Project description:Type I diabetes (T1D) impairs bone accrual in patients, but the mechanism is unclear. Here in a murine monogenic model for T1D, we demonstrate that diabetes suppresses bone formation resulting in a rapid loss of both cortical and trabecular bone. Single-cell RNA sequencing uncovers metabolic dysregulation in bone marrow osteogenic cells of the diabetic mice. In vivo stable isotope tracing reveals impaired glycolysis in diabetic bone that is highly responsive to insulin stimulation. Remarkably, deletion of the insulin receptor reduces cortical but not trabecular bone. Increasing glucose uptake by overexpressing Glut1 in osteoblasts exacerbates bone defects in T1D mice. Conversely, activation of glycolysis by Pfkfb3 overexpression preserves both trabecular and cortical bone mass in the face of diabetes. The study identifies defective glucose metabolism in osteoblasts as a pathogenic mechanism for osteopenia in T1D, and furthermore implicates boosting osteoblast glycolysis as a potential anabolic therapy.

Project description:Skeletal fragility is associated with type 2 diabetes mellitus (T2D), but the underlying mechanism is not well understood. Here, in a mouse model for youth-onset T2D, we show that both trabecular and cortical bone mass are reduced due to diminished osteoblast activity. Stable isotope tracing in vivo with 13C-glucose demonstrates that both glycolysis and glucose fueling of the TCA cycle are impaired in diabetic bones. Similarly, Seahorse assays show suppression of both glycolysis and oxidative phosphorylation by diabetes in bone marrow mesenchymal cells as a whole, whereas single-cell RNA sequencing reveals distinct modes of metabolic dysregulation among the subpopulations. Metformin not only promotes glycolysis and osteoblast differentiation in vitro, but also improves bone mass in diabetic mice. Finally, osteoblast-specific overexpression of either Hif1a, a general inducer of glycolysis, or Pfkfb3 which stimulates a specific step in glycolysis, averts bone loss in T2D mice. The study identifies osteoblast-intrinsic defects in glucose metabolism as an underlying cause of diabetic osteopenia, which may be targeted therapeutically.

Project description:Aims:We aimed to explore possible mechanisms of bone loss in T1D and clarify whether liraglutide have effects on bone quality of T1D mice using transcriptomics, . Methods:Female streptozotocin-induced diabetic C57BL/6J mice were randomly divided into 4 groups and received the following treatments daily for 8 weeks: saline as controls; insulin; liraglutide; liraglutide combined with insulin. These groups were also compared to non-STZ-treated normal glucose tolerance (NGT) group. Trunk blood and bone tissues were collected for analysis. Three tibia from each of the NGT, saline treated and liraglutide treated group were randomly selected for transcriptomics. Results:Compared with NGT mice,saline treated T1D mice manifested markedly hyperglycemia and weight loss, and micro-CT revealed significantly lower bone mineral density(BMD) and deficient microarchitectures in tibias.8 weeks’ treatment with liraglutide alone or combined with insulin rescued the decreased BMD and partly corrected compromised trabecular microarchitectures. Transcriptomics analysis showed there were 789 differentially expressed genes mainly mapped to osteoclastogenesis and inflammation pathways.RT-qPCR verified gene expression of Trem2, Nfatc1, Trap and Ctsk were significantly increased in tibia of T1D compared to that in NGT group. Liraglutide treatment alone or combined with insulin could effectively suppress osteoclastogenesis by down-regulating gene expression of Trem2, Nfatc1, Ctsk and Trap.

Project description:Type 2 diabetes is a complex disease associated with many underlying pathomechanisms. Epigenetic regulation of gene expression by DNA methylation has become increasingly recognized as an important component in the etiology of type 2 diabetes. We performed genome-wide methylome and transcriptome analysis in liver from severely obese patients with or without type 2 diabetes to discover aberrant pathways underlying the development of insulin resistance. We identified hypomethylation of five key genes involved in hepatic glycolysis, de novo lipogenesis and insulin resistance with concomitant increased mRNA expression and protein content. The CpG-site within the ATF-motif was hypomethylated in four of these genes in liver of non-diabetic and type 2 diabetic obese patients, suggesting epigenetic regulation of transcription by altered ATF-DNA binding. In conclusion, severely obese non-diabetic and type 2 diabetic patients have distinct alterations in the hepatic methylome and transcriptome and genes controlling glucose and lipid metabolism are hypomethylated at a regulatory site. Thus, obesity may epigenetically reprogram the liver towards increased lipid production and exacerbate the development of insulin resistance. To better understand the molecular mechanisms underlying the development of hepatic insulin resistance and type 2 diabetes at a molecular level, we performed a genome-wide methylome and transcriptome analysis of liver from non-obese metabolically healthy, obese non-diabetic and obese type 2 diabetic patients. Distinct DNA methylation and gene expression profiles were identified in liver from the obese and type 2 diabetic patients compared with the non-obese participants.

Project description:As early as one month of age, nonobese diabetic (NOD) mice feature pancreatic infiltration of autoreactive T lymphocytes, which destruct insulin-producing beta cells, producing autoimmune diabetes mellitus (T1D) within eightmonths. Thus, we hypothesized that during the development of T1D, the transcriptional modulation of immune reactivity genes may occur as thymocytes mature into peripheral T lymphocytes. The transcriptome of thymocytes and peripheral CD3+ T lymphocytes from prediabetic or diabetic mice analyzed through microarray hybridizations identified the differentially expressed genes.

Project description:Inflammation, including reactive oxygen species and inflammatory cytokines in tissues amplify various post-translational modifications (PTMs) of self-proteins. A number of PTMs have been identified as autoimmune biomarkers in the initiation and progression of Type 1 diabetes (T1D). In this study, we have identified the citrullination of pancreatic glucokinase (GK) as a result of inflammation, triggering autoimmunity and affecting GK biological functions. Glucokinase is expressed in hepatocytes to regulate glycogen synthesis, and in pancreatic beta cells as a glucose sensor to initiate glycolysis and insulin signaling. We identify autoantibodies and autoreactive CD4+ T cells to glucokinase epitopes in the circulation of T1D patients and NOD mice. Finally, citrullination alters GK biologic activity (Km) and suppresses glucose-stimulated insulin secretion. Our studies define glucokinase as a T1D biomarker, providing new insights of how inflammation drives PTMs to create both neoautoantigens and affect beta cell metabolism.

Project description:Using an integrated approach to characterize the pancreatic tissue and isolated islets from a 33-year-old with 17 years of type 1 diabetes (T1D), we found donor islets contained β cells without insulitis and lacked glucose-stimulated insulin secretion despite a normal insulin response to cAMP-evoked stimulation. With these unexpected findings for T1D, we sequenced the donor DNA and found a pathogenic heterozygous variant in hepatocyte nuclear factor 1 alpha (HNF1A). In one of the first studies of human pancreatic islets with a disease-causing HNF1A variant associated with the most common form of monogenic diabetes, we found that HNF1A dysfunction leads to insulin-insufficient diabetes reminiscent of T1D by impacting the regulatory processes critical for glucose-stimulated insulin secretion and suggest a rationale for a therapeutic alternative to current treatment.

Project description:In an effort to reduce hepatic glucose production and lower plasma glucose levels that are characteristics of diabetes, we have devised a treatment whereby we enhance glycolysis in the liver of a type 2 diabetic mouse model (KK/H1J). We achieve this by raising the levels of a potent regulator of glucose metabolism, fructose-2,6-bisphosphate (F26BP). Treating the mice in this way, we have demonstrated amelioration of the diabetic phenotype in terms of lowering plasma glucose and insulin levels. These treated mice also display reduced weight gain, reduced adiposity, and normalized plasma and hepatic lipid levels. These latter metabolic changes brought about by raising F26BP levels are counterintuitive. A concurrent increase in glycolysis and lipogenesis is expected, however, we observe an increase in glycolysis with a concurrent decrease in lipogenesis. Preliminary analysis of gene expression in these mice has revealed alterations in gene expression of several genes that support the therapeutic effect of raising F26BP levels. To further profile F26BP effects on hepatic gene expression, we have applied a comprehensive approach to identify sets of genes and thereby biological pathways that are differentially regulated when hepatic glycolysis is accelerated in diabetic mice. Comparing diabetic and treated animals, we hope to further clarify the molecular and genetic signature of type 2 diabetes and obesity and elucidate how this signature is affected by raising F26BP levels. Our study examining gene array as well as the hepatic proteome has identified multiple gene and protein expression changes. Of particular relevance, we note that fatty acid metabolism and cholesterol metabolism pathways are significantly down-regulated in diabetic mice treated with a PFK-2 mutant engineered to raise F26BP levels, which underlie the changes we see in the metabolic parameters. 6 KK/H1J mice, a polygenic model of type 2 diabetes and obesity, weighing approximately 35g were used in this study. 3 mice were injected with GFP control adenovirus and 3 mice were injected with bisphosphatase deficient PFK-2 adenovirus (BPD). Mice were followed for 7 days before livers were extracted. Total cellular RNA was extracted from each mouse and analyzed by microarray separately.

Project description:Diabetes (T1D) is a disease in which the immune system destroys the insulin-producing beta cells. Recently, researchers have become interested in the role of the innate immune system in initiating this process. To further investigate this, we used RNA-seq to analyze sorted beta cells from non-diabetic and pre-diabetic female non-obese models of diabetes (NOD). These results shed light on the potential involvement of m6A mediators in the development of T1D, highlighting a promising avenue for future research.

Project description:We recently reported the scalable in vitro production of functional stem cell-derived β cells. Here we extend this approach to generate SC-β cells from Type 1 diabetic patients (T1D), a cell type that is destroyed during disease progression and has not been possible to extensively study. These cells express β cell markers, respond to glucose both in vitro and in vivo, prevent alloxan-induced diabetes in mice, and respond to anti-diabetic drugs. Furthermore, we use an in vitro disease model to demonstrate the cells respond to different forms of β cell stress. Using these assays, we find no major differences in T1D SC-β cells compared to SC-β cells derived from non-diabetic patients (ND). These results show that T1D SC-β cells can be used for the treatment of diabetes, drug screening, and the study of β cell biology. Differentiated cells were sorted and processed for RNA isolation using the MARIS protocol published previously (PMID: 24516164.) Human induced pluripotent stem cell (hiPSC) line were differentiated into SC-beta cells or dysfunctional, polyhormonal cells (PH). Four biological replicates were assessed with differentiation to both SC-beta and PH cells. Those data were normalized together with and compared to existing, previously published data from Hrvatin et al. (PMID: 24516164) and Pagliuca et al. (PMID: 25303535) from human islet-derived insulin+ cells, undifferentiated HUES8 hES cells, SC-beta cells derived from HUES8 and PH cells derived from HUES8 according to previously published protocols.