Estrogen regulation of the molecular phenotype and active translatome of AVPV kisspeptin neurons

In females, ovarian estradiol (E2) exerts both negative and positive feedback regulation on the neural circuits governing reproductive hormone secretion, but the cellular and molecular mechanisms underlying this remain poorly understood. In rodents, ERα-expressing kisspeptin neurons in the hypothalamic anteroventral periventricular region (AVPV) are prime candidates to mediate E2 positive feedback induction of preovulatory GnRH and LH surges. E2 stimulates AVPV Kiss1 expression, but the full extent of estrogen effects in these neurons is unknown; whether E2 stimulates or inhibits other genes in AVPV Kiss1 cells has not been determined. Indeed, understanding of the function(s) of AVPV kisspeptin cells is limited, in part, by minimal knowledge of their overall molecular phenotype, as only a few genes are currently known to be co-expressed in AVPV Kiss1 cells. To provide a more detailed profiling of co-expressed genes in AVPV Kiss1 cells, including receptors and other signaling factors, and test how these genes respond to E2, we selectively isolated actively-translated mRNAs from AVPV Kiss1 cells of female mice and performed RNA-Seq. This identified >13,000 mRNAs co-expressed in AVPV Kiss1 cells, including multiple receptor and ligand transcripts positively or negatively regulated by E2. We also performed RNAscope to validate high co-expression of several transcripts identified by RNA-Seq, including Pdyn (prodynorphin), Penk (proenkephalin), Vgf (VGF), and Cartpt (CART), in female AVPV Kiss1 cells. Given the important role of AVPV kisspeptin cells in positive feedback, E2 effects on identified genes may relate to the LH surge mechanism and/or other physiological processes involving these AVPV kisspeptin cells.

Previous estradiol treatment during midlife maintains transcriptional regulation of memory-related proteins by ERα in the hippocampus in a rat model of menopause

Previous midlife estradiol treatment, like continuous treatment, improves memory and results in lasting increases in hippocampal levels of estrogen receptor (ER) α and ER-dependent transcription in ovariectomized rodents. We hypothesized that previous and continuous midlife estradiol act to specifically increase levels of nuclear ERα, resulting in transcriptional regulation of proteins that mediate estrogen effects on memory. Ovariectomized middle-aged rats received estradiol or vehicle capsule implants. After 40 days, rats initially receiving vehicle received another vehicle capsule (Vehicle). Rats initially receiving estradiol received either another estradiol (Continuous Estradiol) or a vehicle (Previous Estradiol) capsule. One month later, hippocampal genes and proteins were analyzed. Continuous and previous estradiol increased levels of nuclear, but not membrane or cytosolic ERα and had no effect on Esr1. Continuous and previous estradiol impacted gene expression and/or protein levels of mediators of estrogenic action on memory including ChAT, BDNF, and PSD-95. Findings demonstrate a long-lasting role for hippocampal ERα as a transcriptional regulator of memory following termination of previous estradiol treatment in a rat model of menopause.

Estrogen metabolism: why it’s so crucial to keep the balance?

Aim. To analyze and systematize the available information on pathogenetic mechanisms of hormonal carcinogenesis. Materials and methods. The review includes data from foreign articles published in PubMed and Medline and national works posted on elibrary.ru over the past 20 years. Results. Currently, the term estrogen is often used in the context of hormonal carcinogenesis. According to most researchers, it should not fit into the narrow framework of receptor-mediated proliferation induced by estrogens in target tissues. The concept of estrobiome as a combination of all mechanisms providing the realization of estrogen effects should include not only hormones and native receptors themselves, but also the enzymes involved in their synthesis, estrogen metabolites, intestinal microbiota, as well as genetic and epigenetic factors. Conclusions. When analyzing cancer risk, it is necessary to comprehensively assess contributing factors and hormonal-metabolic preconditions for neoplastic process.

Effects of Estradiol on Basal Forebrain Cholinergic Neurons and Their Impact on Cognitive Performance and Age-Related Cognitive Decline

Cholinergic neurons in the basal forebrain play an important role in modulating wakefulness, alertness, and selective attention and contribute significantly to learning and memory processes. These neurons also are affected by estrogens. Loss of circulating estrogens negatively impacts the functionality of cholinergic projections to the hippocampus and cerebral cortex, resulting in impaired cognitive performance. These effects can be reversed by appropriate estrogen treatment or treatment with selective estrogen receptor agonists. Evidence also suggests that the cholinergic neurons play an essential role in enabling effects of estrogens on synaptic plasticity, which benefit cognitive performance. This chapter summarizes evidence for estrogen effects on basal forebrain cholinergic projections and the relevance of these findings to the maintenance of cognitive performance and to the prevention of age- and disease-related cognitive decline in women.

Estradiol Metabolism: Crossroads in Pulmonary Arterial Hypertension

Pulmonary arterial hypertension (PAH) is a debilitating and progressive disease that predominantly develops in women. Over the past 15 years, cumulating evidence has pointed toward dysregulated metabolism of sex hormones in animal models and patients with PAH. 17β-estradiol (E2) is metabolized at positions C2, C4, and C16, which leads to the formation of metabolites with different biological/estrogenic activity. Since the first report that 2-methoxyestradiol, a major non-estrogenic metabolite of E2, attenuates the development and progression of experimental pulmonary hypertension (PH), it has become increasingly clear that E2, E2 precursors, and E2 metabolites exhibit both protective and detrimental effects in PH. Furthermore, both experimental and clinical data suggest that E2 has divergent effects in the pulmonary vasculature versus right ventricle (estrogen paradox in PAH). The estrogen paradox is of significant clinical relevance for understanding the development, progression, and prognosis of PAH. This review updates experimental and clinical findings and provides insights into: (1) the potential impacts that pathways of estradiol metabolism (EMet) may have in PAH; (2) the beneficial and adverse effects of estrogens and their precursors/metabolites in experimental PH and human PAH; (3) the co-morbidities and pathological conditions that may alter EMet and influence the development/progression of PAH; (4) the relevance of the intracrinology of sex hormones to vascular remodeling in PAH; and (5) the advantages/disadvantages of different approaches to modulate EMet in PAH. Finally, we propose the three-tier-estrogen effects in PAH concept, which may offer reconciliation of the opposing effects of E2 in PAH and may provide a better understanding of the complex mechanisms by which EMet affects the pulmonary circulation–right ventricular interaction in PAH.