Mending Broken Hearts: Israeli Scientists Find The Molecule That Regenerates Heart Cells
Heart disease remains the leading cause of death worldwide, yet the few available treatments are still mostly unsuccessful once the heart tissue has suffered damage. Mammalian hearts are actually able to regenerate and repair damage – but only up to around the time of birth. Afterward, that ability disappears, seemingly forever.
Research at the Weizmann Institute of Science has uncovered a molecule in newborn hearts that appears to control the renewal process. When injected into adult mouse hearts injured by heart attacks, this molecule, called Agrin, seems to “unlock” that renewal process and enable heart muscle repair. These findings are already pointing to new directions for research on restoring the function of damaged hearts.
Human heart cells cannot regenerate
Prof. Eldad Tzahor, who led the study with Elad Bassat, Alex Genzelinakh and other team members in the Weizmann Institute’s Molecular Cell Biology Department, explains that following a heart attack in humans, the healing process is long and inefficient. Once damaged, muscle cells are replaced by scar tissue, which is incapable of contracting and thus cannot participate in pumping. This, in turn, leads to further stress on the remaining muscle and eventual heart failure.
Heart regeneration into adulthood does exist in some of our fellow vertebrates. Fish, for example, can efficiently regenerate damaged hearts. Closer relatives on the evolutionary tree – mice – are born with this ability but lose it after a week of life. That week gives Tzahor and his lab a time window in which to explore the cues that promote heart regeneration.
Looking for outside sources
Tzahor and Bassat believed that part of the secret might lay outside of the heart cells themselves – in the surrounding supportive tissue known as the extracellular matrix, or ECM. Many cell-to-cell messages are passed through this matrix, while others are stored within its fibrous structure. So the team began to experiment with ECM from both newborn and week-old mice, clearing away the cells until only the surrounding material was left, and then observing what happened when bits of the ECM were added to cardiac cells in culture. The researchers found that the younger ECM, in contrast to the older, elicited the proliferation of heart muscle cells.
A screening of ECM proteins identified several candidate molecules for regulating this response, among them Agrin. In mouse hearts, levels of this molecule drop over the first seven days of life, suggesting a possible role in heart regeneration. The researchers then added Agrin to cell cultures and noted that it caused the cells to multiply.
Next, the researchers tested Agrin on mouse models of heart injury, asking whether it could reverse the damage. They found that following a single injection of Agrin mouse hearts were almost completely healed and fully functional, although the scientists were surprised to find that it took over a month for the treatment to impart its full impact on cardiac function and regeneration. At the end of the recovery period, however, the scar tissue was dramatically reduced, replaced by living heart tissue that restored the heart’s pumping function.
In other words, Tzahor speculates that in addition to causing a certain amount of direct heart cell renewal, Agrin somehow affects the body’s inflammatory and immune responses to a heart attack, as well as the pathways involved in suppressing the scarring, which leads to heart failure. The length of the recovery process, however, is still a mystery, as the Agrin, itself, disappears from the body within a few days of the injection.
“Clearly this molecule sets a chain of events in motion” he says. “We discovered that it attaches to a previously unstudied receptor on the heart muscle cells, and this binding takes the cells back to a slightly less mature state – closer to that of the embryo – and releases signals that may, among other things, initiate cell division.” Experiments with mice that were genetically engineered to lack Agrin in their hearts further support this idea: In its absence, newborn mice could not properly regenerate heart tissue following injury. Because mice cannot live without the other functions of Agrin, this was a technically challenging experiment to perform, adds Tzahor.
Testing on human heart cells proves successful
The team then proved that Agrin has a similar effect on human heart cells grown in culture. He and his team are now working to understand exactly what happens in the period of time between the injection of Agrin and the return of full cardiac functionality. In addition, members of Tzahor’s team have started pre-clinical studies in larger animals in Germany in collaboration with Prof. Kupatt of the Technical University of Munich to determine the effect of Agrin on cardiac repair.
Among other things, the findings of this study have highlighted a role for the ECM in both directing heart growth and promoting regeneration, and this insight may help in the design of breakthrough biomedical research.