Probes for INSULIN

Thioredoxin-interacting protein (Txnip) has emerged as a key factor in pancreatic beta cell biology and its upregulation by glucose and diabetes contributes to the impairment in functional beta cell mass and glucose homeostasis. In addition, beta cell deletion of Txnip protects against diabetes in different mouse models. However, while Txnip is ubiquitously expressed, its role in pancreatic alpha cells has remained elusive. We therefore now generated an alpha cell Txnip knockout (aTKO) mouse and assessed the effects on glucose homeostasis. While no significant changes were observed on regular chow, after a 30-week high-fat diet, aTKO animals showed improvement in glucose tolerance and lower blood glucose levels compared to their control littermates. Moreover, in the context of streptozotocin (STZ)-induced diabetes, aTKO mice showed significantly lower blood glucose levels compared to controls. While serum insulin levels were reduced in both control and aTKO mice, STZ-diabetes significantly increased glucagon levels in control mice, but this effect was blunted in aTKO mice. Moreover, glucagon secretion from aTKO islets was >2-fold lower than from control islets, while insulin secretion was unchanged in aTKO islets. At the same time, no change in alpha cell or beta cell numbers or mass was observed and glucagon and insulin expression and content were comparable in isolated islets from aTKO and control mice. Thus, together the current studies suggest that downregulation of alpha cell Txnip is associated with reduced glucagon secretion and that this may contribute to the glucose-lowering effects observed in diabetic aTKO mice.

Increasing incidence of metabolic disturbances has become a severe public healthcare problem. Ion channels and receptors in the paraventricular nucleus (PVN) of the hypothalamus serve vital roles in modulating neuronal activities and endocrine functions, which are linked to the regulation of energy balance and glucose metabolism. In this study, we found that acid-sensing ion channel 1a (ASIC1a), a Ca2+-permeable cationic ion channel was localized in the PVN. Knockdown of ASIC1a in this region led to significant body weight gain, glucose intolerance, and insulin resistance. Pharmacological inhibition of ASIC1a resulted in an increase in food intake and a decrease in energy expenditure. Our findings suggest ASIC1a in the PVN as a potential new target for the therapeutic intervention of metabolic disorders.

Polycystic ovarian syndrome (PCOS) is the leading cause of anovulatory infertility and is a heterogenous condition associated with a range of reproductive and metabolic impairments. While its etiology remains unclear, hyperandrogenism and impaired steroid negative feedback have been identified as key factors underpinning the development of PCOS-like features both clinically and in animal models. We tested the hypothesis that androgen signaling in kisspeptin-expressing neurons, which are key drivers of the neuroendocrine reproductive axis, is critically involved in PCOS pathogenesis. To this end, we used a previously validated letrozole (LET)-induced hyperandrogenic mouse model of PCOS in conjunction with Cre-lox technology to generate female mice exhibiting kisspeptin-specific deletion of androgen receptor (KARKO mice) to test whether LET-treated KARKO females are protected from the development of reproductive and metabolic PCOS-like features. LET-treated mice exhibited hyperandrogenism, and KARKO mice exhibited a significant reduction in the coexpression of kisspeptin and androgen receptor mRNA compared to controls. In support of our hypothesis, LET-treated KARKO mice exhibited improved estrous cyclicity, ovarian morphology, and insulin sensitivity in comparison to LET-treated control females. However, KARKO mice were not fully protected from the effects of LET-induced hyperandrogenism and still exhibited reduced corpora lutea numbers and increased body weight gain. These data indicate that increased androgen signaling in kisspeptin-expressing neurons plays a critical role in PCOS pathogenesis, but highlight that other mechanisms are also involved.

Androgens are steroid hormones crucial for sexual differentiation of the brain and reproductive function. In excess, however, androgens may decrease fertility as observed in polycystic ovary syndrome, a common endocrine disorder characterized by oligo/anovulation and/or polycystic ovaries. Hyperandrogenism may also disrupt energy homeostasis, inducing higher central adiposity, insulin resistance, and glucose intolerance, which may exacerbate reproductive dysfunction. Androgens bind to androgen receptors (AR), which are expressed in many reproductive and metabolic tissues, including brain sites that regulate the hypothalamo-pituitary-gonadal axis and energy homeostasis. The neuronal populations impacted by androgen excess, however, have not been defined. We and others have shown that, in mice, AR is highly expressed in leptin receptor (LepRb) neurons, particularly in the arcuate (ARH) and the ventral premammillary nuclei (PMv). Here, we assessed if LepRb neurons, which are critical in the central regulation of energy homeostasis and exert permissive actions on puberty and fertility, have a role in the pathogenesis of female hyperandrogenism. Prenatally androgenized (PNA) mice lacking AR in LepRb cells (LepRbΔAR) show no changes in body mass, body composition, glucose homeostasis, or sexual maturation. They show, however, a remarkable improvement of estrous cycles combined with normalization of ovary morphology compared to PNA controls. Our findings indicate that the prenatal androgenization effects on adult reproductive physiology (i.e., anestrus and anovulation) are mediated by a subpopulation of LepRb neurons directly sensitive to androgens. They also suggest that the effects of hyperandrogenism on sexual maturation and reproductive function in adult females are controlled by distinct neural circuits.