Scientists have developed a new technique that can repair and even regenerate heart muscle cells after a heart attack (or myocardial infarction).
While it has only been tested on mice so far, if it works the same in humans it could potentially be a life-saving treatment for people who have suffered a heart attack.
The technique uses a synthetic messenger ribonucleic acid (mRNA). mRNA creates a ‘blueprint’ of DNA sequences that the body then uses to build the proteins that form and regulate our cells. By tweaking the mRNA, scientists can deliver different instructions for different biological processes.
Here, the edited instructions promote the replication of heart muscle cells (cardiomyocytes) via two so-called mutated transcription factors, Stemin and YAP5SA.
Essentially, the idea is to make heart muscle cells, which have very little ability to regenerate, act more like stem cells, which can be turned into various other types of specialized cells by the body.
“No one has been able to do this to this extent and we think it could become a possible treatment for humans,” says biologist Robert Schwartz, from the University of Houston in Texas.
Less than 1 percent of adult cardiac muscle cells can regenerate – the cardiomyocytes we have when we die are mostly the same ones we’ve had since the first month of life – and that means heart attacks and heart disease can leave the heart in a permanently fragile state.
In experiments in both tissue culture dishes and in living mice, Stemin was shown to turn on stem cell-like properties in the cardiomyocytes, while YAP5SA promoted organ growth and replication. The process has been described as a “game-changer” by the team.
The in vivo study involving living mice affected by damaged hearts showed myocyte nuclei replicating by at least 15-fold in the 24 hours after the injections of the mutated transcription factors, Stemin and YAP5SA.
“When both transcription factors were injected into infarcted adult mouse hearts, the results were stunning,” says Schwartz.
“The lab found cardiac myocytes multiplied quickly within a day, while hearts over the next month were repaired to near normal cardiac pumping function with little scarring.”
The synthetic mRNA added to the cells disappeared in a few days, just as the mRNA produced in our bodies does, the researchers report. This gives the new technique an advantage over gene therapy processes that cannot be easily stopped or removed once they’re underway.
It still remains to be seen whether the approach can be translated successfully into humans – and many more years of research will be required to get this into a working treatment – but the team behind the research is confident.
Work continues to understand more about heart disease and heart injury, and how the body responds in its aftermath. Studying cardiovascular health remains a priority for scientists, with heart disease currently the leading cause of death in the US (accounting for around a quarter of all deaths).
“This is a huge study in heart regeneration especially given the smart strategy of using mRNA to deliver Stemin and YAP5SA,” says biologist Siyu Xiao, from the University of Houston.