According to a new study published in the journal Science, the mechanical load from the constant beating of the heart might be aiding in consistently suppressing the growth of cancer cells, offering an explanation as to why cancer of the blood-pumping organ is rare.

Cellular pathways in tissues of the heart alter gene regulation in cancer cells to keep them from proliferating, researchers said.

Findings published in the journal Science shed light on how mechanical forces could be important in protecting the heart from cancer and may pave the way to new cancer therapies based on mechanical stimulation.

Researchers, including those from the International Centre for Genetic Engineering and Biotechnology in Italy, said cancer rarely forms in or metastasises to the heart, suggesting "there is something" in the cardiac microenvironment that inhibits cancer growth.

They proposed an explanation, pointing to the intense mechanical demands placed on heart tissues, which must continuously pump blood against significant resistance -- the persistent strain could suppress the heart cells' ability to proliferate.

The pressures may also inhibit cancer cells in the heart from proliferation, the team said and added that however, the mechanisms underlying the resistance remain unclear.

For the study, the authors developed a transplantation model in which the heart's mechanical workload could be reduced.

They grafted a donor heart into the neck of a compatible mouse to create a "mechanically unloaded" organ, one that remained perfused with blood but did not bear a physiological strain.

The team injected human cancer cells directly into the heart muscle and compared tumour behaviour in the unloaded transplanted heart with that in the animal's native, mechanically active heart.

The researchers found that the mechanical load consistently suppressed the growth of varied cancer types, while unloading the heart promoted tumour cell proliferation within the cardiac tissue.

"A key potential explanation is mechanical load," the authors said.

Mechanical forces within the tissue reshape the cancer cell genome's regulatory landscape, influencing whether cells can proliferate, they said.

Central to the process is Nesprin-2, a protein that transmits mechanical signals from the cell surface to the nucleus, the team said.

The protein senses the mechanical microenvironment of the heart and functionally alters chromatin structure and histone methylation -- both are methods which control gene expression -- reducing gene activity linked to tumour cell proliferation, the researchers said.

Silencing Nesprin-2 in cancer cells was related with the cells regaining the ability to grow in the mechanically active environment of the heart, forming tumours.

"The authors determined that increased mechanical load promoted Nesprin-2 signalling, which then led to changes in chromatin compaction and histone methylation, resulting in the suppression of cancer growth," the study said.

With inputs from PTI