June 20, 2012 in Cardiology Johns Hopkins researchers
have discovered that a single protein molecule may hold the key to turning
cardiac stem cells into blood vessels or muscle tissue, a finding that may lead
to better ways to treat heart attack patients. Human heart tissue does not heal
well after a heart attack, instead forming debilitating scars. For reasons not
completely understood, however, stem cells can assist in this repair process by
turning into the cells that make up healthy heart tissue, including heart
muscle and blood vessels. Recently, doctors elsewhere have reported promising
early results in the use of cardiac stem cells to curb the formation of
unhealthy scar tissue after a heart attack. But the discovery of a "master
molecule" that guides the destiny of these stem cells could result in even
more effective treatments for heart patients, the Johns Hopkins researchers
say. In a study published in the June 5 online edition of the journal Science
Signaling, the team reported that tinkering with a protein molecule called
p190RhoGAP shaped the development of cardiac stem cells, prodding them to
become the building blocks for either blood vessels or heart muscle. The team
members said that by altering levels of this protein, they were able to affect
the future of these stem cells. "In biology, finding a central regulator
like this is like finding a pot of gold," said Andre Levchenko, a
biomedical engineering professor and member of the Johns Hopkins Institute for
Cell Engineering, who supervised the research effort. The lead author of the
journal article, Kshitiz, a postdoctoral fellow who uses only his first name,
said, "Our findings greatly enhance our understanding of stem cell biology
and suggest innovative new ways to control the behavior of cardiac stem cells
before and after they are transplanted into a patient. This discovery could
significantly change the way stem cell therapy is administered in heart
patients." Earlier this year, a medical team at Cedars-Sinai
Medical Center
in Los Angeles
reported initial success in reducing scar tissue in heart attack patients after
harvesting some of the patient's own cardiac stem cells, growing more of these
cells in a lab and transfusing them back into the patient. Using the stem cells
from the patient's own heart prevented the rejection problems that often occur
when tissue is transplanted from another person. Levchenko's team wanted to
figure out what, at the molecular level, causes the stem cells to change into
helpful heart tissue. If they could solve this mystery, the researchers hoped
the cardiac stem cell technique used by the Los Angeles doctors could be altered to yield
even better results. During their research, the Johns Hopkins team members
wondered whether changing the surface where the harvested stem cells grew would
affect the cells' development. The researchers were surprised to find that
growing the cells on a surface whose rigidity resembled that of heart tissue
caused the stem cells to grow faster and to form blood vessels. A cell
population boom occurred far less often in the stem cells grown in the glass or
plastic dishes typically used in biology labs. This result also suggested why
formation of cardiac scar tissue, a structure with very different rigidity, can
inhibit stem cells naturally residing there from regenerating the heart. Looking
further into this stem cell differentiation, the Johns Hopkins researchers
found that the increased cell growth occurred when there was a decrease in the
presence of the protein p190RhoGAP. "It was the kind of master regulator
of this process," Levchenko said. "And an even bigger surprise was
that if we directly forced this molecule to disappear, we no longer needed the
special heart-matched surfaces. When the master regulator was missing, the stem
cells started to form blood vessels, even on glass." A final surprise
occurred when the team decided to increase the presence of p190RhoGAP, instead
of making it disappear. "The stem cells started to turn into cardiac
muscle tissue, instead of blood vessels," Levchenko said. "This told
us that this amazing molecule was the master regulator not only of the blood
vessel development, but that it also determined whether cardiac muscles and
blood vessels would develop from the same cells, even though these types of
tissue are quite different." But would these lab discoveries make a
difference in the treatment of living beings? To find out, the researchers,
working on the heart-matching surfaces they had designed, limited the
production of p190RhoGAP within the heart cells. The cells that possessed less
of this protein integrated more smoothly into an animal's blood vessel networks
in the aftermath of a heart attack. In addition, more of these transplanted
heart cells survived, compared to what had occurred in earlier cell-growing
procedures. Kshitiz said that the special heart-like surface on which the
cardiac stem cells were grown triggers regulation of the master molecule, which
then steers the next steps. "This single protein can control the cells'
shape, how fast they divide, how they become blood vessel cells and how they
start to form a blood vessel network," he said. "How it performed all
of these myriad tasks that require hundreds of other proteins to act in a
complex interplay was an interesting mystery to address, and one that rarely
occurs in biology. It was like a molecular symphony being played in time, with
each beat placed right at the moment before another melody has to start." Journal
reference: Science Signaling
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