CYP3A genes and the association between prenatal methylmercury exposure and neurodevelopment

Llop, Sabrina; Tran, Van Du T.; Ballester, Ferrán; Barbone, Fabio; Sofianou-Katsoulis, Aikaterini; Sunyer, Jordi; Engström, Karin; Alhamdow, Ayman; Love, Tanzy; Watson, Gene E.; Murcia, Mario; Íñiguez, Carmen; Shamlaye, Conrad; Rosolen, Valentina; Mariuz, Marika; Horvat, Milena; Tratnik, Janja Snoj; Mazej, Darja; Wijngaarden, Edwin van; Davidson, Philip W.; Myers, Gary J.; Rand, Matthew D.

doi:10.1016/j.envint.2017.04.013

Cited by 25 publications

(26 citation statements)

References 39 publications

(55 reference statements)

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“…Genetic factors underlie an individual's vulnerability to the toxic effects of mercury (Gundacker et al, 2010: Llop et al, 2014Andreoli and Sprovieri, 2017;Llop et al, 2017). The incorporation of newer genetic (or genomic) and epigenetic insights into theories of causation of neurodevelopmental disease constitutes an important means to more fully understand the fundamental etiologies of these conditions.…”

Section: Geneticsmentioning

confidence: 99%

Autism spectrum disorder and mercury toxicity: use of genomic and epigenetic methods to solve the etiologic puzzle

McCaulley¹

2019

Acta Neurobiologiae Experimentalis

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Autism spectrum disorder (ASD) is an increasingly prevalent neurodevelopmental condition of unknown etiology. Mercury is a common, highly neurotoxic heavy metal. The similarities of neurologic manifestations of mercury exposure and ASD raise an intriguing hypothetical question: Is ASD, at least partially, a manifestation of mercury toxicity? The fetus is particularly vulnerable to mercury exposure from the "double jeopardy" combination of the genetics of his mother and his own genetics, as relates to mercury toxicity. In this paper, I review the evidence suggesting relationships between ASD and mercury toxicity. I suggest ways to confirm these relationships with genetic and epigenetic research. I propose a hypothesis associating mercury toxicity with ASD. This may present opportunities for further research in prevention and treatment of ASD.

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Section: Geneticsmentioning

confidence: 99%

Autism spectrum disorder and mercury toxicity: use of genomic and epigenetic methods to solve the etiologic puzzle

McCaulley¹

2019

Acta Neurobiologiae Experimentalis

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“…MeHg is a toxic compound formed in aquatic systems and, because it is not readily biodegraded, it accumulates up the food chain, with fish consumption being the major source of exposure in humans. The pathways involved in MeHg metabolism are poorly defined, but it is known that GSTM1 is necessary for conjugation with glutathione ( Llop et al, 2017 ). In this study we did not consider etHg, since a role of thimerosal exposure and vaccination in ASD has been discredited ( Taylor et al, 2014 ).…”

Section: Discussionmentioning

confidence: 99%

A Role for Gene-Environment Interactions in Autism Spectrum Disorder Is Supported by Variants in Genes Regulating the Effects of Exposure to Xenobiotics

et al. 2022

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Heritability estimates support the contribution of genetics and the environment to the etiology of Autism Spectrum Disorder (ASD), but a role for gene-environment interactions is insufficiently explored. Genes involved in detoxification pathways and physiological permeability barriers (e.g., blood-brain barrier, placenta and respiratory airways), which regulate the effects of exposure to xenobiotics during early stages of neurodevelopment when the immature brain is extremely vulnerable, may be particularly relevant in this context. Our objective was to identify genes involved in the regulation of xenobiotic detoxification or the function of physiological barriers (the XenoReg genes) presenting predicted damaging variants in subjects with ASD, and to understand their interaction patterns with ubiquitous xenobiotics previously implicated in this disorder. We defined a panel of 519 XenoReg genes through literature review and database queries. Large ASD datasets were inspected for in silico predicted damaging Single Nucleotide Variants (SNVs) (N = 2,674 subjects) or Copy Number Variants (CNVs) (N = 3,570 subjects) in XenoReg genes. We queried the Comparative Toxicogenomics Database (CTD) to identify interaction pairs between XenoReg genes and xenobiotics. The interrogation of ASD datasets for variants in the XenoReg gene panel identified 77 genes with high evidence for a role in ASD, according to pre-specified prioritization criteria. These include 47 genes encoding detoxification enzymes and 30 genes encoding proteins involved in physiological barrier function, among which 15 are previous reported candidates for ASD. The CTD query revealed 397 gene-environment interaction pairs between these XenoReg genes and 80% (48/60) of the analyzed xenobiotics. The top interacting genes and xenobiotics were, respectively, CYP1A2, ABCB1, ABCG2, GSTM1, and CYP2D6 and benzo-(a)-pyrene, valproic acid, bisphenol A, particulate matter, methylmercury, and perfluorinated compounds. Individuals carrying predicted damaging variants in high evidence XenoReg genes are likely to have less efficient detoxification systems or impaired physiological barriers. They can therefore be particularly susceptible to early life exposure to ubiquitous xenobiotics, which elicit neuropathological mechanisms in the immature brain, such as epigenetic changes, oxidative stress, neuroinflammation, hypoxic damage, and endocrine disruption. As exposure to environmental factors may be mitigated for individuals with risk variants, this work provides new perspectives to personalized prevention and health management policies for ASD.

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“…For example, it is known that Hg can induce direct and indirect DNA post-translational modifications (PTMs) such as phosphorylation, ubiquitination, acetylation, nitrosylation, and S-mercuration on targeted proteins implicated in many cellular pathways [57,58]. Specific polymorphisms of glutathione-related genes (e.g., glutamate-cysteine ligase regulatory subunit, glutamate-cysteine ligase), Hg transporter proteins (e.g., MTs, ABCs), cytochrome p450 3A, ε4 APOE, and Brain Derived Neurotrophic Factor (BDNF) have been associated with the magnitude of toxic Hg effects in biological tissues [39,[58][59][60][61]. The induction of oxidative stress, which can activate the process of mitochondrial autophagy, is the initial step of Hg neurotoxicity [62].…”

Section: Discussionmentioning

confidence: 99%

Personalized Prevention in Mercury-Induced Amyotrophic Lateral Sclerosis: A Case Report

et al. 2020

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Chronic exposure to low levels of mercury is involved in the development of motor neuron diseases (MND). Genetic alterations may have a crucial role in the onset and progression. We presented a case of a TANK-binding kinase 1 (TBK1)-mutated 54-year-old male worker who developed a MND due to chronic mercury exposure at work. He was employed in a chlor-alkali plant in Central Italy. After two years of employment he had acute mercury intoxication with suggestive neurological symptoms and a high urinary level of the metal. Through years, many episodes of intoxication occurred, but he continued to perform the same job and be exposed to mercury. After yet another episode of intoxication in 2013, he showed fasciculations of the upper limbs and trunk, and electromyographic activity patterns were consistent with amyotrophic lateral sclerosis (ALS). In 2016, a genetic test revealed a mutation of TBK1, an ALS-related gene. This case highlights the important role of genetics in personalized occupational medicine. Occupational physicians should use genetic tests to identify conditions of individual susceptibility in workers with documented frequent episodes of mercury intoxication recorded during health surveillance programs to customize prevention measures in the workplace and act before damage appears.

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CYP3A genes and the association between prenatal methylmercury exposure and neurodevelopment

Cited by 25 publications

References 39 publications

Autism spectrum disorder and mercury toxicity: use of genomic and epigenetic methods to solve the etiologic puzzle

Autism spectrum disorder and mercury toxicity: use of genomic and epigenetic methods to solve the etiologic puzzle

A Role for Gene-Environment Interactions in Autism Spectrum Disorder Is Supported by Variants in Genes Regulating the Effects of Exposure to Xenobiotics

Personalized Prevention in Mercury-Induced Amyotrophic Lateral Sclerosis: A Case Report

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