The Laboratory of Cardiovascular Science has a strong commitment to the study of aging myocardium. To identify gene products in heart potentially involved in aging, functional genomic analyses (cDNA microarrays and Serial Analysis of Gene Expression) have been employed to analyze mRNA from left ventricles of Fisher 344 rats with or without caloric restriction, Wistar rats, C57Bl/6 mice during the perinatal period and with aging, CBA mice treated with biopeptides implicated in gerontoprotection, and human biopsies from failing and non-failing myocardium.
The aim of these projects are to determine which gene products are regulated as a function of age or disease, and then use independent methods to determine the underlying mechanisms responsible for the altered changes in gene expression. In 2002, we published a reference dataset (SAGE analysis) of the mouse myocardium that is publicly available, and we have expanded these studies to examine male versus female mice and young versus old mice. We have completed a large-scale transcriptome analysis of an aging Fisher 344 aging rat model and compared these results with other rodent strains. We are completing an extensive quantitative-PCR analysis to validate these data, and by independent techniques, to determine the significance of the changes in gene expression with the aging process. We have expanded our aging studies in rodent to include in vitro analyses of cultured cardiomyoyctes and fibroblasts to delineate mechanisms underlying the aging response of cardiac genes, and are in the process of elucidating genetic correlates underlying these changes in transcript abundance. Finally, we have employed functional genomic techniques (microarrays) to examine the transcriptomes of LVs from failing (n=8) and non-failing human myocardium (n=7). Following identification of a pool of HF-responsive candidate genes by microarrays and statistical methods, we employed Q-PCR on a larger sample population (n=34) to validate and examine the role of contributing biological variables (age and gender). We find that most of the HF-candidate genes (including transcription factors, modifying enzymes, ECM proteins and metabolic enzymes) demonstrated significant changes in gene expression;however, the majority of the putative changes depended on variables such as sex and age, and not on HF alone. Additionally, some putative HF-responsive gene products demonstrated highly significant changes in expression as a function of age and/or sex, but independent of HF. Based on these previously published data and subsequent microarray analyses using Prediction Analysis of Microarray software, our research efforts have focused on two transcription factors - Ets1 and Ets2. Their specific roles in aging are yet to be elucidated, but from in vitro analyses, these factors are pro-apoptotic;however, the effects differ between fibroblasts and cardiomyocytes. Ets2 is preferentially pro-apoptotic in cardiomyocytes, and both Ets1 and Ets2 can be up-regulated by angiotensin II. These findings are now being expanded to tissue samples obtained from aged rodents and and recent data suggest that the mechanisms of apoptosis in fibroblasts versus cardiomyocytes differ depending on activation via Ets1 and Ets2.

Agency
National Institute of Health (NIH)
Institute
National Institute on Aging (NIA)
Type
Investigator-Initiated Intramural Research Projects (ZIA)
Project #
1ZIAAG000288-11
Application #
8148205
Study Section
Project Start
Project End
Budget Start
Budget End
Support Year
11
Fiscal Year
2010
Total Cost
$211,103
Indirect Cost
Name
National Institute on Aging
Department
Type
DUNS #
City
State
Country
Zip Code
Sheydina, Anna; Volkova, Maria; Jiang, Liqun et al. (2012) Linkage of cardiac gene expression profiles and ETS2 with lifespan variability in rats. Aging Cell 11:350-9
Sheydina, Anna; Riordon, Daniel R; Boheler, Kenneth R (2011) Molecular mechanisms of cardiomyocyte aging. Clin Sci (Lond) 121:315-29
Wiese, Cornelia; Nikolova, Teodora; Zahanich, Ihor et al. (2011) Differentiation induction of mouse embryonic stem cells into sinus node-like cells by suramin. Int J Cardiol 147:95-111
Boheler, Kenneth R (2010) Pluripotency of human embryonic and induced pluripotent stem cells for cardiac and vascular regeneration. Thromb Haemost 104:23-9