News Release

Surprise COVID discovery helps explain how coronaviruses jump species

New insights boost scientists’ efforts to stay ahead of COVID-19, next pandemic

Peer-Reviewed Publication

University of Virginia Health System

Surprise COVID discovery helps explain how coronaviruses jump species

image: “The virus that causes COVID-19 uses ACE2 as the front door to infect cells, but we’ve found that if the front door is blocked, it can also use the back door or the windows,” said researcher Peter Kasson, MD, PhD, of the University of Virginia School of Medicine. “This means the virus can keep spreading as it infects a new species until it adapts to use a particular species’ front door. So we have to watch out for new viruses doing the same thing to infect us.” view more 

Credit: UVA Health

Unexpected new insights into how COVID-19 infects cells may help explain why coronaviruses are so good at jumping from species to species and will help scientists better predict how COVID-19 will evolve.

Throughout the pandemic, there has been much discussion of how COVID-19 infiltrates cells by hijacking a protein called ACE2 found on human cells. But the new research from the School of Medicine reveals that ACE2 isn’t required for infection. Instead, the virus has other means it can use to infect cells. 

That versatility suggests that coronaviruses can use multiple “doors” to enter cells, potentially explaining how they are so good at infecting different species.

“The virus that causes COVID-19 uses ACE2 as the front door to infect cells, but we’ve found that if the front door is blocked, it can also use the back door or the windows,” said researcher Peter Kasson, MD, PhD, of UVA’s Departments of Molecular Physiology and Biomedical Engineering. “This means the virus can keep spreading as it infects a new species until it adapts to use a particular species’ front door. So we have to watch out for new viruses doing the same thing to infect us.”

Understanding COVID-19

COVID-19 has killed almost 7 million people around the world. Thankfully, the availability of vaccines and the increase in population immunity means that the virus is no longer the threat it once was to most people (though it remains a concern for groups such as the immunocompromised and elderly). With the expiration of the United States’ official Public Health Emergency in May, most Americans have largely returned to lives similar to the ones they knew before the pandemic emerged in 2019. But COVID-19 continues to evolve and change, and scientists are keeping a close eye on it so that they can take quick action if a more dangerous variant emerges. They also continue to monitor other coronaviruses in case they jump to humans and become the next great public health threat. 

As part of this effort, Kasson and his team wanted to better understand how the virus responsible for COVID-19, SARS-CoV-2, can enter human cells. Scientists have known that the virus essentially knocks on the cell’s door by binding to ACE2 proteins. These proteins are bountiful on the surfaces of cells lining the nose and lungs.

SARS-CoV-2 can also bind with other proteins, however. Was it possible, the scientists wondered, that it could use those other proteins to infiltrate cells? The answer was yes. ACE-2 was the most efficient route, but it was not the only route. And that suggests that the virus can bind and infect even cells without any ACE-2 receptors at all.

That unexpected finding may help explain why coronaviruses are so adept at species-hopping, Kasson says. And that makes it even more important that scientists keep a close eye on them, he notes.

“Coronaviruses like SARS-CoV-2 have already caused one pandemic and several near misses that we know of,” he said. “That suggests there are more out there, and we need to learn how they spread and what to watch out for.”

Findings Published

The scientists have published their findings in the scientific journal Chemical Science. The research team consisted of Marcos Cervantes, Tobin Hess, Giorgio G. Morbioli, Anjali Sengar and Kasson. The researchers have no financial interest in the work.

The work was supported by the Commonwealth Health Research Board, grant 207-01-18; UVA’s Global Infectious Diseases Institute; and the Knut and Alice Wallenberg Foundation, grant KAW2020.0209.

UVA’s Department of Biomedical Engineering is a joint program of its School of Medicine and School of Engineering and Applied Science.

To keep up with the latest medical research news from UVA, subscribe to the Making of Medicine blog.


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