Project description:Accumulation of DNA damage drives β-cell dysfunction, senescence, and death in Type 1 and Type 2 diabetes. While α-cell dysfunction also contributes to disease pathology, they remain remarkably resistant to senescence and cell-death. The mechanisms underlying these differential responses to diabetogenic stress, particularly differences in their DNA damage vulnerability, remain unclear. We demonstrate that replication introduces a window of genomic vulnerability in both α- and β-cells during neonatal growth, with α-cells exhibiting higher replication rates and DNA damage. We show that neonatal β-cells resolve DNA damage more efficiently during mitosis and favor error-free repair, while α-cells compensate for their higher DNA damage vulnerability through increased cellular turnover. Using mouse models of overnutrition and diabetes, we show that β-cells exhibit greater vulnerability to terminal DNA damage and impaired repair capacity under diabetogenic stress, with compensatory replication amplifying this vulnerability. We demonstrate that developmental epigenetic programs shape the differential DNA damage vulnerability of postnatal β- and α-cells. Loss of de novo DNA methyltransferase Dnmt3a in pancreatic progenitors selectively increases the DNA damage vulnerability of β-cells from neonatal growth through adulthood. Our findings uncover novel developmental mechanisms that shape the distinct DNA damage responses of postnatal β- and α-cells during growth and diabetes.

Project description:Loss of mature β cell function and identity, or β cell dedifferentiation, is seen in all types of diabetes mellitus. Two competing models explain β cell dedifferentiation in diabetes. In the first model, β cells dedifferentiate in the reverse order of their developmental ontogeny. This model predicts that dedifferentiated β cells resemble β cell progenitors. In the second model, β cell dedifferentiation depends on the type of diabetogenic stress. This model, which we call the “Anna Karenina” model, predicts that in each type of diabetes, β cells dedifferentiate in their own way, depending on how their mature identity is disrupted by any particular diabetogenic stress. We directly tested the two models using a β cell-specific lineage-tracing system coupled with RNA-sequencing in mice. We constructed a multidimensional map of β cell transcriptional trajectories during the normal course of β cell postnatal development, and during their dedifferentiation in models of both type 1 diabetes (NOD) and type 2 diabetes (BTBR-Lepob/ob). Using this unbiased approach, we show here that despite some similarities between immature and dedifferentiated β cells, β cells dedifferentiation in the two mouse models is not a reversal of developmental ontogeny and is different between different types of diabetes.

Project description:Developmental control of DNA damage responses in α- and β-cells shapes the selective beta-cell susceptibility in diabetes

Project description:The circadian clock plays a vital role in modulating the cellular immune response. However, its role in mediating pro-inflammatory diabetogenic β-cell injury remains largely unexplored. Our studies demonstrate that conditional deletion of Bmal1 in mouse β-cells was shown to impair the ability of β-cells to recover from streptozotocin-mediated pro-inflammatory injury in vivo, leading to β-cell failure and the development of diabetes. Our study suggests that the β-cell circadian clock mediates β-cell response and recovery from pro-inflammatory injury common to the pathogenesis of diabetes mellitus.

Project description:Immune-mediated beta cell destruction and lack of alpha cell responsiveness to hypoglycaemia are hallmarks of type 1 diabetes pathology. The incretin hormone glucose-dependent insulinotropic polypeptide (GIP) may hold therapeutic potential for type 1 diabetes due to its insulinotropic and glucagonotropic effects as well as its beta cell protective effects shown in rodent islets. Here, we examined the functional and transcriptomic effects of GIP treatment upon diabetogenic cytokine exposure to interleukin (IL)-1β ± interferon (IFN)-γ in human EndoC-βH5 beta cells and isolated human islets, respectively. GIP dose-dependently augmented glucose-stimulated insulin secretion from EndoC-βH5 cells and increased insulin and glucagon secretion from human islets during high and low glucose concentrations, respectively. The insulinotropic effect of GIP in EndoC-βH5 cells was abrogated by KN-93, an inhibitor of calcium/calmodulin-dependent protein kinase 2 (CaMK2). GIP did not prevent cytokine-induced apoptosis or cytokine-induced functional impairment of human EndoC-βH5 cells. GIP also did not prevent cytokine-induced apoptosis in human islets. GIP treatment of human islets with or without cytokines for 24 hours did not significantly impact the transcriptome. GIP potentiated cytokine-induced secretion of IL-10 and c-c motif chemokine ligand (CCL)-2 from human islets while decreasing the secretion of c-x-c motif chemokine ligand (CXCL)-8. In EndoC-βH5 cells, GIP reduced IFN-γ-induced secretion of tumor necrosis factor (TNF)-α, IL-2, IL-6, and IL-10, but increased the secretion of CXCL8, CCL2, CCL4, and CCL11. In conclusion, our results suggest that the insulinotropic effect of GIP is CaMK2-dependent. Furthermore, our results indicate that GIP does not provide substantial cytoprotective effects against diabetogenic cytokine challenge or significantly modulate the transcriptome of human islets when applied at a supraphysiological level. GIP may, however, still exert selective inflammation-modulatory effects upon diabetogenic cytokine exposure.

Project description:Developmental control of DNA damage responses in α- and β-cells shapes the selective beta-cell susceptibility in diabetes [RNA-Seq]

Project description:Developmental control of DNA damage responses in α- and β-cells shapes the selective beta-cell susceptibility in diabetes [scRNA-Seq]

Project description:Activating mutations in the KATP channel cause a rare genetic form of diabetes called neonatal diabetes. These mutations render the channel permanently open results in membrane hyperpolarisation of the pancreatic beta-cell. This prevents calcium influx and impairs insulin secretion. Mice expressing the human neonatal diabetes mutation Kir6.2-V59M specifically in pancreatic beta-cells are diabetic but do not display dyslipidaemia or insulin resistance. In this experiment, gene expression changes were analysed to explore the effect of high blood glucose per se on isolated pancreatic islets

Project description:Diabetes results from an inadequate number of insulin-producing human beta cells. There is currently no effective means to restore beta cell mass in millions of people with diabetes. Although the DYRK1A inhibitors, either alone or in combination with GLP1 receptor agonists (GLP1) or TGF superfamily inhibitors (LY), induce beta cell replication and increase beta cell mass, the precise mechanisms of action remain elusive. We performed single cell RNA sequencing on human pancreatic islets treated with a DYRK1A inhibitor, either alone, or with GLP1 or LY. We identify Cycling Alpha Cells as the most responsive cells to DYRK1A inhibition. Lineage trajectory analyses suggest that Cycling Alpha Cells may serve as precursor cells that transdifferentiate into beta cells. In addition to shedding light onto the mechanisms of action of DYRK1A inhibitors, our findings suggest that the proper target for regenerative drugs in human islets may be Cycling Alpha Cells.

Project description:Type 1 diabetes mellitus (T1D) is caused by killing of insulin producing β cells by CD8+T cells. The disease progression accelerates as glucose tolerance deteriorates suggesting that acquired factors contribute. To identify how environmental factors may lead to the expansion and pathogenicity of the diabetogenic T cells, we analyzed diabetogenic NRP-V7-reactive CD8+ T cells that recognize a peptide from the diabetes antigen IGRP in prediabetic NOD mice. There was an increase in the frequency of the NRP-V7-reactive cells coinciding with the time of glucose intolerance. The T cells persisted in hyperglycemic NOD mice maintained with an insulin pellet despite destruction of beta cells. We compared gene expression in the NRP-V7-reactive T cells to others that shared their phenotype but not selected for reactivity to diabetes antigens viral antigen reactive cells. Compared to these other cells, the NRP-V7-reactive cells exhibited gene expression of memory precursor effector cells. They had reduced cellular proliferation and were less dependent on oxidative phosphorylation. When prediabetic NOD mice were treated with 2DG to block aerobic glycolysis, there was a reduction in the diabetes antigen vs other cells of similar phenotype and loss of lymphoid cells infiltrating the islets. In addition, treatment of NOD mice with 2DG resulted in improved cell granularity. These findings identify a link between metabolic disturbances and autoreactive T cells that promotes development of autoimmune diabetes.