Project description:Cardiovascular disease is the leading cause of mortality in individuals with diabetes. However, the specific mechanisms and cell heterogeneity underlying cardiac injury in diabetes are still unclear, making it difficult to effectively manage diabetic cardiovascular damage. Our study used leptin receptor knockout (db/db) mice as diabetic models and sequenced their hearts at different pathological stages. Our findings provide important insights for preventing and treating diabetic heart damage.

Project description:The number of patients with diabetes is increasing worldwide. Diabetic testicular damage can cause spermiogenesis disorders and sexual dysfunction. We thus explored the role of miRNAs in diabetic testicular damage, and revealed that they could serve as effective prevention and treatment therapeutic targets.Streptozotocin (STZ) was used to generate a rat model of type 2 diabetes. Rat testicular tissues were used for miRNA sequencing. we identified 19 differentially expressed miRNAs in the testes of diabetic rats.

Project description:The number of patients with diabetes is increasing worldwide. Diabetic testicular damage can cause spermiogenesis disorders and sexual dysfunction. We thus explored the role of circRNA, lncRNA and mRNA in diabetic testicular damage, and revealed that they could serve as effective prevention and treatment therapeutic targets. Streptozotocin (STZ) was used to generate a rat model of type 2 diabetes. Rat testicular tissues were used for circRNA, lncRNA and mRNA sequencing.

Project description:Diabetic kidney disease (DKD) is the leading cause of progressive chronic kidney disease in adults in the United States. However, the impact of preterm birth on the progression of DKD has not been studied. The goal of this project is to determine the effect of preterm birth on kidney health in a diabetic mouse model. CD-1 pups born preterm (19 days post conception (dpc)) and term (20 dpc) were studied, and outcomes of the male mice were reported, all compared to term mice. Preterm and term mice were treated with streptozotocin at six weeks to induce hyperglycemia. Body weight and blood sugar were monitored. Histologic, molecular, and imaging techniques were used to characterize the mice at 18 weeks. The preterm mice with diabetes had a lower podocyte density, lower proximal tubular fraction, and more atubular glomeruli compared to the term mice without diabetes. They also had a lower podocyte density and lower renin expression compared to term mice with diabetes. Based on single-cell RNA sequencing, preterm mice with diabetes had increased expression of genes related to the angiogenesis migration pathway-related in endothelial cells and increased expression of genes in the actin adhesion pathway in podocytes compared to term mice with diabetes. Furthermore, the preterm mice with diabetes exhibited a weaker endothelial cell-podocyte interaction compared to term mice with diabetes. These data suggest that preterm birth increases susceptibility to glomerular and tubular damage after a brief “second hit” of hyperglycemia. In conclusion, preterm birth disrupts endothelial-podocyte crosstalk and increases susceptibility to kidney injury induced by hyperglycemia.

Project description:Diabetic kidney disease (DKD) is the leading cause of progressive chronic kidney disease in adults in the United States. However, the impact of preterm birth on the progression of DKD has not been studied. The goal of this project is to determine the effect of preterm birth on kidney health in a diabetic mouse model. CD-1 pups born preterm (19 days post conception (dpc)) and term (20 dpc) were studied, and outcomes of the male mice were reported, all compared to term mice. Preterm and term mice were treated with streptozotocin at six weeks to induce hyperglycemia. Body weight and blood sugar were monitored. Histologic, molecular, and imaging techniques were used to characterize the mice at 18 weeks. The preterm mice with diabetes had a lower podocyte density, lower proximal tubular fraction, and more atubular glomeruli compared to the term mice without diabetes. They also had a lower podocyte density and lower renin expression compared to term mice with diabetes. Based on single-cell RNA sequencing, preterm mice with diabetes had increased expression of genes related to the angiogenesis migration pathway-related in endothelial cells and increased expression of genes in the actin adhesion pathway in podocytes compared to term mice with diabetes. Furthermore, the preterm mice with diabetes exhibited a weaker endothelial cell-podocyte interaction compared to term mice with diabetes. These data suggest that preterm birth increases susceptibility to glomerular and tubular damage after a brief “second hit” of hyperglycemia. In conclusion, preterm birth disrupts endothelial-podocyte crosstalk and increases susceptibility to kidney injury induced by hyperglycemia.

Project description:Studies of diabetic glomerular injury raise the possibility of developing useful early biomarkers and therapeutic approaches for the treatment of type 2 diabetic nephropathy (T2DN). In this study, it is found that FGF13 expression is induced in glomerular endothelial cells (GECs) during T2DN progression, and endothelial-specific deletion of Fgf13 potentially alleviates T2DN damage. Fgf13 deficiency restores the expression of Parkin both in the cytosolic, mitochondrial, and nuclear fractions under diabetic conditions, resulting in improved mitochondrial homeostasis and endothelial barrier integrity due to promotion of mitophagy and inhibition of apoptosis. Additionally, it is confirmed that the beneficial effects of Fgf13 deficiency on T2DN are abolished by endothelial-specific double deletion of Fgf13 and Prkn. The effects of Fgf13 deficiency on mitophagy and apoptosis via Parkin-dependent regulation may be distinct and separable events under diabetic conditions. These data show that the bifunctional role of Fgf13 deficiency in promoting mitophagy and inhibiting apoptosis through Parkin can shape mitochondrial homeostasis regulation in GECs and T2DN progression. Acting as a potential biomarker and therapeutic target for prevention and control of T2DN, mechanistically understanding of the biofunction of FGF13 may also be of relevance to the pathogenesis of other FGF13- and Parkin-associated diseases.

Project description:Hyperglycemia accelerates calcification of atherosclerotic plaques in diabetic patients, and the prolonged accumulation of advanced glycation end products (AGEs) induced by hyperglycemia may be closely related to the pathogenesis of aortic calcification. However, the mechanisms underlying this association remain unclear. In the current study, we investigated the role of vascular smooth muscle cell nuclear factor 90/110 (NF90/110) in mediating AGEs accumulation and accelerating diabetic atherosclerotic calcification. Using vascular smooth muscle cells (VSMCs), human samples, and mouse models, we found that hyperglycemia-mediated AGEs markedly increased VSMC NF90/110 activation both in human and mouse atherosclerotic calcified tissues with diabetes. Silencing of NF90/110 in vitro and genetic deletion of VSMC NF90/110 in mice decreased obviously AGEs-induced arteriosclerotic calcification. Mechanistically, AGEs increased the activity of NF90, which then enhanced ubiquitination and degradation of AGE receptor 1 (AGER1) by stabilizing the mRNA of E3 ubiquitin ligase, F-box, and WD repeat domain 7 (FBXW7), thus causing the accumulation of more AGEs. Furthermore, AGEs accumulation accelerated diabetic atherosclerotic calcification by inducing VSMC phenotypic changes to osteoblast-like cells, apoptosis, and matrix vesicle release. Collectively, our study demonstrated the effects of VSMC NF90 in mediating the metabolic imbalance of AGEs to accelerate diabetic arteriosclerotic calcification. These novel findings elucidate a pivotal mechanism underlying AGE-induced diabetic atherosclerotic calcification and provide a framework for potential interventions against diabetic vascular complications.

Project description:Diabetic kidney disease (DKD) is the leading cause of end-stage renal disease. Neutrophil extracellular traps (NETs) are a network structure composed of loose chromatin and embedded with multiple proteins. Here, we observed increased NETs deposition in the glomeruli of DKD patients and diabetic mice (streptozotocin-induced or db/db mice). After degrading NETs with DNase I, diabetic mice exhibited attenuated glomerulopathy and glomerular endothelial cell (GEC) injury. We also observed alleviated glomerulopathy and GEC injury in peptidylarginine deiminase 4 (PAD4)-knockout mice with streptozotocin-induced diabetes. In vitro, NET-induced GEC pyroptosis was characterized by pore formation in the cell membrane, dysregulation of multiple genes involved in cell membrane function, and high expression of pyroptosis-related proteins. Strengthening the GEC surface charge by oleylamine significantly inhibited NET-induced GEC pyroptosis. These results indicate that NET-induced alterations in GEC charge are associated with GEC pyroptosis in the pathogenesis of DKD and suggest that NETs are a potential therapeutic target for DKD.

Project description:Tendon pathologies affect a large portion of people with diabetes. This high rate of tendon pain, injury, and disease appears to manifest independent of well-controlled HbA1c and fasting blood glucose. Advanced glycation end products (AGEs) are elevated in the serum of those with diabetes. In vitro, AGEs severely impact tendon fibroblast proliferation and mitochondrial function. However, the extent that AGEs impact the tendon cell transcriptome has not been evaluated. The purpose of this study was to investigate transcriptome-wide changes that occur to tendon-derived fibroblasts following treatment with AGEs. We propose to complete a descriptive approach to pathway profiling to broaden our mechanistic understanding of cell signaling events that may contribute to the development of tendon pathology. Rat Achilles tendon fibroblasts were treated with glycolaldehyde-derived AGEs (200μg/ml) for 48 hours in normal glucose (5.5mM) conditions. In addition, total RNA was isolated, and the PolyA+ library was sequenced. We demonstrate that tendon fibroblasts treated with 200μg/ml of AGEs differentially express 2,159 gene targets compared to fibroblasts treated with an equal amount of BSA-Control. Additionally, we report in a descriptive and ranked fashion 21 implicated cell-signaling pathways. We demonstrate that tendon fibroblasts treated with 200μg/ml of AGEs differentially express 2,159 gene targets compared to fibroblasts treated with an equal amount of BSA-Control. Additionally, we report in a descriptive and ranked fashion 21 implicated cell-signaling pathways. Our findings suggest that AGEs disrupt the tendon fibroblast transcriptome on a large scale and that these pathways may contribute to the development and progression of diabetic tendinopathy. Specifically, pathways related to cell cycle progression and extracellular matrix remodeling were affected in our data set and may play a contributing role in the development of diabetic tendon complications.

Project description:Diabetes mellitus [DM], with its burden of premature morbidity and mortality, represents one of the major threats to human health in the 21st century (Zimmet 2001). Accelerated atherosclerosis affecting arteries that supply the heart, brain and lower extremities is responsible for an increased risk of acute ischemic events. DM is also associated with microvascular disease, which is a leading cause of blindness, renal failure and debilitating neuropathies. Endothelial dysfunction, increased vascular permeability and microvascular cell loss by apoptosis are all hallmarks of diabetic microangiopathy. Diabetic patients not only incur cardiovascular complications more frequently, but also experience worse outcomes due to attenuation of vascular repair mechanisms. This impairment includes quantitative and qualitative abnormalities of bone marrow [BM]-derived progenitor cells (Emanueli 2002&2004; Loomans 2004; Krankel 2005; Fadini 2006). The mechanisms underlying BM dysfunction remain however enigmatic, especially when considering the privileged location that protects stem cells [SC] and progenitor cells [PC] of the marrow from external insults (Kopp 2008 and Kiel 2008). BM endothelial cells [EC] are instead an obvious target of DM, because they are directly exposed to blood glucose and incapable to regulate glucose influx. Strangely enough, little is known about the impact of diabetes on BM microvasculature. We hypothesize that damage induced by DM might start at the microvascular level, in a similar fashion to microangiopathy, which occurs in kidney, retina, heart and brain. We also propose that enduring microvascular cell loss might result in marrow hypo-perfusion and destabilization of SC homeostasis. In order to test this hypothesis, we studied streptozotocin-induced (STZ) type-1 DM and age-matched non-DM mice (n=6 to 10 per group in each experiment). Histological examination of femurs, collected from STZ-mice at 28-30 weeks from induction of DM or controls, showed remarkable differences in bone density and marrow composition. Bone marrow cells from healthy and diabetic animals were next selected for endothelial progenitors and cultured for 10 days under endothelial cell growth conditions. Next RNA was isolated and analysed by Illumina Sentrix Beadarrays.