Sox9 regulates alternative splicing and pancreatic beta cell function [mouse]

Type 2 Diabetes Mellitus (T2D), a multifactorial disease, can result from perturbations in numerous pancreatic genes. We describe a previously unanticipated role for Sox9, a transcriptional regulator of embryonic pancreas and endocrine cell development, in mature beta cells. Our data demonstrate that Sox9 has continued function in beta cells as they mature, and elimination of Sox9 compromises beta cell activities. Sox9-depleted rodent beta cells fail to appropriately secrete insulin and exhibit glucose intolerance in aging animals, mimicking the progressive degeneration observed in T2D. Human beta cells lacking SOX9 are functionally impaired with stunted first phase insulin secretion. In both rodent and human, Sox9 loss in beta cells disrupts alternative splicing patterns, with significant implications for maintenance of cellular function. Thus, our data uncover a novel, unprecedented role for a developmental transcription factor in mature beta cell function. To investigate the role of SOX9 in pancreatic beta cells, we crossed Ins-Cre mice with Sox 9 flox mice to generate the beta cell-specific Sox9 Knockout mice.