BMC Biology (May 2022)

The steroid hormone estriol (E3) regulates epigenetic programming of fetal mouse brain and reproductive tract

  • Yuping Zhou,
  • Baoxia Gu,
  • Geraldine Brichant,
  • Jay Prakash Singh,
  • Huan Yang,
  • Hao Chang,
  • Yanding Zhao,
  • Chao Cheng,
  • Zhong-Wu Liu,
  • Myles H. Alderman,
  • Lingeng Lu,
  • Xiaoyong Yang,
  • Xiao-Bing Gao,
  • Hugh S. Taylor

DOI
https://doi.org/10.1186/s12915-022-01293-4
Journal volume & issue
Vol. 20, no. 1
pp. 1 – 22

Abstract

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Abstract Background Estriol (E3) is a steroid hormone formed only during pregnancy in primates including humans. Although E3 is synthesized at large amounts through a complex pathway involving the fetus and placenta, it is not required for the maintenance of pregnancy and has classically been considered virtually inactive due to associated very weak canonical estrogen signaling. However, estrogen exposure during pregnancy may have an effect on organs both within and outside the reproductive system, and compounds with binding affinity for estrogen receptors weaker than E3 have been found to impact reproductive organs and the brain. Here, we explore potential effects of E3 on fetal development using mouse as a model system. Results We administered E3 to pregnant mice, exposing the fetus to E3. Adult females exposed to E3 in utero (E3-mice) had increased fertility and superior pregnancy outcomes. Female and male E3-mice showed decreased anxiety and increased exploratory behavior. The expression levels and DNA methylation patterns of multiple genes in the uteri and brains of E3-mice were distinct from controls. E3 promoted complexing of estrogen receptors with several DNA/histone modifiers and their binding to target genes. E3 functions by driving epigenetic change, mediated through epigenetic modifier interactions with estrogen receptors rather than through canonical nuclear transcriptional activation. Conclusions We identify an unexpected functional role for E3 in fetal reproductive system and brain. We further identify a novel mechanism of estrogen action, through recruitment of epigenetic modifiers to estrogen receptors and their target genes, which is not correlated with the traditional view of estrogen potency.

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