Cell membranes play a larger role than thought in allowing spike proteins on viruses to infect cells


University of Alberta research shows how cell membranes play a much larger role than previously understood in allowing spike proteins on viruses to infect cells. The findings, published in the journal iScience, could give scientists the upper hand in tackling SARS-CoV-2—the virus that causes COVID-19—and other potentially deadly viruses.

The team of researchers, led by U of A professor of biochemistry Michael Overduin, used software called Membrane Optimal Docking Area (MODA) to identify interactions between proteins and membranes within cells.

When the COVID-19 pandemic shut down labs at the U of A, Troy Kervin, an undergraduate student in Overduin’s lab, shifted his research to work he could do outside of the lab. He assembled all the proteins in one family of membrane-binding domains, and used MODA to predict which regions on the domains bind to membranes. He found that cell membranes—the barrier around cells made of fat molecules called lipids—play a more significant role in viruses binding to cells than previously thought.

Those findings became the foundation for additional research about cell-binding activity, namely if spike proteins—such as those found on the SARS-CoV-2 virus—bind to membranes.

The consensus in the scientific community has been that the job of spike proteins in SARS-CoV-2 is to bind to angiotensin converting enzyme-2 (ACE-2) receptors that are on the outside of cells, not to the cell membrane.

With the help of another undergraduate student, Anh Tran, the team began the process of using MODA to compare a large number of structures of spike proteins in both the original—or ‘wild type’—virus and the variants.

“We found out how the spike protein engages the lipids of our lung cells and gets in. Then we found that the Omicron variant was super active. We thought that’s really, really exciting. Maybe that’s contributing to how it gets in easier and spreads more quickly,” says Overduin.

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