Gene that regulates development of heart cells identified, described by Penn researchers
Scientists at the University of Pennsylvania School of Medicine have identified and described a small gene that regulates the delicate balance involved in the healthy growth and replication of heart muscle cells.
“This finding is likely to be important for our understanding of the causes of congenital heart disease. It is also relevant to our attempts to regrow damaged heart muscle,” said the corresponding author of the study, Jonathan A. Epstein, MD, of Penn’s Departments of Medicine and Cell & Developmental Biology. The study is scheduled to appear in the September 20 issue of the journal Cell.
The newly identified heart gene, Hop (an acronym for homeodomain only protein), is a small protein that lacks certain residues required for DNA binding, but is activated early in fetal development and continues modulating the expression of cardiac-specific genes throughout life. Hop appears to bind directly to another important regulator of development, serum response factor (SRF), and block SRF from binding to DNA. By inhibiting the expression of SRF, Hop protects cardiac muscle cells from over-development, and from developing fatal abnormalities.
“There has been a lot of effort to try to determine how SRF is regulated in different tissues,” Epstein said. “Now we see that Hop plays a vital part.”
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