Exploring the Effects of Metabolism-Disrupting Chemicals on Pancreatic α-Cell Viability, Gene Expression and Function: A Screening Testing Approach.

Humans are constantly exposed to many environmental pollutants, some of which have been largely acknowledged as key factors in the development of metabolic disorders such as diabetes and obesity. These chemicals have been classified as endocrine-disrupting chemicals (EDCs) and, more recently, since they can interfere with metabolic functions, they have been renamed as metabolism-disrupting chemicals (MDCs). MDCs are present in many consumer products, including food packaging, personal care products, plastic bottles and containers, and detergents. The scientific literature has ever-increasingly focused on insulin-releasing pancreatic ß-cells as one of the main targets for MDCs. Evidence highlights that these substances may disrupt glucose homeostasis by altering pancreatic ß-cell physiology. However, their potential impact on glucagon-secreting pancreatic α-cells remains poorly known despite the essential role that this cellular type plays in controlling glucose metabolism. In the present study, we have selected seven paradigmatic MDCs representing major toxic classes, including bisphenols, phthalates, perfluorinated compounds, metals, and pesticides. By using an in vitro cell-based model, the pancreatic α-cell line αTC1-9, we have explored the effects of these compounds on pancreatic α-cell viability, gene expression, and secretion. We found that cell viability was moderately affected after bisphenol-A (BPA), bisphenol-F (BPF), and perfluorooctanesulfonic acid (PFOS) exposure, although cytotoxicity was relatively low. In addition, all bisphenols, as well as di(2-ethylhexyl) phthalate (DEHP) and cadmium chloride (CdCl2), promoted a marked decreased on glucagon secretion, together with changes in the expression of glucagon and/or transcription factors involved in cell function and identity, such as Foxo1 and Arx. Overall, our results indicated that most of the selected chemicals studied caused functional alterations in pancreatic α-cells. Moreover, we revealed, for the first time, their direct effects on key molecular aspects of pancreatic α-cell biology.

The immunolocalization of HIF-2α, GLUT1 and CAIX in porcine oviduct during the estrous cycle.

Oxygen (O2 ) rates in the oviduct are essential to human and animal reproduction. These rates are regulated by the activity of hypoxia markers such as the hypoxia-inducible factors (HIFs), the glucose transporters (GLUT), and the carbonic anhydrase (CA). In the porcine model, scarce studies have been reported regarding these markers and their effects in reproduction are unknown. The objective was to characterize the immunolocalization of HIF-2α, GLUT1, and CAIX in porcine oviducts throughout the estrous cycle. Oviducts (ampulla and isthmus) of adult sows (n = 45) were collected for histological and immunohistochemical analysis with HIF-2α, GLUT1, and CAIX markers. The percentage of immunopositive area was quantified, and the differences among phases of the estrous cycle were analyzed (folicular, early luteal, and late luteal). The three markers showed epithelial presence mainly. Significantly lower expression of HIF-2α was found in the luteal phases, especially in the isthmus. GLUT1 expression did not change throughout the estrous cycle, but differences were found between the ampulla and isthmus. CAIX expression showed the highest, with a significant downward trend throughout estrous cycle. The ubiquitous expression of hypoxia markers shows the porcine oviduct physiology in relation to O2 . The differential expression of HIF-2α, GLUT1, and CAIX in different subcompartments of the oviduct throughout the estrous cycle contributes to improve the knowledge of the cell physiology of the oviduct, which can be useful in fertilization studies.

Combinatorial pathway disruption is a powerful approach to delineate metabolic impacts of endocrine disruptors.

The prevalence of metabolic diseases, such as obesity, diabetes, metabolic syndrome and chronic liver diseases among others, has been rising for several years. Epidemiology and mechanistic (in vivo, in vitro and in silico) toxicology have recently provided compelling evidence implicating the chemical environment in the pathogenesis of these diseases. In this review, we will describe the biological processes that contribute to the development of metabolic diseases targeted by metabolic disruptors, and will propose an integrated pathophysiological vision of their effects on several organs. With regard to these pathomechanisms, we will discuss the needs, and the stakes of evolving the testing and assessment of endocrine disruptors to improve the prevention and management of metabolic diseases that have become a global epidemic since the end of last century.

Screening of Relevant Metabolism-Disrupting Chemicals on Pancreatic ß-Cells: Evaluation of Murine and Human In Vitro Models.

Endocrine-disrupting chemicals (EDCs) are chemical substances that can interfere with the normal function of the endocrine system. EDCs are ubiquitous and can be found in a variety of consumer products such as food packaging materials, personal care and household products, plastic additives, and flame retardants. Over the last decade, the impact of EDCs on human health has been widely acknowledged as they have been associated with different endocrine diseases. Among them, a subset called metabolism-disrupting chemicals (MDCs) is able to promote metabolic changes that can lead to the development of metabolic disorders such as diabetes, obesity, hepatic steatosis, and metabolic syndrome, among others. Despite this, today, there are still no definitive and standardized in vitro tools to support the metabolic risk assessment of existing and emerging MDCs for regulatory purposes. Here, we evaluated the following two different pancreatic cell-based in vitro systems: the murine pancreatic ß-cell line MIN6 as well as the human pancreatic ß-cell line EndoC-ßH1. Both were challenged with the following range of relevant concentrations of seven well-known EDCs: (bisphenol-A (BPA), bisphenol-S (BPS), bisphenol-F (BPF), perfluorooctanesulfonic acid (PFOS), di(2-ethylhexyl) phthalate (DEHP), cadmium chloride (CdCl2), and dichlorodiphenyldichloroethylene (DDE)). The screening revealed that most of the tested chemicals have detectable, deleterious effects on glucose-stimulated insulin release, insulin content, electrical activity, gene expression, and/or viability. Our data provide new molecular information on the direct effects of the selected chemicals on key aspects of pancreatic ß-cell function, such as the stimulus-secretion coupling and ion channel activity. In addition, we found that, in general, the sensitivity and responses were comparable to those from other in vivo studies reported in the literature. Overall, our results suggest that both systems can serve as effective tools for the rapid screening of potential MDC effects on pancreatic ß-cell physiology as well as for deciphering and better understanding the molecular mechanisms that underlie their action.

Bisphenol-A exposure during pregnancy alters pancreatic ß-cell division and mass in male mice offspring: A role for ERß.

Bisphenol-A (BPA) is a widespread endocrine disrupting chemical that constitutes a risk factor for type 2 diabetes mellitus (T2DM). Data from animal and human studies have demonstrated that early exposure to BPA results in adverse metabolic outcomes in adult life. In the present work, we exposed pregnant heterozygous estrogen receptor ß (ERß) knock out (BERKO) mice to 10 µg/kg/day BPA, during days 9-16 of pregnancy, and measured ß-cell mass and proliferation in wildtype (WT) and BERKO male offspring at postnatal day 30. We observed increased pancreatic ß-cell proliferation and mass in WT, yet no effect was produced in BERKO mice. Dispersed islet cells in primary culture treated with 1 nM BPA showed an enhanced pancreatic ß-cell replication rate, which was blunted in pancreatic ß-cells from BERKO mice and mimicked by the selective ERß agonist WAY200070. This increased ß-cell proliferation was found in male adult as well as in neonate pancreatic ß-cells, suggesting that BPA directly impacts ß-cell division at earliest stages of life. These findings strongly indicate that BPA during pregnancy upregulates pancreatic ß-cell division and mass in an ERß-dependent manner. Thus, other natural or artificial chemicals may use this ERß-mediated pathway to promote similar effects.

Maternal Exposure to Bisphenol-A During Pregnancy Increases Pancreatic ß-Cell Growth During Early Life in Male Mice Offspring.

Alterations during development of metabolic key organs such as the endocrine pancreas affect the phenotype later in life. There is evidence that in utero or perinatal exposure to bisphenol-A (BPA) leads to impaired glucose metabolism during adulthood. However, how BPA exposure during pregnancy affects pancreatic ß-cell growth and function in offspring during early life has not been explored. We exposed pregnant mice to either vehicle (control) or BPA (10 and 100 µg/kg·d, BPA10 and BPA100) and examined offspring on postnatal days (P) P0, P21, P30, and P120. BPA10 and BPA100 mice presented lower birth weight than control and subsequently gained weight until day 30. At that age, concentration of plasma insulin, C-peptide, and leptin were increased in BPA-exposed animals in the nonfasting state. Insulin secretion and content were diminished in BPA10 and maintained in BPA100 compared with control. A global gene expression analysis indicated that genes related with cell division were increased in islets from BPA-treated animals. This was associated with an increase in pancreatic ß-cell mass at P0, P21, and P30 together with increased ß-cell proliferation and decreased apoptosis. On the contrary, at P120, BPA-treated animals presented either equal or decreased ß-cell mass compared with control and altered fasting glucose levels. These data suggest that in utero exposure to environmentally relevant doses of BPA alters the expression of genes involved in ß-cell growth regulation, incrementing ß-cell mass/area, and ß-cell proliferation during early life. An excess of insulin signaling during early life may contribute to impaired glucose tolerance during adulthood.