More than meets the islet: aligning nutrient and paracrine inputs with hormone secretion in health and disease.

The pancreatic islet is responsive to an array of endocrine, paracrine, and nutritional inputs that adjust hormone secretion to ensure accurate control of glucose homeostasis. Although the mechanisms governing glucose-coupled insulin secretion have received the most attention, there is emerging evidence for a multitude of physiological signaling pathways and paracrine networks that collectively regulate insulin, glucagon, and somatostatin release. Moreover, the modulation of these pathways in conditions of glucotoxicity or lipotoxicity are areas of both growing interest and controversy. In this review, the contributions of external, intrinsic, and paracrine factors in pancreatic ß-, α-, and δ-cell secretion across the full spectrum of physiological (i.e., fasting and fed) and pathophysiological (gluco- and lipotoxicity; diabetes) environments will be critically discussed.

Gestational Diabetes Adversely Affects Pancreatic Islet Architecture and Function in the Male Rat Offspring.

Fetal exposure to gestational diabetes mellitus (GDM) and poor postnatal diet are strong risk factors for type 2 diabetes development later in life, but the mechanisms connecting GDM exposure to offspring metabolic health remains unclear. In this study, we aimed to determine how GDM interacts with the postnatal diet to affect islet function in the offspring as well as characterize the gene expression changes in the islets. GDM was induced in female rats using a high-fat, high-sucrose (HFS) diet, and litters from lean or GDM dams were weaned onto a low-fat (LF) or HFS diet. Compared with the lean control offspring, GDM exposure reduced glucose-stimulated insulin secretion in islets isolated from 15-week-old offspring, which was additively worsened when GDM exposure was combined with postnatal HFS diet consumption. In the HFS diet-fed offspring of lean dams, islet size and number increased, an adaptation that was not observed in the HFS diet-fed offspring of GDM dams. Islet gene expression in the offspring of GDM dams was altered in such categories as inflammation (e.g., Il1b, Ccl2), mitochondrial function/oxidative stress resistance (e.g., Atp5f1, Sod2), and ribosomal proteins (e.g., Rps6, Rps14). These results demonstrate that GDM exposure induced marked changes in gene expression in the male young adult rat offspring that cumulatively interact to worsen islet function, whole-body glucose homeostasis, and adaptations to HFS diets.

Maternal obesity, diabetes during pregnancy and epigenetic mechanisms that influence the developmental origins of cardiometabolic disease in the offspring.

Since 1980, global obesity has doubled, and the incidence of cardiometabolic diseases such as type 2 diabetes and heart disease is also increasing. While genetic susceptibility and adult lifestyle are implicated in these trends, evidence from clinical cohorts, epidemiological studies and animal model experiments support a role for early-life environmental exposures in determining the long-term health of an individual, which has led to the formulation of the Developmental Origins of Health and Disease (DOHaD) theory. In fact, maternal obesity and diabetes during pregnancy, which are on the rise, are strongly associated with altered fetal growth and development as well as with lifelong perturbations in metabolic tissues. A mounting body of evidence implicates epigenetic mechanisms (e.g. DNA methylation and histone modifications) in the regulation of these effects and their transmission to future generations. This review critically discusses the current evidence (in animal model systems and humans) that implicates maternal obesity and diabetes during pregnancy in perturbing the epigenome of the next generation, and the consequential impact on growth, organ development and ultimately cardiometabolic disease progression. Additionally, this review will address some of the limitations of the DOHaD approach and areas that require further study. For example, future research requires verification of the mechanistic impact of the epigenetic marks and their persistence over the life course. Ultimately, this knowledge is needed to establish optimal screening, prevention and therapeutic approaches for children at risk of cardiometabolic disease development.