Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Age-Dependent Transcriptional Alterations in Cardiac Endothelial Cells

Project description:Purpose: The goal of this study is to determine alterations in heart endothelial cell transcripts and cell populations associated with aging. Methods: Endothelial single cell mRNA profiles of 3 month and 24 month old wild-type mice were generated by 10X Genomics Results: Using an optimized data analysis workflow, we mapped about 50 thousand reads per cell Conclusions: Our study represents the first analysis of aged cardiac endothelial cell transcriptomes using single cell RNA-seq technology, identifiying specific transcripts and cell populations affected by age.

Project description:Purpose: The goal of this study is to determine alterations in heart endothelial cell transcripts associated with aging. This is accomplished by comparing endothelial transcriptomes from young and aged organs (heart, brain and kidney). Methods: Endothelial mRNA profiles of 3 month and 24 month old wild-type mice were generated by next generation sequencing using libraries generated via SmartSeq V4 chemistry (Takara) and sequenced on an HiSeq 2500 (Illuina). Tophat2 with default parameters was used to align the sequenced reads against the mouse genome using the GRCm38. HTSeq python software with default parameters was used to quantify the transcripts of the aligned reads using the corresponding GRCm38 gene annotation model from Ensembl. Results: Highly enriched populations of endothelial cells (ECs) isolated from the heart, brain and kidney of young (3 months) and old (24 months) C57/BL6 mice were profiled for RNA expression via bulk RNA sequencing. Approximately 700 cardiac endothelial transcripts significantly differ by age. Gene set enrichment analysis indicated similar patterns for cellular pathway perturbations. Receptor-ligand comparisons indicated parallel alterations in age-affected circulating factors and cardiac endothelial-expressed receptors. Single-cell RNA-seq analysis identified 9 distinct endothelial cell subtypes in the heart with an age-associated population shift observed for an Aplnr-enriched endothelial cell clusters. Conclusions: Gene and pathway enrichment analyses show that age-related transcriptional response of cardiac endothelial cells is distinct from that of endothelial cells derived from the brain or kidney vascular bed. Furthermore, single-cell analysis identified 9 distinct EC subtypes, and shows that Aplnr-enriched subtype is reduced with age in mouse heart. Finally, we identify age-dysregulated genes in specific aged cardiac endothelial subtypes.

Project description:Age-Dependent Transcriptional Alterations in Cardiac Endothelial Cells [scRNA-seq]

Project description:Age-Dependent Transcriptional Alterations in Cardiac Endothelial Cells [bulk RNA-seq]

Project description:As we age, structural changes contribute to progressive decline in organ function, which in the heart act through poorly characterized mechanisms. Taking advantage of the short lifespan and conserved cardiac proteome of the fruit fly, we found that cardiomyocytes exhibit progressive loss of Lamin C (mammalian Lamin A/C homologue) with age, coincident with decreasing nuclear size and increasing nuclear stiffness. Premature genetic reduction of Lamin C phenocopies aging's effects on the nucleus, and subsequently decreases heart contractility and sarcomere organization. Surprisingly, Lamin C reduction downregulates myogenic transcription factors and cytoskeletal regulators, possibly via reduced chromatin accessibility. Subsequently, we find a role for cardiac transcription factors in regulating adult heart contractility and show that maintenance of Lamin C, and cardiac transcription factor expression, prevents age-dependent cardiac decline. Our findings are conserved in aged non-human primates and mice, demonstrating that age-dependent nuclear remodeling is a major mechanism contributing to cardiac dysfunction.

Project description:Metabolism has emerged as a regulator of core stem cell properties such as proliferation, survival, self-renewal, and multilineage potential. Metabolites serve as secondary messengers, fine-tuning signaling pathways in response to microenvironment alterations. Studies show a role for central metabolite acetyl-CoA in the regulation of chromatin state through changes in histone acetylation. Nevertheless, metabolic regulators of chromatin remodeling in cardiac cells in response to increasing biological age remains unknown. Previously, we identified novel cardiac-derived stem-like cells (CTSCs) that exhibit increased functional properties in the neonatal heart (nCTSC). These cells are linked to a unique metabolism which is altered with CTSC aging (aCTSC). Here, we present an in-depth, RNA-sequencing-based (RNA-Seq) bioinformatic with cluster analysis that details a distinct epigenome present in nCTSCs but not in aCTSCs. Gene Ontology (GO) and pathway enrichment reveal biological processes, including metabolism, gene regulation enriched in nCTSCs, and STRING analysis that identifies a network of genes related to acetyl-CoA that can potentially influence chromatin remodeling. Additional validation by Western blot and qRT-PCR shows increased acetyl-CoA signaling and histone acetylation in nCTSCs compared to aCTSCs. In conclusion, our data reveal that the link between metabolism and histone acetylation in cardiac cells is altered with the aging of the cardiac tissue.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Calstabin2 is a component of the cardiac ryanodine receptor (RyR2) macromolecular complex, which modulates Ca(2+) release from the sarcoplasmic reticulum in cardiomyocytes. Previous reports implied that genetic deletion of Calstabin2 leads to phenotypes related to cardiac aging. However, the mechanistic role of Calstabin2 in the process of cardiac aging remains unclear. To assess whether Calstabin2 is involved in age-related heart dysfunction, we studied Calstabin2 knockout (KO) and control wild-type (WT) mice. We found a significant association between deletion of Calstabin2 and cardiac aging. Indeed, aged Calstabin2 KO mice exhibited a markedly impaired cardiac function compared with WT littermates. Calstabin2 deletion resulted also in increased levels of cell cycle inhibitors p16 and p19, augmented cardiac fibrosis, cell death, and shorter telomeres. Eventually, we demonstrated that Calstabin2 deletion resulted in AKT phosphorylation, augmented mTOR activity, and impaired autophagy in the heart. Taken together, our results identify Calstabin2 as a key modulator of cardiac aging and indicate that the activation of the AKT/mTOR pathway plays a mechanistic role in such a process.