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In a study published in Science, researchers found that the defense protein "Resistin like molecule gamma" (Relmy), produced by neutrophils, punches holes into heart cells after a heart attack. This promotes dangerous, fast, and irregular heart rhythm and cell death in the heart.

The paper is titled "Resistin-like molecule γ attacks cardiomyocyte membranes and promotes ventricular tachycardia." Nina Kumowski, MD, of the Department of Radiology and Center for Systems Biology at Massachusetts General Hospital is the lead author, and Matthias Nahrendorf, MD, Ph.D. of the Department of Radiology and Center for Systems Biology at MGH is the senior author.

In MI, the blockage of a heart artery leads to insufficient oxygen supply to heart muscle cells (cardiomyocytes). This compromises their ability to maintain a stable rhythm and can give rise to a dangerous, unstable heart rhythm (arrhythmia) called ventricular tachycardia (VT) and ventricular fibrillation (VF).

VT and VF are both serious arrhythmias that can lead to sudden cardiac arrest and death within minutes. In VT, the heart beats very rapidly, but in a coordinated rhythm. In VF, the rhythm is chaotic and uncoordinated.

Most arrhythmias occur within 48 hours after MI and coincide with massive immune cell infiltration into the heart tissue. The researchers were interested in how these immune cells may promote arrhythmia.

The research team found neutrophils that get recruited into the infarct (the area of dead tissue resulting from the cutoff of oxygen supply) in large numbers upregulate the gene "Retnlg, " coding the protein resistin like molecule gamma (RELMy).

They also found a comparable gene, "RETN, " in human infarcted heart tissue. When this protein was removed from neutrophils in mice, the arrhythmia burden after MI was reduced 12-fold.

The team was investigating the question of how neutrophils, a specific kind of immune cell, promote ventricular arrhythmia (a dangerous fast irregular heartbeat) after heart attacks. Cardiomyocytes as the main actors in arrhythmia are very well studied, but if and how immune cells can promote arrhythmia is less clear.

This work is important because ventricular arrhythmia is the most lethal complication after myocardial infarction. Understanding better what promotes arrhythmia will help the development of new antiarrhythmic drugs.

The researchers used a plethora of methods to figure this out. For an initial understanding about which proteins in neutrophils might be important, they used deposited data on gene expression generated by single cell and spatial RNA sequencing from mice that underwent myocardial infarction. They also used data from human studies to find similarities in human tissue.

They also relied on confocal and super-high resolution microscopy in isolated mouse heart muscle cells that were treated with the labeled protein. Further, the team deployed in vitro assays such as a liposome model and cell culture techniques to investigate the mouse and the human version of the protein to find out if they work similar.

They found that after MI in mouse models, neutrophils upregulate the expression of "Retnlg, " the gene coding for RELMy. The team also found that the human biological homolog "RETN, " the gene coding for Resistin, was higher expressed in human infarcted myocardial tissue compared to non-infarcted tissue, similar to mice.

They saw that deleting the gene from bone marrow-derived cells (such as neutrophils) and deleting the gene from neutrophils specifically significantly reduced incidents of ventricular arrhythmia in the mouse models.

The implications are that immune cells play a crucial role in sudden death and arrhythmia.

The researchers say physicians should think about treating the myocardial infarction by quick recanalization of the vessel to restore oxygenated blood supply and also target immune cells to mitigate the arrhythmic effects of the injury.

"When we understand the underlying mechanisms better, we can pursue therapeutic targets that go beyond the broad immune suppression that is used today, " they say. "If we can treat targets more specifically, we can reduce unwanted side effects and unravel the full potential of immune modulation in cardiovascular disease."

The next steps are to find a way to neutralize the harmful protein and test if this can reduce VT burden and infarct size. First in the mouse models, but, eventually also in humans.

More evidence about the significance of this protein in human disease should be gathered, the researchers say. It is also interesting to see these findings have implications for other diseases with neutrophil recruitment and activation.

More information: Nina Kumowski et al, Resistin-like molecule γ attacks cardiomyocyte membranes and promotes ventricular tachycardia, Science (2025). DOI: 10.1126/science.adp7361  Journal information: Science