Millions of people around the world have received two shots of Sinovac-CoronaVac COVID-19 vaccine, a Chinese-manufactured inactive vaccine that is used in 48 countries to help reduce transmission rates of COVID-19.
However, those vaccinations alone are of no help against the widely circulating Omicron variant, show a new study by researchers at Yale and the Dominican Republic. The results are published in the journal Nature Medicine.
An analysis of blood serum from 101 individuals from the Dominican Republic showed that Omicron infection produced no neutralizing antibodies among those who received the standard two-shot regimen of the Sinovac vaccine. Antibody levels against Omicron rose among those who had also received a booster shot of the mRNA vaccine made by Pfizer-BioNTech.
But when researchers compared these samples with blood serum samples stored at Yale, they found that even those who had received two Sinovac shots and a booster had antibody levels that were only about the same as those who’d received two shots of the mRNA vaccines but no booster shot. In other studies, the two-shot mRNA regimen without a booster has been shown to offer only limited protection against Omicron.
Also, the researchers found that individuals who had been infected by earlier strains of the SARS-Cov-2 virus saw little immune protection against Omicron.
The findings will likely complicate global efforts to combat the Omicron strain, which has supplanted the more dangerous but less transmissible Delta strain as the most dominant circulating virus in much of the world. An additional booster shot — and possibly two — are clearly needed in areas of the globe where the Sinovac shot has been chief source of vaccination, said Akiko Iwasaki, the Waldemar Von Zedtwitz Professor of Immunobiology and senior author of the paper.
“Booster shots are clearly needed in this population because we know that even two doses of mRNA vaccines do not offer sufficient protection against infection with Omicron,” Iwasaki said.
Omicron has proven particularly problematic to combat because it possesses 36 mutations on the spike proteins on its surface, which the virus uses to enter cells, researchers say. Existing mRNA vaccines are designed to trigger antibody response when spike proteins are recognized.
Iwasaki stressed, however, that the human immune system still has other weapons it can use against COVID-19, such as T cells that can attack and kill infected cells and prevent severe disease.
“But we need antibodies to prevent infection and slow transmission of the virus,” she said.
Materials provided by Yale University. Content may be edited for clarity, style, and length.