Some covid transformations may help it evade immune system's T-killer cells, say researchers

Some covid transformations may help it evade immune system's T-killer cells, say researchers

• By Staff Writer

Some covid transformations may help it evade immune system's T-killer cells, say researchers

Some mutations in the novel coronavirus may not only enable it to evade antibodies, but also make the virus unrecognisable to the immune system's T-killer cells, says a new study which could aid in the further development of vaccines. While antibodies dock directly onto viruses to neutralise them, the scientists, including those from the Medical University of Vienna in Austria, said the T-killer cells acknowledge viral protein fragments on infected cells and subsequently kill them to stop virus production.

In the current study, published in the journal Cell Immunology, the researchers sequenced 750 genomes of the novel covid from infected individuals and examine mutations for their potential to alter T cell epitopes.

These are regions on the virus recognised by the body's T cells.

"Our results show that many mutations in SARS-CoV-2 are actually capable of doing this," said study co-author Andreas Bergthaler.

"With the assistance of bioinformatic and biochemical investigations as well as laboratory experiments with blood cells from COVID-19 patients, we were able to show that mutated viruses can no longer be recognized by T-killer cells in these regions," Bergthaler added.

According to the researchers, there are several epitopes available for recognition by T-killer cells in most natural infections, and if the virus mutates in one place, other sites on its surface may still indicate its presence to T cells.

They said the spike protein of the virus, which it uses to enter cells and against which most vaccines are targeted, has, on average, one to six of these T cell epitopes.

"If the virus mutates in one of these regions, the risk that the infected cells will not be recognized by the T-killer cells increases," explained Johannes Huppa, another co-author of the study.

"Especially for the further development of vaccines, we therefore have to keep a close eye on how the virus mutates and which mutations prevail globally. Currently, we see few indications that mutations in T killer cell epitopes are increasingly spreading," added Judith Aberle, another of the study's co-authors from the Medical University of Vienna.

The scientists believe the findings issue important insights on how the novel coronavirus interacts with the immune system.

"Furthermore, this knowledge helps to develop extra productive vaccines with the potential to activate as many T-killer cells as possible via a variety of epitopes," the scientists said.

"The goal are vaccines that trigger neutralizing antibody and T killer cell responses for the broadest possible protection," they wrote in the study.