In a recent study, found in Cell Reports.
New research from
The research identifies the vulnerable sites on the spike protein that can be targeted by human antibodies, providing valuable information for the development of future vaccines and antibody treatments.
Preclinical studies in mice suggest that some of these antibodies may also be effective in preventing severe cases of COVID-19.
"To blunt the next pandemic and protect people from seasonal re-emergence of this one, we need antibodies of the broadest possible capacity—ones that are not escaped,” says LJI President and CEO
In reference to the study participant who had displayed the effective antibodies, LJI Instructor
Uncovering antibodies to combat COVID-19 variants
Scientists in
In the new study, antibodies were obtained from a clinical studies volunteer who received two doses of the Moderna SARS-CoV-2 vaccine. The vaccine prompts the body to produce the spike protein, which allows the immune system to develop antibodies against the real virus. The samples used in the study were collected before the emergence of Omicron, therefore any antibodies produced were due to vaccination rather than exposure to Omicron.
The emergence of the SARS-CoV-2 Omicron variant in late 2021 was marked by its ability to quickly spread, owing to mutations that helped it evade immune cell protection. Unlike earlier SARS-CoV-2 variants, many antibodies designed to fight them were unable to target Omicron.
Winning antibodies unveiled
The composition of virus-fighting cells and antibodies differs among individuals. In this study, researchers started with a pool of antibodies from a
"We found that this pool of antibodies could also neutralise other variants, such as Delta and Omicron," relayed Hastie.
The researchers discovered that the volunteer still had significant levels of antibodies against the Beta, Delta and Omicron variants of SARS-CoV-2. They identified five antibodies that were particularly effective at reducing the infectivity of the BA.1 variant by more than 85 percent.
The researchers then conducted additional tests on these five antibodies; one of which, 1C3, showed potential in blocking a step in the infection process where the virus’s receptor binding domain interacts with human protein ACE2. However, this was only effective against BA.1 and BA.2 lineages. Another antibody, 1H2, was able to neutralise certain Omicron lineages but in a different manner than 1C3. Antibody 2A10 was able to react with all SARS-CoV-2 Omicron lineages tested, including the most prevalent ones such as XBB and BQ1.
Mapping vulnerabilities of SARS-CoV-2 spike protein
The researchers utilised cryo-electron microscopy, a high-resolution imaging technique, to map out the vulnerabilities on the spike protein. “We were really interested to see how these antibodies recognise the spike protein and structure,” says LJI Postdoctoral Fellow
Two of the antibodies studied were found to bind to two different parts of the spike protein simultaneously, according to high-resolution imaging conducted using cryo-electron microscopy. This binding mechanism locks the viral structure in place and effectively prevents infection by the virus. This finding is consistent with another recent Cell Reports study from the
The three promising antibodies identified in the study showed potential in reducing the viral load in the lungs of mice infected with SARS-CoV-2 BA.1 and BA.2 when administered alone. This suggests that they could be used in the development of antibody therapeutics to treat COVID-19.
The researchers plan to continue their work by using the same pipeline to study more human antibodies. By doing so, they hope to find more potential targets for future vaccine development and therapeutics that can help combat COVID-19 and its variants. “We can carry out the entire pipeline of antibody discovery now,” says Yu. “This research will help us combat the variants we have right now and give us targets for future vaccine development and therapeutics.”
References
Fang Li [Internet]. [cited 2023 May 11]. Available from: https://www.annualreviews.org/doi/abs/10.1146/annurev-virology-110615-042301
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