News Release

Preventing heart cells from turning to bone

Scientists have discovered why some heart tissue turns into bone, and they may have learned how to stop it

Peer-Reviewed Publication

Gladstone Institutes

Artistic Rendering of Blood Flow's Protective Qualities in the Heart

image: This image shows blood flow in the heart activates the NOTCH1 gene, triggering a cascade of anti-inflammatory and anti-calcification pathways. Disruption of this process can result in a hardening of the valves in cardiovascular disease. view more 

Credit: Christina Theodoris

Researchers from the Gladstone Institutes have used human cells to discover how blood flow in the heart protects against the hardening of valves in cardiovascular disease. What's more, they've identified a potential way to correct this process when it goes wrong by flipping the switch on just a handful of genes. These findings may have implications for related conditions, like hardening of the arteries, which causes heart attacks and stroke.

Calcific aortic valve disease (CAVD) is the third leading cause of heart disease, affecting nearly 1.5 million people and resulting in 100,000 heart valve replacement surgeries in the U.S. alone. In CAVD, which can develop with age, heart valves begin to produce calcium, causing them to harden like bone. Scientists have long known that blood flow in the heart plays a role in the calcification of valves and arteries, but they did not understand how.

In a new study published in the journal Cell, Gladstone investigators reveal the chain of events that cause healthy valves to become bone-like. Senior author on the paper, Deepak Srivastava, MD, director of cardiovascular and stem cell research at Gladstone and a pediatric cardiologist at the University of California San Francisco (UCSF), had previously discovered that disruption of one of two copies of a master gene called NOTCH1 can cause valve birth defects and CAVD. In the current study, the researchers report that NOTCH1 acts like a sensor on the endothelial cells--the cells that line the valve and vessels--detecting blood flow outside of the cell and transmitting information to a network of genes inside the cell. Activation of NOTCH1 by blood flow causes a domino effect, triggering numerous other genes in the network to turn on or off, resulting in suppression of inflammation and calcification. However, if this process is disrupted by a decrease in NOTCH1, the cells become confused and start to act like bone cells, laying down calcium and leading to a deadly hardening of the valve.

In a collaborative effort between the Gladstone laboratories of Benoit Bruneau, PhD, Katherine Pollard, PhD, and Dr. Srivastava, the scientists used stem cell technology to make large amounts of endothelial cells from patients with CAVD, comparing them to healthy cells and mapping their genetic and epigenetic changes as they developed into valve cells. The researchers used the power of gene sequencing and clever computational methods to uncover the "source code" for human endothelial cells and learn how that code is disturbed in human disease.

"By understanding the gene networks that get disrupted in CAVD, we can pinpoint what we need to fix and find new therapeutics to correct the disease process," says first author Christina Theodoris, an MD/PhD student at the Gladstone Institutes and UCSF.

Sifting through this mountain of data, the scientists found three key genes that were altered by the NOTCH1 mutation and also acted as master regulators, turning off the critical pathways that normally prevent inflammation and calcification. Remarkably, when the researchers manipulated the activity of these three genes, almost all of the other genes in the network were corrected, pointing to novel therapeutic targets for CAVD. The scientists are now screening for drugs that restore the gene network to its normal state.

"Identifying these master regulators is a big step in treating CAVD, not just in people with the NOTCH1 mutation, but also in other patients who experience calcification in their valves and arteries," says Dr. Srivastava. "Now that we know how calcification happens and what the key nodes are, we know what genes to look for that might be mutated in other related forms of cardiovascular disease."


Molong Li, Mark White, Lei Liu, and Daniel He also contributed to the research, and Katherine Pollard and Benoit Bruneau from the Gladstone Institutes were co-senior authors on the paper. Funding for the study was provided by the Bench to Bassinet Program of the National Heart, Lung, and Blood Institute (NHLBI), the NHLBI Progenitor Cell Biology Consortium, the LK Whittier Foundation, the William Younger Family Foundation, the Eugene Roddenberry Foundation, the Winslow family, the Lawrence J. and Florence A. De George Charitable Trust, the Sarnoff Cardiovascular Research Program, the California Institute for Regenerative Medicine, and the American Heart Association.

About the Gladstone Institutes

To ensure our work does the greatest good, the Gladstone Institutes focuses on conditions with profound medical, economic, and social impact--unsolved diseases of the brain, the heart, and the immune system. Affiliated with the University of California, San Francisco, Gladstone is an independent, nonprofit life science research organization that uses visionary science and technology to overcome disease.

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