Project description:Loss of pancreatic Beta cell mass, identity, and function contribute to the development of diabetes. Here, we show that the endoplasmic reticulum (ER) calcium sensor, stromal interaction molecule 1 (STIM1), is critical for the maintenance of Beta cell function in female mice. When mice with Beta cell- specific deletion of STIM1 (STIM1-delta-Beta) were challenged with high-fat diet, Beta cell dysfunction was observed in female, but not male, mice. Impaired glucose tolerance was accompanied by reductions in Beta cell mass, a concomitant increase in alpha cell mass, and significant reductions in the expression of markers of Beta cell maturity, including MafA and UCN3. Mechanistic assays demonstrated that the sexually dimorphic phenotype observed in STIM1-Delta-Beta mice was due in part to loss of signaling through the noncanonical 17-Beta estradiol receptor, GPER1. Together, these data suggest that STIM1 orchestrates pancreatic Beta cell function and identity through GPER1- mediated estradiol signaling.

Project description:The risk of type 2 diabetes increases with age. Although changes in function and proliferation of aged beta cells resemble those preceding the development of diabetes, the contribution of beta cell aging and senescence remains unclear. The proportion of aged beta cells increases with animal age but even in young mice, senescent beta cells can be found. We showed that different models of insulin resistance accelerated aging and senescence marker expression in beta cells, BGal, led to loss of function and impaired glucose tolerance. Clearance of p16Ink4a+ cells, using the INK-ATTAC mouse model, ameliorated glucose metabolism, insulin secretion and decreased expression of aging, senescence and SASP genes in pancreatic islets. Senolytic drug ABT263 also improved glucose metabolism and beta cell identity when administered during insulin resistance. Human beta cells from diabetic and non-diabetic donors shared some of the same biology laying the foundation for translation into humans. These novel findings lay the framework to pursue senolysis of beta cells as a preventive and alleviating strategy for T2D.

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:The maintenance of pancreatic islet architecture is crucial for proper β-cell function. We previously reported that disruption of human islet integrity could result in altered β-cell identity. Here we combine β-cell lineage tracing and single-cell transcriptomics to investigate the mechanisms underlying this process in primary human islet cells. Using drug-induced ER stress and cytoskeleton modification models, we demonstrate that altering the islet structure triggers an unfolding protein response that causes the downregulation of β-cell maturity genes. Collectively, our findings illustrate the close relationship between endoplasmic reticulum homeostasis and β-cell phenotype, and strengthen the concept of altered β-cell identity as a mechanism underlying the loss of functional β-cell mass.

Project description:Aging causes a functional decline in tissues throughout the body that may be delayed by caloric restriction (CR). However, the cellular profiles and signatures of aging, as well as those ameliorated by CR, remain unclear. Here, we built comprehensive single-cell and single-nucleus transcriptomic atlases across various rat tissues undergoing aging and CR. CR attenuated aging-related changes in cell type composition, gene expression, and core transcriptional regulatory networks. Immune cells were increased during aging, and CR favorably reversed the aging-disturbed immune ecosystem. Computational prediction revealed that the abnormal cell-cell communication patterns observed during aging, including the excessive proinflammatory ligand-receptor interplay, were reversed by CR. Our work provides multi-tissue single-cell transcriptional landscapes associated with aging and CR in a mammal, enhances our understanding of the robustness of CR as a geroprotective intervention, and uncovers how metabolic intervention can act upon the immune system to modify the process of aging.

Project description:Although caloric restriction (CR) was first shown to extend the lifespan of rodents over 75 years ago, the underlying mechanisms remain unclear. Additionally, the majority of published studies have focused on the effects of short-term CR. To better understand cell signaling alterations in a tissue known to be highly impacted by CR, we sought to assess the impact of aging and lifelong CR on skeletal muscle protein phosphorylation dynamics. We performed phosphoproteomic analysis on skeletal muscle from young mice, old mice fed on an ad libitum diet, and old mice fed a CR diet. This analysis revealed distinct phosphoproteomic signatures associated with both aging and diet. Importantly, CR appeared to promote a signature that was more similar to young mice than old mice fed on an ad lib diet. From the phosphorylation measurements on its known substrates, we deciphered that aging promotes Protein kinase A (PKA) signaling, and CR inhibits this signaling cascade. Given the demonstrated role of PKA signaling as a “pro-aging” pathway in various model organisms, including yeast and mice, we propose that CR exerts its longevity-enhancing effects partially via the suppression of this pathway.

Project description:Here we show that oral creatine (Cr) supplementation leads to increased life span in mice. Treated mice showed improved neurobehavioral performance, decreased accumulation of the aging pigment lipofuscin and upregulation of anti-aging genes in brain. As Cr is virtually free of adverse effects, it may be a promising food supplement for healthy aging in man. Experiment Overall Design: 6 biological replicates for creatine-treated mice, 7 biological replicates for untreated mice.

Project description:Type 1 diabetes (T1D) is a chronic autoimmune disease that involves immune mediated destruction of β cells. How β cells respond to immune attack is unknown. We identified a population of β cells during the progression of T1D in non-obese diabetic (NOD) mice that survives immune attack. This population develops from normal β cells confronted with islet infiltrates. Pathways involving cell movement, growth and proliferation, immune responses, and cell death and survival are activated in these cells. There is reduced expression of β cell identity genes and diabetes antigens and increased immune inhibitory markers and stemness genes. This new subpopulation is resistant to killing when diabetes is precipitated with cyclosphosphamide. Human β cells show similar changes when cultured with immune cells. These changes may account for the chronicity of the disease and the long term survival of β cells in some patients.

Project description:The hypothalamus has recently emerged as a key regulator of metabolism and aging in mammals. We have examined the impact of targeted disruption of hypothalamic hypophysiotropic peptide: Growth Hormone-releasing Hormone (GHRH) in mice on longevity, and the putative mechanisms of delayed aging. GHRH knockout (KO) mice are remarkably long-lived and in comparison to genetically normal (wild type) animals exhibiting major shifts in the expression of genes related to xenobiotic detoxification, stress resistance, and insulin signaling. These mutant mice also have increased adiponectin levels and alterations in glucose homeostasis consistent with the removal of the counter-insulin effects of GH. While these effects overlap with those of caloric restriction (CR), we show that effects of CR and the GHRH mutation are additive, with lifespan of GHRH-KO mutants further increased by CR. We conclude that GHRH-KO mice feature perturbations in a network of signaling pathways related to stress resistance, metabolic control and inflammation, and therefore provide a new model that can be used to explore links between GHRH repression, downregulation of the somatotropic axis, and extended longevity. Hepatic tissue was obtained from 3 Ghrh-KO mice and 3 control (wild-type) mice (males). Expression in each sample was profiled using Affymetrix Mouse Genome 430 2.0 arrays.

Project description:Insulin secretion from pancreatic β-cells is essential for glucose homeostasis. An insufficient response to the demand for insulin results in diabetes. We previously showed that β-cell-specific deletion of Zfp148 (β-Zfp148KO) improves glucose tolerance and insulin secretion in mice. These RNA sequencing data show pathways altered in the β-Zfp148KO consistent with altered PEP cycling and improved insulin secretion responses.