et al., 1994) and the same characteristic mode of cholinergic toxicity has been reported in human (Taylor P et al., 1996). Previous study showed that OP is more effective inhibitor of AChE than neuropathy target esterage (NTE) which causing delayed polyneuropathy at higher dose (Lotti M et al., 1992; Moretto A et al., 1998), simultaneously patients with low level repeated exposure of OP developed sensory neuropathy (Kaplan JG et al., 1993; Moretto A et al., 1998).  Inhibition of AChE (MIE) is considered a vital event in the mechanism of cholinergic toxicity, the AChE-inhibiting OP causes a broad range of adverse effects including sensory, cognitive, and psychological effects (Reigart, R. and Roberts, 1999). Decreasing AChE level and increasing CYP2E1 (KE1) is reported in farm worker (Sharma RK et al., 2013). CYP2E1-induced oxidative stress (KE2) (Schattenberg JM et al., 2014) causes neurodegeneration (KE3) (Gandhi S et al., 2012) that leads to dysfunction of neuronal function (Palop et al., 2006). Subsequently, the loss of neuronal network function (KE4) leads to an adverse outcome of sensory axonal peripheral neuropathy (AO) and the symptoms may include lack of coordination, impairment of motor nerve, dizziness, burning sensation, numbness etc. (DiAntonio et al., 2019). This desperate group of diseases due to peripheral neuropathy causes fatal disability and mortality (AO) in population (Martyn CN and Hughes RA, 1997). As per latest report Peripheral neuropathy was self-sufficiently allied with mortality in the U.S. population, concluded that decreased sensation in the foot may be an unpredictable risk factor for death and the rate of mortality associated with peripheral neuropathy is 34.3 % in the general population (Hicks CW et al., 2021). Thus clinical symptoms with behavioral or physiological effects is the most direct evidence of the potential adverse consequences of human exposure to anticholinesterase pesticides like OP (<a href="https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf" style="color:blue; text-decoration:underline">https://www.epa.gov/sites/production/files/2015-07/documents/cholin.pdf</a>).
</div>
<div id="considerations_for_potential_applicaitons">
<h2>Considerations for Potential Applications of the AOP (optional)</h2>
The potential application of this AOP includes risk assessment in predictive modeling of OP pesticide toxicity via AChE dependent pathways. Thus this AOP is an attempt to create the mechanism of organophosphorus (OP) pesticides induced sensory peripheral neuropathy and mortality as an adverse outcome. Supplementary evidence may help this AOP to fully elucidate the mechanistic approach and the neurotoxic potential of OP pesticide.
</div>
<div id="references">
<h2>References</h2>
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</div>
<div id="appendicies">
<h2>Appendix 1</h2>
<h3>List of MIEs in this AOP</h3>
<h4><a href="/events/12">Event: 12: Acetylcholinesterase (AchE) Inhibition</a></h4>
<h5>Short Name: AchE Inhibition</h5>
<h4>Key Event Component</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Process</th>
<th scope="col">Object</th>
<th scope="col">Action</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>acetylcholinesterase activity</td>
<td>acetylcholinesterase</td>
<td>decreased</td>
</tr>
</tbody>
</table>
</div>
<h4>AOPs Including This Key Event</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP ID and Name</th>
<th scope="col">Event Type</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/16">Aop:16 - Acetylcholinesterase inhibition leading to acute mortality</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/281">Aop:281 - Acetylcholinesterase Inhibition Leading to Neurodegeneration</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/312">Aop:312 - Acetylcholinesterase Inhibition leading to Acute Mortality via Impaired Coordination & Movement</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/405">Aop:405 - Organo-Phosphate Chemicals induced inhibition of AChE leading to impaired cognitive function</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/450">Aop:450 - Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
~~<td><a href="/aops/471">Aop:471 - Various neuronal effects induced by elavl3, sox10, and mbp</a></td>~~
<td><a href="/aops/471">Aop:471 - Neuron defect induced early behavioral change</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/559">Aop:559 - Inhibition of acetylcholinesterase (AChE) leading to arrhythmias</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
</tbody>
</table>
</div>
<h4>Stressors</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Name</th></tr>
</thead>
<tbody>
<tr><td>Organophosphates</td></tr>
<tr><td>N-methyl Carbamates</td></tr>
</tbody>
</table>
</div>
<h4>Biological Context</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Level of Biological Organization</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>Cellular</td></tr>
</tbody>
</table>
</div>
<h4>Cell term</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Cell term</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>eukaryotic cell</td></tr>
</tbody>
</table>
</div>
<h4>Organ term</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Organ term</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>nervous system</td></tr>
</tbody>
</table>
</div>
~~<h3>Evidence for Perturbation by Stressor</h3>~~
~~<h4>Overview for Molecular Initiating Event</h4>~~
~~<ul>~~
<li>Organophosphate and carbamate insecticides are prototypical AChE inhibitors. The OP and carbamate pesticides were synthesized specifically to act as inhibitors of AChE, with OPs developed from early nerve agents (e.g., sarin) and carbamate pesticides based on the natural plant alkaloid physostigmine (Ecobichon 2001).</li>
<li>A positive and significant correlation between the log of the Eserine IC50 (in vitro) for AChE inhibition and the log Km value for the AChE in the fish and crustacea species has been reported, explaining 92% of the variation in enzyme inhibition (Monserrat and Bianchini, 2001). Similar success was found in relating the rate constants for inhibition of AChE in housefly and the pseudo first-order hydrolysis rate constant for active forms of OPs (Fukuto 1990).</li>
~~</ul>~~
~~<ul>~~
<li>The open literature includes many studies on vertebrate and invertebrate species that demonstrate a clear dependence of AChE activity on the dose or concentration of the substance with increased concentrations leading to an increase in the inhibition of AChE (e.g., fish ( Karen et al., 2001), birds (Hudson et al., 1984 (see dimethoate and disulfoton), Grue and Shipley 1984; and Al-Zubaidy et al., 2011); cladocera (Barata et al., 2004); nematodes (Rajini et al., 2008); rodents (Roberts et al., 1988; and mollusk (Bianco et al., 2011)).</li>
<li>The open literature includes many studies on vertebrate and invertebrate species that demonstrate a clear relationship between increasing AChE inhibition as duration of exposure increases (e.g., amphibians ( Venturino et al., 2001); fish (Rao 2008; Ferrari et al., 2004); insects (Rose and Sparks 1984); birds (Ludke 1985; Grue and Shipley 1984); annelids (Reddy and Rao 2008); cladocera (Barata et al., 2004)).</li>
<li>Rao et al. 2008 exposed the estuarine fish Oreochromis mossambicus to a 24 h LC50 concentration of chlorpyrifos and reported that it took 6 hr to reach >40% AChE inhibition and 24 hr to reach 90% AChE inhibition. It took >100 days to recover to normal AChE levels when fish were placed in clean water.</li>
<li>A time course study of earthworms (Eisenis foetida) exposed to the 48 hr LC50 of profenofos found a significant relationship (between increases in percent inhibition of AChE and increase in time of exposure from 8-48 hrs (Chakra Reddy and Rao 2008).</li>
~~</ul>~~
~~<h4>Organophosphates</h4>~~
The MIE, AChE inhibition, is triggered via electrostatic interaction at the anionic site of the enzyme and binding with the serine hydroxyl group at the esteratic site of AChE (Wilson 2010; Fukuto 1990).  Organophosphate pesticides attach to the AChE via an ‘irreversible’ phosphorylation of the enzyme. Note that the use of the term ‘irreversible’ relates to the relative rate at which the phosphorylation occurs since acetylcholine and organophosphates both form covalent bonds with the enzyme. The phosphorylated form may persist for up to a week if it has undergone an ‘aging’ process; i.e., the organophosphate has undergone a dealkylation, thereby strengthening the bond between the OP and the enzyme (Mileson et al. 1998; Kropp and Richardson 2003; Sogob and Vilanova 2002).  Certain steric and electronic requirements must be met in order for an organophosphate to inhibit AChE. For instance, organophosphates require a leaving group sufficiently electronegative to ensure the formation of a reactive electrophile (Fukuto 1990; Sogob and Vilanova 2002; Schűűrmann 1992). Substances with subtle structural differences can result in major changes in AChE inhibition capabilities.  For example, OPs having identical R and R1 alkyl groups display decreasing AChE inhibition as the R / R1 carbon chain increases from a single carbon to a propyl moiety, with the latter resulting in an ineffective AChE inhibitor (Fukuto 1999).
Metabolism also plays an important role in the potency of organophosphates.  For instance, organophosphates in the phosphorothionate and phosphorodithioate families (i.e., P=S) must undergo metabolic activation, via cytochrome P450-based monoxygenases, to an oxon form in order to inhibit AChE effectively (Fukuto 1990).
~~ ~~
~~<table>~~
~~<tbody>~~
~~<tr>~~
~~<td>~~
~~Base Structure (OP)~~
~~</td>~~
~~<td>~~
~~Configuration~~
~~</td>~~
~~</tr>~~
~~<tr>~~
~~<td>~~
<img src="https://lh5.googleusercontent.com/qiC4hNQAdAEfDUQ5LQIjFh5X9jW4Xi-I-MNblu0nh1WffQtgnigmg-elmu5q4rTdpZyeSBLcUBhPYQxHCRlRRgXoFuA4bmq2xio3RfM9OlE38n6dYa3F4OXb1BBKPSwNiZrASgQJ" style="height:135px; width:158px" />
~~</td>~~
~~<td>~~
~~R: A simple alkyl (e.g., methyl or ethyl group) or aryl group bonded to either an oxygen or sulfur that is directly bonded to the phosphorous; ~~
~~R1:  Methoxy, ethoxy, ethyl, phenyl, amino, substituted amino, or alkylthio group;~~
~~X:  Leaving group that is or contains an electronegative moiety (e.g., phenoxy or aromatic group containing hetero atoms, substituted thioalkyl, or substituted alkoxy groups);~~
~~O: Oxons are direct acting~~
~~S: Thiophosphates require metabolic activation to the oxon form in order to be active AChE inhibitors~~
~~</td>~~
~~</tr>~~
~~</tbody>~~
~~</table>~~
~~ ~~
Evidence exists that immature life stages in mammals and birds may be more sensitive to organophosphate pesticides (see Grue et al., 1997; Grue et al., 1983; Grue et.al; 1981). It has been suggested that this may be related to the amount of pesticide ingested in relation to body size (Ludke et al, 1975), but there is direct data in rats showing that differential sensitivity to OPs is determined at least in part by inadequate detoxification in the young (Moser, 2011). OP detoxification is highly dependent on enzymes such as A-esterases (paraoxonases, PON) and carboxylesterases (e.g., Benke and Murphy, 1974; Furlong, 2007; Sterri et al., 1985; Vilanova and Sogorb, 1999), which are present at lower levels in the young (e.g., Chanda et al., 2002; Mendoza, 1976; Mortensen et al., 1996; Moser et al., 1998).
~~~~
~~<h4>N-methyl Carbamates</h4>~~
Carbamates trigger AChE inhibition through electrostatic interactions at the enzyme’s anionic site and binding with the serine hydroxyl group at the esteratic site (Wilson 2010; Fukuto 1990). Carbamates, which were originally based on the plant alkaloid physostigmine, attach to the AChE via a ‘reversible’ carbamylation. Note that the use of the term ‘reversible’ relates to the relative rate at which the carbamylation occurs since acetylcholine and carbamates both form covalent bonds with the enzyme. Certain steric and electronic requirements, as well as the leaving group on the pesticide, are critical to the likelihood that the methyl-carbamate will inhibit AChE (See Figure).
Metabolism also plays a role in the potency of some carbamates.  Select procarbamates require metabolism to form an active AChE inhibitor (e.g., carbosulfan must be metabolized to carbofuran), or are made more potent via metabolism (e.g., aldicarb oxidation to the more toxic sulfoxide form) (Sogob and Vilanova 2002; Stenersen 2004).
~~ ~~
~~ ~~
~~<table>~~
~~<tbody>~~
~~<tr>~~
~~<td>~~
~~Base Structure (Carbamate)~~
~~</td>~~
~~<td>~~
~~Configuration~~
~~</td>~~
~~</tr>~~
~~<tr>~~
~~<td>~~
<img src="https://lh4.googleusercontent.com/7D5LQOwCuGSKbQ0_dR4TKpo1XZrl02VGQ5R6zOFVY3g76gLTvqCBVE-qzaHaoNzTAisenSO8jDeKkLs1k5pKIGQnPOUp3wzslSY6ENV9gqLJl8H6wo5HkZkvYIb2KtmmhKw_sv94" style="height:158px; width:183px" />
~~</td>~~
~~<td>~~
~~R1: Methyl group~~
~~R2:  Hydrogen group;~~
~~XR3:  Leaving group that is an aryloxy or oxime;~~
~~pKa:  For oxime and substituted phenols, a pKa in the range of 10 ensures carbamylation;~~
~~Carbamates must ‘fit’ in the enzyme active site to be effective inhibitors~~
~~</td>~~
~~</tr>~~
~~</tbody>~~
~~</table>~~
~~ ~~
~~~~
<h4>Domain of Applicability</h4>
Life Stage Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Life Stage</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>All life stages</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
Sex Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sex</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Unspecific</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
AChE is present in all life stages of both vertebrate and invertebrate species (Lu et al 2012).
<ul>
<li dir="ltr">
Acetylcholinesterase associated with cholinergic responses in most insects is coded by the ace1 gene and in vertebrates by the ace gene (Lu et al 2012; Taylor 2011.
</li>
<li dir="ltr">
Plants have AChE but it is most likely involved in regulation of membrane permeability and the ability of a leaf to unroll (Tretyn and Kendrick 1991).
</li>
</ul>
<ul>
<li dir="ltr">
The primary amino acid sequence of the AChE enzyme is relatively well conserved across vertebrate and invertebrate species, suggesting that chemicals are likely to interact with the enzyme in a similar manner across a wide range of animals. From the sequence similarity analyses, the taxonomic domain of applicability of this MIE likely includes species belonging to many lineages, including branchiopoda (crustaceans, e.g., daphnids), insecta (insects), arachnida (arachnids, e.g., spiders, ticks, scorpions), cephalopoda (molluscans, e.g., octopods, squids), lepidosauria (reptiles, e.g., snakes, lizards), chondrichthyes (cartilaginous fishes, e.g., sharks), amphibia (amphibians), mammalian (mammals), aves (birds), actinopterygii (bony fish), ascidiacea (sac-like marine invertebrates), trematoda (platyhelminthes, e.g., flatworms), and gastropoda (gastropods, e.g., snails and slugs) Species within these taxonomic lineages and others are predicted to be intrinsically susceptible to chemicals that target functional orthologs of the daphnid AChE (Russom, 2014).
</li>
<li dir="ltr">
Advanced computational approaches such as crystal structures of the enzyme and transcriptomics have provided empirical evidence of the enzyme structure, relevant binding sites, and function across species (Lushington et al., 2006; Lu et al., 2012; Wallace 1992).
</li>
</ul>
Studies have found that AChE activity increases as the organism develops.
<ul>
<li dir="ltr">
Prakesh and Kaur 1982 looked at AChE inhibition across three insect species; controls and those exposed to DDVP. They saw little difference in the larval stages but did see increased inhibition in pupal and adult stages (greatest inhibition).
</li>
<li dir="ltr">
Karanth and Pope 2003 looked at AChE and acetylcholine synthesis in rat striatum in controls and animals exposed to 0.3 and 1 times the maximum tolerated dose. Although these doses are below the lethal concentrations and they mention that not observed cholinergic responses were observed, they do provide differences related to life stages of the rodents.
</li>
<li dir="ltr">
Grue et al 1981 present baseline (no toxicity exposure) in wild starlings (both sexes) of brain cholinesterase and found activity increased as birds aged from 1-20 days until it reached a steady state at adulthood.
</li>
<li dir="ltr">
A study with Red Flour Beetle found that the gene associated with cholinergic functions (Ace1) was expressed at all life-stages, with increases as the organism developed from egg to larva to pupa to adult. (Lu et al., 2012 cited in Russom et al 2014.)
</li>
<li dir="ltr">
In mammals and birds, studies have determined that skeletal muscles of immature birds and mammals contain both butyrylcholinesterase and AChE, with butyrylcholinesterase decreasing and AChE increasing as the animal develops (Tsim et al. 1988; Berman et al, 1987).
</li>
<li dir="ltr">
Another study found that changes in AChE within the developing pig brain were dependent on the area of the brain, and life stage of the animal, with significant decreases in activity within the pons and hippocampus from birth to 36 months, and no significant change in activity in the cerebellum, where activity increased up to four months of age, leveling off thereafter (Adejumo and Egbunike, 2004).
</li>
</ul>
<h4>Key Event Description</h4>
"Acetylcholinesterase is found primarily in blood, brain, and muscle, and regulates the level of the neurotransmitter ACh [acetylcholine] at cholinergic synapses of muscarinic and nicotinic receptors. Acetylcholinesterase features an anionic site (glutamate residue), and an esteratic site (serine hydroxyl group) (Wilson, 2010; Soreq, 2001). In response to a stimulus, ACh is released into the synaptic cleft and binds to the receptor protein, resulting in changes to the flow of ions across the cell, thereby signaling nerve and muscle activity. The signal is stopped when the amine of ACh binds at the anionic site of AChE, and aligns the ester of ACh to the serine hydroxyl group of the enzyme. Acetylcholine is subsequently hydrolyzed, resulting in a covalent bond with the serine hydroxyl group and the subsequent release of choline, followed by a rapid hydrolysis of the enzyme to form free AChE and acetic acid (Wilson, 2010; Soreq, 2001)." [From Russom et al. 2014. Environ. Toxicol. Chem. 33: 2157-2169]
Molecular target gene symbol: ACHE
KEGG enzyme: EC 3.1.1.7
<h4>How it is Measured or Detected</h4>
<ul>
<li>Direct measures of AChE activity levels can be made using the modified Ellman method, although selective inhibitors that remove other cholinesterases not directly related to cholinergic responses (e.g., butyrylcholinesterase) are required [45,46].</li>
<li>Radiometric methods have been identified as better for measuring inhibition because of carbamylation (carbamate exposure) [20,46,47].</li>
<li>TOXCAST: NVS_ENZ_hAChE</li>
<li>A direct measure of cholinesterase activity levels can be made within the relevant tissues after in vivo exposure, specifically the brain as well as red blood cells in mammals. Some analytical methods used to measure cholinesterase activity may not distinguish between butyrylcholinesterase, which is found with AChE in plasma and some skeletal and muscle tissues. Although the structure of butyrylcholinesterase is very similar to AChE, its biological function is not clear, and its activity is not associated with cholinergic response covered under this AOP (Lushington et al., 2006). Therefore experimental procedures used to measure cholinesterase as well as the tissue analyzed should be considered when evaluating studies reporting AChE inhibition (Wilson 2010; Wilson and Henderson 2007). For measuring AChE levels, the Ellman method is recommended with some modifications (Ellman et al., 1961; Wilson et al., 1996) while radiometric methods have been identified as better for measuring inhibition due to carbamylation (carbamate exposure) (see Wilson 2010; Wilson et al., 1996; Johnson and Russell 1975).</li>
</ul>
<ul>
<li>In order to effectively bind to the AChE enzyme, thion forms of OPs (i.e., RO)3P=S) must first undergo a metabolic activation via mixed function oxidases to yield the active, oxon form (Fukuto 1990). Estimating the potential toxicity in whole organisms based on in vitro data may be problematic since metabolic activation may be required (e.g., phosphorothionates) and may not be reflected in the in vitro test result (Guo et al. 2006; Lushington et al. 2006).</li>
<li>Typically, carbamates do not require metabolic activation in order to bind to the enzyme, although some procarbamates (e.g., carbosulfan) have been developed that are not direct inhibitors of AChE, but take advantage of metabolic distinctions between taxa, resulting in a toxic form in invertebrates (e.g., carbofuran) but not vertebrate species (Stenersen 2004). Therefore in vitro assays measuring AChE inhibition for procarbamates in invertebrate species will not account for metabolic activation and therefore may not represent the actual enzyme activity.</li>
</ul>
<h4>References</h4>
<ul>
<li dir="ltr">
Augustinsson KB. 1957. Assay methods for cholinesterases. Methods of Biochemical Analysis, Vol 5, Interscience Publishers, Inc., New York, NY, USA, pp 1-63.
</li>
<li dir="ltr">
Ecobichon, D.J. 2001. Toxic effects of pesticides. In: C.D. Klaassen (Ed.), Casarett and Doull’s Toxicology: The Basic Science of Poisons; Sixth Edition. (pp. 763-810). McGraw-Hill, New York, NY.
</li>
<li dir="ltr">
Ellman GL, Courtney KD, Andres V Jr, Featherstone RM. 1961. A new and rapid colormetric determination of acetylcholinesterase activity. Biochem Pharmacol 7:88-95.
</li>
<li dir="ltr">
Fukuto, TR. 1990. Mechanism of action of organophosphorus and carbamate insecticides. Environ Health Perspect. 87:245-254.
</li>
<li dir="ltr">
Guo, J.-X., J.J.-Q. Wu, J.B. Wright, and G.H. Lushington. 2006. Mechanistic insight into acetylcholinesterase inhibition and acute toxicity of organophosphorus compounds: A molecular modeling study. Chem. Res. Toxicol. 19: 209-216.
</li>
<li dir="ltr">
Johnson CD, Russell RL. 1975. A rapid, simple radiometric assay for cholinesterase suitable for multiple determinations. Anal Biochem 64:229-238.
</li>
<li dir="ltr">
Kropp, T.J., and Richardson, R.J. 2003. Relative inhibitory potencies of chlorpyrifos oxon, chlorpyrifos methyl oxon, and mipafox for acetylcholinesterase versus neuropathy target esterase. J. Toxicol. Environ.l Health, Part A, 66:1145–1157.
</li>
<li dir="ltr">
Lu Y, Park Y, Gao X, Zhang X, Yoo J, Pang X-P, Jiang H, Zhu KY. 2012. Cholinergic and non-cholinergic functions of two acetylcholinesterase genes revealed by gene-silencing in Tribolium castaneum. Sci Rep 2:1-7.
</li>
<li dir="ltr">
Ludke JL, Hill EF, Dieter MP. 1975. Cholinesterase (ChE) response and related mortality among birds fed ChE inhibitors. Arch Environ ContamToxicol 3:1–21.
</li>
<li dir="ltr">
Lushington, G.H., J-X. Guo, and M.M. Hurley. 2006. Acetylcholinesterase: Molecular modeling with the whole toolkit. Curr. Topics Medic. Chem. 6: 57-73.
</li>
<li dir="ltr">
Mileson, BE, Chambers JE, Chen WL, Dettbarn W, Ehrich M, Eldefrawi AT, Gaylor DW, Hamernik K, Hodgson E, Karczmar AG, Padilla S, Pope CN, Richardson RJ, Saunders DR, Sheets LP, Sultatos LG, Wallace KB.  1998. Common mechanism of toxicity: A case study of organophosphorus pesticides. Toxicol Sci 41:8-20.
</li>
<li dir="ltr">
Moser, Virginia C. 2011. “Age-Related Differences in Acute Neurotoxicity Produced by Mevinphos, Monocrotophos, Dicrotophos, and Phosphamidon.” Neurotoxicology and Teratology 33 (4): 451–57.<a href="https://doi.org/10.1016/j.ntt.2011.05.012"> https://doi.org/10.1016/j.ntt.2011.05.012</a>.
</li>
<li dir="ltr">
Monserrat, J.M. and A. Bianchini. 2001. Anticholinesterase effect of eserine (physostigmine) in fish and crustacean species. Braz. Arch. Biol. Technol. 44(1): 63-68.
</li>
<li dir="ltr">
Russom, Christine L., Carlie A. LaLone, Daniel L. Villeneuve, and Gerald T. Ankley. 2014. “Development of an Adverse Outcome Pathway for Acetylcholinesterase Inhibition Leading to Acute Mortality.” Environmental Toxicology and Chemistry 33 (10): 2157–69.<a href="https://doi.org/10.1002/etc.2662"> https://doi.org/10.1002/etc.2662</a>.
</li>
<li dir="ltr">
Schűűrmann G. 1992. Ecotoxicology and structure-activity studies of organophosphorus compounds. Rational Approaches to Structure, Activity, and Ecotoxicology of Agrochemicals, CRC Press, Boca Raton, FL, USA pp 485-541
</li>
<li dir="ltr">
Sogob MA, Vilanova E. 2002. Enzymes involved in the detoxification of organophosphorus, carbamate and pyrethroid insecticides through hydrolysis. Toxicol Lett 128:215-228.
</li>
<li dir="ltr">
Soreq H, Seidman S. 2001. Acetylcholinesterase -- New roles for an old actor. Nature Reviews Neurosci 2:294-302.
</li>
<li dir="ltr">
Stenersen, J. 2004. Specific enzyme inhibitors. In: Chemical Pesticides: Mode of action and toxicology. (41 p). CRC Press, Boca Raton, FL.
</li>
<li dir="ltr">
Taylor P. 2011. Anticholinesterase agents. Goodman and Gilman’s The Pharmacological Basis of Therapeutics, 12th ed, McGraw Hill, New York, NY, USA, pp 255-276.
</li>
<li dir="ltr">
Tretyn A, Kendrick RE. 1991. Acetylcholine in plants: Metabolism and mechanism of action. Bot Rev 57:33-73.
</li>
<li dir="ltr">
Wilson BW, Padilla S, Henderson JD, Brimijoin S, Dass PD, Elliot G, Jaeger B, Lanz D, Pearson R, Spies R. 1996. Factors in standardizing automated cholinesterase assays. J Toxicol Environ Health 48:187-195.
</li>
<li dir="ltr">
Wilson, B.W. and J.D. Henderson. 2007. Determination of cholinesterase in blood and tissue. Current Protocols in Toxicology 12.13.1-12.13.16.
</li>
<li dir="ltr">
Wilson BW. 2010. Cholinesterases. Hayes’ Handbook of Pesticide Toxicology, 3rd ed, Vol 2. Elsevier, Amsterdam, The Netherlands, pp 1457-1478.
</li>
</ul>
<h3>List of Key Events in the AOP</h3>
<h4><a href="/events/1391">Event: 1391: Activation of Cyp2E1</a></h4>
<h5>Short Name: Activation of Cyp2E1</h5>
<h4>AOPs Including This Key Event</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP ID and Name</th>
<th scope="col">Event Type</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/220">Aop:220 - Cyp2E1 Activation Leading to Liver Cancer</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/450">Aop:450 - Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>KeyEvent</td>
</tr>
</tbody>
</table>
</div>
<h4>Stressors</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Name</th></tr>
</thead>
<tbody>
<tr><td>Chloroform</td></tr>
<tr><td>Acetaminophen</td></tr>
<tr><td>furan</td></tr>
<tr><td>Ethanol</td></tr>
<tr><td>acetone</td></tr>
</tbody>
</table>
</div>
<h4>Biological Context</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Level of Biological Organization</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>Molecular</td></tr>
</tbody>
</table>
</div>
~~<h3>Evidence for Perturbation by Stressor</h3>~~
~~<h4>Overview for Molecular Initiating Event</h4>~~
A variety of substrates have been described (Lieber 1997, Tanaka, et al. 2000). There are >85 known Cyp2E1 substrates. They are low molecular weight compounds, including: molecular oxygen, acetone <!--[if supportFields]><span style='font-size:11.0pt;
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~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{839 Bondoc,F.Y. 1999}}<span~~
~~style='mso-element:field-separator'><![endif]-->(Bondoc, et al. 1999)<!--[if supportFields]><span~~
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~~EN-US;mso-bidi-language:AR-SA'><![endif]-->, acetaminophen <!--[if supportFields]><span style='font-size:11.0pt;~~
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~~mso-fareast-font-family:Calibri;mso-fareast-theme-font:minor-latin;mso-hansi-theme-font:~~
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~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{680 Lee,S.S. 1996; 835~~
~~Zaher,H. 1998}}<![endif]-->(Lee, et al. 1996, Zaher, et al. 1998)<!--[if supportFields]><span style='font-size:11.0pt;~~
~~line-height:115%;font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;~~
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~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-end'><![endif]-->, carbon tetrachloride <!--[if supportFields]><span style='font-size:11.0pt;~~
~~line-height:115%;font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;~~
~~mso-fareast-font-family:Calibri;mso-fareast-theme-font:minor-latin;mso-hansi-theme-font:~~
~~minor-latin;mso-bidi-font-family:"Times New Roman";mso-bidi-theme-font:minor-bidi;~~
~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{838 Wong,F.W. 1998}}<span~~
~~style='mso-element:field-separator'><![endif]-->(Wong, et al. 1998)<!--[if supportFields]><span~~
~~style='font-size:11.0pt;line-height:115%;font-family:"Calibri","sans-serif";~~
~~mso-ascii-theme-font:minor-latin;mso-fareast-font-family:Calibri;mso-fareast-theme-font:~~
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~~mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:~~
EN-US;mso-bidi-language:AR-SA'><![endif]-->, pyrazole, vinyl chloride, furan, chloroform, ethanol <!--[if supportFields]><span style='font-size:11.0pt;
~~line-height:115%;font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;~~
~~mso-fareast-font-family:Calibri;mso-fareast-theme-font:minor-latin;mso-hansi-theme-font:~~
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~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{848 Bardag-Gorce,F.~~
~~2000}}<![endif]-->(Bardag-Gorce, et al. 2000)<!--[if supportFields]><span~~
~~style='font-size:11.0pt;line-height:115%;font-family:"Calibri","sans-serif";~~
~~mso-ascii-theme-font:minor-latin;mso-fareast-font-family:Calibri;mso-fareast-theme-font:~~
~~minor-latin;mso-hansi-theme-font:minor-latin;mso-bidi-font-family:"Times New Roman";~~
~~mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:~~
~~EN-US;mso-bidi-language:AR-SA'><![endif]-->, benzene <!--[if supportFields]><span style='font-size:11.0pt;~~
~~line-height:115%;font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;~~
~~mso-fareast-font-family:Calibri;mso-fareast-theme-font:minor-latin;mso-hansi-theme-font:~~
~~minor-latin;mso-bidi-font-family:"Times New Roman";mso-bidi-theme-font:minor-bidi;~~
~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{840 Powley,M.W. 2001}}<span~~
~~style='mso-element:field-separator'><![endif]-->(Powley and Carlson 2001)<!--[if supportFields]><span~~
~~style='font-size:11.0pt;line-height:115%;font-family:"Calibri","sans-serif";~~
~~mso-ascii-theme-font:minor-latin;mso-fareast-font-family:Calibri;mso-fareast-theme-font:~~
~~minor-latin;mso-hansi-theme-font:minor-latin;mso-bidi-font-family:"Times New Roman";~~
~~mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:~~
~~EN-US;mso-bidi-language:AR-SA'><![endif]-->, acrylonitrile (El Hadri, et al. 2005)<!--[if supportFields]><span~~
~~style='font-size:11.0pt;line-height:115%;font-family:"Calibri","sans-serif";~~
~~mso-ascii-theme-font:minor-latin;mso-fareast-font-family:Calibri;mso-fareast-theme-font:~~
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~~mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:~~
~~EN-US;mso-bidi-language:AR-SA'><![endif]-->, trichloroethylene <!--[if supportFields]><span style='font-size:11.0pt;line-height:115%;~~
~~font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;mso-fareast-font-family:~~
~~Calibri;mso-fareast-theme-font:minor-latin;mso-hansi-theme-font:minor-latin;~~
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~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{844 Kim,D. 2006}}<span~~
~~style='mso-element:field-separator'><![endif]-->(Kim and Ghanayem 2006)<!--[if supportFields]><span~~
~~style='font-size:11.0pt;line-height:115%;font-family:"Calibri","sans-serif";~~
~~mso-ascii-theme-font:minor-latin;mso-fareast-font-family:Calibri;mso-fareast-theme-font:~~
~~minor-latin;mso-hansi-theme-font:minor-latin;mso-bidi-font-family:"Times New Roman";~~
~~mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:~~
EN-US;mso-bidi-language:AR-SA'><![endif]-->, aniline, N-nitrosodimethylamine, N-nitrosodiethylamine, diethylnitrosamine, thioacetamide <!--[if supportFields]><span style='font-size:11.0pt;line-height:115%;
~~font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;mso-fareast-font-family:~~
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~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{841 Chilakapati,J. 2007}}<span~~
~~style='mso-element:field-separator'><![endif]-->(Chilakapati, et al. 2007)<!--[if supportFields]><span~~
~~style='font-size:11.0pt;line-height:115%;font-family:"Calibri","sans-serif";~~
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~~mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:~~
~~EN-US;mso-bidi-language:AR-SA'><![endif]-->, urethane <!--[if supportFields]><span style='font-size:11.0pt;line-height:115%;~~
~~font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;mso-fareast-font-family:~~
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~~mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span~~
~~style='mso-element:field-begin'>ADDIN RW.CITE{{847 Hoffler,U. 2003; 845~~
~~Hoffler,U. 2005}}<![endif]-->(Hoffler, et al. 2003, Hoffler and Ghanayem 2005)<!--[if supportFields]><span style='font-size:~~
~~11.0pt;line-height:115%;font-family:"Calibri","sans-serif";mso-ascii-theme-font:~~
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~~mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:~~
~~EN-US;mso-bidi-language:AR-SA'><![endif]-->, and toluene.~~
<h4>Domain of Applicability</h4>
Taxonomic Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Term</th>
<th scope="col">Scientific Term</th>
<th scope="col">Evidence</th>
<th scope="col">Links</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>rodents</td>
<td>rodents</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=0" target="_blank">NCBI</a></td>
</tr>
<tr>
<td>Homo sapiens</td>
<td>Homo sapiens</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=9606" target="_blank">NCBI</a></td>
</tr>
</tbody>
</table>
</div>
Life Stage Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Life Stage</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>All life stages</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
Sex Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sex</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Mixed</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
Taxonomic applicability: The Cyp2E1 gene is present across a variety of taxa including humans and primates, mice and rats. AceView (http://www.ncbi.nlm.nih.gov/IEB/Research/Acembly/index.html) indicates high levels of Cyp2E1 expression from RNA-seq experiments in liver across primate species. Cype2E1 is also present in frogs <!--[if supportFields]><span style='font-size:
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RW.CITE{{1321 Fort,D.J. 2003; 1323 Saito,H. 1997}}<span style='mso-element:
field-separator'><![endif]-->(Fort, et al. 2003, Saito, et al. 1997)<!--[if supportFields]><span style='font-size:11.0pt;
line-height:115%;font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;
mso-fareast-font-family:Calibri;mso-fareast-theme-font:minor-latin;mso-hansi-theme-font:
minor-latin;mso-bidi-font-family:"Times New Roman";mso-bidi-theme-font:minor-bidi;
mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span
style='mso-element:field-end'><![endif]--> and fish <!--[if supportFields]><span
style='font-size:11.0pt;line-height:115%;font-family:"Calibri","sans-serif";
mso-ascii-theme-font:minor-latin;mso-fareast-font-family:Calibri;mso-fareast-theme-font:
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mso-bidi-theme-font:minor-bidi;mso-ansi-language:EN-CA;mso-fareast-language:
EN-US;mso-bidi-language:AR-SA'>ADDIN
RW.CITE{{1322 Howarth,D.L. 2011}}<![endif]-->(Howarth, et al. 2011)<!--[if supportFields]><span style='font-size:11.0pt;
line-height:115%;font-family:"Calibri","sans-serif";mso-ascii-theme-font:minor-latin;
mso-fareast-font-family:Calibri;mso-fareast-theme-font:minor-latin;mso-hansi-theme-font:
minor-latin;mso-bidi-font-family:"Times New Roman";mso-bidi-theme-font:minor-bidi;
mso-ansi-language:EN-CA;mso-fareast-language:EN-US;mso-bidi-language:AR-SA'><span
style='mso-element:field-end'><![endif]-->.
Life stages: Studies are primarily on adult liver tissues.
Sex applicability: Cyp2E1 is expressed in both males and females.
<h4>Key Event Description</h4>
Cyp2E1 is a membrane-bound monooxygenase that is primarily located in zone 3 hepatocytes (Ingelman-Sundberg, et al. 1988, Tsutsumi, et al. 1989). Although it is also expressed in other tissues (http://www.genecards.org/cgi-bin/carddisp.pl?gene=CYP2E1), the body of literature on CYP2E1 is focussed on measurement in liver. CYP2E1 is primarily located in the endoplasmic reticulum, but can also be present in the mitochondria.  It is a phase I metabolism enzyme that catalyzes the oxidation of low molecular weight substrates. Unlike most cytochrome P450 enzymes, Cyp2E1 is constitutively expressed (i.e., its expression is not transcriptionally controlled by substrate-bound nuclear receptors). Alternatively, exposure to a substrate increases its activity through post-translational stabilization of the molecule. Thus, the presence of substrate significantly increases the half-life of the Cyp2E1 enzyme thereby allowing it to be active for a longer period of time (Gonzalez 2007, Song, et al. 1989). The sustained activation of Cyp2E1 due to the presence of the chemical substrate is required for this MIE to produce downstream adverse effects.
Cyp2E1 is also regulated by the ubiquitin-proteasome pathway and the involvement of hsp-based chaperone (Morishima et al. 2005); however, this mechanism of regulation is not discussed further herein.
<h4>How it is Measured or Detected</h4>
<ul>
<li>Mixed function oxidase catalytic activity. These assays have been thoroughly reviewed by Cederbaum (2014). The paper describes preparation of microsomes from both liver homogenates and cell cultures for testing Cyp2E1 activity. Briefly, the ratio of 6-hydroxychlorzoxazone/chlorzoxazone can be used to estimate levels of CYP2E1 in humans (Girre, et al. 1994). In addition, the oxidation of para-nitrophenol (PNP) to para nitrocatechol is an efficient and relatively specific assay to determine catalytic activity dependent on CYP2E1 [e.g., (Koop 1986, Koop, et al. 1989, Reinke and Moyer 1985)]. Other assays are described within the review article by Cederbaum.</li>
<li>Western blot or Immunohistochemistry.  Following chemical treatment, Cyp2E1 protein levels should increase if it is involved in the metabolism of that substrate. Western blot (of protein extracted from liver or cultured cells) or immunohistochemistry (of fixed liver or cultured cells) using anti-Cyp2E1 antibodies is the most straightforward approach for directly measuring increased levels of Cyp2E1.</li>
<li>HepG2 cells. A compound’s Cyp2E1-dependence can be determined by comparing toxic effects in HepG2 versus HepG2-E47 cells. HepG2 cells are immortalized human hepatoma cells that do not express Cyp2E1; whereas, HepG2-E47 cells over-express Cyp2E1 (by recombinant retroviral infection). Chemicals that are metabolically activated by Cyp2E1 will cause cytotoxicity and oxidative stress in the E47 cells only. Toxicity can be blocked by treatment with antioxidants or Cyp2E1 inhibitors. Toxicity is exacerbated when glutathione is depleted (Wu and Cederbaum 2005) (e.g., ethanol (Cederbaum, et al. 2001, Chen and Cederbaum 1998, Chen, et al. 1998, Dai, et al. 1993).</li>
<li>Measurement of chemical oxidation by Cyp2E1 in liver microsomes; described in the methodology review by Cederbaum (Cederbaum 2014). Reactions use specific probes to confirm that the compound undergoes oxidation, and that this oxidation reaction is catalyzed by Cyp2E1. See also: (Koop 1986, Koop, et al. 1989, Reinke and Moyer 1985).</li>
<li>Cyp2E1 knock-out mouse. Chemical exposures in knockout mice are conducted and the production of the anticipated metabolites is measured. Lack of metabolite production indicates that Cyp2E1 is required for the chemical’s metabolism. Effects in knock-out mice are always measured in reference to wild-type (control) mice, which allows investigators to attribute the altered phenotype to the gene that has been knocked-out. Studies in Cyp2E1 knockout mice indicate the following chemicals interact with it: carbon tetrachloride (Wong, et al. 1998), acetone (Bondoc, et al. 1999), benzene (Powley and Carlson 2001), thioacetamide (Chilakapati, et al. 2007), trichloroethylene (Kim and Ghanayem 2006), acrylonitrile (El Hadri, et al. 2005), urethane (Hoffler, et al. 2003, Hoffler and Ghanayem 2005), acetaminophen (Lee, et al. 1996, Zaher, et al. 1998), and ethanol (Bardag-Gorce, et al. 2000).</li>
<li>Humanized Cyp2E1 mice. Two transgenic mice with human Cyp2E1 have been created. The first mouse reproduces and develops normally, and demonstrates Cyp2E1-dependent toxicity (Morgan, et al. 2002). However, these mice express human and endogenous Cyp2E1, which is not ideal. A true ‘humanized’ Cyp2E1 transgenic mouse was produced by the Gonzalez lab in which the endogenous Cyp2E1 gene was replaced with the human Cyp2E1 gene (Cheung, et al. 2005, Cheung and Gonzalez 2008). Studies in these mice are conducted in order to provide evidence that the Cyp2E1-dependent effects observed in experimental animals will also occur in humans.</li>
<li>2-Piperidone. 2-Piperidone is a newly proposed biomarker of Cyp2E1 activity that is detected in urine (Cheng, et al. 2013).</li>
</ul>
<h4>References</h4>
Bardag-Gorce, F., Yuan, Q.X., Li, J., French, B.A., Fang, C., Ingelman-Sundberg, M., French, S.W., 2000. The effect of ethanol-induced cytochrome p4502E1 on the inhibition of proteasome activity by alcohol. Biochem. Biophys. Res. Commun. 279, 23-29.
Bondoc, F.Y., Bao, Z., Hu, W.Y., Gonzalez, F.J., Wang, Y., Yang, C.S., Hong, J.Y., 1999. Acetone catabolism by cytochrome P450 2E1: studies with CYP2E1-null mice. Biochem. Pharmacol. 58, 461-463.
Cederbaum, A.I., 2014. Methodology to assay CYP2E1 mixed function oxidase catalytic activity and its induction. Redox Biol. 2C, 1048-1054.
Cheng, J., Chen, C., Kristopher, K.W., Manna, S.K., Scerba, M., Friedman, F.K., Luecke, H., Idle, J.R., Gonzalez, F.J., 2013. Identification of 2-piperidone as a biomarker of CYP2E1 activity through metabolomic phenotyping. Toxicol. Sci. 135, 37-47.
Cheung, C., Gonzalez, F.J., 2008. Humanized mouse lines and their application for prediction of human drug metabolism and toxicological risk assessment. J. Pharmacol. Exp. Ther. 327, 288-299.
Chilakapati, J., Korrapati, M.C., Shankar, K., Hill, R.A., Warbritton, A., Latendresse, J.R., Mehendale, H.M., 2007. Role of CYP2E1 and saturation kinetics in the bioactivation of thioacetamide: Effects of diet restriction and phenobarbital. Toxicol. Appl. Pharmacol. 219, 72-84.
El Hadri, L., Chanas, B., Ghanayem, B.I., 2005. Comparative metabolism of methacrylonitrile and acrylonitrile to cyanide using cytochrome P4502E1 and microsomal epoxide hydrolase-null mice. Toxicol. Appl. Pharmacol. 205, 116-125.
Fort, D.J., McLaughlin, D.W., Rogers, R.L., Buzzard, B.O., 2003. Evaluation of the developmental toxicities of ethanol, acetaldehyde, and thioacetamide using FETAX. Drug Chem. Toxicol. 26, 23-34.
Girre, C., Lucas, D., Hispard, E., Menez, C., Dally, S., Menez, J.F., 1994. Assessment of cytochrome P4502E1 induction in alcoholic patients by chlorzoxazone pharmacokinetics. Biochem. Pharmacol. 47, 1503-1508.
Gonzalez, F.J., 2007. The 2006 Bernard B. Brodie Award Lecture. Cyp2e1. Drug metabolism and disposition: the biological fate of chemicals 35, 1-8.
Hoffler, U., El-Masri, H.A., Ghanayem, B.I., 2003. Cytochrome P450 2E1 (CYP2E1) is the principal enzyme responsible for urethane metabolism: comparative studies using CYP2E1-null and wild-type mice. J. Pharmacol. Exp. Ther. 305, 557-564.
Hoffler, U., Ghanayem, B.I., 2005. Increased bioaccumulation of urethane in CYP2E1-/- versus CYP2E1+/+ mice. Drug Metab. Dispos. 33, 1144-1150.
Howarth, D.L., Passeri, M., Sadler, K.C., 2011. Drinks Like a Fish: Using Zebrafish to Understand Alcoholic Liver Disease. Alcohol. Clin. Exp. Res. 35, 826-829.
Ingelman-Sundberg, M., Johansson, I., Penttila, K.E., Glaumann, H., Lindros, K.O., 1988. Centrilobular expression of ethanol-inducible cytochrome P-450 (IIE1) in rat liver. Biochem. Biophys. Res. Commun. 157, 55-60.
Kim, D., Ghanayem, B.I., 2006. Comparative metabolism and disposition of trichloroethylene in Cyp2e1-/-and wild-type mice. Drug Metab. Dispos. 34, 2020-2027.
Koop, D.R., 1986. Hydroxylation of p-nitrophenol by rabbit ethanol-inducible cytochrome P-450 isozyme 3a. Mol. Pharmacol. 29, 399-404.
Koop, D.R., Laethem, C.L., Tierney, D.J., 1989. The utility of p-nitrophenol hydroxylation in P450IIE1 analysis. Drug Metab. Rev. 20, 541-551.
Lee, S.S., Buters, J.T., Pineau, T., Fernandez-Salguero, P., Gonzalez, F.J., 1996. Role of CYP2E1 in the hepatotoxicity of acetaminophen. J. Biol. Chem. 271, 12063-12067.
Lieber, C.S., 1997. Cytochrome P-4502E1: its physiological and pathological role. Physiol. Rev. 77, 517-544.
Morishima, Y., Peng, H-M., Lin, H-L., Hollenberg, P.F., Sunahara, R., K., Osawa, Y., Pratt, W.B. Regulation of Cytochrome P450 2E1 by Heat Shock Protein 90-Dependent Stabilization and CHIP-Dependent Proteasomal Degradation. 2005. Biochemistry. 44, 49, 16333-16340.
Morgan, K., French, S.W., Morgan, T.R., 2002. Production of a cytochrome P450 2E1 transgenic mouse and initial evaluation of alcoholic liver damage. Hepatology 36, 122-134.
Powley, M.W., Carlson, G.P., 2001. Hepatic and pulmonary microsomal benzene metabolism in CYP2E1 knockout mice. Toxicology 169, 187-194.
Reinke, L.A., Moyer, M.J., 1985. p-Nitrophenol hydroxylation. A microsomal oxidation which is highly inducible by ethanol. Drug Metab. Dispos. 13, 548-552.
Saito, H., Ohi, H., Sugata, E., Murayama, N., Fujita, Y., Higuchi, S., 1997. Purification and characterization of a cytochrome P450 from liver microsomes of Xenopus laevis. Arch. Biochem. Biophys. 345, 56-64.
Song, B.J., Veech, R.L., Park, S.S., Gelboin, H.V., Gonzalez, F.J., 1989. Induction of rat hepatic N-nitrosodimethylamine demethylase by acetone is due to protein stabilization. J. Biol. Chem. 264, 3568-3572.
Tanaka, E., Terada, M., Misawa, S., 2000. Cytochrome P450 2E1: its clinical and toxicological role. J. Clin. Pharm. Ther. 25, 165-175.
Tsutsumi, M., Lasker, J.M., Shimizu, M., Rosman, A.S., Lieber, C.S., 1989. The intralobular distribution of ethanol-inducible P450IIE1 in rat and human liver. Hepatology 10, 437-446.
Wu, D., Cederbaum, A.I., 2005. Oxidative stress mediated toxicity exerted by ethanol-inducible CYP2E1. Toxicol. Appl. Pharmacol. 207, 70-76.
Zaher, H., Buters, J.T., Ward, J.M., Bruno, M.K., Lucas, A.M., Stern, S.T., Cohen, S.D., Gonzalez, F.J., 1998. Protection against acetaminophen toxicity in CYP1A2 and CYP2E1 double-null mice. Toxicol. Appl. Pharmacol. 152, 193-199.
~~<h4><a href="/events/1510">Event: 1510: Oxidative Stress in Brain</a></h4>~~
~~<h5>Short Name: Oxidative Stress in Brain</h5>~~
<h4><a href="/events/1392">Event: 1392: Increase, Oxidative Stress </a></h4>
<h5>Short Name: Increase, Oxidative Stress </h5>
<h4>Key Event Component</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Process</th>
<th scope="col">Object</th>
<th scope="col">Action</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>oxidative stress</td>
<td></td>
<td>increased</td>
</tr>
</tbody>
</table>
</div>
<h4>AOPs Including This Key Event</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP ID and Name</th>
<th scope="col">Event Type</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/220">Aop:220 - Cyp2E1 Activation Leading to Liver Cancer</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/17">Aop:17 - Binding of electrophilic chemicals to SH(thiol)-group of proteins and /or to seleno-proteins involved in protection against oxidative stress during brain development leads to impairment of learning and memory</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/284">Aop:284 - Binding of electrophilic chemicals to SH(thiol)-group of proteins and /or to seleno-proteins involved in protection against oxidative stress leads to chronic kidney disease</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/377">Aop:377 - Dysregulated prolonged Toll Like Receptor 9 (TLR9) activation leading to Multi Organ Failure involving Acute Respiratory Distress Syndrome (ARDS)</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/411">Aop:411 - Oxidative stress Leading to Decreased Lung Function </a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/424">Aop:424 - Oxidative stress Leading to Decreased Lung Function via CFTR dysfunction</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/425">Aop:425 - Oxidative Stress Leading to Decreased Lung Function via Decreased FOXJ1</a></td>
<td>MolecularInitiatingEvent</td>
</tr>
<tr>
<td><a href="/aops/429">Aop:429 - A cholesterol/glucose dysmetabolism initiated Tau-driven AOP toward memory loss (AO) in sporadic Alzheimer's Disease with plausible MIE's plug-ins for environmental neurotoxicants</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/452">Aop:452 - Adverse outcome pathway of PM-induced respiratory toxicity</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/464">Aop:464 - Calcium overload in dopaminergic neurons of the substantia nigra leading to parkinsonian motor deficits</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/470">Aop:470 - Deposition of energy leads to abnormal vascular remodeling</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/478">Aop:478 - Deposition of energy leading to occurrence of cataracts</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/479">Aop:479 - Mitochondrial complexes inhibition leading to left ventricular function decrease via increased myocardial oxidative stress</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/481">Aop:481 - AOPs of amorphous silica nanoparticles: ROS-mediated oxidative stress increased respiratory dysfunction and diseases.</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/482">Aop:482 - Deposition of energy leading to occurrence of bone loss</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/483">Aop:483 - Deposition of Energy Leading to Learning and Memory Impairment</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/505">Aop:505 - Reactive Oxygen Species (ROS) formation leads to cancer via inflammation pathway</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/521">Aop:521 - Essential element imbalance leads to reproductive failure via oxidative stress</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/26">Aop:26 - Calcium-mediated neuronal ROS production and energy imbalance</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/488">Aop:488 - Increased reactive oxygen species production leading to decreased cognitive function</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/396">Aop:396 - Deposition of ionizing energy leads to population decline via impaired meiosis</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/437">Aop:437 - Inhibition of mitochondrial electron transport chain (ETC) complexes leading to kidney toxicity</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/535">Aop:535 - Binding and activation of GPER leading to learning and memory impairments</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/171">Aop:171 - Chronic cytotoxicity of the serous membrane leading to pleural/peritoneal mesotheliomas in the rat.</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/138">Aop:138 - Organic anion transporter (OAT1) inhibition leading to renal failure and mortality</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/177">Aop:177 - Cyclooxygenase 1 (COX1) inhibition leading to renal failure and mortality</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/186">Aop:186 - unknown MIE leading to renal failure and mortality</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/200">Aop:200 - Estrogen receptor activation leading to breast cancer </a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/444">Aop:444 - Ionizing radiation leads to reduced reproduction in Eisenia fetida via reduced spermatogenesis and cocoon hatchability</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/447">Aop:447 - Kidney failure induced by inhibition of mitochondrial electron transfer chain through apoptosis, inflammation and oxidative stress pathways</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/476">Aop:476 - Adverse Outcome Pathways diagram related to PBDEs associated male reproductive toxicity</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/497">Aop:497 - ERa inactivation alters mitochondrial functions and insulin signalling in skeletal muscle and leads to insulin resistance and metabolic syndrome</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/457">Aop:457 - Succinate dehydrogenase inhibition leading to increased insulin resistance through reduction in circulating thyroxine</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/459">Aop:459 - AhR activation in the thyroid leading to Subsequent Adverse Neurodevelopmental Outcomes in Mammals</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/507">Aop:507 - Nrf2 inhibition leading to vascular disrupting effects via inflammation pathway</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/509">Aop:509 - Nrf2 inhibition leading to vascular disrupting effects through activating apoptosis signal pathway and mitochondrial dysfunction</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/510">Aop:510 - Demethylation of PPAR promotor leading to vascular disrupting effects</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/511">Aop:511 - The AOP framework on ROS-mediated oxidative stress induced vascular disrupting effects </a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/538">Aop:538 - Adverse outcome pathway of PFAS-induced vascular disrupting effects via activating oxidative stress related pathways </a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/260">Aop:260 - CYP2E1 activation and formation of protein adducts leading to neurodegeneration</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/450">Aop:450 - Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/501">Aop:501 - Excessive iron accumulation leading to neurological disorders</a></td>
<td>KeyEvent</td>
</tr>
<tr>
~~<td><a href="/aops/471">Aop:471 - Various neuronal effects induced by elavl3, sox10, and mbp</a></td>~~
<td><a href="/aops/540">Aop:540 - Oxidative Stress in the Fish Ovary Leads to Reproductive Impairment via Reduced Vitellogenin Production</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/471">Aop:471 - Neuron defect induced early behavioral change</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/31">Aop:31 - Oxidation of iron in hemoglobin leading to hematotoxicity</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/534">Aop:534 - Succinate dehydrogenase (SDH) inhibition leads to cancer through oxidative stress</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/462">Aop:462 - Activation of reactive oxygen species leading the atherosclerosis</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/324">Aop:324 - Excessive reactive oxygen species leading to growth inhibition via uncoupling of oxidative phosphorylation and cell death</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/325">Aop:325 - Excessive reactive oxygen species leading to growth inhibition via uncoupling of oxidative phosphorylation and reduced cell growth</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/326">Aop:326 - Excessive reactive oxygen species leading to growth inhibition via uncoupling of oxidative phosphorylation and reduced cell proliferation</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/331">Aop:331 - Excessive reactive oxygen species leading to growth inhibition via lipid peroxidation and cell death</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/332">Aop:332 - Excessive reactive oxygen species leading to growth inhibition via lipid peroxidation and reduced cell growth</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/333">Aop:333 - Excessive reactive oxygen species leading to growth inhibition via lipid peroxidation and reduced cell proliferation</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/595">Aop:595 - Emerging OPFRS reproductive outcome pathway</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/596">Aop:596 - Excessive reactive oxygen species leading to growth inhibition via protein oxidation and cell injury/death</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/598">Aop:598 - Excessive reactive oxygen species leading to growth inhibition via protein oxidation and reduced cell proliferation</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/599">Aop:599 - Excessive reactive oxygen species leading to growth inhibition via fatty acid oxidation and cell injury/death</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/600">Aop:600 - Excessive reactive oxygen species leading to growth inhibition via fatty acid oxidation and reduced cell growth</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/601">Aop:601 - Excessive reactive oxygen species leading to growth inhibition via fatty acid oxidation and reduced cell proliferation</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/602">Aop:602 - Excessive reactive oxygen species leading to growth inhibition via oxidative DNA damage</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/603">Aop:603 - Excessive reactive oxygen species leading to growth inhibition via protein oxidation and cell cycle disruption</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/608">Aop:608 - Thyroid Hormone Excess Leading to Reduced, Swimming Performance via Hypomyelination</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/616">Aop:616 - organic UV filter and its Photoproducts reproductive toxicity pathways </a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/622">Aop:622 - Calcineurin inhibitor induced nephrotoxicity leading to kidney failure</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/624">Aop:624 - Altered glucocorticoid receptor signaling leading to MASLD progression via insulin resistance-associated mitochondrial dysfunction</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/625">Aop:625 - Altered glucocorticoid receptor signaling leading to MASLD progression via reduced very low-density lipoprotein export-associated mitochondrial dysfunction</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/626">Aop:626 - Altered glucocorticoid receptor signaling leading to MASLD progression via reduced VLDL export-associated mitochondrial dysfunction</a></td>
<td>KeyEvent</td>
</tr>
</tbody>
</table>
</div>
<h4>Stressors</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Name</th></tr>
</thead>
<tbody>
<tr><td>Acetaminophen</td></tr>
<tr><td>Chloroform</td></tr>
<tr><td>furan</td></tr>
<tr><td>Platinum</td></tr>
<tr><td>Aluminum</td></tr>
<tr><td>Cadmium</td></tr>
<tr><td>Mercury</td></tr>
<tr><td>Uranium</td></tr>
<tr><td>Arsenic</td></tr>
<tr><td>Silver </td></tr>
<tr><td>Manganese</td></tr>
<tr><td>Nickel</td></tr>
<tr><td>Zinc</td></tr>
<tr><td>nanoparticles</td></tr>
</tbody>
</table>
</div>
<h4>Biological Context</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Level of Biological Organization</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>Molecular</td></tr>
</tbody>
</table>
</div>
<h4>Domain of Applicability</h4>
Taxonomic Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Term</th>
<th scope="col">Scientific Term</th>
<th scope="col">Evidence</th>
<th scope="col">Links</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>rodents</td>
<td>rodents</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=0" target="_blank">NCBI</a></td>
</tr>
<tr>
<td>Homo sapiens</td>
<td>Homo sapiens</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=9606" target="_blank">NCBI</a></td>
</tr>
</tbody>
</table>
</div>
Life Stage Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Life Stage</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>All life stages</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
Sex Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sex</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Mixed</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
Taxonomic applicability: Occurrence of oxidative stress is not species specific.
Life stage applicability: Occurrence of oxidative stress is not life stage specific.
Sex applicability: Occurrence of oxidative stress is not sex specific.
Evidence for perturbation by prototypic stressor: There is evidence of the increase of oxidative stress following perturbation from a variety of stressors including exposure to ionizing radiation and altered gravity (Bai et al., 2020; Ungvari et al., 2013; Zhang et al., 2009).
<h4>Key Event Description</h4>
Oxidative stress is the imbalance between ROS and defence mechanisms against these ROS. Due to this imbalance the concentration of ROS can rise in the cells. The oxidizing free radicals can cause damage in the cell, at the DNA but also on multiple proteins. Nrf2 is an example of an defence mechanism against ROS.
Oxidative stress is defined as an imbalance in the production of reactive oxygen species (ROS) and antioxidant defenses. High levels of oxidizing free radicals can be very damaging to cells and molecules within the cell.  As a result, the cell has important defense mechanisms to protect itself from ROS. For example, Nrf2 is a transcription factor and master regulator of the oxidative stress response. During periods of oxidative stress, Nrf2-dependent changes in gene expression are important in regaining cellular homeostasis (Nguyen, et al., 2009) and can be used as indicators of the presence of oxidative stress in the cell.
In addition to the directly damaging actions of ROS, cellular oxidative stress also changes cellular activities on a molecular level. Redox sensitive proteins have altered physiology in the presence and absence of ROS, which is caused by the oxidation of sulfhydryls to disulfides on neighboring amino acids (Antelmann & Helmann 2011). Importantly Keap1, the negative regulator of Nrf2, is regulated in this manner (Itoh, et al. 2010).
ROS also undermine the mitochondrial defense system from oxidative damage. The antioxidant systems consist of superoxide dismutase, catalase, glutathione peroxidase and glutathione reductase, as well as antioxidants such as α-tocopherol and ubiquinol, or antioxidant vitamins and minerals including vitamin E, C, carotene, lutein, zeaxanthin, selenium, and zinc (Fletcher, 2010). The enzymes, vitamins and minerals catalyze the conversion of ROS to non-toxic molecules such as water and O2. However, these antioxidant systems are not perfect and endogenous metabolic processes and/or exogenous oxidative influences can trigger cumulative oxidative injuries to the mitochondria, causing a decline in their functionality and efficiency, which further promotes cellular oxidative stress (Balasubramanian, 2000; Ganea & Harding, 2006; Guo et al., 2013; Karimi et al., 2017).
However, an emerging viewpoint suggests that ROS-induced modifications may not be as detrimental as previously thought, but rather contribute to signaling processes (Foyer et al., 2017).
 
Sources of ROS Production 
Direct Sources: Direct sources involve the deposition of energy onto water molecules, breaking them into active radical species. When ionizing radiation hits water, it breaks it into hydrogen (H*) and hydroxyl (OH*) radicals by destroying its bonds. The hydrogen will create hydroxyperoxyl free radicals (HO2*) if oxygen is available, which can then react with another of itself to form hydrogen peroxide (H2O2) and more O2 (Elgazzar and Kazem, 2015). Antioxidant mechanisms are also affected by radiation, with catalase (CAT) and peroxidase (POD) levels rising as a result of exposure (Seen et al. 2018; Ahmad et al. 2021).
Indirect Sources: An indirect source of ROS is the mitochondria, which is one of the primary producers in eukaryotic cells (Powers et al., 2008).  As much as 2% of the electrons that should be going through the electron transport chain in the mitochondria escape, allowing them an opportunity to interact with surrounding structures. Electron-oxygen reactions result in free radical production, including the formation of hydrogen peroxide (H2O2) (Zhao et al., 2019). The electron transport chain, which also creates ROS, is activated by free adenosine diphosphate (ADP), O2, and inorganic phosphate (Pi) (Hargreaves et al. 2020; Raimondi et al. 2020; Vargas-Mendoza et al. 2021). The first and third complexes of the transport chain are the most relevant to mammalian ROS production (Raimondi et al., 2020). The mitochondria has its own set of DNA and it is a prime target of oxidative damage (Guo et al., 2013). ROS is also produced through nicotinamide adenine dinucleotide phosphate oxidase (Nox) stimulation, an event commenced by angiotensin II, a product/effector of the renin-angiotensin system (Nguyen Dinh Cat et al. 2013; Forrester et al. 2018). Other ROS producers include xanthine oxidase, immune cells (macrophage, neutrophils, monocytes, and eosinophils), phospholipase A2 (PLA2), monoamine oxidase (MAO), and carbon-based nanomaterials (Powers et al. 2008; Jacobsen et al. 2008; Vargas-Mendoza et al. 2021).
<h4>How it is Measured or Detected</h4>
One way to show oxidative stress in cells is to measure the ROS level. ROS generation can be determined in neuron cells. DHE, a small-molecule ROS probe, can be used for visualizing ROS generation with the use of an epifluorescence microscope. DHE is a direct way of measuring ROS, an indirect way is the measurement of glutathione depletion. The ratio between glutathione and oxidized glutathione can be determined, which shows indirectly whether the ROS level is increased. When oxidized glutathione is present in a higher concentration the ROS level is increased. Finally the expression level of Nrf2 can be determined in cells, with the use of a western blot analysis and antibodies for Nrf2. When the expression level of Nrf2 is much higher than in a control cell it indirectly shows that there is an increase in the concentration of ROS.
Oxidative Stress: Direct measurement of ROS is difficult because ROS are unstable. The presence of ROS can be assayed indirectly by measurement of cellular antioxidants, or by ROS-dependent cellular damage. Listed below are common methods for detecting the KE, however there may be other comparable methods that are not listed
<ul>
<li>Detection of ROS by chemiluminescence (https://www.sciencedirect.com/science/article/abs/pii/S0165993606001683) </li>
<li>Detection of ROS by chemiluminescence is also described in OECD TG 495 to assess phototoxic potential. </li>
<li>Glutathione (GSH) depletion. GSH can be measured by assaying the ratio of reduced to oxidized glutathione (GSH:GSSG) using a commercially available kit (e.g., http://www.abcam.com/gshgssg-ratio-detection-assay-kit-fluorometric-green- ab138881.html). </li>
<li>TBARS. Oxidative damage to lipids can be measured by assaying for lipid peroxidation using TBARS (thiobarbituric acid reactive substances) using a commercially available kit. </li>
<li>8-oxo-dG. Oxidative damage to nucleic acids can be assayed by measuring 8-oxo-dG adducts (for which there are a number of ELISA based commercially available kits),or HPLC, described in Chepelev et al. (Chepelev, et al. 2015). </li>
</ul>
  
Molecular Biology: Nrf2. Nrf2’s transcriptional activity is controlled post-translationally by oxidation of Keap1. Assay for Nrf2 activity include: 
<ul>
<li>Immunohistochemistry for increases in Nrf2 protein levels and translocation into the nucleus Western blot for increased Nrf2 protein levels </li>
<li>Western blot of cytoplasmic and nuclear fractions to observe translocation of Nrf2 protein from the cytoplasm to the nucleus qPCR of Nrf2 target genes (e.g., Nqo1, Hmox-1, Gcl, Gst, Prx, TrxR, Srxn), or by commercially available pathway-based qPCR array (e.g., oxidative stress array from SABiosciences) </li>
<li>Whole transcriptome profiling by microarray or RNA-seq followed by pathway analysis (in IPA, DAVID, metacore, etc.) for enrichment of the Nrf2 oxidative stress response pathway (e.g., Jackson et al. 2014) </li>
<li>OECD TG422D describes an ARE-Nrf2 Luciferase test method </li>
</ul>
In general, there are a variety of commercially available colorimetric or fluorescent kits for detecting Nrf2 activation.
<table border="1">
<tbody>
<tr>
<td>
Assay Type & Measured Content 
</td>
<td>
Description 
</td>
<td>
Dose Range Studied 
</td>
<td>
Assay Characteristics (Length/Ease of use/Accuracy) 
</td>
</tr>
<tr>
<td>
ROS 
Formation in the Mitochondria assay (Shaki et al., 2012) 
</td>
<td>
“The mitochondrial ROS measurement was performed flow cytometry using DCFH-DA. Briefly, isolated kidney mitochondria were incubated with UA (0, 50, 100 and 200 µM) in respiration buffer containing (0.32 mM sucrose, 10mM Tris, 20 mM Mops, 50 µM EGTA, 0.5 mM MgCl2, 0.1 mM KH2PO4 and 5 mM sodium succinate) [32]. In the interval times of 5, 30 and 60 min following the UA addition, a sample was taken and DCFH-DA was added (final concentration, 10 µM) to mitochondria and was then incubated for 10 min.Uranyl acetate-induced ROS generation in isolated kidney mitochondria were determined through the flow cytometry (Partec, Deutschland) equipped with a 488-nm argon ion laser and supplied with the Flomax software and the signals were obtained using a 530-nm bandpass filter (FL-1 channel). Each determination is based on the mean fluorescence intensity of 15,000 counts.”
 
</td>
<td>
0, 50,100 and 200 µM of Uranyl Acetate 
 
</td>
<td>
 Long/ Easy High accuracy 
 
</td>
</tr>
<tr>
<td>
Mitochondrial Antioxidant Content Assay Measuring GSH content (Shaki et al., 2012) 
 
</td>
<td>
“GSH content was determined using DTNB as the indicator and spectrophotometer method for the isolated mitochondria. The mitochondrial fractions (0.5 mg protein/ml) were incubated with various concentrations of uranyl acetate for 1 h at 30 °C and then 0.1 ml of mitochondrial fractions was added into 0.1 mol/l of phosphate buffers and 0.04% DTNB in a total volume of 3.0 ml (pH 7.4). The developed yellow color was read at 412 nm on a spectrophotometer (UV-1601 PC, Shimadzu, Japan). GSH content was expressed as µg/mg protein.”
</td>
<td>
0, 50, 
100, or 
200 µM 
Uranyl Acetate 
</td>
<td>
 
</td>
</tr>
<tr>
<td>
H2O2 Production Assay Measuring H2O2 Production in isolated mitochondria (Heyno et al., 2008) 
 
</td>
<td>
“Effect of CdCl2 and antimycin A (AA) on H2O2 production in isolated mitochondria from potato. H2O2 production was measured as scopoletin oxidation. Mitochondria were incubated for 30 min in the measuring buffer
(see the Materials and Methods) containing 0.5 mM succinate as an electron donor and 0.2 µM mesoxalonitrile 3‐chlorophenylhydrazone (CCCP) as an uncoupler, 10 U horseradish peroxidase and 5 µM scopoletin.”
</td>
<td>
0, 10, 30 
µM Cd2+ 
  
2 µM antimycin A 
</td>
<td>
 
</td>
</tr>
<tr>
<td>
Flow Cytometry ROS & Cell Viability (Kruiderig et al., 1997) 
 
</td>
<td>
“For determination of ROS, samples taken at the indicated time points were directly transferred to FACScan tubes. Dih123 (10 mM, final concentration) was added and cells were incubated at 37°C in a humidified atmosphere (95% air/5% CO2) for 10 min. At t 5 9, propidium iodide (10 mM, final concentration) was added, and cells were analyzed by flow cytometry at 60 ml/min. Nonfluorescent Dih123 is cleaved by ROS to fluorescent R123 and detected by the FL1 detector as described above for Dc (Van de Water 1995)”“For determination of ROS, samples taken at the indicated time points were directly transferred to FACScan tubes. Dih123 (10 mM, final concentration) was added and cells were incubated at 37°C in a humidified atmosphere (95% air/5% CO2) for 10 min. At t 5 9, propidium iodide (10 mM, final concentration) was added, and cells were analyzed by flow cytometry at 60 ml/min. Nonfluorescent Dih123 is cleaved by ROS to fluorescent R123 and detected by the FL1 detector as described above for Dc (Van de Water 1995)”
</td>
<td>
 
</td>
<td>
 
 
 
 
 
Strong/easy medium 
</td>
</tr>
<tr>
<td>
DCFH-DA 
Assay Detection of hydrogen peroxide production (Yuan et al., 
2016) 
</td>
<td>
Intracellular ROS production was measured using DCFH-DA as a probe. Hydrogen peroxide oxidizes DCFH to DCF. The probe is hydrolyzed intracellularly to DCFH carboxylate anion. No direct reaction with H2O2 to form fluorescent production.
 
</td>
<td>
0-400 
µM 
</td>
<td>
Long/ Easy High accuracy 
</td>
</tr>
<tr>
<td>
H2-DCF-DAAssay Detection of superoxide production (Thiebault etal., 2007) 
 
</td>
<td>
This dye is a stable nonpolar compound which diffuses readily into the cells and yields H2-DCF. Intracellular OH or ONOO- react with H2-DCF when cells contain peroxides, to form the highly fluorescent compound DCF, which effluxes the cell. Fluorescence intensity of DCF is measured using a fluorescence spectrophotometer.
</td>
<td>
0–600 
µM 
</td>
<td>
Long/ Easy High accuracy 
</td>
</tr>
<tr>
<td>
CM-H2DCFDA 
Assay (Eruslanov  & Kusmartsev, 2009) 
</td>
<td>
The dye (CM-H2DCFDA) diffuses into the cell and is cleaved by esterases, the thiol reactive chlormethyl group reacts with intracellular glutathione which can be detected using flow cytometry.
</td>
<td>
 
</td>
<td>
Long/Easy/ High Accuracy 
</td>
</tr>
</tbody>
</table>
 
<table border="1">
<tbody>
<tr>
<td>
Method of Measurement  
</td>
<td>
References  
</td>
<td>
Description  
</td>
<td colspan="2">
OECD-Approved Assay 
</td>
</tr>
<tr>
<td>
Chemiluminescence  
</td>
<td>
(Lu, C. et al., 2006;  
Griendling, K. K., et al., 2016) 
</td>
<td>
ROS can induce electron transitions in molecules, leading to electronically excited products. When the electrons transition back to ground state, chemiluminescence is emitted and can be measured. Reagents such as luminol and lucigenin are commonly used to amplify the signal.
</td>
<td colspan="2">
No 
 
</td>
</tr>
<tr>
<td>
Spectrophotometry  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
NO has a short half-life. However, if it has been reduced to nitrite (NO2-), stable azocompounds can be formed via the Griess Reaction, and further measured by spectrophotometry.  
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Direct or Spin Trapping-Based electron paramagnetic resonance (EPR) Spectroscopy  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
The unpaired electrons (free radicals) found in ROS can be detected with EPR and is known as electron paramagnetic resonance. A variety of spin traps can be used.  
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Nitroblue Tetrazolium Assay  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
The Nitroblue Tetrazolium assay is used to measure O2.− levels. O2.− reduces nitroblue tetrazolium (a yellow dye) to formazan (a blue dye), and can be measured at 620 nm.
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Fluorescence analysis of dihydroethidium (DHE) or Hydrocyans  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
Fluorescence analysis of DHE is used to measure O2.− levels.  O2.− is reduced to O2 as DHE is oxidized to 2-hydroxyethidium, and this reaction can be measured by fluorescence. Similarly, hydrocyans can be oxidized by any ROS, and measured via fluorescence.
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Amplex Red Assay  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
Fluorescence analysis to measure extramitochondrial or extracellular H2O2 levels. In the presence of horseradish peroxidase and H2O2, Amplex Red is oxidized to resorufin, a fluorescent molecule measurable by plate reader.
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Dichlorodihydrofluorescein Diacetate (DCFH-DA)  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
An indirect fluorescence analysis to measure intracellular H2O2 levels.  H2O2 interacts with peroxidase or heme proteins, which further react with DCFH, oxidizing it to dichlorofluorescein (DCF), a fluorescent product.
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
HyPer Probe  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
Fluorescent measurement of intracellular H2O2 levels. HyPer is a genetically encoded fluorescent sensor that can be used for in vivo and in situ imaging.  
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Cytochrome c Reduction Assay  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
The cytochrome c reduction assay is used to measure O2.− levels. O O2.− is reduced to O2 as ferricytochrome c is oxidized to ferrocytochrome c, and this reaction can be measured by an absorbance increase at 550 nm.
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Proton-electron double-resonance imaging (PEDRI)  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
The redox state of tissue is detected through nuclear magnetic resonance/magnetic resonance imaging, with the use of a nitroxide spin probe or biradical molecule.  
</td>
<td colspan="2">
No 
 
 
 
 
 
 
</td>
</tr>
<tr>
<td>
Glutathione (GSH) depletion  
</td>
<td>
(Biesemann, N. et al., 2018)  
</td>
<td>
A downstream target of the Nrf2 pathway is involved in GSH synthesis. As an indication of oxidation status, GSH can be measured by assaying the ratio of reduced to oxidized glutathione (GSH:GSSG) using a commercially available kit (e.g., <a href="http://www.abcam.com/gshgssg-ratio-detection-assay-kit-fluorometric-green-ab138881.html" rel="noreferrer noopener" target="_blank">http://www.abcam.com/gshgssg-ratio-detection-assay-kit-fluorometric-green-ab138881.html</a>).
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Thiobarbituric acid reactive substances (TBARS)  
</td>
<td>
(Griendling, K. K., et al., 2016) 
</td>
<td>
Oxidative damage to lipids can be measured by assaying for lipid peroxidation with TBARS using a commercially available kit.   
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Protein oxidation (carbonylation) 
</td>
<td>
(Azimzadeh et al., 2017; Azimzadeh et al., 2015; Ping et al., 2020) 
</td>
<td>
Can be determined with ELISA or a commercial assay kit. Protein oxidation can indicate the level of oxidative stress. 
</td>
<td colspan="2">
No 
</td>
</tr>
<tr>
<td>
Seahorse XFp Analyzer 
</td>
<td>
Leung et al. 2018 
</td>
<td>
The Seahorse XFp Analyzer provides information on mitochondrial function, oxidative stress, and metabolic dysfunction of viable cells by measuring respiration (oxygen consumption rate; OCR) and extracellular pH (extracellular acidification rate; ECAR).
</td>
<td>
No 
</td>
</tr>
</tbody>
</table>
 
Molecular Biology: Nrf2. Nrf2’s transcriptional activity is controlled post-translationally by oxidation of Keap1. Assays for Nrf2 activity include:  
<table border="1">
<tbody>
<tr>
<td>
Method of Measurement  
</td>
<td>
References  
</td>
<td>
Description  
</td>
<td>
OECD-Approved Assay 
</td>
</tr>
<tr>
<td>
Immunohistochemistry  
</td>
<td>
(Amsen, D., de Visser, K. E., and Town, T., 2009) 
</td>
<td>
Immunohistochemistry for increases in Nrf2 protein levels and translocation into the nucleus   
</td>
<td>
No 
</td>
</tr>
<tr>
<td>
qPCR  
</td>
<td>
(Forlenza et al., 2012) 
</td>
<td>
qPCR of Nrf2 target genes (e.g., Nqo1, Hmox-1, Gcl, Gst, Prx, TrxR, Srxn), or by commercially available pathway-based qPCR array (e.g., oxidative stress array from SABiosciences)
</td>
<td>
No 
</td>
</tr>
<tr>
<td>
Whole transcriptome profiling via microarray or via RNA-seq followed by a pathway analysis 
</td>
<td>
(Jackson, A. F. et al., 2014) 
</td>
<td>
Whole transcriptome profiling by microarray or RNA-seq followed by pathway analysis (in IPA, DAVID, metacore, etc.) for enrichment of the Nrf2 oxidative stress response pathway 
</td>
<td>
No 
</td>
</tr>
</tbody>
</table>
 
<h4>References</h4>
Halpin, L. E., Collins, S. A. & Yamamoto, B. K. Neurotoxicity of methamphetamine and 3,4-methylenedioxymethamphetamine. Life Sciences 97, 37–44 (2014).
Ahmad, S. et al. (2021), “60Co-γ Radiation Alters Developmental Stages of Zeugodacus cucurbitae (Diptera: Tephritidae) Through Apoptosis Pathways Gene Expression”, Journal Insect Science, Vol. 21/5, Oxford University Press, Oxford, <a href="https://doi.org/10.1093/jisesa/ieab080" rel="noreferrer noopener" target="_blank">https://doi.org/10.1093/jisesa/ieab080</a>
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<h4><a href="/events/352">Event: 352: N/A, Neurodegeneration</a></h4>
<h5>Short Name: N/A, Neurodegeneration</h5>
<h4>Key Event Component</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Process</th>
<th scope="col">Object</th>
<th scope="col">Action</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>neurodegeneration</td>
<td></td>
<td>increased</td>
</tr>
</tbody>
</table>
</div>
<h4>AOPs Including This Key Event</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP ID and Name</th>
<th scope="col">Event Type</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/12">Aop:12 - Chronic binding of antagonist to N-methyl-D-aspartate receptors (NMDARs) during brain development leads to neurodegeneration with impairment in learning and memory in aging</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/48">Aop:48 - Binding of agonists to ionotropic glutamate receptors in adult brain causes excitotoxicity that mediates neuronal cell death, contributing to learning and memory impairment.</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/281">Aop:281 - Acetylcholinesterase Inhibition Leading to Neurodegeneration</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/374">Aop:374 - Binding of Sars-CoV-2 spike protein to ACE 2 receptors expressed on brain cells (neuronal and non-neuronal) leads to neuroinflammation resulting in encephalitis</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/450">Aop:450 - Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/500">Aop:500 - Activation of MEK-ERK1/2 leads to deficits in learning and cognition via ROS and apoptosis</a></td>
<td>KeyEvent</td>
</tr>
<tr>
~~<td><a href="/aops/471">Aop:471 - Various neuronal effects induced by elavl3, sox10, and mbp</a></td>~~
<td><a href="/aops/471">Aop:471 - Neuron defect induced early behavioral change</a></td>
<td>KeyEvent</td>
</tr>
</tbody>
</table>
</div>
<h4>Stressors</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Name</th></tr>
</thead>
<tbody>
<tr><td>Sars-CoV-2</td></tr>
<tr><td>Chemical</td></tr>
<tr><td>SARS-CoV</td></tr>
<tr><td>Virus</td></tr>
</tbody>
</table>
</div>
<h4>Biological Context</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Level of Biological Organization</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>Tissue</td></tr>
</tbody>
</table>
</div>
<h4>Organ term</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Organ term</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>brain</td></tr>
</tbody>
</table>
</div>
<h4>Domain of Applicability</h4>
Taxonomic Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Term</th>
<th scope="col">Scientific Term</th>
<th scope="col">Evidence</th>
<th scope="col">Links</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>human</td>
<td>Homo sapiens</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=9606" target="_blank">NCBI</a></td>
</tr>
<tr>
<td>mouse</td>
<td>Mus musculus</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=10090" target="_blank">NCBI</a></td>
</tr>
<tr>
<td>zebrafish</td>
<td>Danio rerio</td>
<td>Moderate</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=7955" target="_blank">NCBI</a></td>
</tr>
</tbody>
</table>
</div>
Life Stage Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Life Stage</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>During brain development, adulthood and aging</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
Sex Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sex</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Mixed</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
The necrotic and apoptotic cell death pathways are quite well conserved throughout taxa (Blackstone and Green, 1999, Aravind et al., 2001). It has been widely suggested that apoptosis is also conserved in metazoans, although despite conservation of Bcl-2 proteins, APAF-1, and caspases there is no biochemical evidence of the existence of the mitochondrial pathway in either C. elegans or Drosophila apoptosis (Baum et al., 2007; Blackstone and Green, 1999).
<h4>Key Event Description</h4>
The term neurodegeneration is a combination of two words - "neuro," referring to nerve cells and "degeneration," referring to progressive damage. The term "neurodegeneration" can be applied to several conditions that result in the loss of nerve structure and function, and neuronal loss by necrosis and/or apoptosis
Neurodegeneration is a key aspect of a large number of diseases that come under the umbrella of “neurodegenerative diseases" including Huntington's, Alzheimer’s and Parkinson’s disease. All of these conditions lead to progressive brain damage and neurodegeneration.
Alzheimer's disease is characterised by loss of neurons and synapses in the cerebral cortex and certain subcortical regions, with gross atrophy of the affected regions; symptoms include memory loss.
Parkinson's disease (PD) results from the death of dopaminergic neurons in the midbrain substantia nigra pars compacta; symptoms include bradykinesia, rigidity, and resting tremor.
Several observations suggest correlative links between environmental exposure and neurodegenerative diseases, but only few suggest causative links:
Only an extremely small proportion (less than 5%) of neurodegenerative diseases are caused by genetic mutations (Narayan and Dragounov, 2017). The remainders are thought to be caused by the following:
·      A build up of toxic proteins in the brain (Evin et al., 2006)
·      A loss of mitochondrial function that leads to the oxidative stress and creation of neurotoxic molecules that trigger cell death (apoptotic, necrotic or autophagy) (Cobley et al., 2018)
·      Changes in the levels and activities of neurotrophic factors (Kazim and Iqbal, 2016; Machado et al., 2016; Rodriguez et al., 2014)
·      Variations in the activity of neural networks (Greicius and Kimmel, 2012)
Protein aggregation: the correlation between neurodegenerative disease and protein aggregation in the brain has long been recognised, but a causal relationship has not been unequivocally established (Lansbury et al., 2006; Kumar et al., 2016). The dynamic nature of protein aggregation mean that, despite progress in understanding its mechanisms, its relationship to disease is difficult to determine in the laboratory.
Nevertheless, drug candidates that inhibit aggregation are now being tested in the clinic. These have the potential to slow the progression of Alzheimer's disease, Parkinson's disease and related disorders and could, if administered pre-symptomatically, drastically reduce the incidence of these diseases.
Loss of mitochondrial function: many lines of evidence suggest that mitochondria have a central role in neurodegenerative diseases (Lin and Beal, 2006). Mitochondria are critical regulators of cell death, a key feature of neurodegeneration. Dysfunction of mitochondria induces oxidative stress, production of free radicals, calcium overload, and mutations in mitochondrial DNA that contribute to neurodegenerative diseases. In all major examples of these diseases there is strong evidence that mitochondrial dysfunction occurs early and acts causally in disease pathogenesis. Moreover, an impressive number of disease- specific proteins interact with mitochondria. Thus, therapies targeting basic mitochondrial processes, such as energy metabolism or free-radical generation, or specific interactions of disease-related proteins with mitochondria, hold great promise.
Decreased level of neurotrophic factors: decreased levels and activities of neurotrophic factors, such as brain-derived neurotrophic factor (BDNF), have been described in a number of neurodegenerative disorders, including Huntington's disease, Alzheimer disease and Parkinson disease (Zuccato and Cattaneo, 2009). These studies have led to the development of experimental strategies aimed at increasing BDNF levels in the brains of animals that have been genetically altered to mimic the aforementioned human diseases, with a view to ultimately influencing the clinical treatment of these conditions. Therefore BDNF treatment is being considered as a beneficial and feasible therapeutic approach in the clinic.
Variations in the activity of neural networks: Patients with various neurodegenerative disorders show remarkable fluctuations in neurological functions, even during the same day (Palop et al., 2006). These fluctuations cannot be caused by sudden loss or gain of nerve cells. Instead, it is likely that they reflect variations in the activity of neural networks and, perhaps, chronic intoxication by abnormal proteins that the brain is only temporarily able to overcome.
Neurodegeneration in relation to COVID19
SARS-CoV-2 patients present elevated plasma levels of neurofilament light chain protein (NfL), which is a well-known biochemical indicator of neuronal injury (Kanberg et al., 2020). Postmortem brain autopsies demonstrate virus invasion to different brain regions, including the hypothalamus and olfactory bulb, accompanied by neural death and demyelination (Archie and Cucullo 2020; Heneka et al. 2020).
Autopsy results of patients with SARS showed ischemic neuronal damage and demyelination; viral RNA was detected in brain tissue, particularly accumulating in and around the hippocampus (Gu et al. 2005).
Brain magnetic resonance imaging (MRI) investigations in SARS-CoV-2 patients show multifocal hyperintense white matter lesions and cortical signal abnormalities (particularly in the medial temporal lobe) on fluid-attenuated inversion recovery (FLAIR), along with intracerebral hemorrhagic and microhemorrhagic lesions, and leptomeningeal enhancement (Kandemirli et al. 2020; Kremer et al. 2020; Mohammadi et al., 2020).
Moreover, eight COVID-19 patients with signs of encephalopathy had anti–SARS-CoV-2 antibodies in their CSF, and 4 patients had CSF positive for 14-3-3-protein suggesting ongoing neurodegeneration (Alexopoulos et al. 2020).
<h4>How it is Measured or Detected</h4>
The assays for measurements of necrotic or apoptotic cell death are described in the Key Event: Cell injury/Cell death
Recent neuropathological studies have shown that Fluoro-Jade, an anionic fluorescent dye, is a good marker of degenerating neurons. Fluoro-Jade and Fluoro-Jade B were found to stain all degenerating neurons, regardless of specific insult or mechanism of cell death (Schmued et al., 2005). More recently, Fluoro-Jade C was shown to be highly resistant to fading and compatible with virtually all histological processing and staining protocols (Schmued et al., 2005). In addition, Fluoro-Jade C is a good tool for detecting acutely and chronically degenerating neurons (Ehara and Ueda, 2009).
<h4>Regulatory Significance of the AO</h4>
Currently the four available OECD Test Guidelines (TGs) for neurotoxicity testing are entirely based on in vivo neurotoxicity studies: (1)Delayed Neurotoxicity of Organophosphorus Substances Following Acute Exposure (TG 418); (2) Delayed Neurotoxicity of Organophosphorus Substances: 28-day Repeated Dose Study (TG 419); (3) Neurotoxicity Study in Rodents (TG 424) involves daily oral dosing of rats for acute, subchronic, or chronic assessments (28 days, 90 days, or one year or longer); (4) Developmental Neurotoxicity (DNT) Study (TG 426) evaluates in utero and early postnatal effects by daily dosing of at least 60 pregnant rats from implantation through lactation. One of the endpoints required by all four of these OECD TGs is evaluation of neurodegeneration that, so far, is performed through in vivo neuropathological and histological studies. Therefore, neurodegeneration described in this AOP as a key event, has a regulatory relevance and could be performed using in vitro assays that allow a reliable evaluation of neurodegeneration using a large range of existing assays, specific for apoptosis, necrosis and autophagy ( see also KE Cell injury/Cell death).
<h4>References</h4>
Aravind, L., Dixit, V. M., and Koonin, E. V. (2001). Apoptotic Molecular Machinery: Vastly Increased Complexity in Vertebrates Revealed by Genome Comparisons. Science 291, 1279-1284.
Baum, J. S., Arama, E., Steller, H., and McCall, K. (2007). The Drosophila caspases Strica and Dronc function redundantly in programmed cell death during oogenesis. Cell Death Differ 14, 1508-1517.
Blackstone, N. W., and Green, D. R. (1999). The evolution of a mechanism of cell suicide. Bioessays 21, 84-88.
Cobley JN, Fiorello ML, Bailey DM (2018) 13 reasons why the brain is susceptible to oxidative stress. Redox Biol 15: 490-503
Ehara A, Ueda S. 2009. Application of Fluoro-Jade C in acute and chronic neurodegeneration models: utilities and staining differences. Acta histochemica et cytochemica 42(6): 171-179.
Evin G, Sernee MF, Masters CL (2006) Inhibition of gamma-secretase as a therapeutic intervention for Alzheimer's disease: prospects, limitations and strategies. CNS Drugs 20: 351-72
Greicius MD, Kimmel DL (2012) Neuroimaging insights into network-based neurodegeneration. Curr Opin Neurol 25: 727-34
Kazim SF, Iqbal K (2016) Neurotrophic factor small-molecule mimetics mediated neuroregeneration and synaptic repair: emerging therapeutic modality for Alzheimer's disease. Mol Neurodegener 11: 50
Kumar V, Sami N, Kashav T, Islam A, Ahmad F, Hassan MI (2016) Protein aggregation and neurodegenerative diseases: From theory to therapy. Eur J Med Chem 124: 1105-1120
Lansbury1 PT & Lashuel HA (2006) A century-old debate on protein aggregation and neurodegeneration enters the clinic. Nature 443, 774-779.
Lin1 MT & Beal MF (2006) Mitochondrial dysfunction and oxidative stress in neurodegenerative diseases. Nature 443, 787-795
Machado V, Zoller T, Attaai A, Spittau B (2016) Microglia-Mediated Neuroinflammation and Neurotrophic Factor-Induced Protection in the MPTP Mouse Model of Parkinson's Disease-Lessons from Transgenic Mice. Int J Mol Sci 17
Narayan P, Dragunow M (2017) Alzheimer's Disease and Histone Code Alterations. Adv Exp Med Biol 978: 321-336
Palop JJ, Chin1 J & Mucke L, Review Article A network dysfunction perspective on neurodegenerative diseases. 2006, Nature 443, 768-773
Rodrigues TM, Jeronimo-Santos A, Outeiro TF, Sebastiao AM, Diogenes MJ (2014) Challenges and promises in the development of neurotrophic factor-based therapies for Parkinson's disease. Drugs Aging 31: 239-61
Schmued LC, Stowers CC, Scallet AC, Xu L. 2005. Fluoro-Jade C results in ultra high resolution and contrast labeling of degenerating neurons. Brain Res 1035(1): 24-31.
Zuccato C & Cattaneo E, Brain-derived neurotrophic factor in neurodegenerative diseases.2009, Nature Reviews Neurology 5, 311-3
COVID19-related references relevant to KE Neurodegeneration:
Alexopoulos et al. Anti-SARS-CoV-2 antibodies in the CSF, blood-brain barrier dysfunction, and neurological outcome: Studies in 8 stuporous and comatose patients. Neurol Neuroimmunol Neuroinflamm. 2020 Sep 25;7(6):e893.
Archie SR, Cucullo L. Cerebrovascular and neurological dysfunction under the threat of COVID-19: is there a comorbid role for smoking and vaping? Int J Mol Sci. 2020 21(11):3916 12.
Gu J et al. Multiple organ infection and the pathogenesis of SARS. J Exp Med. 2005;202:415–424.
Heneka MT, et al. Immediate and long-term consequences of COVID-19 infections for the development of neurological disease. Alzheimers Res Ther. 2020 12(1):1–3.
Kandemirli SG, et al. Brain MRI findings in patients in the intensive care unit with COVID-19 infection. Radiology. 2020 Oct;297(1):E232-E235.
Kanberg N, et al. Neurochemical evidence of astrocytic and neuronal injury commonly found in COVID-19. Neurology. 2020 Sep 22;95(12):e1754-e1759.
Kremer S, et al. Brain MRI findings in severe COVID-19: a retrospective observational study. Radiology. 2020 Nov;297(2):E242-E251.
Mohammadi S. et al. Understanding the Immunologic Characteristics of Neurologic Manifestations of SARS-CoV-2 and Potential Immunological Mechanisms. Mol Neurobiol. 2020 Dec;57(12):5263-5275.
<h4><a href="/events/618">Event: 618: Decreased, Neuronal network function in adult brain</a></h4>
<h5>Short Name: Decreased, Neuronal network function in adult brain</h5>
<h4>Key Event Component</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Process</th>
<th scope="col">Object</th>
<th scope="col">Action</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>synaptic signaling</td>
<td></td>
<td>decreased</td>
</tr>
</tbody>
</table>
</div>
<h4>AOPs Including This Key Event</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP ID and Name</th>
<th scope="col">Event Type</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/48">Aop:48 - Binding of agonists to ionotropic glutamate receptors in adult brain causes excitotoxicity that mediates neuronal cell death, contributing to learning and memory impairment.</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/450">Aop:450 - Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>KeyEvent</td>
</tr>
<tr>
~~<td><a href="/aops/471">Aop:471 - Various neuronal effects induced by elavl3, sox10, and mbp</a></td>~~
<td><a href="/aops/471">Aop:471 - Neuron defect induced early behavioral change</a></td>
<td>KeyEvent</td>
</tr>
</tbody>
</table>
</div>
<h4>Biological Context</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Level of Biological Organization</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>Organ</td></tr>
</tbody>
</table>
</div>
<h4>Organ term</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Organ term</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>brain</td></tr>
</tbody>
</table>
</div>
<h4>Domain of Applicability</h4>
The ability to process complex spatiotemporal information through neuronal networking is a fundamental process underlying the behaviour of all higher organisms.
The most studied are the neuronal networks of rodents (e.g Reig et al., 2015) and primates (e.g. Wang and Arnsten, 2015) and extremely large amount of the published data exist to support this topic.
Invertebrates hold neural circuitries in various degrees of complexity and there are studies describing how neurons are organized into functional networks to generate behaviour. (Wong and Wong, 2004; Marder, 1994).
<h4>Key Event Description</h4>
Biological state:
In the brain, neurons never work alone. They create a network where the activity of one cell directly influences many others. Each neuron is a specialized cell and when activated, it fires an electrochemical signal along the axon. A neuron fires only if the total signal received at the cell body from the dendrites exceeds a certain level (the firing threshold). The strength of the signal received by a neuron (and therefore its chances of firing) critically depends on the efficacy of the synapses. Each synapse actually contains a synaptic cleft with neurotransmitter that transmits a signal across the gap. During synaptic transmission neurotransmitters are released by a presynaptic neuron and bind to and activate the receptors of the postsynaptic neuron in response to a threshold of action potential. Synaptic transmission relies on: the availability of the neurotransmitter; the release of the neurotransmitter by exocytosis; the binding of the postsynaptic receptor by the neurotransmitter; the functional response of the postsynaptic cell; and the subsequent removal or deactivation of the neurotransmitter.
Neurons form complex networks of synapses through which action potentials travel. When the nerve impulse arrives at the synapse, it may cause the release of neurotransmitters, which influence another (postsynaptic) neuron. The postsynaptic neurons receive inputs from many additional neurons, both excitatory and inhibitory. The excitatory and inhibitory influences are summed (neural summation) resulting in inhibition or "firing" (i.e., generate an action potential) if the threshold potential has been reached. The voltage at which an action potential is triggered happens if enough voltage-dependent sodium channels are activated and the net inward sodium current exceeds all outward currents (Kolb and Whishaw, 2003). Therefore, at the beginning of the action potential, the Na+ channels open and Na+ moves into the axon, causing depolarization. Re-polarization occurs when the K+ channels open and K+ moves out of the axon. This creates a change in polarity between the outside of the cell and the inside. The impulse travels down from the axon hillock in one direction only, to the axon terminal. Here, the neurotransmitter is released releasing neurotransmitter at the synaptic cleft to pass along information to another adjacent neuron. Excitatory inputs bring a neuron closer to a firing threshold, while inhibitory inputs bring the neuron farther from threshold. An action potential is an "all-or-none" event; neurons whose membranes have not reached threshold will not fire, while those that do, will fire.
One of the most influential researchers into neurological systems (Donald Hebb) postulated that learning consisted principally in altering the "strength" of synaptic networking. Recent research in cognitive science, in particular in the area of non-conscious information processing, have further demonstrated the enormous capacity of the human mind to learn simple input-output co-variations from extremely complex stimuli. Consequently, the neurodegeneration and cell death disrupt the natural rhythms of brain network communication. Cognitive disorders are primarily associated with dysfunction of the neurons of the prefrontal cortex, hippocampus and with changes mainly in NMDARs function (Wang et al, 2015).
Biological compartments:
The interface through which neurons interact with their neighbours usually consists of several axon terminals connected via synapses to dendrites on other neurons. If the hippocampal or cortical neurons are damaged or killed by the over-activation of receptors for the excitatory neurotransmitter glutamate, such as the NMDA, kainate and AMPA receptors, the neuronal networking and number of synapses are decreased. Indeed, it has been proved that lesions of the hippocampus in humans prevent the acquisition of new episodic memories suggesting that hippocampus-dependent memory is mediated, at least in part, by hippocampal synaptic plasticity that is a prominent feature of hippocampal synapses of the neuronal network (Neves et al., 2008). Since the finding that the hippocampus plays a pivotal role in long-term memory consolidation (dogma, well established fact in the literature, described in the text books; e.g. Andersen et al., 2007; Byrne, 2008; Eichenbaum, 2002), many proposals have been made regarding its specific role. A prominent view of the mechanisms underlying consolidation of episodic memories involves fast formation (e.g., via Hebbian mechanisms) of strong associations between hippocampal sparse patterns of activity and distributed neocortical representations.
Recent research on the primate prefrontal cortex discovered that the pyramidal cell circuits that generate the persistent firing underlying spatial working memory communicate through synapses on spines containing NMDARs with NR2B subunits (GluN2B) in the post-synaptic density. This contrasts with synapses in the hippocampus and primary visual cortex, where GluN2B receptors are both synaptic and extrasynaptic. Cholinergic stimulation of nicotinic α7 receptors within the glutamate synapse is necessary for NMDAR actions (Wang and Arnsten, 2015).
General role in biology:
Glutamatergic neurotransmission (NMDA, AMPA and KA receptors)
The network of glutamatergic neurons is heavily involved in long-term synaptic plasticity, the main process linked to learning and memory. At the same time over-activation of these neurons (excitotoxicity) leads to neuronal cell death that can be mediated by increased levels of extracellular glutamate or a molecule that behaves as its analogue. Glutamate acts at a variety of ionotropic receptors, including AMPARs, kainate receptors, and NMDARs. The NMDARs have been of particular interest due to their unique properties. They require neuronal depolarization to relieve their Mg++ block, and are permeable to Ca++ that can initiate second-messenger signalling events, such as mediating neuroplasticity or negative feedback through Ca++-sensitive K+ channels. There have been extensive studies on the glutamate NMDAR and AMPAR mechanisms underlying long-term synaptic plasticity in the primary visual cortex and in CA1 neurons of the hippocampus (Liu et al., 2004; Cho et al., 2009; Lüscher and Malenka, 2012).
Neuronal network function and long-term plasticity is also regulated by the levels of AMPAR expression as the number of AMPARs inserted into the post-synaptic density can mediate the degree of spine depolarization and thus the NMDAR opening. Synaptic plasticity in the mature visual cortex appears to be governed by GluN2A subunits, which have faster kinetics than GluN2B. GluN2B receptors are expressed in synapses early in development, but many move to extra-synaptic locations in the mature visual cortex and hippocampus (Goebel-Goody et al., 2009). The actions of NMDARs on the dorsolateral prefrontal cortex neuronal circuitry network underlying spatial working memory in primates and it mechanism is described in detail by Wang and Arnsten (2015). In the hippocampus, there is some evidence that long-term potentiation (LTP) is mediated by synaptic GluN2A, while long-term depression is mediated by extrasynaptic GluN2B receptors (Liu et al., 2004).
Kainate receptors (KARs) also play an important role in neuronal network function. They play a major function in the pre-synaptic terminal, in particular in the hippocampus. Activation of kainate receptors in have been shown to regulate glutamate release (Jane et al., 2009) and to both depress and factilitate transmission in different synapses. Pre-synaptic kainate receptors in the hippocampus facilitate AMPA and NMDA receptor-mediated transmission at mossy fibre-CA3 synapses (Lauri et al, 2005). Activation of post-synaptic KARs facilitates activation of NMDARs as it has been described in the context of DomA exposure.
Role of other neurotransmitters
It is important to stress that other classical neurotransmitter systems also play an important role in learning and memory processes (Blokland 1996). The role of the most critical neurotransmitters has been evaluated in a meta-analysis based on studies of four behavioral tasks relevant for evaluation of rat cognitive functions such as Morris water maze, radial maze, passive avoidance, and spontaneous alternation (Myhrer, 2003). Calculation of impact factors (percentage of significant effects of chemical agents like agonists, antagonists, neurotoxins) showed that glutamate was ranking highest (93), followed by GABA (81), dopamine (81), acetylcholine (81), serotonin (55), and norepinephrine (48).
GABA-ergic receptors: indeed, presynaptic GABA B receptors mediate GABA-dependent inhibition of glutamate release, impacting plasticity of hippocampal synapses and hippocampus-dependent memory function (Vigot et al., 2006). A critical link between GABABR heterodimer conformational dynamics and local regulation of release probability at hippocampal synapses has been recently proved (Laviv et al., 2010).
5-Hydroxytrytamine (serotonin) type 3A receptors (5-HT3ARs), as the only ligand-gated ion channels in the serotonin receptor family, are known to regulate neuronal excitation and release of GABA in hippocampal interneurons, playing also an important role in glutamatergic synaptic plasticity. Deletion of the 5-HT3AR gene in transgenic mice abolished NMDAR-dependent long-term depression (LTD) induced by low-frequency stimulation (LFS) in hippocampal CA1 synapses in slices. In addition, 5-HT3ARs disruption inhibited AMPARs internalization, without altering basal surface levels of AMPARs. These observations revealed an important role of 5-HT3ARs in NMDAR-dependent long-term depression, which is critical for learning behaviours (Yu et al., 2014).
The cholinergic hypothesis claims that the decline in cognitive functions in dementia is predominantly related to a decrease in cholinergic neurotransmission. This hypothesis has led to great interest in the putative involvement of the cholinergic neurotransmission in learning and memory processes (Blokland 1996; Bracco et al., 2014).
Dopamine plays diverse roles in human behaviour and cognition but it is mainly involved in motivation, decision-making, reward processing, attention, working memory and learning (Steinberg and Janak, 2012; Labudda et al., 2010).
Noradrenaline is associated with memory processing as it induces lasting changes in the brain that could sustain memories over time (Gazarini et al., 2013). As confirmed later on its neurotransmission indeed strengthens memory-related synaptic plasticity such as long-term potentiation, allowing memories to be formed and maintained in a more intense and enduring manner, a notion particularly valid for those with emotional content (Joëls et al. 2011). Like other types of memory, an emotional memory has to be consolidated to allow its later retrieval. Accumulating evidence has indicated that noradrenaline acts during these gradual stages to fine-tune the strength and/or persistence of a memory (Guzmán-Ramos et al. 2012; Gazarini et al., 2013).
<h4>How it is Measured or Detected</h4>
Methods that have been previously reviewed and approved by a recognized authority should be included in the Overview section above.
All other methods, including those well established in the published literature, should be described here.
Consider the following criteria when describing each method:
1. Is the assay fit for purpose?
2. Is the assay directly or indirectly (i.e. a surrogate) related to a key event relevant to the final
adverse effect in question?
3. Is the assay repeatable?
4. Is the assay reproducible?
Neuronal network activity is fundamental to brain function and now can be measured using in vitro and in vivo techniques such as:
1. Two-photon imaging of cell populations in vivo that are labelled with fluorescent calcium indicators. Two-photon imaging relies on fluorescence excitation and, in general, necessitates staining of cells with fluorescent dyes. Various staining methods have been developed for in vivo calcium measurements. Single cells can be filled with membrane-impermeable calcium indicators via intracellular recording electrodes or by single-cell electroporation. The basic aspects of in vivo calcium imaging and recent developments that allow evaluation of the neural circuits activity are described by Göbel et al., (2007a).
With new imaging technology, scientists are now better able to visualize neural circuits connecting brain regions in humans. Advances in genetic engineering, microscopy, and computing are enabling scientists to begin to map the connections between individual nerve cells.
2. Optical detection of neuronal spikes both in vivo and in vitro.
Assuming action potential (AP) as the only trigger of calcium influx, spike patterns are directly reflected in the trains of calcium transients. Each fluorescence trace is the convolution of the spike train with the single AP-evoked calcium transient plus added noise. The temporal resolution will be limited by the acquisition rate of the network scanning approach. In addition, the signal-to-noise ratio of fluorescence signals will be a decisive factor for the accuracy of the reconstruction.
3. Microelectrode array (MEA) recordings in primary cultures. Glutamate analogues effects on neuronal network activity can be assessed (Lantz et al., 2014) and neuronal spontaneous activity evaluation is already used for screening purposes (Valdivia et al., 2014).
4. To understand the function of a neural circuit, it is important to discriminate its sub-network components. This is possible through counterstaining of specific neuronal and glial cell types, especially in bulk loaded tissue where markers need not be calcium sensitive. In addition, transgenic mice with fluorescent protein expression in specific neuronal subsets, allow separation of functional signals into different neuronal subtypes (Göbel et al., 2007b).
5. Combined positron emission tomography (PET) and magnetic resonance imaging (MRI) is a new tool to study functional processes in the brain, including the response to a stimulus simultaneously using PET. Functional MRI (fMRI), is used to assesses at the same time fast vascular and oxygenation changes during activation. These results demonstrate the feasibility of combined PET-MRI for the simultaneous study of the brain at activation and rest, revealing comprehensive and complementary information to further decode brain function and brain networks (Wehrl et al., 2013).
6. Seed-based correlative analysis of [18F]fluorodeoxyglucose (FDG)-PET (FDG-PET) differences in images (resting state minus activation) is suitable to identify cerebral networks in rats. Using awake and freely moving animals enables functional network analysis of complex behavioral paradigms (Rohleder et al., 2015).
Although most experiments at present are carried out in anesthetized animals, several approaches for imaging in awake behaving animals have been devised that ultimately aim at directly correlating neuronal network dynamics with behaviour (Dombeck et al., 2007, Arenkiel et al., 2007). Finally, through expression of light-activated channel proteins, it might become possible in the future to not only read-out but also control neuronal networks in vivo (Garaschuk et al., 2006)since with the development of X-ray, CT, and MRI, deep neural networks involved in learning and memory processes can be studied in vivo (Cheng et al., .2014).
7. NMDAR overactivation-induced LTD that decrease number of spine density can be measured in vitro using GFP technology and by cofilin-F-actin quantification (Calabrese et al., 2014).
Current behavioural tests used for evaluating neural network function:
1. The Morris water maze: this test is developed to measure spatial orientation in rats
The rat has to swim around the pool to search for a platform onto which he can escape from the water. In one condition, the platform is visible, rising 1 cm above the water surface. In a Second condition the rat has to learn to find the hidden platform provided it remains in the fixed position relative to distal room cues.
2. Radial maze: In the T-maze version of working memory, the animal has to remember only a single item for each trial. In the radial arm version of the working memory procedure rats have to learn multiple items.
3. Passive avoidance: fear-motivated avoidance tests are usually based on electric current as source of punishment.
4. Spontaneous alternation: spontaneous alternation is spatial alternation and represents a tendency to avoid stimulus re-exposure during exploratory behaviour. T-maze (simple or multiple), Y-maze, and radial maze are used to quantify an innate, unlearned response in rats.
These four behavioural tests are described in detail in the review by Myhrer (Myhrer et al., 2003).
<h4>References</h4>
Andersen Per, Richard Morris, David Amaral, Tim Bliss and John O'Keefe, eds., The Hippocampus Book. Oxford University Press. ISBN, 2007, 978-0-19-510027-3.
Arenkiel BR, Peca J, Davison IG, Feliciano C, Deisseroth K, Augustine GJ, Ehlers MD, Feng G. In vivo light-induced activation of neural circuitry in transgenic mice expressing channelrhodopsin-2. Neuron, 2007, 54: 205–218.
Blokland A, Acetylcholine: a neurotransmitter for learning and memory? Brain Research Reviews, 1996, 21: 285-300.
Bracco L, Bessi V, Padiglioni S, Marini S1, Pepeu G., Do cholinesterase inhibitors act primarily on attention deficit? A naturalistic study in Alzheimer's disease patients. J Alzheimers Dis. 2014, 40(3):737-42.
Byrne John H, ed., Learning and Memory: A comprehensive reference. Elsevier. 2008, <a href="/wiki/index.php/Special:BookSources/9780123705099" class="internal mw-magiclink-isbn">ISBN 978-0-12-370509-9</a>.
Calabrese B., Saffin JM, Halpain SH. Activity-Dependent Dendritic Spine Shrinkage and Growth Involve Downregulation of Cofilin via Distinct Mechanisms, 2014 DOI: 10.1371/journal.pone.0094787
Cheng Da, Haixian Zhang, Yongsheng Sang. Brain CT Image Classification with Deep Neural Networks,Chapter from Proceedings of the 18th Asia Pacific Symposium on Intelligent and Evolutionary Systems, 2014, Volume 1 of the series Proceedings in Adaptation, Learning and Optimization pp 653-662.
Cho KK, Khibnik L, Philpot BD, Bear MF., The ratio of NR2A/B NMDA receptor subunits determines the qualities of ocular dominance plasticity in visual cortex. Proc Natl Acad Sci USA 2009, 106: 5377–5382.
Dombeck DA, Khabbaz AN, Collman F, Tank DW., Imaging large scale neural activity with cellular resolution in awake mobile mice. Neuron, 2007, 56: 43–57.
Eichenbaum Howard, The Cognitive Neuroscience of Memory. Oxford University Press US. 2002, <a href="/wiki/index.php/Special:BookSources/9780195141757" class="internal mw-magiclink-isbn">ISBN 978-0-19-514175-7</a>.
Gazarini L, Cristina A. Jark Stern, Antônio P., Carobrez and Leandro J. Bertoglio. 2013 Enhanced noradrenergic activity potentiates fear memory consolidation and reconsolidation by differentially recruiting α1- and β-adrenergic receptorsCurrent Issue Learning Memory, 2013, 20: 210-219.
Göbel W, Fritjof Helmchen, In Vivo Calcium Imaging of Neural Network Function, Physiology, 2007a, 22: 358-365.
Göbel W, Fritjof Helmchen, New Angles on Neuronal Dendrites In Vivo, Journal of Neurophysiology, 2007b, 98: 3770-3779.
Goebel-Goody SM, Davies KD, Alvestad Linger RM, Freund RK, Browning MD, Phospho-regulation of synaptic and extrasynaptic N-methyl-d-aspartate receptors in adult hippocampal slices. Neuroscience 2009, 158: 1446–1459.
Garaschuk O, Milos RI, Grienberger C, Marandi N, Adelsberger H, Konnerth A., Optical monitoring of brain function in vivo: from neurons to networks. Pflügers Arch., 2006, 453: 385–396.
Guzmán-Ramos K, Osorio-Gómez D, Moreno-Castilla P, Bermúdez-Rattoni F., Post-acquisition release of glutamate and norepinephrine in the amygdala is involved in taste-aversion memory consolidation. Learn Mem., 2012, 19: 231–238.
Jane DE, Lodge D, Collingridge GL. Kainate receptors: pharmacology, function and therapeutic potential. Neuropharmacology. 2009;56(1):90-113.
Joëls M, Fernandez G, Roozendaal B., Stress and emotional memory: A matter of timing. Trends Cogn Sci., 2011, 15: 280–288.
Kolb, Bryan; Whishaw, Ian Q., Fundamentals of Human Neuropsychology (5th ed.). 2003, Worth. pp. 102–104. <a href="/wiki/index.php/Special:BookSources/9780716753001" class="internal mw-magiclink-isbn">ISBN 978-0-7167-5300-1</a>.
Labudda K, Brand M, Mertens M, Ollech I, Markowitsch HJ and Woermann FG., Decision making under risk condition in patients with Parkinson’s disease: A behavioural and fMRI study. Behavioral Neurology. 2010, 23(3): 131-143.
Lantz SR1, Mack CM2, Wallace K2, Key EF3, Shafer TJ2, Casida JE3. 2014, Glufosinate binds N-methyl-D-aspartate receptors and increases neuronal network activity in vitro, Neurotoxicology. 2014, 45:38-47.
Lauri S.E., Mikael Segerstråle, Aino Vesikansa, Francois Maingret, Christophe Mulle, Graham L. Collingridge, John T. R. Isaac, Tomi Taira. Endogenous Activation of Kainate Receptors Regulates Glutamate Release and Network Activity in developing Hippocampus. The Journal of Neuroscience, 2005, 25(18): 4473-4484.
Laviv Tal, Inbal Riven, Iftach Dolev, Irena Vertkin, Bartosz Balana, Paul A. Slesinger, Inna Slutsky, Basal GABA Regulates GABABR Conformation and Release Probability at Single Hippocampal Synapses. Neuron, 2010, 67: 253–267.
Liu L, Wong TP, Pozza MF, Lingenhoehl K, Wang Y, Sheng M, et al., Role of NMDA receptor subtypes in governing the direction of hippocampal synaptic plasticity. Science 2004, 304: 1021–1024.
Lüscher C., Malenka RC. NMDA receptor-dependent longterm potentiation and long-term depression (LTP/LTD). Cold Spring Harb Perspect Biol 2012, 4: pii: a005710.
Marder E., Invertebrate neurobiology. Polymorphic neural networks. Curr Biol. 1994, 4: 752-4.
Myhrer T., Neurotransmitter systems involved in learning and memory in the rat: a meta-analysis based on studies of four behavioral tasks. Brain Res Brain Res Rev. 2003, 41(2-3):268-87.
Neves G., Sam F. Cooke & Tim V. P. Bliss, Synaptic plasticity, memory and the hippocampus: a neural network approach to causality. Nature Reviews Neuroscience, 2008, 9: 65-75.
Reig R, Zerlaut Y, Vergara R, Destexhe A, Sanchez-Vives MV., Gain modulation of synaptic inputs by network state in auditory cortex in vivo. J Neurosci. 2015, 35(6) :2689-702.
Rohleder Cathrin, F. Leweke, Bernd Neumaier, Alexander Drzezga, Heike Endepols Characterization of functional neural networks using [18F]fluorodeoxyglucose (FDG)-PET in awake rats. J Nucl Med May 1, 2015, 56 no. supplement 3 1542.
Steinberg EE and Janak PH., Establishing causality for dopamine in neural function and behavior with optogenetics. Brain Research, 2012, 9: 52-63.
Valdivia P., Matt Martin, William R. LeFew, James Ross, Keith A. Houck, Timothy J. Shafer, Multi-well microelectrode array recordings detect neuroactivity of ToxCast compounds, NeuroToxicology, 2014, 44: 204–217.
Vigot, R., Barbieri, S., Brauner-Osborne, H., Turecek, R., Shigemoto, R., Zhang, Y.P., Lujan, R., Jacobson, L.H., Biermann, B., Fritschy, J.M., et al., Differential compartmentalization and distinct functions of GABAB receptor variants. Neuron, 2006, 50: 589–601.
Wang M., Amy F T Arnsten, Contribution of NMDA receptors to dorsolateral prefrontal cortical networks in primates, Neurosci Bull April 1, 2015, 31(2): 191–197
Wehrl Hans F, Mosaddek Hossain, Konrad Lankes, Chih-Chieh Liu, Ilja Bezrukov, Petros Martirosian, Fritz Schick, Gerald Reischl, Bernd J Pichler, Simultaneous PET-MRI reveals brain function in activated and resting state on metabolic, hemodynamic and multiple temporal scales. Nature Medicine, 2013, 19: 1184–1189.
Wong Y.H. and Wong J.T.Y, Invertebrate Neural Networks, Neuro-Signals, 2004, 13, No. 1-2.
Yu Y, Cao DQ, Xu HY, Sun M, Huang ZL, Yung WH, Lu N, Huang Y6., 5-HT3A receptors are required in long-term depression and AMPA receptor internalization. Neuroscience. 2014, 278:105-12.
<h3>List of Adverse Outcomes in this AOP</h3>
<h4><a href="/events/1583">Event: 1583: Sensory axonal peripheral neuropathy</a></h4>
<h5>Short Name: Sensory axonal peripheral neuropathy</h5>
<h4>AOPs Including This Key Event</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP ID and Name</th>
<th scope="col">Event Type</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/279">Aop:279 - Microtubule interacting drugs lead to peripheral neuropathy</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/450">Aop:450 - Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
~~<td><a href="/aops/471">Aop:471 - Various neuronal effects induced by elavl3, sox10, and mbp</a></td>~~
<td><a href="/aops/471">Aop:471 - Neuron defect induced early behavioral change</a></td>
<td>KeyEvent</td>
</tr>
</tbody>
</table>
</div>
<h4>Biological Context</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Level of Biological Organization</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>Individual</td></tr>
</tbody>
</table>
</div>
<h4>Key Event Description</h4>
The peripheral nervous system (PNS) connects the central nervous system with peripheral tissues and can be divided into the visceral and the somatic nervous system.The somatic nervous system consists of sensory and motor neurons. While the motor neurons control the contraction of skeletal muscles, the sensory neurons receive information from joints, muscles and skin and send it to the CNS. Motor neuron cell bodies lie in the spinal cord but cell bodies of the sensory neurons are located in the dorsal root ganglia (DRG). In contrast to the central nervous system (CNS), the PNS is not protected by the blood-brain-barrier, the skull or the spinal column and is therefore highly vulnerable to toxicants and mechanical damage. [1] However, the PNS neurons exhibits a greater ability of regeneration compared to neurons of the CNS. [2]
Peripheral neuropathies mostly affect sensory neurons in a length-dependent manner and therefore are characterized by a stocking-and-glove distribution of the symptoms. Sensory symptoms occurring upon taxol treatment are for example numbness and paresthesia. [3-6] Reversibility of neuropathy upon discontinuation of treatment is reported. [7]
<h4>How it is Measured or Detected</h4>
- Retrospective study: Patients are interviewed after chemotherapy treatment and symptoms are assessed. [8, 9]
- Abnormal pin perception: Measurement of the distance in centimeters from the tip of the great toe or index finger to a level where normal pin sensation was sensed.
- Abnormalities in vibration and position sensation: Measurement at distal phalanx of the great toe or index finger. [9, 10]
- Reductions in strength of toe extensors, index finger abductors, arm abductors, hip flexors, foot dorsiflexors: Measurement by using the MRC scale and dynamometer [9, 10]
- Nerve conduction studies: Electrophysiological measurement of nerve conduction amplitudes and velocities in sensory neurons [9, 10]
- Quantitative sensory testing of vibratory threshold: Measurement of vibratory latency in seconds between the patient and the examiner in toes and fingers. [9, 10] Automated measurement using e.g. ‘Vibration 2’ (Physitemp Instruments Inc., Clifton NJ) which can be adjusted to different vibration amplitudes and records vibration units. [6]
- Quantitative sensory testing of thermal threshold: Using the Thermal Sensitivity Tester or NTE-2 (Physitemp Instruments Inc., Clifton NJ), the ability to discriminate small temperature differences at the index finger or the great toe can be quantified. [6, 11, 12]
- Sural nerve biopsy: A part of the sural nerve (some millimetres) is removed, fixed and investigated via light or electron microscopy. [13]
<h4>References</h4>
1. Benoy V. , d.Y.C., Van Den Bosch L. , Charcot-Marie-Tooth Disease and other peripheral neuropathies, in Young Perspectives for Old Diseases, M.H. G., Editor. 2015, Bentham Science Publishers. p. pp. 269-325.
2. Yiu, G. and Z. He, Glial inhibition of CNS axon regeneration. Nature Reviews Neuroscience, 2006. 7: p. 617.
3. Rowinsky, E.K., et al., Neurotoxicity of Taxol. J Natl Cancer Inst Monogr, 1993(15): p. 107-15.
4. Rowinsky , E.K. and R.C. Donehower Paclitaxel (Taxol). New England Journal of Medicine, 1995. 332(15): p. 1004-1014.
5. Donehower, R.C., et al., Phase I trial of taxol in patients with advanced cancer. Cancer treatment reports, 1987. 71(12): p. 1171-1177.
6. Forsyth, P.a., et al., Prospective study of paclitaxel-induced peripheral neuropathy with quantitative sensory testing. Journal of Neuro-Oncology, 1997. 35(1): p. 47-53.
7. Brown, T., et al., A phase I trial of taxol given by a 6-hour intravenous infusion. Journal of Clinical Oncology, 1991. 9(7): p. 1261-1267.
8. Pignata, S., et al., Residual neurotoxicity in ovarian cancer patients in clinical remission after first-line chemotherapy with carboplatin and paclitaxel: The Multicenter Italian Trial in Ovarian cancer (MITO-4) retrospective study. BMC Cancer, 2006. 6(1): p. 5.
9. Rowinsky, E.K., et al., Sequences of taxol and cisplatin: a phase I and pharmacologic study. Journal of Clinical Oncology, 1991. 9(9): p. 1692-1703.
10. Chaudhry, V., et al., Peripheral neuropathy from taxol and cisplatin combination chemotherapy: Clinical and electrophysiological studies. Annals of Neurology, 1994. 35(3): p. 304-311.
11. Arezzo, J.C., H.H. Schaumburg, and C. Laudadio, Thermal Sensitivity Tester: Device for Quantitative Assessment of Thermal Sense in Diabetic Neuropathy. Diabetes, 1986. 35(5): p. 590-592.
12. Wiernik, P.H., et al., Phase I Clinical and Pharmacokinetic Study of Taxol. Cancer Research, 1987. 47(9): p. 2486-2493.
13. Behse, F., F. Buchthal, and F. Carlsen, Nerve biopsy and conduction studies in diabetic neuropathy. Journal of Neurology, Neurosurgery, and Psychiatry, 1977. 40(11): p. 1072-1082.
<h4><a href="/events/351">Event: 351: Increased Mortality</a></h4>
<h5>Short Name: Increased Mortality</h5>
<h4>Key Event Component</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Process</th>
<th scope="col">Object</th>
<th scope="col">Action</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>mortality</td>
<td></td>
<td>increased</td>
</tr>
</tbody>
</table>
</div>
<h4>AOPs Including This Key Event</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP ID and Name</th>
<th scope="col">Event Type</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/16">Aop:16 - Acetylcholinesterase inhibition leading to acute mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/96">Aop:96 - Axonal sodium channel modulation leading to acute mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/104">Aop:104 - Altered ion channel activity leading impaired heart function</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/113">Aop:113 - Glutamate-gated chloride channel activation leading to acute mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/160">Aop:160 - Ionotropic gamma-aminobutyric acid receptor activation mediated neurotransmission inhibition leading to mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/161">Aop:161 - Glutamate-gated chloride channel activation leading to neurotransmission inhibition associated mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/138">Aop:138 - Organic anion transporter (OAT1) inhibition leading to renal failure and mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/177">Aop:177 - Cyclooxygenase 1 (COX1) inhibition leading to renal failure and mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/186">Aop:186 - unknown MIE leading to renal failure and mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/312">Aop:312 - Acetylcholinesterase Inhibition leading to Acute Mortality via Impaired Coordination & Movement</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/320">Aop:320 - Binding of SARS-CoV-2 to ACE2 receptor leading to acute respiratory distress associated mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/155">Aop:155 - Deiodinase 2 inhibition leading to increased mortality via reduced posterior swim bladder inflation</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/156">Aop:156 - Deiodinase 2 inhibition leading to increased mortality via reduced anterior swim bladder inflation</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/157">Aop:157 - Deiodinase 1 inhibition leading to increased mortality via reduced posterior swim bladder inflation </a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/158">Aop:158 - Deiodinase 1 inhibition leading to increased mortality via reduced anterior swim bladder inflation</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/159">Aop:159 - Thyroperoxidase inhibition leading to increased mortality via reduced anterior swim bladder inflation</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/363">Aop:363 - Thyroperoxidase inhibition leading to altered visual function via altered retinal layer structure</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/377">Aop:377 - Dysregulated prolonged Toll Like Receptor 9 (TLR9) activation leading to Multi Organ Failure involving Acute Respiratory Distress Syndrome (ARDS)</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/364">Aop:364 - Thyroperoxidase inhibition leading to altered visual function via decreased eye size</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/365">Aop:365 - Thyroperoxidase inhibition leading to altered visual function via altered photoreceptor patterning</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/399">Aop:399 - Inhibition of Fyna leading to increased mortality via decreased eye size (Microphthalmos)</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/413">Aop:413 - Oxidation and antagonism of reduced glutathione leading to mortality via acute renal failure</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/410">Aop:410 - GSK3beta inactivation leading to increased mortality via defects in developing inner ear</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/450">Aop:450 - Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/536">Aop:536 - Estrogen receptor agonism leading to reduced survival and population growth due to renal failure</a></td>
<td>KeyEvent</td>
</tr>
<tr>
<td><a href="/aops/564">Aop:564 - DBDPE-induced inhibition of mitochondrial complex Ⅰ leading to population decline via neurotoxicity and metabotoxicity.</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/605">Aop:605 - Thyroid Peroxidase Inhibition Leading to Reduced, Swimming Performance via Hypomyelination</a></td>
<td>AdverseOutcome</td>
</tr>
<tr>
<td><a href="/aops/608">Aop:608 - Thyroid Hormone Excess Leading to Reduced, Swimming Performance via Hypomyelination</a></td>
<td>KeyEvent</td>
</tr>
</tbody>
</table>
</div>
<h4>Biological Context</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr><th scope="col">Level of Biological Organization</th></tr>
</thead>
<tbody class="tbody-striped">
<tr><td>Population</td></tr>
</tbody>
</table>
</div>
<h4>Domain of Applicability</h4>
Taxonomic Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Term</th>
<th scope="col">Scientific Term</th>
<th scope="col">Evidence</th>
<th scope="col">Links</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>all species</td>
<td>all species</td>
<td>High</td>
<td><a href="http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?mode=Info&id=0" target="_blank">NCBI</a></td>
</tr>
</tbody>
</table>
</div>
Life Stage Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Life Stage</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>All life stages</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
Sex Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sex</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Unspecific</td>
<td>Moderate</td>
</tr>
</tbody>
</table>
</div>
All living things are susceptible to mortality.
<h4>Key Event Description</h4>
Increased mortality refers to an increase in the number of individuals dying in an experimental replicate group or in a population over a specific period of time.
<h4>How it is Measured or Detected</h4>
Mortality of animals is generally observed as cessation of the heart beat, breathing (gill or lung movement) and locomotory movements. Mortality is typically measured by observation. Depending on the size of the organism, instruments such as microscopes may be used. The reported metric is mostly the mortality rate: the number of deaths in a given area or period, or from a particular cause.
Depending on the species and the study setup, mortality can be measured:
<ul>
<li>in the lab by recording mortality during exposure experiments</li>
<li>in dedicated setups simulating a realistic situation such as mesocosms or drainable ponds for aquatic species</li>
<li>in the field, for example by determining age structure after one capture, or by capture-mark-recapture efforts. The latter is a method commonly used in ecology to estimate an animal population's size where it is impractical to count every individual.</li>
</ul>
<h4>Regulatory Significance of the AO</h4>
Increased mortality is one of the most common regulatory assessment endpoints, along with reduced growth and reduced reproduction.
<h2>Appendix 2</h2>
<h2>List of Key Event Relationships in the AOP</h2>
<div id="evidence_supporting_links">
<h3>List of Adjacent Key Event Relationships</h3>
<div>
<h4><a href="/relationships/2653">Relationship: 2653: AchE Inhibition leads to Activation of Cyp2E1</a></h4>
<h4>AOPs Referencing Relationship</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP Name</th>
<th scope="col">Adjacency</th>
<th scope="col">Weight of Evidence</th>
<th scope="col">Quantitative Understanding</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/450"> Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>adjacent</td>
<td>Low</td>
<td>Moderate</td>
</tr>
</tbody>
</table>
</div>
</div>
<div>
~~<h4><a href="/relationships/2654">Relationship: 2654: Activation of Cyp2E1 leads to Oxidative Stress in Brain</a></h4>~~
<h4><a href="/relationships/1512">Relationship: 1512: Activation of Cyp2E1 leads to Increase, Oxidative Stress </a></h4>
<h4>AOPs Referencing Relationship</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP Name</th>
<th scope="col">Adjacency</th>
<th scope="col">Weight of Evidence</th>
<th scope="col">Quantitative Understanding</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/220">Cyp2E1 Activation Leading to Liver Cancer</a></td>
<td>adjacent</td>
<td>High</td>
<td>Not Specified</td>
</tr>
<tr>
<td><a href="/aops/450"> Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>adjacent</td>
<td>Moderate</td>
<td>Moderate</td>
</tr>
</tbody>
</table>
</div>
<h4>Evidence Supporting Applicability of this Relationship</h4>
<div>
</div>
<div>
</div>
<div>
Sex Applicability
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">Sex</th>
<th scope="col">Evidence</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td>Mixed</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
</div>
<h4>Key Event Relationship Description</h4>
Cyp2E1 activation has two major outcomes: (1) the production of reactive, electrophilic metabolites, and (2) a significant increase in the half-life of the Cyp2E1 enzyme (Gonzalez 2007, Song, et al. 1989). The former is important because metabolites can go on to produce cellular damage by reacting with cellular nucleophiles. The latter is important because the Cyp2E1 catalytic cycle is prone to uncoupling (i.e., instead of incorporating an oxygen atom in to the substrate, the catalytic cycle is interrupted because a superoxide radical is released), which results in the release of reactive oxygen species (ROS) and an increase in cellular oxidative stress (Lieber 1999).
<h4>Evidence Supporting this KER</h4>
Biological Plausibility
It is well known that uncoupling of Cyp2E1 catalytic cycle results in the release of harmful reactive oxygen species in the cell (Lieber 1999).
Oxidative stress is produced during chronic activation (and uncoupling) of the Cyp2E1 catalytic cycle. The cytochrome P-450 catalytic cycle is known to undergo uncoupling leading to the production of ROS (Gorsky, et al. 1984, Loida and Sligar 1993, Meunier, et al. 2004). If this uncoupling occurs, a molecule of superoxide radical is released, which has the effect of interrupting the P450 catalytic cycle and releasing harmful ROS into the cell. Typically superoxide is converted to hydrogen peroxide (H2O2) by superoxide dismutase (SOD), which is further reduced into the hydroxyl radical (OH•), and then to water. Other relevant cellular antioxidants include glutathione, thioredoxin, and peroxiredoxins. However, it is also possible for these ROS to scavenge electrons from cellular macromolecules (proteins, lipids, nucleic acids). Because Cyp2E1 is membrane-bound, ROS most commonly react with lipids and initiate lipid peroxidation.  Further, Cyp2E1 can undergo NADPH-dependent ‘futile cycling’, which produces ROS and contributes to the occurrence of lipid peroxidation (Ekstrom and Ingelman-Sundberg 1989). The cellular sources and effects of ROS, as well as the corresponding enzymes and antioxidants are have been thoroughly reviewed (Nakazawa, et al. 1996).
Empirical Evidence
Empirical data collected from different experiments strongly supports that oxidative stress and cytotoxicity are downstream of Cyp2E1 activation. Evidence of both temporal and dose-response concordance are available for a variety of chemical exposures.
Cyp2E1 protein levels increase when its substrates are present in a tissue. Therefore, prolonged exposure to substrate leads to prolonged activation of Cyp2E1, which is related to a substantial increase in cellular oxidative stress. For example:
- Treatment with acetone or ethanol in male Sprague-Dawley rats results in an increase in Cyp2E1 protein levels in the liver. Increasing Cyp2E1 levels are linearly correlated to concomitant increases in NADPH oxidase, superoxide radical, hydrogen peroxide, and lipid peroxidation (TBARS).
- Both hydrogen peroxide production and lipid peroxidation are blocked in rat microsomes following inhibition of Cyp2E1 with anti-Cyp2E1 IgG (Ekstrom and Ingelman-Sundberg 1989).
- Ethanol treatment leads to correlated increases in both Cyp2E1 protein and lipid peroxidation in male Wister rats, C57BL/129SV mice, and superoxide dismutase (Sod) knockout mice (Kessova, et al. 2003, Nanji, et al. 1994).
- Wild type and humanized Cype2E1 knock-in mice have dose-dependent increases in Cyp2E1 protein and activity levels when exposed to ethanol, whereas Cyp2E1 knock-out mice do not. Further, the humanized mice show the largest increases in necrosis, inflammation, AST, ALT and TBARS, and the largest decrease in GSH levels of all three groups (Lu, et al. 2010).
- Exposure of male Sprague-Dawley rats to 95% oxygen results in a time-dependent increase in Cyp2E1 protein levels, superoxide radical production, and lipid peroxidation (TBARS) (various time-points over 78 hours).
- Lipid peroxidation is further increased following treatment of rat microsomes with carbon tetrachloride, or co-treatment of rats with oxygen, acetone and/or carbon tetrachloride (Tindberg and Ingelman-Sundberg 1989), established Cyp2E1 substrates.
- Cyp2E1 expressing HepG2 cells (called E47 cells) have higher baseline expression of anti-oxidant molecules thioredoxin and glutathione compared to non-Cyp2E1 expressing HepG2 cells (called C34 cells); they also have higher levels of ROS and lipid peroxidation (Yang, et al. 2011).
- Studies of ethanol- and Cyp2E1-dependent oxidative injury in HepG2 E47 and C34 cells, and in the liver, have been reviewed previously (Caro and Cederbaum 2004, Lu and Cederbaum 2008).
- At the molecular level, global gene expression profiling of mice exposed to a carcinogenic dose of furan (a Cyp2E1 substrate) demonstrated that the most perturbed molecular pathway was the Nrf2 Oxidative Stress Response pathway (Jackson, et al. 2014).
Uncertainties and Inconsistencies
None.
<h4>References</h4>
References
Caro, A.A., Cederbaum, A.I., 2004. Oxidative stress, toxicology, and pharmacology of CYP2E1. Annu. Rev. Pharmacol. Toxicol. 44, 27-42.
Ekstrom, G., Ingelman-Sundberg, M., 1989. Rat liver microsomal NADPH-supported oxidase activity and lipid peroxidation dependent on ethanol-inducible cytochrome P-450 (P-450IIE1). Biochem. Pharmacol. 38, 1313-1319.
Gonzalez, F.J., 2007. The 2006 Bernard B. Brodie Award Lecture. Cyp2e1. Drug metabolism and disposition: the biological fate of chemicals 35, 1-8.
Gorsky, L.D., Koop, D.R., Coon, M.J., 1984. On the stoichiometry of the oxidase and monooxygenase reactions catalyzed by liver microsomal cytochrome P-450. Products of oxygen reduction. J. Biol. Chem. 259, 6812-6817.
Jackson, A.F., Williams, A., Recio, L., Waters, M.D., Lambert, I.B., Yauk, C.L., 2014. Case study on the utility of hepatic global gene expression profiling in the risk assessment of the carcinogen furan. Toxicol. Appl. Pharmacol. 274, 63-77.
Kessova, I.G., Ho, Y.S., Thung, S., Cederbaum, A.I., 2003. Alcohol-induced liver injury in mice lacking Cu, Zn-superoxide dismutase. Hepatology 38, 1136-1145.
Lieber, C.S., 1999. Microsomal ethanol-oxidizing system (MEOS): The first 30 years (1968- 1998) - A review. Alcohol. Clin. Exp. Res. 23, 991-1007.
Lu, Y., Cederbaum, A.I., 2008. CYP2E1 and oxidative liver injury by alcohol. Free Radical Biology and Medicine 44, 723-738.
Lu, Y., Wu, D., Wang, X., Ward, S.C., Cederbaum, A.I., 2010. Chronic alcohol-induced liver injury and oxidant stress are decreased in cytochrome P4502E1 knockout mice and restored in humanized cytochrome P4502E1 knock-in mice. Free Radic. Biol. Med. 49, 1406-1416.
Meunier, B., de Visser, S.P., Shaik, S., 2004. Mechanism of oxidation reactions catalyzed by cytochrome p450 enzymes. Chem. Rev. 104, 3947-3980.
Nakazawa, H., Genka, C., Fujishima, M., 1996. Pathological aspects of active oxygens/free radicals. Jpn. J. Physiol. 46, 15-32.
Nanji, A.A., Zhao, S., Sadrzadeh, S.M., Dannenberg, A.J., Tahan, S.R., Waxman, D.J., 1994. Markedly enhanced cytochrome P450 2E1 induction and lipid peroxidation is associated with severe liver injury in fish oil-ethanol-fed rats. Alcohol. Clin. Exp. Res. 18, 1280-1285.
Song, B.J., Veech, R.L., Park, S.S., Gelboin, H.V., Gonzalez, F.J., 1989. Induction of rat hepatic N-nitrosodimethylamine demethylase by acetone is due to protein stabilization. J. Biol. Chem. 264, 3568-3572.
Tindberg, N., Ingelman-Sundberg, M., 1989. Cytochrome P-450 and oxygen toxicity. Oxygen-dependent induction of ethanol-inducible cytochrome P-450 (IIE1) in rat liver and lung. Biochemistry 28, 4499-4504.
Yang, L., Wu, D., Wang, X., Cederbaum, A.I., 2011. Depletion of cytosolic or mitochondrial thioredoxin increases CYP2E1-induced oxidative stress via an ASK-1-JNK1 pathway in HepG2 cells. Free Radic. Biol. Med. 51, 185-196.
</div>
<div>
~~<h4><a href="/relationships/2655">Relationship: 2655: Oxidative Stress in Brain leads to N/A, Neurodegeneration</a></h4>~~
<h4><a href="/relationships/3312">Relationship: 3312: Increase, Oxidative Stress leads to N/A, Neurodegeneration</a></h4>
<h4>AOPs Referencing Relationship</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP Name</th>
<th scope="col">Adjacency</th>
<th scope="col">Weight of Evidence</th>
<th scope="col">Quantitative Understanding</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/450"> Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>adjacent</td>
<td>High</td>
<td>High</td>
</tr>
<tr>
~~<td><a href="/aops/471">Various neuronal effects induced by elavl3, sox10, and mbp</a></td>~~
<td><a href="/aops/471">Neuron defect induced early behavioral change</a></td>
<td>adjacent</td>
<td>Moderate</td>
<td>Moderate</td>
</tr>
</tbody>
</table>
</div>
</div>
<div>
<h4><a href="/relationships/647">Relationship: 647: N/A, Neurodegeneration leads to Decreased, Neuronal network function in adult brain</a></h4>
<h4>AOPs Referencing Relationship</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP Name</th>
<th scope="col">Adjacency</th>
<th scope="col">Weight of Evidence</th>
<th scope="col">Quantitative Understanding</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/48">Binding of agonists to ionotropic glutamate receptors in adult brain causes excitotoxicity that mediates neuronal cell death, contributing to learning and memory impairment.</a></td>
<td>adjacent</td>
<td>Low</td>
<td></td>
</tr>
<tr>
<td><a href="/aops/450"> Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>adjacent</td>
<td>High</td>
<td>High</td>
</tr>
</tbody>
</table>
</div>
<h4>Evidence Supporting Applicability of this Relationship</h4>
<div>
</div>
<div>
</div>
<div>
</div>
It has been shown at the neuromascular junction of D. melanogaster that quisqualate-type glutamate receptors are blocked by DomA (1 mM) (Lee et al.,
2009). However, in crayfish (Procambarus clarkia) the same concentration of DomA has no effect in spike activity (Bierbower and Cooper, 2013).
<h4>Key Event Relationship Description</h4>
Neurodegeneration (retraction of dendrites or axons) or neuronal cell death decreases the number of synaptic connections affecting the neuronal network function (Seeley et al., 2009). Based on neuropathology (Braak and Braak, 1991), neuroimaging (Buckner et al., 2005 and Greicius et al., 2004), and evidence from transgenic animal models (Palop et al., 2007a), it is suggested that neurodegeneration leads to neural network dysfunction (Buckner et al., 2005 and Palop et al., 2006). In human spongiform encephalopathies, which cause rapidly progressive dementia, direct evidence supports disease propagation along affected trans-synaptic connections (Scott et al., 1992). For all other neurodegenerative diseases, there are limited human experimental data supporting the “network degeneration hypothesis.”
It is demonstrated as a class-wide phenomenon, with major mechanistic significance, predicting that the spatial patterning of disease relates to some structural, metabolic, or physiological aspect of neural network biology dysfunction. Confirming the network degeneration hypothesis has clinical impact, stimulating development of new network-based diagnostic and disease-monitoring assays.
<h4>Evidence Supporting this KER</h4>
Biological Plausibility
Based on neuropathological findings and neuroimaging from patients suffering from neurodegeneration as well as from evidence derived by transgenic animal models of neurodegeneration, it has been suggested that neurodegeneration is related to neural network dysfunction (Palop et al., 2007b; Seeley et al., 2009). Neurodegeneration leads to impairment of retrograde axonal transport that prohibits the growth factor supply to long-range projection neurons, causing synapse loss, and post-synaptic dendrite retraction that leads to decreases of the neuronal network (Seeley et al., 2009).
Empirical Evidence
Include consideration of temporal concordance here
The effective concentration of DomA causing a decrease to 50% of control mean firing rate (MFR) values (EC50) in rat primary cultures (13-30 DIV) is 0.28 μM (Mack et al., 2014). Decrease of MFR has also been reported before by Hogberg et al. 2011, where mature cultures (28-35 DIV) have been exposed acutely to a wide range of concentrations of DomA. The concentration of 0.5 μM DomA significantly reduces MFR (77 %), the MBR (78 %)and the number of spikes per burst (71 %). Higher concentrations of DomA (1 and 2 μM) also significantly decrease the MFR, whereas concentrations up to 0.1 μM of DomA do not cause any effect on MFR (Hogberg et al., 2011). In primary rat cortical neurons (12-22 DIV), DomA (50 μM) has been
reported to reduce MFR by more than 90% (McConnell et al., 2012).
Ten-minute exposure of rat hippocampal CA1 region slices to 400 nM DA causes depression of fEPSP (Qiu et al., 2009). After 1 h washout, fEPSP
gradually has been gradually recovered. DomA-potentiated slices have shown also less tetanus-induced LTP compared with control slices when tested with
either original stimulus or reset stimulus (Qiu et al., 2009). In addition, prolonged application of 400 nM DA reversibly depresses CA1 fEPSP and
impairs the subsequent development of tetanus LTP (Qiu et al., 2009).
Gap of knowledge: there are no experiments to support such a KE relationship after exposure to GLF.
Uncertainties and Inconsistencies
Administration of high dose DomA (4.4 mg/kg) to adult male Sprague-Dawley rats causes elevation of electrocorticogram (ECoG) beginning 30 min post
injection, whereas at a lower dose (2.2 mg/kg) ECoG becomes elevated after 110 min (Binienda et al., 2011).
<h4>References</h4>
Bierbower SM, Cooper RL. The mechanistic action of carbon dioxide on a neural circuit and NMJ communication. J Exp Zool A Ecol Genet Physiol., 2013, 319: 340-54.
Binienda ZK, Beaudoin MA, Thorn BT, Ali SF. Analysis of electrical brain waves in neurotoxicology: γ-hydroxybutyrate. Curr Neuropharmacol., 2011, 9: 236-9.
Braak H., E. Braak, Neuropathological staging of Alzheimer-related changes, Acta Neuropathol., 1991, 82: 239–259.
Buckner R.L., A.Z. Snyder, B.J. Shannon, G. LaRossa, R. Sachs, A.F. Fotenos, Y.I. Sheline, W.E. Klunk, C.A. Mathis, J.C. Morris, M.A.Molecular, structural, and functional characterization of Alzheimer's disease: evidence for a relationship between default activity, amyloid, and memory. J. Neurosci., 2005, 25:7709–7717.
Greicius M.D., G. Srivastava, A.L. Reiss, V. Menon, Default-mode network activity distinguishes Alzheimer's disease from healthy aging: evidence from functional MRI. Proc. Natl. Acad. Sci. USA, 2004, 101: 4637–4642.
Hogberg HT, Sobanski T, Novellino A, Whelan M, Weiss DG, Bal-Price AK. Application of micro-electrode arrays (MEAs) as an emerging technology for developmental neurotoxicity: evaluation of domoic acid-induced effects in primary cultures of rat cortical neurons. Neurotoxicology, 2011, 32: 158-168.
Lee JY, Bhatt D, Bhatt D, Chung WY, Cooper RL. Furthering pharmacological and physiological assessment of the glutamatergic receptors at the Drosophila neuromuscular junction. Comp Biochem Physiol C Toxicol Pharmacol., 2009, 150(4): 546-57.
Mack CM, Lin BJ, Turner JD, Johnstone AF, Burgoon LD, Shafer TJ. Burst and principal components analyses of MEA data for 16 chemicals describe at least three effects classes. Neurotoxicology, 2014, 40: 75-85.
McConnell ER, McClain MA, Ross J, Lefew WR, Shafer TJ. Evaluation of multi-well microelectrode arrays for neurotoxicity screening using a chemical training set. Neurotoxicology, 2012, 33: 1048-1057.
Palop J.J., J. Chin, L. Mucke, A network dysfunction perspective on neurodegenerative diseases. Nature, 2006, 443: 768–773.
Palop JJ, Chin J, Roberson ED, Wang J, Thwin MT, Bien-Ly N, Yoo J, Ho KO, Yu GQ, Kreitzer A, et al. Aberrant excitatory neuronal activity and compensatory remodeling of inhibitory hippocampal circuits in mouse models of Alzheimer's disease. Neuron, 2007a, 55: 697-711.
Palop J.J, J. Chin, E.D. Roberson, J. Wang, M.T. Thwin, N. Bien-Ly, J. Yoo, K.O. Ho, G.Q. Yu, A. Kreitzer, et al., Aberrant excitatory neuronal activity and compensatory remodeling of inhibitory hippocampal circuits in mouse models of Alzheimer's disease. Neuron, 2007b, 55: 697–711.
Qiu S, Jebelli AK, Ashe JH, Currás-Collazo MC. Domoic acid induces a long-lasting enhancement of CA1 field responses and impairs tetanus-induced long-term potentiation in rat hippocampal slices. Toxicol Sci., 2009, 111: 140-150.
Scott R.S., D. Davies, H. Fraser. Scrapie in the central nervous system: neuroanatomical spread of infection and Sinc control of pathogenesis. J. Gen. Virol., 1992, 73: 1637–1644.
Seeley WW, Crawford RK, Zhou J, Miller BL, Greicius MD. Neurodegenerative diseases target large-scale human brain networks. Neuron, 2009, 62: 42-52.
</div>
<div>
<h4><a href="/relationships/2656">Relationship: 2656: Decreased, Neuronal network function in adult brain leads to Sensory axonal peripheral neuropathy</a></h4>
<h4>AOPs Referencing Relationship</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP Name</th>
<th scope="col">Adjacency</th>
<th scope="col">Weight of Evidence</th>
<th scope="col">Quantitative Understanding</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/450"> Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>adjacent</td>
<td>Moderate</td>
<td>Low</td>
</tr>
</tbody>
</table>
</div>
</div>
<h3>List of Non Adjacent Key Event Relationships</h3>
<div>
<h4><a href="/relationships/2657">Relationship: 2657: Sensory axonal peripheral neuropathy leads to Increased Mortality</a></h4>
<h4>AOPs Referencing Relationship</h4>
<div class="table-responsive">
<table class="table table-bordered table-fullwidth">
<thead class="thead-light">
<tr>
<th scope="col">AOP Name</th>
<th scope="col">Adjacency</th>
<th scope="col">Weight of Evidence</th>
<th scope="col">Quantitative Understanding</th>
</tr>
</thead>
<tbody class="tbody-striped">
<tr>
<td><a href="/aops/450"> Inhibition of AChE and activation of CYP2E1 leading to sensory axonal peripheral neuropathy and mortality</a></td>
<td>non-adjacent</td>
<td>Low</td>
<td>Low</td>
</tr>
</tbody>
</table>
</div>
</div>
</div>
</div>
</div>
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