Project description:Aims/hypothesis Pancreatic β cell dedifferentiation underlies the reversible reduction in β cell mass and function in diabetes. Interventional targets and adjuvant therapies to prevent/reverse β cell dedifferentiation and transdifferentiation may provide evidence to support the effective treatment of diabetes, while the underlying molecular mechanism remains elusive. Methods LDHA expression and activity were analysed in islets obtained from humans with type 2 diabetes, hyperglycaemic db/db mice, and a high-fat diet (HFD)-induced mouse model of diabetes. The impact of LDHA inhibition on β cell function and identity was investigated in high-fat diet (HFD) feeding mice and db/db mice. ChIP-seq and RNA-seq were used to investigate the specific molecular mechanism underlying the effect of LDHA on the H3K9la enhancement and beta cell function under glucotoxic conditions. Results We demonstrated that inhibition of LDHA effectively preserved β cell identity, which not only delay disease progression in prediabetic stage, but also improve insulin output and glucose homeostasis in diabetic models. Mechanistically, the activation of LDHA led to a marked increase in histone H3 lysine 9 lactylation (H3K9la) in the promoter region of the β cells dedifferentiation markers Sox9, Hes1 and Aldh1a3, and facilitated their transcription, thereby triggering β cell dedifferentiation as well as impaired glucose homeostasis and β cell function in mice. Conclusions/interpretation We unraveled the role of lactate dehydrogenase A (LDHA)-mediated metabolic and epigenetic reprogramming in β cell dedifferentiation during diabetes development. This study suggests that LDHA inhibition could be a novel therapeutic strategy for diabetes treatment.

Project description:β-Cell dysfunction, manifested as impaired glucose-stimulated insulin secretion (GSIS), and β-cell loss, which presents as dedifferentiation, inhibited transcriptional identity and death, are the hallmarks of type 2 diabetes. Trimethylamine N-oxide (TMAO), a gut microbiota metabolite, has been shown to play a role in cardiovascular disease. Here, we found that plasma TMAO levels are elevated in both diabetic mice and human subjects and that TMAO at a similar concentration to that found in diabetes could directly decrease β-cell GSIS in both MIN6 cells and primary islets from mice or humans. Elevation of TMAO levels through choline diet feeding impairs GSIS, the β-cell proportion, and glucose tolerance. TMAO inhibits calcium transients through NLRP3 inflammasome-related inflammatory cytokines and induced Serca2 loss, and a Serca2 agonist reversed the effect of TMAO on β-cell function in vitro and in vivo. Additionally, long-term TMAO exposure promotes β-cell ER stress, dedifferentiation, and apoptosis and inhibits β-cell transcriptional identity. Inhibition of TMAO production through either genetic knockdown or antisense oligomers of Fmo3, the TMAO-producing enzyme, improves β-cell GSIS, the β-cell proportion, and glucose tolerance in both db/db and choline diet-fed mice. These observations elucidate a novel role for TMAO in β-cell dysfunction and maintenance, and inhibition of TMAO could be a new approach for the treatment of type 2 diabetes.

Project description:The chronic inflammation resultant from type 2 diabetes (T2D) is also associated with spinal pathologies, including intervertebral disc (IVD) degeneration and chronic neck and back pain. Although confounding factors, such as increased weight gain in obesity, studies have shown that even after adjusting age, body mass index, and genetics (e.g. twins), patients with T2D suffer from disproportionately more IVD degeneration and back pain. We hypothesize that chronic T2D fosters a proinflammatory microenvironment within the IVD that promotes degeneration and disrupts disc homeostasis. To test this hypothesis, we evaluated two commonly used mouse models of T2D – the leptin-receptor deficient mouse (db/db) and the chronic high-fat diet in mice with impaired beta-cell function (STZ-HFD). STZ-HFD IVDs were more degenerated and showed differential expression of chemokines from the db/db models. Moreover, the RNAseq analysis revealed vast transcriptional dysregulation of many pathways in the STZ-HFD but not in the db/db tissues. Taken together, the STZ-HFD may better recapitulates the complexities of the chronic inflammatory processes in the IVD during T2D

Project description:Objective Notch signaling is re-activated in β cells from obese mice, and is causal to β cell dysfunction. Notch activity is determined in part by expression of transmembrane ligand availability in a neighboring cell. We hypothesized that β cell expression of Jagged1 determines the maladaptive Notch response and resultant β cell dysfunction in obese mice. Methods We assessed expression of Notch pathway components in diet-induced obese (DIO) or leptin receptor-deficient (db/db) mice, and performed single cell RNA sequencing (scRNAseq) in islets from patients with and without type 2 diabetes (T2D). We generated and performed glucose tolerance testing in inducible, β cell-specific Jagged1 gain-of- and loss-of-function mice. We also tested effects of monoclonal neutralizing antibodies to Jagged1 in glucose-stimulated insulin secretion (GSIS) assays in isolated islets. Results Jag1 was the only Notch ligand that tracked with increased Notch activity in DIO and db/db mice. Consistently, JAG1 tracked with Notch activity in metabolically inflexible β cells enriched in patients with T2D. Neutralizing antibodies to block Jagged1 in islets isolated from DIO and db/db mice potentiated GSIS ex vivo. To demonstrate if β cell Jagged1 is sufficient to cause glucose tolerance in vivo, we generated inducible β cell-specific Jag1 transgenic mice (β-Jag1TG), which showed impaired glucose intolerance due to reduced GSIS. However, β cell-specific Jagged1 loss-of-function (β-Jag1KO) did not protect against HFD-induced insulin secretory defects or glucose intolerance. Conclusions Jagged1 is increased in islets from obese mice and in patients with T2D, and neutralizing Jagged1 antibodies lead to improved GSIS, suggesting that inhibition of Jagged1-Notch signaling may have therapeutic benefit. However, genetic loss-of-function experiments suggest that β cells are not a likely source of the Jagged1 signal.

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:Purpose: RNA seq analysis were to compare and contrast the gene expression profile involved in the dedifferentiation of db/db islets in type 2 diabetes Methods: Islets of wild type, db/+ and db/db were purified using perfusion from 12 week old mice and RNA were isolated. Islated RNA were used in RNA seq to understand the expression pattern Results: Using an optimized data analysis workflow, we mapped about 10 million sequence reads per sample to the mouse genome (build mm9) and identified 16,014 transcripts WT, db/+ and db/db mice islets with TopHat workflow. Hierarchical clustering of differentially expressed genes uncovered there role in type 2 diabetes. Data analysis with TopHat workflows revealed a significant overlap yet provided complementary insights in transcriptome profiling. Conclusions: We characterised and identified genes involved in dedifferentiation of islets.

Project description:Insulin-producing beta cells become dedifferentiated during diabetes progression. An impaired ability to select substrates for oxidative phosphorylation, or metabolic inflexibility, sets the stage for progression from beta cell dysfunction to beta cell dedifferentiation. In this study, we sought to isolate and functionally characterize failing beta cells, as a preliminary step to identify pathways to reverse dedifferentiation. Using various experimental models of diabetes, we found a striking enrichment in the expression of aldehyde dehydrogenase 1 isoform A3 (ALDH+) as beta cells become dedifferentiated. Flow-sorted ALDH+ islet cells demonstrate impaired glucose-induced insulin secretion, are depleted of Foxo1 and MafA, and include a Neurogenin3-positive subset. RNA sequencing analysis demonstrates that ALDH+ cells are characterized by: (i) impaired oxidative phosphorylation and mitochondrial complex I, IV, and V; (ii) activated RICTOR; and (iii) progenitor cell markers. We propose that impaired mitochondrial function marks the progression from metabolic inflexibility to dedifferentiation in the natural history of beta cell failure. RNA-Sequencing analysis of 2 different cell types in 2 different genotype categories.

Project description:Type 2 diabetes (T2D) is associated with defective insulin secretion, reduced β-cell mass, and β-cell dedifferentiation. Aldehyde dehydrogenase 1 isoform A3 (ALHD1A3) serves as a marker of β-cell dedifferentiation and correlates with T2D progression. ALDH1A3-positive β-cells (A+) demonstrate impaired insulin secretion, and their numbers decrease when diabetic mice are rendered euglycemic by pair-feeding. It is unknown whether ALDH1A3 activity contributes to β-cell failure, and whether the decrease of A+ cells under pair-feeding is due to β-cell restoration. To tackle these questions, we (i) investigated the fate of A+ cells during pair-feeding by lineage-tracing, (ii) somatically ablated ALDH1A3 in diabetic β-cells, and (iii) used a novel selective ALDH1A3 inhibitor to treat diabetes. Lineage tracing and functional characterization show that A+ cells can be reconverted to functional, mature β-cells. Genetic or pharmacological inhibition of ALDH1A3 in diabetic mice lowers glycemia and increases insulin secretion. Molecular interrogation of β-cells following ALDH1A3 inhibition show a reactivation of differentiation as well as regeneration pathways through the REG gene family. We conclude that ALDH1A3 inhibition offers a therapeutic strategy for β-cell dysfunction in diabetes.

Project description:This program addresses the molecular basis of beta-cell failure associated with the development of type 2 diabetes in the db/db mice. Specifically, which genes are differentially expressed in pancreatic islets of the db/db mice compared to the control db/+ mice?

Project description:This program addresses the molecular basis of beta-cell failure associated with the development of type 2 diabetes in the db/db mice. Specifically, which genes are differentially expressed in pancreatic islets of the db/db mice compared to the control db/+ mice?