In our cellular 'glue,' scientists find answers about heart attacks, strokes

Civelek and his team thought that the scaffolding our bodies build over these plaques might contain important clues that could improve our understanding of cardiovascular diseases, the leading cause of death around the world. And by taking a clever approach, the scientists were able to obtain important new insights that could advance the development of lifesaving treatments.

"We combined two decades of human genetics findings and a unique resource of smooth muscle cells, an important component of arteries where the plaques develop," said Civelek, of UVA's Center for Public Health Genomics and the Department of Biomedical Engineering. "We discovered that our genetic makeup impacts the ways smooth muscle cells secrete proteins that provide strength to plaques and prevent them from rupturing and causing heart attacks and strokes."

Vital Cellular Glue

To construct the protective scaffolding over the potentially deadly plaques, smooth muscle cells that line our blood vessels secrete what is known as "extracellular matrix" -- a fibrous, glue-like material rich in proteins. Civelek and his team measured these proteins, and related proteins, in smooth muscle cells collected from 123 heart transplant donors. The scientists were then able to work backward, essentially, to identify genes that made those proteins.

Doing this let the scientists identify 20 locations on our chromosomes that house genes that influence the production of the critical proteins. It also let them pinpoint a naturally occurring gene variation that puts certain people at higher risk for hardening of the arteries, as well as identify types of proteins that contribute to our cardiovascular risk. Doctors may be able to leverage the new insights to identify patients at greatest risk of having the plaques break free and cause heart attacks or strokes, the UVA researchers say.

The findings also shed important light on why the efforts of the smooth muscle cells sometimes are beneficial and sometimes are harmful. That information will be a great asset to researchers seeking to develop new treatments for atherosclerosis and cardiovascular diseases, Civelek says.

"We identified one protein, LTBP1, that we think plays an important role in plaque stability," he said. "We will continue to study if this protein can be a beneficial therapeutic target and hope to translate our findings to patient care soon."