you are here: HomeNewsTrendsHealth

South Africa virus strain poses 're-infection risk': study

In a new study, which has not yet been peer reviewed, researchers in South Africa tested the variant found there -- called 501Y.V2 -- against blood plasma from recovered Covid-19 patients.

January 20, 2021 / 11:32 PM IST
Representative image: Reuters

Representative image: Reuters

The coronavirus variant detected in South Africa poses a "significant re-infection risk" and raises concerns over vaccine effectiveness, according to preliminary research January 20, as separate studies suggested the British strain would likely be constrained by immunisations.

Several new variants -- each with a cluster of genetic mutations -- have emerged in recent weeks, sparking fears over an increase in infectiousness as well as suggestions that the virus could begin to elude immune response, whether from prior infection or a vaccine.

These new variants, detected from Britain, South Africa and Brazil, have mutations to the virus' spike protein, which enables the virus to latch onto human cells and therefore plays a key role in driving infections.

But it is one mutation in particular -- known as E484K and present in the variants detected in South Africa and Brazil but not the one from Britain -- that has experts particularly worried about immunity "escape".

In a new study, which has not yet been peer reviewed, researchers in South Africa tested the variant found there -- called 501Y.V2 -- against blood plasma from recovered Covid-19 patients.


COVID-19 Vaccine

Frequently Asked Questions

View more
How does a vaccine work?

A vaccine works by mimicking a natural infection. A vaccine not only induces immune response to protect people from any future COVID-19 infection, but also helps quickly build herd immunity to put an end to the pandemic. Herd immunity occurs when a sufficient percentage of a population becomes immune to a disease, making the spread of disease from person to person unlikely. The good news is that SARS-CoV-2 virus has been fairly stable, which increases the viability of a vaccine.

How many types of vaccines are there?

There are broadly four types of vaccine — one, a vaccine based on the whole virus (this could be either inactivated, or an attenuated [weakened] virus vaccine); two, a non-replicating viral vector vaccine that uses a benign virus as vector that carries the antigen of SARS-CoV; three, nucleic-acid vaccines that have genetic material like DNA and RNA of antigens like spike protein given to a person, helping human cells decode genetic material and produce the vaccine; and four, protein subunit vaccine wherein the recombinant proteins of SARS-COV-2 along with an adjuvant (booster) is given as a vaccine.

What does it take to develop a vaccine of this kind?

Vaccine development is a long, complex process. Unlike drugs that are given to people with a diseased, vaccines are given to healthy people and also vulnerable sections such as children, pregnant women and the elderly. So rigorous tests are compulsory. History says that the fastest time it took to develop a vaccine is five years, but it usually takes double or sometimes triple that time.

View more

They found that it was resistant to neutralising antibodies built up from prior infection, but said more research was needed into the effectiveness of other parts of the immune response.

"Here we show that the 501Y.V2 lineage, which contains nine spike mutations and rapidly emerged in South Africa during the second half of 2020, is largely resistant to neutralising antibodies elicited by infection with previously circulating lineages," the authors said.

"This suggests that, despite the many people who have already been infected with SARS-CoV-2 globally and are presumed to have accumulated some level of immunity, new variants such as 501Y.V2 pose a significant re-infection risk."

The researchers added that this might also affect the use of convalescent plasma as a treatment for Covid-19. They also suggested it could have "implications" for vaccines developed based on immune responses to the virus's spike protein.

Trevor Bedford of the Fred Hutchinson Research Center tweeted that this variant could "spread more widely in the coming months".

If the results of the South African study are confirmed, he said it may be necessary to adapt the virus "strain" used in developing the vaccine by autumn of this year.

The findings are "not good news but it's not unexpected," said James Naismith, Director of the Rosalind Franklin Institute, in comments to the Science Media Centre.

He said real world immune responses were more complex than those of the blood plasma neutralising antibodies.

"The vaccines do stimulate very strong responses, immunity is a sliding scale, it's not an on/off switch," he added.

- UK strain -

Two other preliminary studies posted online on Wednesday found that the antibodies from previously-infected patients are largely effective against the variant detected in Britain and that the BioNTech/Pfizer vaccine appears to be guard against it as well.

Researchers said their early findings into the fast-spreading strain, known as B.1.1.7, suggested that the variant would not be able to evade the protective effect of current vaccines.

"Our results suggest that the majority of vaccine responses should be effective against the B.1.1.7 variant," concluded researchers from Britain and the Netherlands in one of the studies.

The authors tested the UK strain in the laboratory with antibody-rich blood plasma from 36 patients who had recovered from either mild or severe forms of Covid-19 and found most were able to neutralise the variant.

A separate study by researchers from BioNTech and Pfizer compared the neutralising effect of plasma from 16 participants in their vaccine clinical trials against the British variant and the original virus that emerged in Wuhan, China.

They concluded it was "unlikely" the B.1.1.7 variant could escape the immune protection of the vaccine.
first published: Jan 20, 2021 11:32 pm

stay updated

Get Daily News on your Browser