Project description:Loss of functional β cells is a hallmark of diabetes, and restoring β cell mass remains a critical goal in the quest for a specific therapy. One potential strategy is to convert non-β cells in the islet, such as α cells, into insulin-producing cells. Although several compounds have been identified to induce β cell-like features in α cells, none have yet been successfully translated into clinical applications. In this study, we identify PRC2 inhibitors as potent inducers of β cell-enriched gene expression in α cells, acting through modulation of the AR-ETV1 complex. AR inhibition suppresses glycogen synthesis and enhances the pentose phosphate pathway (PPP). Direct metabolic reprogramming with methyl esterified 6-phosphogluconate (ME-6-PG), an intermediate metabolite of the PPP, induces β cell-like features in α cells, stimulate β cell regeneration and ameliorates diabetes. Our findings demonstrate that metabolic reprogramming can drive β cell regeneration and highlight a promising therapeutic strategy for diabetes.

Project description:Loss of functional β cells is a hallmark of diabetes, and restoring β cell mass remains a critical goal in the quest for a specific therapy. One potential strategy is to convert non-β cells in the islet, such as α cells, into insulin-producing cells. Although several compounds have been identified to induce β cell-like features in α cells, none have yet been successfully translated into clinical applications. In this study, we identify PRC2 inhibitors as potent inducers of β cell-enriched gene expression in α cells, acting through modulation of the AR-ETV1 complex. AR inhibition suppresses glycogen synthesis and enhances the pentose phosphate pathway (PPP). Direct metabolic reprogramming with methyl esterified 6-phosphogluconate (ME-6-PG), an intermediate metabolite of the PPP, induces β cell-like features in α cells, stimulate β cell regeneration and ameliorates diabetes. Our findings demonstrate that metabolic reprogramming can drive β cell regeneration and highlight a promising therapeutic strategy for diabetes.

Project description:Loss of functional β cells is a hallmark of diabetes, and restoring β cell mass remains a critical goal in the quest for a specific therapy. One potential strategy is to convert non-β cells in the islet, such as α cells, into insulin-producing cells. Although several compounds have been identified to induce β cell-like features in α cells, none have yet been successfully translated into clinical applications. In this study, we identify PRC2 inhibitors as potent inducers of β cell-enriched gene expression in α cells, acting through modulation of the AR-ETV1 complex. AR inhibition suppresses glycogen synthesis and enhances the pentose phosphate pathway (PPP). Direct metabolic reprogramming with methyl esterified 6-phosphogluconate (ME-6-PG), an intermediate metabolite of the PPP, induces β cell-like features in α cells, stimulate β cell regeneration and ameliorates diabetes. Our findings demonstrate that metabolic reprogramming can drive β cell regeneration and highlight a promising therapeutic strategy for diabetes.

Project description:In this study, the distribution and regulation of periplasmic and cytoplasmic carbon fluxes in Gluconobacter oxydans 621H with glucose were studied by 13C-based metabolic flux analysis (13C-MFA) in combination with transcriptomics and enzyme assays. For 13C-MFA, cells were cultivated with specifically 13C-labeled glucose and intracellular metabolites were analyzed for their labeling pattern by LC-MS. In growth phase I, 90% of the glucose was oxidized periplasmatically to gluconate and partially further oxidized to 2-ketogluconate. Of the glucose taken up by the cells, 9% was phosphorylated to glucose 6-phosphate, whereas 91% was oxidized by cytoplasmic glucose dehydrogenase to gluconate. Additional gluconate was taken up into the cells by transport. Of the cytoplasmic gluconate, 70% was oxidized to 5-ketogluconate and 30% was phosphorylated to 6-phosphogluconate. In growth phase II, 87% of gluconate was oxidized to 2-ketogluconate in the periplasm and 13% was taken up by the cells and almost completely converted to 6-phosphogluconate. Since G. oxydans lacks phosphofructokinase, glucose 6-phosphate can only be metabolized via the oxidative pentose phosphate pathway (PPP) or the Entner-Doudoroff pathway (EDP). 13C-MFA showed that 6-phosphogluconate is catabolized primarily via the oxidative PPP in both phase I and II (62% and 93%) and demonstrated a cyclic carbon flux through the oxidative PPP. The transcriptome comparison revealed an increased expression of PPP genes in growth phase II, which was supported by enzyme activity measurements and correlated with the increased PPP flux in phase II. Moreover, genes possibly related to a general stress response displayed increased expression in growth phase II. The transcriptome comparisons of G. oxydans growth phase II vs. growth phase I were repeated independently three times in biological replicates resulting in 3 hybridizations as termed by sample 1 to 3.

Project description:We aimed to understand the functional roles of islet cellular oscillators under diabetic conditions and during β-cell regeneration. We assessed diurnal regulation of β-cell proliferation and the transcriptional landscape in α- and residual β-cells following β-cell ablation in Insulin-rtTA/TET-DTA mice that simultaneously expressed α- and β-cell specific fluorescent reports. The mouse pancreatic islets were isolated over 24-h with 4-h interval, followed by separation of α- and β- cells using FACS sorting, RNA extraction and RNA sequencing. Acute hyperglycemia and loss of β-cell mass perturbed absolute expression levels and temporal transcriptome profiles in residual β-cells, whereas in neighboring α-cells only changes in temporal profiles were observed. Strikingly, compensatory regeneration of β-cells exhibited circadian rhythmicity. In arrhythmic Bmal1 deficient mice, massive β-cell ablation led to aggravated hyperglycemia, hyperglucagonemia and a fatal diabetes. No compensatory proliferation of β-cells was observed in arrhythmic mice, suggesting an essential role of circadian clocks in β-cell regeneration.

Project description:We aimed to fill the gap in understanding functional roles of the islet cellular oscillators under diabetic conditions following massive β-cell ablation, and during β-cell regeneration. We assessed diurnal regulation of β-cell proliferation and transcriptional landscape in separated α- and residual β-cells -utilizing rtTA/TET-DTA mouse model that bears α- and β-cell specific labeling. Acute hyperglycemia and loss of β-cell mass perturbed absolute expression levels and temporal transcriptome profiles in residual β-cells, whereas in neighboring α-cells only changes in temporal profiles were observed. Strikingly, compensatory regeneration of β-cells exhibited circadian rhythmicity. In arrhythmic BMAL1 knockout mice, massive β-cell ablation led to aggravated hyperglycemia, hyperglucagonemia and a fatal non-compensated diabetes. No activation of β-cell regeneration via entry into cell-cycle was observed in arrhythmic mice, suggesting essential role of functional circadian clocks in this process.

Project description:Diabetes mellitus is characterized by chronic hyperglycemia with loss of β-cell function and mass. An attractive therapeutic approach to treat patients with diabetes in a non-invasive way is to harness the innate regenerative potential of the pancreas. The Islet Neogenesis-Associated Protein pentadecapeptide (INGAP-PP) has been shown to induce β-cell regeneration and improve their function in rodents. To investigate its possible mechanism of action, we report here the global transcriptional effects induced by the short-term INGAP-PP in vitro treatment of adult rat pancreatic islets. We identify 1,669 differentially expressed genes by INGAP-PP treatment, including dozens of previously unannotated rat transcripts. In-depth analysis suggests that INGAP-PP engages the transcriptional program regulated by vitamin D receptor activation, among other pathways relevant for β-cell function, ultimately leading to enhanced glucose-stimulated insulin release. Supported by epigenomic and single-cell RNA-seq data, we identify 9 previously unannotated long noncoding RNAs upregulated by INGAP-PP, some of which are also differentially regulated by IL1β and vitamin D in β-cells. These include Ri-lnc1, which is enriched in mature β-cells. Taken together, the results presented here reveal novel potential mechanisms that could underlie the positive physiological effects of INGAP on β-cell function and mass.

Project description:In this study, the distribution and regulation of periplasmic and cytoplasmic carbon fluxes in Gluconobacter oxydans 621H with glucose were studied by 13C-based metabolic flux analysis (13C-MFA) in combination with transcriptomics and enzyme assays. For 13C-MFA, cells were cultivated with specifically 13C-labeled glucose and intracellular metabolites were analyzed for their labeling pattern by LC-MS. In growth phase I, 90% of the glucose was oxidized periplasmatically to gluconate and partially further oxidized to 2-ketogluconate. Of the glucose taken up by the cells, 9% was phosphorylated to glucose 6-phosphate, whereas 91% was oxidized by cytoplasmic glucose dehydrogenase to gluconate. Additional gluconate was taken up into the cells by transport. Of the cytoplasmic gluconate, 70% was oxidized to 5-ketogluconate and 30% was phosphorylated to 6-phosphogluconate. In growth phase II, 87% of gluconate was oxidized to 2-ketogluconate in the periplasm and 13% was taken up by the cells and almost completely converted to 6-phosphogluconate. Since G. oxydans lacks phosphofructokinase, glucose 6-phosphate can only be metabolized via the oxidative pentose phosphate pathway (PPP) or the Entner-Doudoroff pathway (EDP). 13C-MFA showed that 6-phosphogluconate is catabolized primarily via the oxidative PPP in both phase I and II (62% and 93%) and demonstrated a cyclic carbon flux through the oxidative PPP. The transcriptome comparison revealed an increased expression of PPP genes in growth phase II, which was supported by enzyme activity measurements and correlated with the increased PPP flux in phase II. Moreover, genes possibly related to a general stress response displayed increased expression in growth phase II.

Project description:The obligatory aerobic acetic acid bacterium Gluconobacter oxydans 621H oxidizes sugars and sugar alcohols primarily in the periplasm and only a small fraction is metabolized in the cytoplasm. The latter can occur either via the Entner-Doudoroff pathway (EDP) or via the pentose phosphate pathway (PPP). The Embden-Meyerhof pathway is non-functional and a cyclic operation of the tricarboxylic acid cycle is prevented by the absence of succinate dehydrogenase. In this work, the cytoplasmic catabolism of fructose formed by oxidation of mannitol was analyzed with a M-NM-^Tgnd mutant lacking the oxidative PPP and a M-NM-^Tedd-eda mutant devoid of the EDP. The growth characteristics of the two mutants under controlled conditions with mannitol as carbon source and enzyme activities showed that the PPP is the main route for cytoplasmic fructose catabolism, whereas the EDP is dispensable and even unfavorable. The M-NM-^Tedd-eda mutant (lacking 6-phosphogluconate dehydratase and 2-keto-3-deoxy-6-phosphogluconate aldolase) formed 24% more cell mass than the reference strain. In contrast, deletion of gnd (6-phosphogluconate dehydrogenase) severely inhibited growth and caused a strong selection pressure for secondary mutations inactivating glucose-6-phosphate dehydrogenase, thus preventing fructose catabolism via the EDP, too. These M-NM-^Tgnd zwf* mutants were almost totally disabled in fructose catabolism, but still produced about 14% of the carbon dioxide of the reference strain, possibly by catabolizing substrates from the yeast extract. Overexpression of gnd in the reference strain improved biomass formation in a similar manner as deletion of edd-eda, further confirming the importance of the PPP for cytoplasmic fructose catabolism. The three transcriptome comparisons of M-NM-^Tupp M-NM-^Tgnd zwf* vs. M-NM-^Tupp and of M-NM-^Tupp M-NM-^Tedd-eda vs. M-NM-^Tupp, and of M-NM-^Tupp M-NM-^Tgnd versus M-NM-^Tupp, were repeated independently three times in biological replicates resulting in 3 x 3 hybridizations as termed by sample 1 to 9.

Project description:The essential roles of PCNA as a scaffold protein in DNA replication and repair are well established, while its more recently discovered cytosolic roles are less explored. Alpha-enolase (ENO1) and 6-phosphogluconate dehydrogenase (6PGD), important proteins in glycolysis and the Pentose Phosphate Pathway (PPP), respectively, both contain PCNA interacting motifs. Here we show reduced binding to PCNA when the PCNA interacting motif APIM in ENO1 is mutated. Mutant cells have lower ENO1 protein levels, have reduced glucose consumption, altered glycolytic metabolite and nucleoside phosphate pools and increased activation of the citric acid cycle (TCA) compared to parental cells. Treatment of a panel of haematological cell lines with a cell penetrating peptide containing APIM (ATX-101), lead to a metabolic shift with reduction in glycolytic metabolite and nucleoside phosphate pools as well reduced levels of ENO1 and 6PGD proteins. These results suggests that PCNA stabilize ENO1 and 6PGD, and that targeting PCNA reduce the glycolysis, PPP and nucleoside phosphate pools via destabilization of these proteins.