Abstract
BackgroundLoss of pancreatic insulin-secreting β-cells due to metabolic or autoimmune damage leads to the development of diabetes. The discovery that α-cells can be efficiently reprogrammed into insulin-secreting cells in mice and humans has opened promising avenues for innovative diabetes therapies. β-cell loss triggers spontaneous reprogramming of only 1–2% of α-cells, limiting the extent of regeneration. Most α-cells are refractory to conversion and their global transcriptomic response to severe β-cell loss as well as the mechanisms opposing their reprogramming into insulin producers are largely unknown. Here, we performed RNA-seq on FAC-sorted α-cells to characterize their global transcriptional responses at different time points after massive β-cell ablation.ResultsOur results show that α-cells undergo stage-specific transcriptional changes 5- and 15-days post-diphtheria toxin (DT)-mediated β-cell ablation. At 5 days, α-cells transiently upregulate various genes associated with interferon signaling and proliferation, including Interferon Induced Protein with Tetratricopeptide Repeats 3 (Ifit3). Subsequently, at 15 days post β-cell ablation, α-cells undergo a transient downregulation of genes from several pathways including Insulin receptor, mTOR and MET signaling.ConclusionsThe results presented here pinpoint novel markers discriminating α-cells at different stages after acute β-cell loss, and highlight additional signaling pathways that are modulated in α-cells in this context.
Highlights
Loss of pancreatic insulin-secreting β-cells due to metabolic or autoimmune damage leads to the development of diabetes
Ectopic expression of the transcription factors (TFs) PDX1 and MAFA in human α-cells efficiently converts them into insulin-secreting cells that lead to diabetes reversal when transplanted into diabetic mice [6]
Loss of β-cells triggers stage-specific global transcriptional changes in the α-cell population To begin dissecting the molecular programs dynamically regulated in α-cells following severe β-cell ablation, we FAC-sorted α-cells from Glucagon-rtTA, TetO-Cre, R26
Summary
Loss of pancreatic insulin-secreting β-cells due to metabolic or autoimmune damage leads to the development of diabetes. The discovery that α-cells can be efficiently reprogrammed into insulin-secreting cells in mice and, remarkably, in humans [6], has spurred intense research to dissect the underlying conversion mechanisms. Ectopic expression of the TFs PDX1 and MAFA in human α-cells efficiently converts them into insulin-secreting cells that lead to diabetes reversal when transplanted into diabetic mice [6]. Taken together, these data suggest that various genetic mechanisms are dynamically integrated to regulate α-cell identity and plasticity in homeostatic or stress conditions. We have just begun to understand these complex α-cell genetic networks and crucial wide-ranging questions remain unanswered
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