Researchers in South Africa are racing to track the concerning rise of a new variant of the SARS-CoV-2 coronavirus that causes COVID-19. The variant harbours a large number of the mutations found in other variants, including Delta, and it seems to be spreading quickly across South Africa.
A top priority is to follow the variant more closely as it spreads: it was first identified in Botswana earlier this month and has since turned up in a traveller arriving in Hong Kong from South Africa. Scientists are also trying to understand the variant’s properties, such as whether it can evade immune responses triggered by vaccines and whether it causes more or less severe disease than other variants do.
“We’re flying at warp speed,” says Penny Moore, a virologist at the University of the Witwatersrand in Johannesburg, South Africa, whose lab is gauging the variant’s potential to dodge immunity from vaccines and previous infections. There are anecdotal reports of reinfections and of cases in vaccinated individuals, but “at this stage it’s too early to tell anything”, Moore adds.
“There’s a lot we don’t understand about this variant,” Richard Lessells, an infectious-diseases physician at the University of KwaZulu-Natal in Durban, South Africa, said at a press briefing organized by South Africa’s health department on 25 November. “The mutation profile gives us concern, but now we need to do the work to understand the significance of this variant and what it means for the response to the pandemic.”
On 26 November, the World Health Organization (WHO) designated the strain, known as B.1.1.529, as a variant of concern and named it Omicron, on the advice of scientists who are part of the WHO’s Technical Advisory Group on SARS-CoV-2 Virus Evolution. Omicron joins Delta, Alpha, Beta and Gamma on the current WHO list of variants of concern.
Researchers also want to measure the variant’s potential to spread globally—possibly sparking new waves of infection or exacerbating ongoing rises being driven by Delta.
Changes to spike
Researchers spotted B.1.1.529 in genome-sequencing data from Botswana. The variant stood out because it contains more than 30 changes to the spike protein—the SARS-CoV-2 protein that recognizes host cells and is the main target of the body’s immune responses. Many of the changes have been found in variants such as Delta and Alpha, and are linked to heightened infectivity and the ability to evade infection-blocking antibodies.
The apparent sharp rise in cases of the variant in South Africa’s Gauteng province—home to Johannesburg—is also setting off alarm bells. Cases increased rapidly in the province in November, particularly in schools and among young people, according to Lessells. Genome sequencing and other genetic analysis from a team led by Tulio de Oliveira, a bioinformatician at the University of KwaZulu-Natal, found that the B.1.1.529 variant was responsible for all 77 of the virus samples they analysed from Gauteng, collected between 12 and 20 November. Analysis of hundreds more samples are in the works.
The variant harbours a spike mutation that allows it to be detected by genotyping tests that deliver results much more rapidly than genome sequencing does, Lessells said. Preliminary evidence from these tests suggest that B.1.1.529 has spread considerably further than Gauteng. “It gives us concern that this variant may already be circulating quite widely in the country,” Lessells said.
To understand the threat B.1.1.529 poses, researchers will be closely tracking its spread in South Africa and beyond. Researchers in South Africa mobilized efforts to quickly study the Beta variant, identified there in late 2020, and a similar effort is starting to study B.1.1.529.
Moore’s team—which provided some of the first data on Beta’s ability to dodge immunity—has already begun work on B.1.1.529. They plan to test the virus’s ability to evade infection-blocking antibodies, as well as other immune responses. The variant harbours a high number of mutations in regions of the spike protein that antibodies recognize, potentially dampening their potency. “Many mutations we know are problematic, but many more look like they are likely contributing to further evasion,” says Moore. There are even hints from computer modelling that B.1.1.529 could dodge immunity conferred by another component of the immune system called T cells, says Moore. Her team hopes to have its first results in two weeks.
“A burning question is ‘does it reduce vaccine effectiveness, because it has so many changes?’,” says Aris Katzourakis, who studies virus evolution at the University of Oxford, UK. Moore says breakthrough infections have been reported in South Africa among people who have received any of the three kinds of vaccines in use there, from Johnson & Johnson, Pfizer–BioNTech and Oxford–AstraZeneca. Two quarantined travellers in Hong Kong who have tested positive for the variant were vaccinated with the Pfizer jab, according to news reports. One individual had travelled from South Africa; the other was infected during hotel quarantining.
Researchers in South Africa will also study whether B.1.1.529 causes disease that is more severe or milder than that produced by other variants, Lessells said. “The really key question comes around disease severity.”
So far, the threat B.1.1.529 poses beyond South Africa is far from clear, researchers say. It is also unclear whether the variant is more transmissible than Delta, says Moore, because there are currently low numbers of COVID-19 cases in South Africa. “We’re in a lull,” she says. Katzourakis says that countries where Delta is highly prevalent should be watching for signs of B.1.1.529. “We need to see what this virus does in terms of competitive success and whether it will increase in prevalence.”
This article is reproduced with permission and was first published on November 25 2021.