News Release

How three mutations work together to spur new SARS-CoV-2 variants

Peer-Reviewed Publication

American Chemical Society

How three mutations work together to spur new SARS-CoV-2 variants

image: The researchers tested how three mutations altered the interaction between a key part of the virus (gray) and the human protein to which it attaches (orange). view more 

Credit: Adapted from Biochemistry 2022, DOI: 10.1021/acs.biochem.2c00132

Like storm waves battering a ship, new versions of the SARS-CoV-2 virus have buffeted the world one after another. Recently, scientists keeping tabs on these variants noticed a trend: Many carry the same set of three mutations. In a new study in ACS’ Biochemistry, researchers examined how these mutations change the way a key piece of the virus functions. Their experiments show how this triad alters traits it needs to cause and sustain COVID-19 infection.

The virus SARS-CoV-2 has forced human cells to copy its genetic code innumerable times over the past couple of years, and, in the process, errors have emerged. These errors, or mutations, are the raw material for new variants. Scientists have found that nearly half of the genetic sequences within variants contain three mutations at positions called K417, E484 and N501. All of these changes tweak the same part of the virus, known as the receptor binding domain, which enables SARS-CoV-2 to infect human cells by latching onto their ACE2 protein. The widespread presence of this combination suggests that together, these mutations provide the virus with benefits not possible with a single change. Vaibhav Upadhyay, Krishna Mallela and colleagues wanted to tease out the advantages — and drawbacks — of each of these three mutations individually and in combination.  

As a first step, the researchers produced domains containing the mutations and studied their effects in cells grown in Petri dishes. The team looked at how well cells could produce the domain, as well as the domain’s stability, ability to bind to ACE2 and ability to evade antibodies. The results showed that each mutation enhances at least one of these characteristics, but at a cost. The K417 change, for example, increased the production and stability of the domain, while also improving its ability to escape one type of antibody. However, it also decreased the domain’s ability to attach to ACE2. The other two mutations had differing strengths and weaknesses. But, when put all together, the changes mitigated one another’s negative effects. Domains with all three mutations could bind ACE2 tightly and escape two types of antibodies, yet also were produced at similar levels as the original virus and were just as stable. By revealing the details of how natural selection can favor a combination of a mutations, these results offer new insight into virus evolution, according to the researchers. 

The authors acknowledge funding from the University of Colorado Skaggs School of Pharmacy and Pharmaceutical Sciences.

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