Prenatal arsenic exposure alters the placental expression of multiple epigenetic regulators in a sex-dependent manner

Winterbottom, Emily F.; Moroishi, Yuka; Halchenko, Yuliya; Armstrong, David A.; Beach, Paul J.; Nguyen, Quang P.; Capobianco, Anthony J.; Ayad, Nagi G.; Marsit, Carmen J.; Li, Zhigang; Karagas, Margaret R.; Robbins, David J.

doi:10.1186/s12940-019-0455-9

Cited by 26 publications

(16 citation statements)

References 41 publications

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“…The functional effects of this epigenetic programming require further investigation. Importantly, other environmental exposures lead to changes in epigenetic regulators that are highly sex-specific, 81 highlighting a potential mechanism by which toxicants, including DEHP, may induce sex-specific epigenomic programming. Alterations in DNMT function are another potential mechanism by which DEHP may alter DNAm.…”

Section: Discussionmentioning

confidence: 99%

Sex-Specific Programming of Cardiac DNA Methylation by Developmental Phthalate Exposure

et al. 2020

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Phthalate plasticizers are ubiquitous chemicals linked to several cardiovascular diseases in animal models and humans. Despite this, the mechanisms by which phthalate exposures cause adverse cardiac health outcomes are unclear. In particular, whether phthalate exposures during pregnancy interfere with normal developmental programming of the cardiovascular system, and the resulting implications this may have for long-term disease risk, are unknown. Recent studies suggest that the effects of phthalates on metabolic and neurobehavioral outcomes are sex-specific. However, the influence of sex on cardiac susceptibility to phthalate exposures has not been investigated. One mechanism by which developmental exposures may influence long-term health is through altered programming of DNA methylation. In this work, we utilized an established mouse model of human-relevant perinatal exposure and enhanced reduced representation bisulfite sequencing to investigate the long-term effects of diethylhexyl phthalate (DEHP) exposure on DNA methylation in the hearts of adult male and female offspring at 5 months of age (n = 5-7 mice per sex and exposure). Perinatal DEHP exposure led to hundreds of sex-specific, differentially methylated cytosines (DMCs) and differentially methylated regions (DMRs) in the heart. Pathway analysis of DMCs revealed enrichment for several pathways in females, including insulin signaling, regulation of histone methylation, and tyrosine phosphatase activity. In males, DMCs were enriched for glucose transport, energy generation, and developmental programs. Notably, many sex-specific genes differentially methylated with DEHP exposure in our mouse model were also differentially methylated in published data of heart tissues collected from human heart failure patients. Together, these data highlight the potential role for DNA methylation in DEHP-induced cardiac effects and emphasize the importance of sex as a biological variable in environmental health studies.

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Section: Discussionmentioning

confidence: 99%

Sex-Specific Programming of Cardiac DNA Methylation by Developmental Phthalate Exposure

et al. 2020

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“…The transgenerational effects of iAs have not been studied in mammals, although the effect of early‐life iAs exposure on later‐life health has been characterized under the DOHaD paradigm. [ 18–30 ] We focused on an exclusive male‐lineage exposure paradigm. This paradigm excludes most early‐life developmental processes from prenatal or in utero exposures, [ 8 ] which allow us to study transgenerational effects within two generations.…”

Section: Introductionmentioning

confidence: 99%

Inter‐ and Transgenerational Effects of Paternal Exposure to Inorganic Arsenic

Gong

Xue

et al. 2021

Advanced Science

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The rise of metabolic disorders in modern times is mainly attributed to the environment. However, heritable effects of environmental chemicals on mammalian offsprings' metabolic health are unclear. Inorganic arsenic (iAs) is the top chemical on the Agency for Toxic Substances and Disease Registry priority list of hazardous substances. Here, we assess cross‐generational effects of iAs in an exclusive male‐lineage transmission paradigm. The exposure of male mice to 250 ppb iAs causes glucose intolerance and hepatic insulin resistance in F1 females, but not males, without affecting body weight. Hepatic expression of glucose metabolic genes, glucose output, and insulin signaling are disrupted in F1 females. Inhibition of the glucose 6‐phosphatase complex masks the intergenerational effect of iAs, demonstrating a causative role of hepatic glucose production. F2 offspring from grandpaternal iAs exposure show temporary growth retardation at an early age, which diminishes in adults. However, reduced adiposity persists into middle age and is associated with altered gut microbiome and increased brown adipose thermogenesis. In contrast, F3 offspring of the male‐lineage iAs exposure show increased adiposity, especially on a high‐calorie diet. These findings have unveiled sex‐ and generation‐specific heritable effects of iAs on metabolic physiology, which has broad implications in understanding gene‐environment interactions.

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“…In the SMCs of mice DA with PRDM6 loss, early differentiation was observed, restricting proliferation. Increased arsenic exposure correlates with the suppression of PRDM6 expression [ 73 ]. This might explain the report showing significantly increased PDA in infants whose mother was exposed to arsenic in drinking water [ 74 ].…”

Section: Mechanisms Of Anatomical Closurementioning

confidence: 99%

Molecular Mechanisms Underlying Remodeling of Ductus Arteriosus: Looking beyond the Prostaglandin Pathway

Hsu

Lin

Liu

et al. 2021

IJMS

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The ductus arteriosus (DA) is a physiologic vessel crucial for fetal circulation. As a major regulating factor, the prostaglandin pathway has long been the target for DA patency maintenance or closure. However, the adverse effect of prostaglandins and their inhibitors has been a major unsolved clinical problem. Furthermore, a significant portion of patients with patent DA fail to respond to cyclooxygenase inhibitors that target the prostaglandin pathway. These unresponsive medical patients ultimately require surgical intervention and highlight the importance of exploring pathways independent from this well-recognized prostaglandin pathway. The clinical limitations of prostaglandin-targeting therapeutics prompted us to investigate molecules beyond the prostaglandin pathway. Thus, this article introduces molecules independent from the prostaglandin pathway based on their correlating mechanisms contributing to vascular remodeling. These molecules may serve as potential targets for future DA patency clinical management.

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Prenatal arsenic exposure alters the placental expression of multiple epigenetic regulators in a sex-dependent manner

Cited by 26 publications

References 41 publications

Sex-Specific Programming of Cardiac DNA Methylation by Developmental Phthalate Exposure

Sex-Specific Programming of Cardiac DNA Methylation by Developmental Phthalate Exposure

Inter‐ and Transgenerational Effects of Paternal Exposure to Inorganic Arsenic

Molecular Mechanisms Underlying Remodeling of Ductus Arteriosus: Looking beyond the Prostaglandin Pathway

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