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Active NON-SBIR/STTR RPGS NIH (US)

Genetic interactions and multifactorial genetics mediate myocardial regeneration

$4.64M USD

Funder NATIONAL HEART, LUNG, AND BLOOD INSTITUTE
Recipient Organization Medical College of Wisconsin
Country United States
Start Date Feb 11, 2021
End Date Jan 31, 2026
Duration 1,815 days
Number of Grantees 1
Roles Principal Investigator
Data Source NIH (US)
Grant ID 10563217
Grant Description

PROJECT SUMMARY/ABSTRACT Dogma in the cardiovascular field argues that the adult mammalian heart is essentially non-regenerative and that this failure to regenerate is primarily attributed to the post-mitotic and polyploid nature of most cardiomyocytes (CMs). Multiple pieces of evidence now support the idea that within the adult mammalian

myocardium, mononuclear diploid cardiomyocytes (MNDCMs) are a privileged subpopulation of CMs that have avoided this proliferative senescence. This attribute confers a unique capacity to re-enter the cell cycle and regenerate myocardial tissue. Our recent work in mice demonstrates that the frequency of MNDCMs and the

competence to regenerate one's heart are two interlinked and variable traits influenced by the complex genetic background of an individual. In other words, contrary to longstanding beliefs, some individuals can mount a meaningful regenerative response after an insult, such as a myocardial infarction. We then took a genome-

wide association strategy to identify the genes associated with the observed variation. From this analysis, we identified Tnni3k as one candidate that regulates CM senescence by inhibiting cytokinesis, specifically. Here, we identify two new candidate genes each of which has a unique effect on CM cell cycle and ploidy.

Furthermore, we hypothesize that identified genes will work cooperatively to maximize the trait effect, thus a multifactorial approach to heart regeneration is prudent. Aim 1 will explore the first novel candidate for its independent effect on heart function and CM cell cycle activity in both uninjured and post-infarction settings. It

will also be tested in combination with Tnni3k. Aim 2 will examine the effect of the second novel candidate on CM ploidy, cell cycle, and heart regeneration both independently and in combination with Tnni3k. Our prior GWAS study affirms that CM ploidy and cardiac regeneration are complex phenotypes relying on multiple

genetic loci. Here, we use genetic approaches to modulate multiple candidate genes in a single animal model and we anticipate that this combinatorial approach will potentiate CM proliferation and cardiac regeneration.

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Medical College of Wisconsin

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