Project description:During obesity and type 2 diabetes, pancreatic β-cells face chronic environmental stress, while islet-resident macrophages (iMACs) undergo metabolic reprogramming that exacerbates β-cell dysfunction. Stress-induced cleavage of tRNAs generates tRNA-derived fragments (tRFs), whose role in this context is not fully understood. We identify elevated levels of 5’tRFGlu(CTC) and 5’tRFGly(GCC) in β-cells and iMACs from db/db mice and in islets from type 2 diabetic (T2D) patients. Notably, 5’tRFGlu(CTC) is also induced under prediabetic conditions and inversely correlates with insulin secretion. Lipotoxic stress triggers their production via Angiogenin-mediated cleavage. Blocking 5’tRFGlu(CTC) in islets protects against β-cell apoptosis and restores insulin secretion under palmitate stress. Using a β-cell/macrophage co-culture system, we show that β-cell contact shapes a unique macrophage phenotype (iMAC-like) that shifts upon palmitate exposure—recapitulating in vivo observations. Inhibiting 5’tRFGlu(CTC) in iMAC-like cells prevents this activation switch, reduces β-cell stress, and improves insulin secretion. Mechanistically, 5’tRFGlu(CTC) interacts with RNA-binding proteins to regulate transcriptional and post-transcriptional pathways linked to immune activation, ECM remodeling, neurogenesis, and oxidative stress. Our study identifies 5’tRFs as key mediators of islet microenvironment remodeling in diabetes, offering new insights into intercellular stress signaling in metabolic disease.

Project description:During obesity and type 2 diabetes, pancreatic β-cells face chronic environmental stress, while islet-resident macrophages (iMACs) undergo metabolic reprogramming that exacerbates β-cell dysfunction. Stress-induced cleavage of tRNAs generates tRNA-derived fragments (tRFs), whose role in this context is not fully understood. We identify elevated levels of 5’tRFGlu(CTC) and 5’tRFGly(GCC) in β-cells and iMACs from db/db mice and in islets from type 2 diabetic (T2D) patients. Notably, 5’tRFGlu(CTC) is also induced under prediabetic conditions and inversely correlates with insulin secretion. Lipotoxic stress triggers their production via Angiogenin-mediated cleavage. Blocking 5’tRFGlu(CTC) in islets protects against β-cell apoptosis and restores insulin secretion under palmitate stress. Using a β-cell/macrophage co-culture system, we show that β-cell contact shapes a unique macrophage phenotype (iMAC-like) that shifts upon palmitate exposure—recapitulating in vivo observations. Inhibiting 5’tRFGlu(CTC) in iMAC-like cells prevents this activation switch, reduces β-cell stress, and improves insulin secretion. Mechanistically, 5’tRFGlu(CTC) interacts with RNA-binding proteins to regulate transcriptional and post-transcriptional pathways linked to immune activation, ECM remodeling, neurogenesis, and oxidative stress. Our study identifies 5’tRFs as key mediators of islet microenvironment remodeling in diabetes, offering new insights into intercellular stress signaling in metabolic disease.

Project description:During obesity and type 2 diabetes, pancreatic β-cells face chronic environmental stress, while islet-resident macrophages (iMACs) undergo metabolic reprogramming that exacerbates β-cell dysfunction. Stress-induced cleavage of tRNAs generates tRNA-derived fragments (tRFs), whose role in this context is not fully understood. We identify elevated levels of 5’tRFGlu(CTC) and 5’tRFGly(GCC) in β-cells and iMACs from db/db mice and in islets from type 2 diabetic (T2D) patients. Notably, 5’tRFGlu(CTC) is also induced under prediabetic conditions and inversely correlates with insulin secretion. Lipotoxic stress triggers their production via Angiogenin-mediated cleavage. Blocking 5’tRFGlu(CTC) in islets protects against β-cell apoptosis and restores insulin secretion under palmitate stress. Using a β-cell/macrophage co-culture system, we show that β-cell contact shapes a unique macrophage phenotype (iMAC-like) that shifts upon palmitate exposure—recapitulating in vivo observations. Inhibiting 5’tRFGlu(CTC) in iMAC-like cells prevents this activation switch, reduces β-cell stress, and improves insulin secretion. Mechanistically, 5’tRFGlu(CTC) interacts with RNA-binding proteins to regulate transcriptional and post-transcriptional pathways linked to immune activation, ECM remodeling, neurogenesis, and oxidative stress. Our study identifies 5’tRFs as key mediators of islet microenvironment remodeling in diabetes, offering new insights into intercellular stress signaling in metabolic disease.

Project description:During obesity and type 2 diabetes, pancreatic β-cells face chronic environmental stress, while islet-resident macrophages (iMACs) undergo metabolic reprogramming that exacerbates β-cell dysfunction. Stress-induced cleavage of transfer RNAs (tRNAs) generates tRNA-derived fragments (tRFs), whose role in this context is not fully understood. We identify elevated levels of 5’tRFGlu(CTC) and 5’tRFGly(GCC) in β-cells and iMACs from db/db mice and in islets from type 2 diabetic (T2D) patients. Notably, 5’tRFGlu(CTC) is also induced under prediabetic conditions and inversely correlates with insulin secretion. Lipotoxic stress triggers their production via Angiogenin-mediated cleavage. Blocking 5’tRFGlu(CTC) in islets protects against β-cell apoptosis and restores insulin secretion under palmitate stress. Using a β-cell/macrophage co-culture system, we show that β-cell contact shapes a unique macrophage phenotype (iMAC-like) that shifts upon palmitate exposure—recapitulating in vivo observations. Inhibiting 5’tRFGlu(CTC) in iMAC-like cells prevents this activation switch, reduces β-cell stress, and improves insulin secretion. Mechanistically, 5’tRFGlu(CTC) interacts with RNA-binding proteins to regulate transcriptional and post-transcriptional pathways linked to immune activation, ECM remodeling, neurogenesis, and oxidative stress. Our study identifies 5’tRFs as key mediators of islet microenvironment remodeling in diabetes, offering new insights into intercellular stress signaling in metabolic disease.

Project description:During obesity and type 2 diabetes, pancreatic β-cells face chronic environmental stress, while islet-resident macrophages (iMACs) undergo metabolic reprogramming that exacerbates β-cell dysfunction. Stress-induced cleavage of transfer RNAs (tRNAs) generates tRNA-derived fragments (tRFs), whose role in this context is not fully understood. We identify elevated levels of 5’tRFGlu(CTC) and 5’tRFGly(GCC) in β-cells and iMACs from db/db mice and in islets from type 2 diabetic (T2D) patients. Notably, 5’tRFGlu(CTC) is also induced under prediabetic conditions and inversely correlates with insulin secretion. Lipotoxic stress triggers their production via Angiogenin-mediated cleavage. Blocking 5’tRFGlu(CTC) in islets protects against β-cell apoptosis and restores insulin secretion under palmitate stress. Using a β-cell/macrophage co-culture system, we show that β-cell contact shapes a unique macrophage phenotype (iMAC-like) that shifts upon palmitate exposure—recapitulating in vivo observations. Inhibiting 5’tRFGlu(CTC) in iMAC-like cells prevents this activation switch, reduces β-cell stress, and improves insulin secretion. Mechanistically, 5’tRFGlu(CTC) interacts with RNA-binding proteins to regulate transcriptional and post-transcriptional pathways linked to immune activation, ECM remodeling, neurogenesis, and oxidative stress. Our study identifies 5’tRFs as key mediators of islet microenvironment remodeling in diabetes, offering new insights into intercellular stress signaling in metabolic disease.

Project description:During obesity and type 2 diabetes, pancreatic β-cells face chronic environmental stress, while islet-resident macrophages (iMACs) undergo metabolic reprogramming that exacerbates β-cell dysfunction. Stress-induced cleavage of transfer RNAs (tRNAs) generates tRNA-derived fragments (tRFs), whose role in this context is not fully understood. We identify elevated levels of 5’tRFGlu(CTC) and 5’tRFGly(GCC) in β-cells and iMACs from db/db mice and in islets from type 2 diabetic (T2D) patients. Notably, 5’tRFGlu(CTC) is also induced under prediabetic conditions and inversely correlates with insulin secretion. Lipotoxic stress triggers their production via Angiogenin-mediated cleavage. Blocking 5’tRFGlu(CTC) in islets protects against β-cell apoptosis and restores insulin secretion under palmitate stress. Using a β-cell/macrophage co-culture system, we show that β-cell contact shapes a unique macrophage phenotype (iMAC-like) that shifts upon palmitate exposure—recapitulating in vivo observations. Inhibiting 5’tRFGlu(CTC) in iMAC-like cells prevents this activation switch, reduces β-cell stress, and improves insulin secretion. Mechanistically, 5’tRFGlu(CTC) interacts with RNA-binding proteins to regulate transcriptional and post-transcriptional pathways linked to immune activation, ECM remodeling, neurogenesis, and oxidative stress. Our study identifies 5’tRFs as key mediators of islet microenvironment remodeling in diabetes, offering new insights into intercellular stress signaling in metabolic disease.

Project description:During obesity and type 2 diabetes, pancreatic β-cells face chronic environmental stress, while islet-resident macrophages (iMACs) undergo metabolic reprogramming that exacerbates β-cell dysfunction. Stress-induced cleavage of transfer RNAs (tRNAs) generates tRNA-derived fragments (tRFs), whose role in this context is not fully understood. We identify elevated levels of 5’tRFGlu(CTC) and 5’tRFGly(GCC) in β-cells and iMACs from db/db mice and in islets from type 2 diabetic (T2D) patients. Notably, 5’tRFGlu(CTC) is also induced under prediabetic conditions and inversely correlates with insulin secretion. Lipotoxic stress triggers their production via Angiogenin-mediated cleavage. Blocking 5’tRFGlu(CTC) in islets protects against β-cell apoptosis and restores insulin secretion under palmitate stress. Using a β-cell/macrophage co-culture system, we show that β-cell contact shapes a unique macrophage phenotype (iMAC-like) that shifts upon palmitate exposure—recapitulating in vivo observations. Inhibiting 5’tRFGlu(CTC) in iMAC-like cells prevents this activation switch, reduces β-cell stress, and improves insulin secretion. Mechanistically, 5’tRFGlu(CTC) interacts with RNA-binding proteins to regulate transcriptional and post-transcriptional pathways linked to immune activation, ECM remodeling, neurogenesis, and oxidative stress. Our study identifies 5’tRFs as key mediators of islet microenvironment remodeling in diabetes, offering new insights into intercellular stress signaling in metabolic disease.

Project description:In this study, we discovered cytosolic and mitochondrial fragments resulting from tRNA and mt-tRNA cleavage, which may act as new regulators of cellular and metabolic functions. We analyzed hundreds of these fragments in the pancreatic islets of db/db mice and compared them to heterozygous control db/+ mice. At 16 weeks of age, db/db mice exhibit obesity, insulin resistance, and glucose intolerance. In our analysis, we identified 3858 tRFs in the islets of db/db mice, among which 342 exhibited significant changes (≥ 2 fold; adjusted p value ≤ 0.05) compared to controls. Of these, 199 tRFs showed increased levels, while 170 tRFs showed decreased levels in the pre-diabetic mice. Notably, a striking majority (147 out of 170) of the tRFs with reduced abundance in the islets of db/db mice were derived from the cleavage of tRNAs encoded by the mitochondrial genome. Our findings reveal a significant reshaping of mitochondrial tRFs in pre-diabetic conditions, coinciding with a well-established mitochondrial metabolic defect under these conditions. Specifically, we demonstrated that a fragment (named mt-tRF-LeuTAA) resulting from the cleavage of mt-tRNA-LeuTAA, encoded by the mitochondrial genome and found to be reduced in the islets of db/db mice, acts as a key regulator of mitochondrial OXPHOS functions, mitochondrial membrane potential, the insulin secretory capacity of ß-cells, and the insulin sensitivity of myotube muscle cells.

Project description:Pancreatic beta-cell dysfunction and death are central in the pathogenesis of type 2 diabetes. Saturated fatty acids cause beta-cell failure and contribute to diabetes development in genetically predisposed individuals. Here we used RNA-sequencing to map transcripts expressed in five palmitate-treated human islet preparations, observing 1,325 modified genes. Palmitate induced fatty acid metabolism and endoplasmic reticulum (ER) stress. Functional studies identified novel mediators of adaptive ER stress signaling. Palmitate modified genes regulating ubiquitin and proteasome function, autophagy and apoptosis. Inhibition of autophagic flux and lysosome function contributed to lipotoxicity. Palmitate inhibited transcription factors controlling beta-cell phenotype including PAX4 and GATA6. 59 type 2 diabetes candidate genes were expressed in human islets, and 11 were modified by palmitate. Palmitate modified expression of 17 splicing factors and shifted alternative splicing of 3,525 transcripts. Ingenuity Pathway Analysis of modified transcripts and genes confirmed that top changed functions related to cell death. DAVID analysis of transcription binding sites in palmitate-modified transcripts revealed a role for PAX4, GATA and the ER stress response regulators XBP1 and ATF6. This human islet transcriptome study identified novel mechanisms of palmitate-induced beta-cell dysfunction and death. The data point to crosstalk between metabolic stress and candidate genes at the beta-cell level. 5 human islet of Langerhans preparations examined under 2 conditions (control and palmitate treatment)

Project description:Loss of pancreatic beta cells is the central feature of all forms of diabetes. Current therapies fail to halt the declined beta cell mass. Thus, strategies to preserve beta cells are imperatively needed. In this study, we identified paired box 6 (PAX6) as a critical regulator of beta cell survival. Under diabetic conditions, the human beta cell line EndoC-bH1, db/db mouse and human islets displayed dampened insulin and incretin signalings and reduced beta cell survival, which were alleviated by PAX6 overexpression. Adeno-associated virus (AAV)-mediated PAX6 overexpression in beta cells of streptozotocin-induced diabetic mice and db/db mice led to a sustained maintenance of glucose homeostasis. AAV-PAX6 transduction in human islets reduced islet graft loss and improved glycemic control after transplantation into immunodeficient diabetic mice. Our study highlights a previously unappreciated role for PAX6 in beta cell survival and raises the possibility that ex vivo PAX6 gene transfer into islets prior to transplantation might enhance islet graft function and transplantation outcome.