What's the Mu variant? And will we keep seeing more concerning variants?
- Written by Paul Griffin, Associate Professor, Infectious Diseases and Microbiology, The University of Queensland
This week the World Health Organization named a new “variant of interest” of the coronavirus, called the Mu variant. It was first found in Colombia in January 2021, and has been found in about 39 countries so far[1].
Mu has changes, called mutations, which mean it might be able to evade some of the protection we get from COVID vaccines.
But one reassuring element is that, despite being around since January 2021, it doesn’t seem to be outcompeting Delta, the dominant variant across most of the world.
If Mu was truly a really bad variant, we would have expected to have started to see indications of this, and we haven’t yet.
Read more: Coronavirus variants have new names: we can finally stop stigmatising countries[2]
What’s a variant of interest?
An impressive element of our COVID response has been frequent genomic sequencing, which we haven’t done before on this scale. This tracks and maps the evolution of the virus in real time, as it adapts and mutates.
Some mutations will be detrimental to the virus, but some will be beneficial, allowing it to spread better, escape the protection offered by vaccines or even evade COVID tests.
If there are changes to the virus that mean it looks like it has the potential to do more harm, then we might designate it a “variant of interest”.
Mu has mutations that might confer some of these properties, but evidence is still emerging.
The four other variants of interest are Eta, Iota, Kappa and Lambda.
If there’s good evidence Mu is more serious and beginning to overtake other variants such as Delta, it might be upgraded to a “variant of concern”. The four variants of concern are Alpha, Beta, Gamma and Delta.
Can it escape vaccines?
Most COVID vaccines target the “spike protein” of the virus, which it uses to enter our cells. Our vaccines expose our bodies to a part of the virus, commonly the spike protein, so our immune system can learn to fight the virus off if it encounters it.
If a variant has significant changes in the spike protein, this may decrease the effectiveness of our vaccines.
Read more: There's no need to panic about the new C.1.2 variant found in South Africa, according to a virologist[3]
The WHO said preliminary evidence suggests the Mu variant could partially evade the antibodies we get from vaccination[4].
But because this data is from lab studies, we can’t be sure how the variant will actually play out in the population.
We need more research to be certain about how it behaves in humans, and work on this is ongoing.
The good news is our vaccines currently protect well against symptomatic infection and severe disease from all variants of the virus so far.
Vaccines may not protect forever
There’s a high probability a new variant will arise one day that can significantly escape the protection offered by our vaccines, which are based on the original strain of the virus. We would call this an “escape variant”.
It’s hard to know if and when this would happen, but rampant community transmission of the virus increases the chances of such a variant emerging.
Read more: How will Delta evolve? Here's what the theory tells us[5]
However, the leading COVID vaccine manufacturers are well prepared if this eventuates. Some are already developing vaccines for new variants, such as Delta[6].
If we did discover an escape variant, some vaccine manufacturers could alter their existing vaccines to match the new variant, possibly within 6-8 weeks. Medical regulators around the world would likely accelerate the approval process to make this possible. Certain studies would be required but these could be done quickly, so long as the new vaccine had basically the same properties as the existing vaccine.
Virginia Mayo/APIt’s possible we could see a variant overtake Delta in terms of infectiousness eventually. Scientists think it’s at least 50% more infectious than the Alpha variant[7], which was about 50% more infectious than the original strain.
Evolutionary theory predicts the virus may become more transmissible over time, but less severe, as a virus wants to spread as much as possible and doesn’t want to kill its host before it can do so. But this may not necessarily be how SARS-CoV-2 plays out, and realistically we’re still in the early days of this virus.
The best way of combating variants is to get as many people vaccinated as possible, so there are fewer susceptible hosts for the virus to reproduce and mutate.
Read more: New COVID variants have changed the game, and vaccines will not be enough. We need global 'maximum suppression'[8]
There is a risk that once we have the majority of the world vaccinated, vaccines may place “selective pressure” on the virus to evolve to escape vaccines. But the benefits of having more people vaccinated outweighs this risk.
I don’t think it’s time to be concerned about Mu yet. If it became a “variant of concern”, then we might be more worried. But we have some amazing tools to fight this virus, including many successful vaccines — the majority of which can be adapted quickly to new variants.
It’s likely we’ll have regular booster shots to protect us against variants in the future.
References
- ^ in about 39 countries so far (www.who.int)
- ^ Coronavirus variants have new names: we can finally stop stigmatising countries (theconversation.com)
- ^ There's no need to panic about the new C.1.2 variant found in South Africa, according to a virologist (theconversation.com)
- ^ partially evade the antibodies we get from vaccination (www.who.int)
- ^ How will Delta evolve? Here's what the theory tells us (theconversation.com)
- ^ such as Delta (investors.biontech.de)
- ^ at least 50% more infectious than the Alpha variant (www.abc.net.au)
- ^ New COVID variants have changed the game, and vaccines will not be enough. We need global 'maximum suppression' (theconversation.com)