Project description:Metabolic alterations occur in the heart of patients with type 2 diabetes mellitus (T2DM). However, the relationships between branched-chain amino acid (BCAA) metabolism and the pathophysiology of diabetic cardiomyopathy (DbCM) remain unclear. Here, we sought to establish a novel model of DbCM and reveal its metabolic alterations, especially focusing on BCAA metabolism. Using adipocyte-specific 3′-phosphoinositide–dependent kinase 1 (PDK1)-deficient (A-PDK1KO) mice as a new model of DbCM, we demonstrated that cardiac BCAA catabolic enzymes were down-regulated in these mice, leading to the accumulation of BCAAs in the heart. Mechanistically, the accumulation of the BCAA leucine could cause cardiac hypertrophy via the activation of mammalian target of rapamycin complex 1 (mTORC1). A-PDK1KO mice mimic the cardiac phenotypes and metabolic alterations seen in human DbCM and exhibit impaired BCAA metabolism in the heart. This model may contribute to a better understanding of DbCM pathophysiology and the development of novel therapies for it.

Project description:VEGF family members are important regulators of vascular functions. Promoting VEGFA signalling in aged mice has been shown to delay various aging phenotypes and extend the survival of aged mice. Although there is profound knowledge on functions of VEGFA, VEGFB has not been investigated in the context of cardiac aging. Our RNA data of aged mouse hearts revealed significant downregulation of Vegfb in the heart, specifically in endothelial cells and cardiomyocytes, while VEGFB expression was reduced in endothelial cells, fibroblasts and cardiomyocytes in aged human hearts. By contrast, VEGFB expression was exclusively reduced in cardiomyocytes of patients with cardiac hypertrophy. Hence, we investigated whether Vegfb gene therapy can revert age-dependent cardiac pathologies. We overexpressed Vegfb186, the soluble VEGFB isoform, via AAV9 vector transduction into 18-month-old C57Bl/6J male mice. AAV9-Vegfb treatment prevented progression age-related diastolic dysfunction and decreased cardiac fibrosis. We further found a rescue of aging-related left ventricular denervation in the hearts of AVV9-Vegfb treated old mice which was associated with an increase in heart rate variability. However, heart to body weight ratio and cardiomyocyte hypertrophy were increased in the AAV9-Vegfb treated mouse hearts, without alteration of cardiac systolic or diastolic function. Histological and transcriptomic analyses revealed that VEGFB186 induces compensatory cardiac hypertrophy which was accompanied by a rescued length-width-ratio, reduced fibrosis and the absence of cardiac inflammation. Cardiac single-nuclei RNA sequencing further suggested that AAV9-Vegfb treatment affects cardiac hypertrophy putatively via STAT3 which was validated in vitro. In conclusion, our data reveals that Vegfb overexpression partially reverses pathological alterations in the aging heart. Despite the overall improvement of the age-related cardiac phenotype, the AAV9-Vegfb-mediated induced cardiac hypertrophy which might reflect protective hypertrophy.

Project description:Diabetic cardiomyopathy (DbCM) is an important clinical syndrome of diabetes and cause great burden to the people's life and health. Understanding its intrinsic epigenetic and metabolic alterations is critical to develop drugs for the treatment of DbCM. Multiple omics technology provides a feasible way for parsing the epigenetic characteristics and metabolic signatures associated with DbCM. The heart isolated from Male db/db mice and db/m mice were used for the analysis of high-throughput sequencing. Non-targeted metabolomics and amino acid-targeted metabolomics analyses were performed to detect the metabolites in plasma and heart tissues. Additionally, RNA-seq, proteomics, and ATAC-seq were employed to elucidate the underlying transcriptional-metabolic regulatory network mechanism in DbCM.

Project description:Diabetic cardiomyopathy (DbCM) is an important clinical syndrome of diabetes and cause great burden to the people's life and health. Understanding its intrinsic epigenetic and metabolic alterations is critical to develop drugs for the treatment of DbCM. Multiple omics technology provides a feasible way for parsing the epigenetic characteristics and metabolic signatures associated with DbCM. The heart isolated from Male db/db mice and db/m mice were used for the analysis of high-throughput sequencing. Non-targeted metabolomics and amino acid-targeted metabolomics analyses were performed to detect the metabolites in plasma and heart tissues. Additionally, RNA-seq, proteomics, and ATAC-seq were employed to elucidate the underlying transcriptional-metabolic regulatory network mechanism in DbCM.

Project description:Patients with long-duration diabetes develop cardiovascular complications resulting in highly increased mortality and complications which affect the kidneys, eyes and peripheral nerves associated with high morbidity. Among the diabetic complications, damage in the eye, diabetic retinopathy, is the most common microvascular complication of diabetes. Diabetic retinopathy is a leading cause of vision-loss globally. It is characterized by a number of different patho-mechanisms including changes in vascular permeability, capillary degeneration, and finally at a late stage overshooting formation of new blood vessels. This expression analysis focused on the use of different experimental models for Diabetes Mellitus and its complications (for a review see 1: Al-Awar et al: Experimental Diabetes Mellitus in Different Animal Models. J Diabetes Res. 2016; doi: 10.1155/2016/9051426). By that, we wanted to uncover the relative contributions of systemic hyperinsulinaemia and/or hyperglycemia to molecular regulations. The following models have been used: As insulinopenic, hyperglycemic model reflecting Type 1 diabetes, male STZ-Wistar rats (60mg/kg BW; i.p.) were used. Wistar rats without STZ injection served as non-diabetic controls. Male obese ZDF rats (Fa/Fa) were used as type-2 diabetes model characterized by persisting hyperglycemia and transient hyperinsulinemia. Male lean ZDF rats (Fa/-) served as non-diabetic controls. Male obese ZF rats (Fa/Fa) hyperglycemia were used reflecting euglycemia and severe insulin resistance. Male lean ZF rats (Fa/-) served as controls. ZDF and ZF rats were obtained in two genotypes, obese (genotype fa/fa) and lean littermates (genotype Fa/?). All rats were housed in standard cages under a normal light-dark cycle for 16 weeks. All animals had free access to food and water. ZF and Wistar rats received a standard chow (Ssniff R/M) and ZDF rats received Purina 5008 chow. A group size of n=8 were used for all study groups. Wistar rats were rendered type-1 like hyperglycemic and hypoinsulinemic via a single injection of streptocotocin (STZ, 60mg/kg; i.p.) at 7 weeks of age. Obese ZDF rats (fa/fa) develop spontaneously a type-2 diabetes phenotype with persisting hyperglycemia and transient hyperinsulinemia (hyperglycemic, hypoinsulinemic). Obese ZF rats (fa/fa) develop insulin resistance with permanent hyperinsulinemia without concomitant hyperglycemia and no overt diabetes phenotype. Non STZ treated Wistar rats, lean ZDF littermates (Fa/?), and lean ZF littermates (Fa/?) served as controls. All groups were kept for 12 weeks on respective conditions together with appropriate age-matched controls. Unbiased gene expression analysis was performed per group using Affymetrix gene arrays.

Project description:In type II diabetes (T2DM), the heart is exposed to hyperglycaemia, hyperlipidaemia, and hyperinsulinaemia, leading to insulin resistance and metabolic dysfunction, culminating in diabetic cardiomyopathy (DbCM). Human-centric models of DbCM are needed to provide mechanistic insights and therapeutic targets in a translationally relevant setting. We hypothesised that culturing human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) in an “insulin resistance” (IR) media, and assessing this using a systems biology approach, would offer a comprehensive evaluation of dysregulated pathways, establishing their suitability as a model of DbCM. Culturing 2D hiPSC-CMs in IR media induced insulin resistance and activated pathways implicated in DbCM, including metabolic remodelling, mitochondrial dysfunction, and endoplasmic reticulum stress. Adaptation to hypoxia, a key component of post-ischaemic remodelling, was blunted in the 2D IR hiPSC-CMs, highlighting impaired cellular responses to low oxygen conditions. Proteomic and transcriptomic analyses revealed significant enrichment of DbCM-related pathways, particularly those involved in metabolic dysregulation. In conclusion, 2D hiPSC-CMs cultured in IR media recapitulate key features of DbCM, including impaired adaptation to hypoxia, providing a valuable model for studying diabetic cardiomyopathy.

Project description:Abnormalities in metabolism of energetic substrates may play a role in progression of chronic heart failure (HF). The goal of the study was to examine the extent and mechanisms of metabolic alterations in rat model of chronic HF due to volume overload. Volume overload was induced in 3 months old male Wistar rats by aorto-caval fistula. In the phase of symptomatic HF (after 21 weeks), we performed myocardial gene expression analysis. Cardiac tissue gene expression analysis showed downregulation of enzymes of respiratory cycle, mitochondrial fatty acid (FA) oxidation and attenuated expression of proteins responsible for FA translocation/transport (CD36/FAT, FABP3, FATP-1). Simultaneously, we performed gene expression analysis of fat tissue.

Project description:Objective: To evaluate the altered expression of genes due to hyperglycaemia during foetal development in heart. Methods: To understand the molecular defects in the two-days old neonatal rats, diabetic female rats were bred with healthy male rats and collected two days old hearts from neonates. Heart mRNA profiles of two-day-old neonatal rats were generated by RNA sequencing, in quadruplicate, using Illumina HiSeq. Results: Using an optimized data analysis workflow, we mapped about 27 million sequence reads per sample to the rat genome (build Rnor_6.0) and identified 25456 transcripts in the heart of the neonatal rats. Approximately 4% of the transcripts showed differential expression between the Control and PGDM (pregestational diabetes mellitus) heart, with a fold change ≥2 and p value <0.05. Conclusions: Transcriptomic profiling of the RNA-seq data revealed that several of the altered genes were associated with cardiac pathogenesis in neonatal heart during PGDM.

Project description:We tested the impact of a graded reduction in insulin on cardiac gene expression with particular focus on metabolism and energy homeostasis. Wistar rats were made diabetic with a single dose of either 55 (D55) or 100 (D100) mg/kg streptozotocin (STZ). Although both D55 and D100 were equally hyperglycemic compared to control, D100 showed markedly lower plasma insulin and robust increases in plasma FA and TG. D100 demonstrated more significant transcriptomic changes than D55 with enrichment for metabolic processes that direct the heart to use FA, when glucose use is obstructed. Analysis of a protein-protein interaction network identified functional networks in D100 that describe mitochondrial overload, incomplete fatty acid oxidation, and loss of cardiomyocytes. Our data suggests that the differential reduction of insulin produced a dramatic change in cardiac gene expression largely enriched for substrate metabolism functions as well as a gene expression program supporting cell death.

Project description:Diabetes-associated microbiota in fa/fa rats is modified by Roux-en-Y gastric bypass