Project description:Wild type, female, C57BL/6 mice were subjected to sham (n=6) surgery, or TAC + MI to cause progressive LV remodeling (n=12). At 2wks post-TAC, one group of mice underwent de-banding (HF-DB, n=6), whereas in a second group of mice the band remained intact (HF; n = 6). LV remodeling was evaluated by 2D echocardiography at 14 days post-TAC+MI , and 4 wks post-debanding. At 6 wks the hearts were excised and analyzed for changes in gene expression using transcriptional profiling. e-banding in the HF-DB mice resulted in normalization of LV volumes and LV mass, and normalization of cardiac myocyte hypertrophy at 6wks, without significant changes in myofibrillar collagen in the HF and HF-DB mice. Both LV ejection fraction (LVEF) and LV radial strain improved numerically following de-banding; however, both measurements remained significantly depressed in the HF-DB mice compared to sham, and were not significantly different from HF mice at 6wks. Reverse LV remodeling in the HF-DB mouse hearts was accompanied by a partial (80%) normalization of the genes that became dysregulated during LV remodeling, whereas 20% of genes remained persistently dysregulated following reverse LV remodeling.

Project description:We analyzed global proteomic adaptations during heart failure (HF) progression in a mouse model, suffering from left ventricular pressure overload due to transverse aortic constriction (TAC) and in response to riociguat (RIO) treatment, to gain deeper insights in beneficial effects due to sGC stimulation on cardiac remodeling and HF. TAC and sham animals were treated with either riociguat (RIO; 3 mg/kg/day) or vehicle (VEH; Transcutol®/Cremophor®/water: 10%/20%/70%) for five weeks, starting three weeks post-op when cardiac hypertrophy was established, resulting in four treatment groups ( n=5-6 per group). At the end of the study, hearts were dissected and proteomes of the left ventricles (LV) were analyzed by mass spectrometry (MS).

Project description:We analyzed time dependent global proteomic adaptations during heart failure (HF) progression in a mouse model, suffering from left ventricular pressure overload due to transverse aortic constriction (TAC), to gain deeper insights in the disease development and identify new biomarker candidates. The hearts from TAC and sham mice were examined by cardiac MRI on either day 4, 14, 21, 28, 42, and 56 after surgery (n=6 group/time point). At each time point, proteomes of the left (LV) and right ventricles (RV) of TAC and sham mice were analyzed by mass spectrometry (MS).

Project description:The specific mechanism of sodium-glucose cotransporter 2 (SGLT2) inhibitor in heart failure (HF) needs to be elucidated. In this study, we use SGLT2 global knockout (SGLT2-KO) mice to assess the mechanism of SGLT2 inhibitor on HF. Dapagliflozin ameliorates both myocardial infarction (MI)-and transverse aortic constriction (TAC) -induced HF. Global SGLT2-deficiency doesn’t exert protection against adverse remodeling in both MI- and TAC-induced HF models. Dapagliflozin blurs MI- and TAC-induced HF phenotypes in SGLT2-KO mice. Dapagliflozin causes major changes in cardiac fibrosis and inflammation. Based on single-cell RNA sequencing dapagliflozin causes significant differences in the gene expression profile of macrophages and fibroblasts. Moreover, dapagliflozin directly inhibites macrophage inflammation, thereby suppressing cardiac fibroblasts activation. The cardio-protection of dapagliflozin is blurred in mice treated with a C-C chemokine receptor type 2 (CCR2) antagonist. Taken together the protective effects of dapagliflozin against HF are independent of SGLT2, macrophage inhibition is the main target of dapagliflozin against HF.

Project description:Heart failure (HF) is defined as an inability of the heart to pump blood sufficiently to meet the metabolic demands of the body. HF with reduced systolic function is characterized by cardiac hypertrophy, ventricular fibrosis and remodeling, and decreased cardiac contractility, leading to cardiac functional impairment and death. Transverse aortic constriction (TAC) is a well-established model for inducing hypertrophy and HF in rodents. Mice globally deficient in sirtuin 5 (SIRT5), a NAD+-dependent deacylase, are hypersensitive to cardiac stress and display increased mortality after TAC. Prior studies assessing SIRT5 functions in the heart have all employed loss-of-function approaches. In this study, we generated SIRT5 overexpressing (SIRT5OE) mice, and evaluated their response to chronic pressure overload using TAC. Compared to littermate controls, SIRT5OE mice were protected against adverse functional consequences of TAC, left ventricular dilation, and impaired ejection fraction. Transcriptomic analyses revealed that SIRT5 suppresses key HF sequelae, including the metabolic switch from fatty acid oxidation to glycolysis, immune activation, and fibrotic signaling pathways. We conclude that SIRT5 is a limiting factor in the preservation of cardiac function in response to experimental pressure overload.

Project description:Wild type, female, C57BL/6 mice were subjected to sham (n=6) surgery, or TAC + MI to cause progressive LV remodeling (n=13). At 2wks post-TAC, one group of mice underwent de-banding (HF-DB, n=6), whereas in a second group of mice the band remained intact (HF_shDB; n = 7). LV remodeling was evaluated by 2D echocardiography at 14 days post-TAC+MI , and 2 wks post-debanding. At 4 wks the hearts were excised and analyzed for changes in gene expression using transcriptional profiling.

Project description:End-stage heart failure has long been regarded as a terminal state of cardiac pathological remodeling that is almost impossible to be reversed by any available therapies.We discovered that short term estrogen (E2) treatment rescues preexisting severe heart failure (HF) induced by trans-aortic constriction (TAC) in mice by restoring ejection fraction (EF) from 30% to 55% and cardiac fibrosis (Iorga A, Li J, Sharma S, Umar S, Bopassa JC, Nadadur RD, et al. Rescue of Pressure Overload‐Induced Heart Failure by Estrogen Therapy. Journal of the American Heart Association [Internet]). Given the role of microRNAs in wide spectrum of physiological and pathological processes in HF and fibrosis, we explored whether E2 rescues HF and fibrosis by controlling the expression of specific microRNAs (miRs). RNA isolated from cardiac left ventricle of mice in sham (n=4), HF (n=5) and E2-rescued (n=5) groups was sent to Ocean Ridge Biosciences for miR microarray analysis. Comparison of E2-Rescued group versus HF and sham groups revealed a subset of 158 miRs significantly regulated by E2.

Project description:Aims: Cardiomyocyte-specific nitric oxide synthase 3 (NOS3) overexpression reduces left ventricular (LV) remodelling after myocardial infarction in mice, but its effect on sustained LV pressure-overload remains incompletely understood. We investigated LV structural and functional adaptation to elevated afterload in mice with cardiomyocyte-restricted NOS3 overexpression (NOS3TG) and wild type littermates (WT). Methods and Results: Hemodynamic indices, cardiac hypertrophy and interstitial fibrosis were measured 10 weeks after transverse aortic constriction (TAC). After 10 weeks TAC, NOS3TG had better preserved systolic function (maximum rates of pressure development normalized to maximal pressure 77±6 versus 65±2 ms-1, P=0.05), reduced heart weight-body weight ratio (HW/BW, 5.0±0.3 versus 5.8±0.1, P<0.05), and cardiomyocyte width than WT (14.9±0.4 vs 16.7±0.2 ?m, P<0.05). After 10 weeks TAC, a 44k cDNA chip-based microarray analysis was validated using real time PCR and revealed significantly altered expression pattern of genes involved in cellular growth, matrix remodelling, and inflammation between genotypes. Conclusions: Cardiomyocyte-restricted NOS3 overexpression attenuates TAC-induced hypertrophy via autocrine inhibition of cardiomyocyte cell growth, but does not mitigate myocardial fibrosis. The subsequent diastolic dysfunction suggests that inhibition of matrix producing cells during hypertrophic stress is necessary to prevent functional and structural deterioration of the pressure-overloaded heart.

Project description:Purpose: Despite the well-established association between T cell-mediated inflammation and non-ischemic heart failure (HF), the specific mechanisms triggering T cell activation during the progression of HF and the antigens involved are poorly understood. We hypothesized that clonal expansion of CD4+ T cell in response to cardiac neoantigens promote the progression of HF. Methods: We used transverse aortic constriction (TAC) in mice to trigger HF and profiled the TCR repertoire by mRNA sequencing of CD4+ T cells from 3 pooled Nur77GFP reporter mice, which transiently express GFP upon TCR engagement. We performed TCR clonal analysis of 5000 TCR-activated GFP+CD4+ T cells sorted from the LV, and 5000 CD4+ T cells sorted from the thymus, the inguinal lymph nodes (iLNs) and the heart-draining mediastinal lymph nodes (mLNs) by bulk RNA sequencing of the TCR beta chain after 8wks of TAC surgery. Paired‐end 300 base pair reads were obtained by Illumina sequencing and aligned and assembled using MiXCR software. Results: As expected, the greatest number of unique TCR beta clonotypes (4412 clones) – and therefore the highest TCR diversity – was identified in the thymus. The heart draining mLNs showed a much lower degree of TCR clonal diversity relative to the peripheral iLNs, suggesting that cardiac antigen-driven clonal expansion occurs at the mLNs that directly drain the heart. TCR-activated GFP+CD4+ T cells in the LV represented even lower TCR diversity relative to other sites. Conclusion: Collectively, our study demonstrates that in response to cardiac pressure overload, CD4+ T cells clonally expand in the heart-draining mLN; whilst a limited repertoire of CD4+ T cell clones engage endogenous antigens in the heart.

Project description:Aims: Cardiac fibroblasts (CFs) play a crucial role in cardiac remodelling, which is a common cause of heart failure (HF). However, the molecular mechanisms underlying the fibroblast-to-myofibroblast transition remain largely unknown. Foxm1 is well known in various cardiopulmonary pathologies. However, Foxm1-driven CF activation in the progression of cardiac remodelling to HF remains to be investigated. Methods: Changes in Foxm1 expression were assessed in samples from patients with HF and mice with transverse aortic constriction (TAC)-induced cardiac remodelling. Pharmacologic antagonist FDI-6 was used to explore the effects of Foxm1 inhibition on post-TAC outcomes. Tcf21-Cre and PostnMCM were used to evaluate Foxm1 loss- and gain-of-function in CFs and myofibroblasts, respectively. Cardiac function and remodelling were examined by echocardiography and histological analysis. Foxm1 downstream target genes were identified by mass spectrometry (MS) and transcriptomic analysis. Post-translational regulation was evaluated by in vitro chromatin immunoprecipitation, co-immunoprecipitation, and ubiquitination assays. Pharmacological inhibition of Usp10 or knockout of p38γ in vivo verified the signalling pathway by which Foxm1 regulated cardiac remodelling. Results: Foxm1 was upregulated in human HF samples as well as in the mouse cardiac remodelling model. CFs were the primary cell type responsible for Foxm1 upregulation. Foxm1 pharmacological inhibition or genetic knockout in CFs or myofibroblasts significantly attenuated TAC-induced cardiac remodelling and HF. Conversely, conditional overexpression of Foxm1 in CFs or myofibroblasts resulted in more severe pathological cardiac remodelling and dysfunction. Combined RNA-sequencing and MS analysis revealed that Foxm1 promoted Usp10 expression by binding to its promoter. Usp10 interacted with p38γ, resulting in p38γ deubiquitination and thus influencing the downstream p38 mitogen-activated protein kinase (MAPK) signalling pathway. Pharmacological inhibition of Usp10 or genetic knockout of p38γ ameliorated the exacerbated TAC-induced cardiac remodelling in mice with myofibroblast-specific Foxm1 overexpression. Conclusion: Our findings reveal an essential role of Foxm1 in CF activation during cardiac remodelling. These results suggest that targeting the Foxm1/Usp10/p38γ MAPK axis may represent a new potential therapeutic strategy against pathological cardiac remodelling and HF.