News Release

A second chance for a healthy heart

Researchers use cellular reprogramming to make damaged organ almost good as new

Peer-Reviewed Publication

American Society for Biochemistry and Molecular Biology

Cardiac muscle cells

image: Cardiac muscle cells derived from cardiac fibroblasts. Fibroblast marker Fsp1 (red), cardiac muscle cell marker troponin I (green) and nuclei (blue). view more 

Credit: Conrad Hodgkinson

A recent study using mice has revealed a way to turn back the clock after heart attack. The researchers behind the work used RNAs to instruct cells in an injured heart to eliminate scar tissue and recreate cardiac muscle, allowing the heart to function like new again.

Cardiovascular disease, including heart attack, is the leading cause of death worldwide.

“Adult human hearts are not very good at repairing themselves,” said Conrad Hodgkinson, an associate professor of medicine and pathology at Duke University School of Medicine who oversaw the study. “Once they have a heart attack or any type of damage, there's no capacity to replace the heart muscle that dies. So, what the heart does to stop itself from basically blowing up is it activates fibroblasts to come in and form a scar.”

Like the scars on skin that result from injury or surgery, the scar tissue generated in the heart after a heart attack is tough and nonflexible and can prevent the organ from functioning at its full potential, Hodgkinson said.

Hodgkinson and his team wanted to find an efficient way to convert the scar tissue back into functioning cardiac muscle to essentially reverse the effects of a heart attack. To do this, they set out to find a way to transform fibroblasts, a type of cell that contributes to the formation of connective tissue, into heart muscle cells via a process called cellular reprogramming. Hodgkinson’s lab delivers reprogramming instructions to cells in form of RNAs. However, they found adult fibroblasts are not very good at following the instructions and are resistant to reprogramming.

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“We found that if you take cardiac fibroblasts from juveniles, they reprogram very nicely,” Hodgkinson said. “But, if you take cardiac fibroblasts from adults, they don't, in fact, respond at all. So, we tried to understand whether the aging process was actually interfering with fibroblast reprogramming.”

Hodgkinson and his team discovered that a protein oxygen sensor, Epas1, prevents adult fibroblasts from reprogramming themselves. The researchers were able to harness the regenerative capacity of young cells by blocking Epas1 in adult fibroblasts.

“When we reversed the fibroblast aging process, essentially making the fibroblasts think they were young again, we converted more fibroblasts into cardiac muscle,” Hodgkinson said.

The researchers formulated a cocktail of RNAs and packaged them into exosomes, a natural product produced by most cells. This technology allowed them to deliver the exosomes without surgical interventions. Exosome packages have unique properties that guide them to cardiac fibroblasts inside an injured heart.

“Exosomes are kind of like shopping bags,” Hodgkinson said. “The cell sticks a lot of stuff into a big fat ball to send out and signal to other cells. They are a way cells can talk to each other.”

When the researchers used the RNA-filled exosomes to instruct the fibroblasts to reprogram themselves in a mouse that had just experienced a heart attack, the results were, according to Hodgkinson, “impressive.”

“We were able to recover almost all of the cardiac function that was lost after a heart attack by reversing the aging of the fibroblasts in the heart,” Hodgkinson said. Their findings were published in the Journal of Biological Chemistry

Cellular reprogramming, coupled with reversing cellular aging, has limitless future applications, including restoring neuron loss in the brains of dementia patients and eliminating skin scarring in psoriasis patients without invasive surgical interventions, Hodgkinson said.

About the American Society for Biochemistry and Molecular Biology (ASBMB) The ASBMB is a nonprofit scientific and educational organization with more than 12,000 members worldwide. Founded in 1906 to advance the science of biochemistry and molecular biology, the society publishes three peer-reviewed journals, advocates for funding of basic research and education, supports science education at all levels, and promotes the diversity of individuals entering the scientific workforce. For more information about the ASBMB, visit

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