Novel way to create better, faster and stronger heart cells

Scientists, including one of Indian origin, have identified two chemicals which can improve speed, quantity and quality of direct cardiac reprogramming, bringing the technology to regenerate damaged hearts one step closer.
The new discovery advances efforts to find new and effective treatments for heart failure. When heart muscle is damaged, the body is unable to repair the dead or injured cells, researchers said.

Scientists at the Gladstone Institutes in the US are exploring cellular reprogramming - turning one type of adult cell into another - in the heart as a way to regenerate muscle cells in the hopes of treating and ultimately curing, heart failure. It takes only three transcription factors - proteins that turn genes on or off in a cell - to reprogramme connective tissue cells into heart muscle cells in a mouse.

After a heart attack, connective tissue forms scar tissue at the site of the injury, contributing to heart failure. The three factors, Gata4, Mef2c, and Tbx5 (GMT), work together to turn heart genes on in these cells and turn other genes off, effectively regenerating a damaged heart with its own cells. However, the method is not foolproof - typically, only ten per cent of cells fully convert from scar tissue to muscle.

In the new study, scientists tested 5500 chemicals to try to improve this process. They identified two chemicals that increased the number of heart cells created by eightfold. The chemicals sped up the process of cell conversion, achieving in one week what used to take six to eight weeks. "While our original process for direct cardiac reprogramming with GMT has been promising, it could be more efficient," said Deepak Srivastava, director of the Gladstone Institute of Cardiovascular Disease.

"With our screen, we discovered that chemically inhibiting two biological pathways active in embryonic formation improves the speed, quantity, and quality of the heart cells produced from our original process," said Srivastava. The first chemical inhibits a growth factor that helps cells grow and divide and is important for repairing tissue after injury. The second chemical inhibits an important pathway that regulates heart development. 

By combining the two chemicals with GMT, the researchers successfully regenerated heart muscle and greatly improved heart function in mice that had suffered a heart attack. The scientists also used the chemicals to improve direct cardiac reprogramming of human cells, which is a more complicated process that requires additional factors. The two chemicals enabled the researchers to simplify the process bringing them one step closer to better treatments for heart failure.