Connie S. Chen scite author profile

In the developing embryo and fetus, endogenous or xenobiotic-enhanced formation of reactive oxygen species (ROS) like hydroxyl radicals may adversely alter development by oxidatively damaging cellular lipids, proteins and DNA, and/or by altering signal transduction. The postnatal consequences may include an array of birth defects (teratogenesis), postnatal functional deficits, and diseases. In animal models, the adverse developmental consequences of in utero exposure to agents like thalidomide, methamphetamine, phenytoin, benzo[a]pyrene, and ionizing radiation can be modulated by altering pathways that control the embryonic ROS balance, including enzymes that bioactivate endogenous substrates and xenobiotics to free radical intermediates, antioxidative enzymes that detoxify ROS, and enzymes that repair oxidative DNA damage. ROS-mediated signaling via Ras, nuclear factor kappa B and related transducers also may contribute to altered development. Embryopathies can be reduced by free radical spin trapping agents and antioxidants, and enhanced by glutathione depletion. Further modulatory approaches to evaluate such mechanisms in vivo and/or in embryo culture have included the use of knockout mice, transgenic knock-ins and mutant deficient mice with altered enzyme activities, as well as antisense oligonucleotides, protein therapy with antioxidative enzymes, dietary depletion of essential cofactors and chemical enzyme inhibitors. In a few cases, measures anticipated to be protective have conversely enhanced the risk of adverse developmental outcomes, indicating the complexity of development and need for caution in testing therapeutic strategies in humans. A better understanding of the developmental effects of ROS may provide insights for risk assessment and the reduction of adverse postnatal consequences.

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Molecular and biochemical mechanisms in teratogenesis involving reactive oxygen species

Wells

Bhuller

Chen

et al. 2005

Toxicology and Applied Pharmacology

206

144

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Enhanced tumorigenesis in p53 knockout mice exposed in utero to high-dose vitamin E

Chen¹,

Wells²

2006

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The limited antioxidative capacity of the embryo and fetus may increase their risk for cancer initiation and/or promotion by reactive oxygen species (ROS)-mediated oxidative DNA damage and/or signaling. To determine if cancer can originate in utero, a high dietary dose of the antioxidant vitamin E (VE) (10% dl-alpha-tocopherol-acetate) was given to cancer-prone p53 knockout mice throughout pregnancy. Although reducing fetal death (P < 0.05), in utero exposure to VE enhanced postnatal tumorigenesis in both +/- (P < 0.04) and -/- (P < 0.0008) p53-deficient offspring. VE did not alter maternal weights, offspring p53 genotypic distribution or tumor spectrum. Constitutive embryonic DNA oxidation in untreated -/- p53 embryos [gestational day (GD) 13] was higher than in +/- and +/+ p53 littermates (P < 0.05). VE reduced DNA oxidation in -/- p53 embryos (P < 0.05) without affecting +/- and +/+ p53 littermates. VE had contrasting, tissue-dependent effects on fetal (GD 19) DNA oxidation, with reductions in -/- and +/- p53-deficient fetal brains (P < 0.01), increases in skin (P < 0.05) and no effect in liver and thymus. The 250-fold increase in dietary VE levels produced only 1.6-6.3-fold, tissue-dependent increases in tissue concentrations. The greatest increase, in fetal skin, correlated with increased DNA oxidation in that tissue in -/- and +/- p53-deficient fetuses and enhanced tumorigenesis in these genotypes. These results show that some cancers may originate in utero and the risk can be enhanced by embryonic and fetal exposure to high dietary levels of VE. The elevated DNA oxidation in some tissues of untreated -/- p53 offspring suggests that ROS may contribute to their higher baseline tumor incidence. The limited and tissue-dependent disposition of VE indicates substantial conceptal regulation. The similarly selective and contrasting effects of VE on DNA oxidation may contribute to its controversial protective efficacy and suggest that its effects on tumorigenesis are cell-specific, possibly in high doses involving a pro-oxidative mechanism.

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Reduced tumorigenesis in p53 knockout mice exposed in utero to low‐dose vitamin E

Chen

Squire

Wells

2009

Cancer

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BACKGROUND: The limited antioxidative capacity of the fetus renders it more susceptible to reactive oxygen species (ROS), and possibly to ROS‐mediated cancer initiation or promotion in utero. METHODS: To test this hypothesis, pregnant cancer‐prone p53 knockout mice were prenatally supplemented with a low dietary dose of the antioxidant vitamin E (VE) (0.1% all‐rac‐α‐tocopherol‐acetate), and the homozygous (−/−) and heterozygous (+/‐) p53‐deficient and wild‐type (+/+) offspring were examined for VE levels, oxidative DNA damage, chromosomal stability, cellular viability and postnatal tumorigenesis. RESULTS: In utero exposure to VE reduced spontaneous postnatal tumorigenesis in p53 +/‐ offspring, and increased VE levels and reduced fetal DNA oxidation in some but not all tissues of p53‐deficient fetuses. Survival of VE‐exposed p53 +/‐ offspring at the end of the study was double that of the +/‐ controls (45% vs 23%). In primary culture of skin fibroblasts from VE‐exposed fetuses, VE did not alter chromosomal ploidy, but reduced cell death, indicating that its protective effect did not involve chromosomal stability. CONCLUSIONS: The tissue‐selective increase in fetal VE levels and reduced DNA oxidation, together with a concomitant reduction in postnatal tumorigenesis, suggest that in utero oxidative stress contributes to some postnatal cancers, and the risk can be reduced by maternal dietary supplementation with low‐dose VE. Cancer 2009. © 2009 American Cancer Society.

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Connie S. Chen

Oxidative Stress in Developmental Origins of Disease: Teratogenesis, Neurodevelopmental Deficits, and Cancer

Molecular and biochemical mechanisms in teratogenesis involving reactive oxygen species

Enhanced tumorigenesis in p53 knockout mice exposed in utero to high-dose vitamin E

Reduced tumorigenesis in p53 knockout mice exposed in utero to low‐dose vitamin E

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