Why virus variants are causing alarm

An Accredited Social Health Activist (ASHA) nurse returns the remaining vaccines from a ‘door-to-door’ vaccination drive to a cold storage facility at a hospital in the Budgam district of Jammu and Kashmir, India, on Aug. 3. Sumit Dayal/Bloomberg

Viruses mutate all the time, including the one, SARS-CoV-2, that’s caused the COVID-19 pandemic. Although most genetic changes are innocuous, some can make the mutant more adept at infecting cells, for example, or evading antibodies. Such “fitter” variants can outcompete other strains, so that they become the predominant source of infections. A succession of more-transmissible variants has emerged over the past year, each harboring a constellation of mutations. The most worrisome so far is the so-called delta variant. It’s become dominant in much of the world since its discovery in India in October, leading to surges in cases and hospitalizations, especially in places where less than half the adult population has been fully immunized.

1. What’s a variant?

During replication, a virus often undergoes genetic changes that may create what are called variants. Some mutations weaken the virus; others may yield an advantage that enables it to proliferate. If changes produce a version with distinctly different physical characteristics, the variant may be co-termed a strain. A variant that deviates significantly from its viral ancestors may be identified as a new lineage, or branch on the evolutionary tree. In general discourse, however, the terms are often used interchangeably.

2. What are the most worrisome ones?

The World Health Organization uses “variants of concern” to signify strains that pose additional risks to global public health, “variants of interest” for those that warrant close monitoring because of their emerging risk, and “alerts for further monitoring” for a variant that possesses genetic characteristics that indicate it may pose a future risk. Assessments may change depending on the evolving pandemic. Variants of concern and variants of interest are assigned letters from the Greek alphabet for identification. As of Aug. 25, the WHO has identified four in each category:

n Alpha: This variant emerged in England in September 2020 and drove a surge in cases that sent the U.K. back into lockdown in January. Other countries, particularly in Europe, followed the U.K. in reimposing movement restrictions. Alpha was previously the dominant strain in the U.S., and has been reported in at least 192 countries, according to the WHO.

n Beta: This one, which appeared in South Africa in August 2020, led to a resurgence in COVID cases that overwhelmed southern Africa. It’s been reported in at least 141 countries.

n Gamma: This variant, first spotted in the Amazon city of Manaus in December 2020, has contributed to a surge in cases that strained Brazil’s health system and led to oxygen shortages. It’s been reported in at least 86 countries.

n Delta: This fast-spreading variant has since been found in at least 163 countries since helping to drive an unprecedented wave of COVID cases in India. It’s estimated to be 55% more transmissible than alpha and almost twice as infectious as the original strain from early 2020. That may be because those infected with the variant can have significantly more infectious viral particles in their airways compared with individuals infected with other strains. Those particles appear to have better affinity with ACE2, the enzyme on the surface of cells that the virus targets to start an infection.

3. Is delta more virulent?

Possibly as it appears patients are more likely to be hospitalized with delta than with the previously dominant alpha strain. A large U.K. study published in Lancet Infectious Diseases showed COVID-19 patients have a 2.3 times increased risk of being hospitalized within two weeks if they have delta compared with an alpha infection. That fit with an earlier study from Scotland that showed the risk of hospital admission was almost doubled in those with delta versus alpha. Doctors in India have linked delta to a broader array of COVID symptoms, including hearing impairment. Other evidence found delta had some propensity to evade antibody-based treatments and carries an increased risk of reinfection in people who have recovered from COVID caused by another strain.

4. How do variants affect the vaccines?

Scientists pay the most attention to mutations in the gene that encodes the virus’s spike protein, which plays a key role in its entry into cells and is targeted by vaccines. The four variants of concern all carry multiple mutations affecting the spike protein. That raises questions about whether people who have developed antibodies to the “regular” or “wild type” strain — either from a vaccine or from having recovered from COVID — will be able to fight off the new variants. In most instances, the variants of concern do lead to a reduction in vaccine effectiveness of varying degrees, though the shots mostly retain their ability to protect against severe disease, according to the WHO.

5. What are countries doing in response?

Waning antibody levels in some highly vaccinated populations such as Israel have prompted calls to offer third vaccine doses to blunt fresh waves of hospitalizations. The case for administering additional vaccine doses is controversial, since it’s seen as reducing supplies needed to immunize people in low- and middle-income countries, where vaccination rates remain stubbornly low.

6. What else is out there?

The WHO has highlighted the risk that more variants will emerge given the ongoing high rates of transmission globally. For example, scientists in South Africa reported in August a potential variant of interest dubbed C.1.2 that carries “concerning constellations of mutations.” It was first identified in May in the provinces of Mpumalanga and Gauteng, where Johannesburg and the capital, Pretoria, are situated. By Aug. 13, it had been found in six of South Africa’s nine provinces as well as the Democratic Republic of Congo, Mauritius, Portugal, New Zealand and Switzerland. Even in South Africa, as of late August, C.1.2 comprised just 2% of the known SARS-CoV-2 variants spreading there.

7. Are there any other implications?

Yes. There are implications for treatments, diagnostics and the spread of SARS-CoV-2 in animals.

n TREATMENTS: Researchers in South Africa found a theoretical risk that some antibodies being developed to treat COVID could be ineffective against the beta variant. But studies at Columbia University supported tests by Regeneron Pharmaceuticals Inc. showing that its antibody cocktail, which was granted emergency-use authorization in the U.S. and administered to then-President Donald Trump, is effective at neutralizing that variant as well as alpha. Drugmakers are using combinations of antibodies that target separate features of the virus to decrease the potential that so-called virus-escape mutants emerge in response to pressure from a single-antibody treatment.

n DIAGNOSTICS: The U.S. Centers for Disease Control and Prevention has said new strains might undermine the performance of some diagnostic tests that use a process called reverse transcription polymerase chain reaction (RT-PCR) to amplify the virus’s genetic material so that it can be studied in detail. A German study on rapid antigen tests — which are faster, cheaper and more accessible but less sensitive — found comparable performance in detecting the alpha, beta and wild-type variants.

n ANIMAL HOSTS: Researchers at France’s Pasteur Institute showed that the beta and gamma variants are capable of infecting common laboratory mice and replicating at high concentrations in the lungs — a feat that strains circulating earlier weren’t able to do. This raises the possibility of mice or other rodents living close to humans becoming reservoirs for SARS-CoV-2 in regions where the variants circulate, with the strains evolving and potentially spilling back to humans, the researchers said in a March 18 paper released prior to peer review.

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