Insulin resistance plays a key role in the pathogenesis of several human diseases, including diabetes, obesity, hypertension, and cardiovascular diseases. The predisposition to insulin resistance results from genetic and environmental factors. The search for gene variants that predispose to insulin resistance has been thwarted by its genetically heterogeneous pathogenesis. However, using techniques of targeted mutagenesis and transgenesis in rodents, investigators have developed mouse models to test critical hypotheses on the pathogenesis of insulin resistance. Moreover, experimental crosses among mutant mice have shed light onto the polygenic nature of the interactions underlying this complex metabolic condition.
Fsrg1 (female sterile homeotic-related gene 1) is the mouse homolog of the human RING3 protein, which has been shown to associate with the E2 promoter binding factor (E2F) transcription factor and to have a possible role in cell cycle-linked transcriptional regulation. The Fsrg1 protein is 60% identical in sequence to the RNA polymerase II mediator subunit Fsrg4, another member of this subfamily of double bromodomain-containing proteins that are homologs of Drosophila female sterile homeotic. Antibodies against murine Fsrg1 were generated and used in immunoblot and immunoprecipitation experiments to identify proteins interacting with Fsrg1 and RING3. In the presence of acetylated but not nonacetylated histone H3 and H4 peptides, RING3 was shown to interact with E2F, mediator components cyclin-dependent kinase 8 and thyroid receptor-associated protein 220, and the RNA polymerase II large subunit. Fsrg1 mRNA had been previously shown to be expressed at high levels in the epithelium of the adult mouse mammary gland. To determine the physiological relevance of these potential associations, we examined the patterns of expression of Fsrg1 mRNA and protein in the adult mammary epithelia during the reproductive cycle as the tissue is responding to estrogen, progesterone, and prolactin. Changes in the nuclear vs. cytoplasmic localization of Fsrg1 were observed and correlated with physiological changes in mammary gland function. The observations suggested that Fsrg1 may be involved in the transcriptional activities of genes involved in proliferation of the mammary epithelia during pregnancy and in orchestrating postlactation involution and apoptosis. Localization of Fsrg1 on euchromatin, the transcribed portion of the chromosomes, is consistent with its hypothesized function as a transcription regulator.
Vitamin D is a steroid hormone with canonical roles in calcium metabolism and bone modeling. However, in recent years there has been a growing body of literature presenting associations between vitamin D levels and a variety of disease processes, including metabolic disorders such as diabetes and prediabetes and autoimmune conditions such as thyroid disease. This review focuses on the potential role of vitamin D in both male and female reproductive function. The vitamin D receptor (VDR) is expressed throughout central and peripheral organs of reproduction. VDR is often co-localized with its metabolizing enzymes, suggesting the importance of tissue specific modulation of active vitamin D levels. Both animal and human studies in males links vitamin D deficiency with hypogonadism and decreased fertility. In females, there is evidence for its role in polycystic ovary syndrome (PCOS), endometriosis, leiomyomas, in-vitro fertilization, and pregnancy outcomes. Studies evaluating the effects of replacing vitamin D have shown variable results. There remains some concern that the effects of vitamin D on reproduction are not direct, but rather secondary to the accompanying hypocalcemia or estrogen dysregulation.
Physiological states of insulin resistance such as obesity and diabetes have been linked to abnormalities in female reproductive function. However, it is difficult to distinguish the direct effects of impaired insulin signaling from those of adiposity or hyperglycemia because these conditions often coexist in human syndromes and animal models of insulin resistance. In this study, we used lean, normoglycemic mouse lines with differing degrees of hyperinsulinemia and insulin receptor (Insr) expression to dissect the effects of altered insulin signaling on female reproduction. All three mouse lines [Ttr-Insr(-/-), Insr(+/-), and Insr(+/+) (wild type)] are able to maintain fertility. However, the insulin-resistant and hyperinsulinemic mice demonstrate altered duration of estrous cycles as well as aberrant distribution and morphology of ovarian follicles. These effects appear to be independent of hyperandrogenism in the mice. Pregnancy studies indicate decreased success in early progression of gestation. In successful pregnancies, decreased embryo weights and increased placental calcification also implicate altered insulin signaling in later gestational effects. Thus, abnormal insulin signaling, independent of adipose tissue mass, adipokine expression levels, and hyperglycemia, can affect parameters of the female hypothalamic-pituitary-gonadal axis and pregnancy outcomes.
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