Project description:Oxidative phosphorylation defects results in mitochondrial diseases, with cardiac involvement markedly impacting prognosis. However, the mechanisms underlying the transition from compensation to dysfunction in response to metabolic deficiency remain unclear, impeding the development of effective treatments. Here, we employed single-nucleus RNA sequencing (snRNA-seq) on hearts from mitochondrial cardiomyopathy (MCM) mice with cardiac-specific Ndufs6 knockdown of (FS6KD). Pseudotime trajectory analysis of cardiomyocytes from early stage of female FS6KD hearts revealed dynamic cellular state transitioning from compensation to severe compromise, coincided with transient upregulation of a critical transcription factor, activating transcription factor 3 (Atf3). Genetic ablation or adeno-associated virus-mediated Atf3 knockdown in FS6KD mice effectively delayed cardiomyopathy progression in a female-specific manner. Notably, human MCM snRNA-seq revealed a similar transition, including the dynamic expression of ATF3. In conclusion, our findings highlight a fate-determining role of Atf3 in female MCM progression, providing a promising therapeutic candidate for the currently intractable disease.

Project description:Oxidative phosphorylation defects results in mitochondrial diseases, with cardiac involvement markedly impacting prognosis. However, the mechanisms underlying the transition from compensation to dysfunction in response to metabolic deficiency remain unclear, impeding the development of effective treatments. Here, we employed single-nucleus RNA sequencing (snRNA-seq) on hearts from mitochondrial cardiomyopathy (MCM) mice with cardiac-specific Ndufs6 knockdown of (FS6KD). Pseudotime trajectory analysis of cardiomyocytes from early stage of female FS6KD hearts revealed dynamic cellular state transitioning from compensation to severe compromise, coincided with transient upregulation of a critical transcription factor, activating transcription factor 3 (Atf3). Genetic ablation or adeno-associated virus-mediated Atf3 knockdown in FS6KD mice effectively delayed cardiomyopathy progression in a female-specific manner. Notably, human MCM snRNA-seq revealed a similar transition, including the dynamic expression of ATF3. In conclusion, our findings highlight a fate-determining role of Atf3 in female MCM progression, providing a promising therapeutic candidate for the currently intractable disease.

Project description:Oxidative phosphorylation defects results in mitochondrial diseases, with cardiac involvement markedly impacting prognosis. However, the mechanisms underlying the transition from compensation to dysfunction in response to metabolic deficiency remain unclear, impeding the development of effective treatments. Here, we employed single-nucleus RNA sequencing (snRNA-seq) on hearts from mitochondrial cardiomyopathy (MCM) mice with cardiac-specific Ndufs6 knockdown of (FS6KD). Pseudotime trajectory analysis of cardiomyocytes from early stage of female FS6KD hearts revealed dynamic cellular state transitioning from compensation to severe compromise, coincided with transient upregulation of a critical transcription factor, activating transcription factor 3 (Atf3). Genetic ablation or adeno-associated virus-mediated Atf3 knockdown in FS6KD mice effectively delayed cardiomyopathy progression in a female-specific manner. Notably, human MCM snRNA-seq revealed a similar transition, including the dynamic expression of ATF3. In conclusion, our findings highlight a fate-determining role of Atf3 in female MCM progression, providing a promising therapeutic candidate for the currently intractable disease.

Project description:Increased COUP-TFII levels are found in human dilated cardiomyopathy as well as in mouse models that develop cardiomyopathy. COUP-TFII overexpression in adult mouse hearts caused ventricular dilation and compromised cardiac functions. To gain insights on COUP-TFII’s effect in hearts, we identified the molecular profile of COUP-TFII overexpressing hearts through microarray analysis. The result may shred light on molecular mechanisms that mediate development of dilated cardiomyopathy. We utilized a previously established CAG-S-COUP-TFII allele and crossed it with the Myh6-MerCreMer (Myh6-MCM) line to overexpress COUP-TFII specifically in cardiomyocytes at two months of age by administration of tamoxifen. The experimental group has genotype of Myh6-MCM; CAG-S-COUP-TFII while the control group consists of Myh6-MCM mice (Figure 1C). Whole ventricles were harvested 16 days post induction for molecular profiling.

Project description:Atf3 controls transitioning in female mitochondrial cardiomyopathy as identified by single-cell transcriptomics [snRNA-seq]

Project description:To establish changes in cardiac transcription profiles brought about by heart failure we collected myocardial samples from patients undergoing cardiac transplantation whose failure arises from different etiologies (e.g. idiopathic dilated cardiomyopathy, ischemic cardiomyopathy, alcoholic cardiomyopathy, valvular cardiomyopathy, and hypertrophic cardiomyopathy) and from "normal" organ donors whose hearts cannot be used for transplants. The transcriptional profile of the mRNA in these samples will be measured with gene array technology. Changes in transcriptional profiles can be correlated with the physiologic profile of heart-failure hearts acquired at the time of transplantation. Keywords: other

Project description:To establish changes in cardiac transcription profiles brought about by heart failure we collected myocardial samples from patients undergoing cardiac transplantation whose failure arises from different etiologies (e.g. idiopathic dilated cardiomyopathy, ischemic cardiomyopathy, alcoholic cardiomyopathy, valvular cardiomyopathy, and hypertrophic cardiomyopathy) and from "normal" organ donors whose hearts cannot be used for transplants. The transcriptional profile of the mRNA in these samples will be measured with gene array technology. Changes in transcriptional profiles can be correlated with the physiologic profile of heart-failure hearts acquired at the time of transplantation. Keywords: other

Project description:Myotonic dystrophy type 1 (DM1) is a dominantly inherited disease that affects multiple organ systems. Cardiac dysfunction is the second leading cause of death in DM1. We quantified gene expression in heart tissue from a heart-specific DM1 mouse model (EpA960/MCM) which inducibly expresses human DMPK exon 15 containing 960 CUG expanded repeats and that reproduced Celf1 up regulation. To assess if, in addition to splicing and miRNA defects, CUGexp RNA also perturbed the steady state mRNA levels of genes, we carried out a microarray study on wildtype E14, adult, MCM controls and DM1 mouse hearts. As anticipated we noted a large number of genes to be developmentally regulated in wildtype hearts, however, within 72h of induction of CUGexp RNA there appeared to be a coordinate adult-to-embryonic shift in steady state levels of many genes. We identified transcripts over-expressed or under-expressed in hearts of wildtype adult mice, wildtype embryonic day 14 (E14), and DM1 mice induced to express CUGexp RNA for 72h and 1wk, when compared to MCM controls. Multiple group comparison.

Project description:Increased COUP-TFII levels are found in human dilated cardiomyopathy as well as in mouse models that develop cardiomyopathy. COUP-TFII overexpression in adult mouse hearts caused ventricular dilation and compromised cardiac functions. To gain insights on COUP-TFII’s effect in hearts, we identified the molecular profile of COUP-TFII overexpressing hearts through microarray analysis. The result may shred light on molecular mechanisms that mediate development of dilated cardiomyopathy.

Project description:Analysis of the effects of aging on the development of dilated cardiomyopathy by characterizing both changes in ejection fraction (EF) and gene expression profile in 3 groups of male mice: Control (Cont or WT, n=11) and transgenic (Tg or KO) mice with either high EF (KO-H or Tg-H, n=7) or low EF (KO-L or Tg-L, n=6). We previously produced a line of transgenic mice (Tg) on a mixed genetic background where cardiac-specific overexpression of Cre recombinase reduced expression of the EP4 receptor gene. There were no obvious phenotypes in 10-12-week-old male Tg mice. To determine if a cardiac phenotype developed in aged mice, we assessed cardiac structure and function by echocardiography, histology and gene expression in 23-33-week-old male Tg and littermates (Cont). After echocardiography, hearts were removed to assess hypertrophy (MCSA), fibrosis (ICF) and macrophage infiltration by histological methods and for extraction of total RNA and protein. Cont mice had a normal EF of 80±0.6% (n=70), whereas Tg mice had a lower EF (60±2.7%, n=55, p<0.001) coupled with left ventricular dilatation. The distribution of EFs in the Tg mice was large, ranging from normal to below 30%. MCSA and infiltrating macrophages were not different between groups, but ICF increased by 35% in Tg mice. Cre protein levels in heart lysates did not correlate with either age or EF. In contrast to male Tg mice, female Tg mice had no cardiac dysfunction assessed by echocardiography from 12 to 28 weeks of age. To understand gene expression differences between Cont and Tg mice, whole genome gene expression profiling (Illumina BeadChips) on hearts of 30-32 week old male mice was done. Data indicated that 595 genes were overexpressed in the Tg hearts, 156 of which changed more than 2-fold, including genes involved in remodeling, inflammation, and oxidative stress. 512 genes were downregulated in the Cont hearts, 79 of which changed more than 2-fold, including genes involved with calcium handling, K+ channels, and fatty acid transport and metabolism. In conclusion, Cre overexpression and EP4 knock down in cardiac myocytes in aged male but not female Tg mice are in part associated with increased fibrosis, reduced EF and dilated cardiomyopathy; however, Cre protein itself does not seem to be responsible for the cardiomyopathy. The absence of cardiac dysfunction in female mice suggests a sexual dimorphism in the phenotype. Creation of the cardiac-myocyte specific EP4 KO mouse and littermate controls was described in JY Qian et al, Hypertension 2008: 51(pt 2):560-566. Total RNA extracted from left ventricle of control (Cont or WT, n =11) and cardiac-specific EP4 KO (Tg or KO, n=13) male mice (mean age 31 weeks).