Mansa Krishnamurthy

Integrin α3, But Not β1, Regulates Islet Cell Survival and Function via PI3K/Akt Signaling Pathways

β1-integrin is a well-established regulator of β-cell activities; however, the role of its associated α-subunits is relatively unknown. Previously, we have shown that human fetal islet and INS-1 cells highly express α3β1-integrin and that collagens I and IV significantly enhance their survival and function; in addition, blocking β1 function in the fetal islet cells decreased adhesion on collagen I and increased apoptosis. The present study investigates the effect of blocking α3. Using α3 blocking antibody or small interfering RNA, the effects of α3-integrin blockade were examined in isolated human fetal or adult islet cells or INS-1 cells, cultured on collagens I or IV. In parallel, β1 blockade was analyzed in INS-1 cells. Perturbing α3 function in human islet or INS-1 cells resulted in significant decreases in cell function (adhesion, spreading, proliferation and Pdx1 and insulin expression/secretion), primarily on collagen IV. A significant decrease in focal adhesion kinase and ERK1/2 phosphorylation and increased caspase3 cleavage were observed on both collagens. These effects were similar to changes after β1 blockade. Interestingly, only α3 blockade reduced expression of phospho-Akt and members of its downstream signaling cascades (glycogen synthase kinase β and X-linked inhibitor of apoptosis), demonstrating a specific effect of α3 on the phosphatidylinositol 3-kinase/Akt pathway. These results suggest that α3- as well as β1-integrin-extracellular matrix interactions are critical for modulating β-cell survival and function through specialized signaling cascades and enhance our understanding of how to improve islet microenvironments for cell-based treatments of diabetes.

Conditional β1-integrin-deficient mice display impaired pancreatic β cell function.

β1‐Integrin, a critical regulator of β cell survival and function, has been shown to protect against cell death and promote insulin expression and secretion in rat and human islet cells in vitro. The aim of the present study was to examine whether the knockout of β1‐integrin in collagen I‐producing cells would have physiological and functional implications in pancreatic endocrine cells in vivo. Using adult mice with a conditional knockout of β1‐integrin in collagen I‐producing cells, the effects of β1‐integrin deficiency on glucose metabolism and pancreatic endocrine cells were examined. Male β1‐integrin‐deficient mice display impaired glucose tolerance, with a significant reduction in pancreatic insulin content (p < 0.01). Morphometric analysis revealed a significant reduction in β cell mass (p < 0.001) in β1‐integrin‐deficient mice, along with a significant decrease in β cell proliferation, Pdx‐1 and Nkx6.1 expression when compared with controls. Interestingly, these physiological and morphometric alterations in female β1‐integrin‐deficient mice were less significant. Furthermore, β1‐integrin‐deficient mice displayed decreased FAK (p < 0.05) and ERK1/2 (p < 0.001) phosphorylation, reduced cyclin D1 levels (p < 0.001) and increased caspase 3 cleavage (p < 0.01), while no changes in Akt phosphorylation were observed, indicating that the β1‐integrin signals through the FAK–MAPK–ERK pathway in vivo. Our results demonstrate that β1‐integrin is involved in the regulation of glucose metabolism and contributes to the maintenance of β cell survival and function in vivo. Copyright

Expression and function of αβ1 integrins in pancretic beta (INS-1) cells

Integrin-extracellular matrix interactions are important determinants of beta cell behaviours. The β1 integrin is a well-known regulator of beta cell activities; however, little is known of its associated α subunits. In the present study, αβ1 integrin expression was examined in the rat insulinoma cell line (INS-1) to identify their role in beta cell survival and function. Seven α subunits associated with β1 integrin were identified, including α1-6 and αV. Among these heterodimers, α3β1 was most highly expressed. Common ligands for the α3β1 integrin, including fibronectin, laminin, collagen I and collagen IV were tested to identify the most suitable matrix for INS-1 cell proliferation and function. Cells exposed to collagen I and IV demonstrated significant increases in adhesion, spreading, cell viability, proliferation, and FAK phosphorylation when compared to cells cultured on fibronectin, laminin and controls. Integrin-dependent attachment also had a beneficial effect on beta cell function, increasing Pdx-1 and insulin gene and protein expression on collagens I and IV, in parallel with increased basal insulin release and enhanced insulin secretion upon high glucose challenge. Furthermore, functional blockade of α3β1 integrin decreased cell adhesion, spreading and viability on both collagens and reduced Pdx-1 and insulin expression, indicating that its interactions with collagen matrices are important for beta cell survival and function. These results demonstrate that specific αβ1 integrin-ECM interactions are critical regulators of INS-1 beta cell survival and function and will be important in designing optimal conditions for cell-based therapies for diabetes treatment.

SOX9 regulates endocrine cell differentiation during human fetal pancreas development

The transition of pancreatic progenitor cells to mature endocrine cells is regulated by the sequential activation and interaction of several transcription factors. In mice, the transcription factor Sox9 has been shown to support endocrine cell differentiation. However, the functional role of SOX9 during pancreas development in the human has yet to be determined. The present study was to characterize SOX9 expression during human fetal pancreas development and examine its functional role by transfection with SOX9 siRNA or SOX9 expression vectors. Here we report that SOX9 was most frequently expressed in PDX1(+) cells (60-83%) and least in mature endocrine cells (<1-14%). The proliferation of SOX9(+) cells was significantly higher at 8-10 weeks than at 14-21 weeks (p<0.05) or 20-21 weeks (p<0.01). SOX9 frequently co-localized with FOXA2, NGN3 and transcription factors linked to NGN3 (NKX2.2, NKX6.1, PAX6). siRNA knockdown of SOX9 significantly decreased islet-epithelial cell proliferation, NGN3, NKX6.1, PAX6 and INS mRNA levels and the number of NGN3(+) and insulin(+) cells (p<0.05) while increasing GCG mRNA and glucagon(+) cells (p<0.05). Examination of SOX9 associated signaling pathways revealed a decrease in phospho-Akt (p<0.01), phospho-GSK3β (p<0.01) and cyclin D1 (p<0.01) with a decrease in nuclear β-catenin(+) (p<0.05) cells following SOX9 siRNA knockdown. In contrast, over-expression of SOX9 significantly increased the number of islet cells proliferating, NGN3, NKX6.1, PAX6 and INS mRNA levels, the phospho-Akt/GSK3β cascade and the number of insulin(+) cells. Our results demonstrated that SOX9 is important for the expression of NGN3 and molecular markers of endocrine cell differentiation in the human fetal pancreas.

The Emerging Role of SOX Transcription Factors in Pancreatic Endocrine Cell Development and Function

The transition of pancreatic progenitor cells to mature beta cells is regulated by the interaction of several transcription factors, including members of the sex-determining region on Y box (SOX) family of transcription factors. The SOX proteins are widely involved in cell fate determination and the development of several tissues, including bone, heart, gonads, lymphocytes, and glial cells as well as the pancreas. In this review, we will present recent findings that illustrate the critical role of SOX transcription factors in maintaining pancreatic progenitor cell pools and in controlling pancreatic islet morphogenesis and islet function. Interrelationships between the SOX family and other pancreatic transcription factors specific to endocrine lineages will also be discussed in light of islet cell-based therapies for the treatment of diabetes.

Inhibition of Gsk3β activity improves β-cell function in c-KitWv/+ male mice

Previous studies have shown that the stem cell marker, c-Kit, is involved in glucose homeostasis. We recently reported that c-KitWv/+ male mice displayed the onset of diabetes at 8 weeks of age; however, the mechanisms by which c-Kit regulates β-cell proliferation and function are unknown. The purpose of this study is to examine if c-KitWv/+ mutation-induced β-cell dysfunction is associated with downregulation of the phospho-Akt/Gsk3β pathway in c-KitWv/+ male mice. Histology and cell signaling were examined in C57BL/6J/KitWv/+ (c-KitWv/+) and wild-type (c-Kit+/+) mice using immunofluorescence and western blotting approaches. The Gsk3β inhibitor, 1-azakenpaullone (1-AKP), was administered to c-KitWv/+ and c-Kit+/+ mice for 2 weeks, whereby alterations in glucose metabolism were examined and morphometric analyses were performed. A significant reduction in phosphorylated Akt was observed in the islets of c-KitWv/+ mice (P<0.05) along with a decrease in phosphorylated Gsk3β (P<0.05), and cyclin D1 protein level (P<0.01) when compared with c-Kit+/+ mice. However, c-KitWv/+ mice that received 1-AKP treatment demonstrated normal fasting blood glucose with significantly improved glucose tolerance. 1-AKP-treated c-KitWv/+ mice also showed increased β-catenin, cyclin D1 and Pdx-1 levels in islets, demonstrating that inhibition of Gsk3β activity led to increased β-cell proliferation and insulin secretion. These data suggest that c-KitWv/+ male mice had alterations in the Akt/Gsk3β signaling pathway, which lead to β-cell dysfunction by decreasing Pdx-1 and cyclin D1 levels. Inhibition of Gsk3β could prevent the onset of diabetes by improving glucose tolerance and β-cell function.

The Role of SOX9 Transcription Factor in Pancreatic and Duodenal Development

Progenitor expansion during development is a highly regulated process dictating the final organ size, while expansion of specific progenitor populators can adjust the final cellular composition of the organ. Understanding factors involved in these pathways is required to develop cell-based therapies such as β-cell transplantation for conditions such as diabetes mellitus. One versatile factor controlling both processes as well as a network of other proteins involved in pancreatic and duodenal development is the transcription factor SOX9. This review will focus on a comparison of SOX9 function during progenitor expansion and differentiation in the developing pancreas and duodenum with specific focus on endocrine development. During human pancreatic development, SOX9 functions in a dose-dependent manner to regulate epithelial progenitor expansion and endocrine differentiation. SOX9 expression is eventually limited to a subset of ductal and centroacinar cells, hypothesized to be the pancreatic stem cell compartment. Similarly, during duodenal development, SOX9 is expressed in most early epithelial progenitors and becomes gradually restricted to proliferative progenitors in the lower crypts, as well as mature Paneth and enteroendocrine cells indicating some differences in functional roles. However, in both developmental contexts, SOX9 is involved in pathways responsible for cellular proliferation and differentiation, such as Notch and Wnt. With its adaptable and central function in progenitor control, SOX9 represents an attractive target for manipulation for in vitro progenitor expansion and differentiation meriting further investigation.