CORONARY ARTERIES HOLD HEART- REGENERATING CELLS
Endothelial cells
residing in the coronary arteries can function as cardiac stem cells to produce
new heart muscle tissue, Vanderbilt University investigators have discovered.
The findings,
published recently in Cell Reports, offer insights into how the
heart maintains itself and could lead to new strategies for repairing the heart
when it fails after a heart attack.
The heart has long
been considered to be an organ without regenerative potential, said Antonis
Hatzopoulos, Ph.D., associate professor of Medicine and Cell and Developmental
Biology.
"People thought
that the same heart you had as a young child, you had as an old man or woman as
well," he said.
Recent findings,
however, have demonstrated that new heart muscle cells are generated at a low
rate, suggesting the presence of cardiac stem cells. The source of these cells
was unknown.
Hatzopoulos and
colleagues postulated that the endothelial cells that line blood vessels might
have the potential to generate new heart cells. They knew that endothelial
cells give rise to other cell types, including blood cells, during development.
Now, using
sophisticated technologies to "track" cells in a mouse model, they
have demonstrated that endothelial cells in the coronary arteries generate new
cardiac muscle cells in healthy hearts. They found two populations of cardiac
stem cells in the coronary arteries -- a quiescent population in the media
layer and a proliferative population in the adventitia (outer) layer.
The finding that
coronary arteries house a cardiac stem cell "niche" has interesting
implications, Hatzopoulos said. Coronary artery disease -- the No. 1 killer in
the United States -- would impact this niche.
"Our study
suggests that coronary artery disease could lead to heart failure not only by
blocking the arteries and causing heart attacks, but also by affecting the way
the heart is maintained and regenerated," he said.
The current research
follows a previous study in which Hatzopoulos and colleagues demonstrated that
after a heart attack, endothelial cells give rise to the fibroblasts that
generate scar tissue.
"It looks like
the same endothelial system generates myocytes (muscle cells) during
homeostasis and then switches to generate scar tissue after a myocardial
infarction. After injury, regeneration turns to fibrosis," he said.
Understanding this
switch could lead to new strategies for restoring regeneration and producing
new heart muscle after a heart attack, during aging or in disease conditions
such as diabetes and high blood pressure, he said.
"If we can
understand the molecular mechanisms that regulate the fate switch that happens
after injury, perhaps we can use some sort of chemical or drug to restore
regeneration and make muscle instead of scar," Hatzopoulos said. "We
think there is an opportunity here to improve the way we treat people who come
into the clinic after myocardial infarction."
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