list to monitor. It’s called the mu variant and has been designated a variant of interest (VOI). What this means is that mu has genetic differences to the other known variants and is causing infections in multiple countries, so therefore might present a particular threat to public health.The World Health Organization (WHO) has added another coronavirus variant to its
It’s possible that mu’s genetic changes might make it more transmissible, allow it to cause more severe disease and render it more able to escape the immune response driven by vaccines or infection with previous variants. This in turn might leave it less susceptible to treatments.
Note the word might. A VOI is not a variant of concern (VOC), which is a variant that has been proven to acquire one of those characteristics, making it more dangerous and so more consequential. Mu is being monitored closely to see if it should be re-designated as a VOC. We have to hope not.
There are four other VOIs being watched by the WHO – eta, iota, kappa and lambda – but none of these have been reclassified as a VOC. That might be the case with mu as well, but we have to await further data.
What makes mu particularly interesting (and concerning) is that it has what the WHO calls a “constellation of mutations that indicate potential properties of immune escape”. In other words, it has the hallmarks of being able to get around existing vaccine protection.
Where is it spreading?
Mu was first seen in Colombia in January 2021, when it was given the designation B1621. It has since been detected in 40 countries, but is thought to currently be responsible for only 0.1% of infections globally.
Mu has been much more prevalent in Colombia than anywhere else. When looking at coronavirus samples that have been genetically sequenced, 39% of those analysed in Colombia have been mu – though no mu samples have been recorded there in the past four weeks.
In contrast, 13% of samples analysed in Ecuador have been mu, with the variant making up 9% of the samples sequenced in the last four weeks, while in Chile just under 40% of sequenced samples have turned out to be mu over the last month. This suggests that the virus is no longer circulating in Colombia, but is being transmitted in other nearby South American countries.
So far, 45 cases have been identified in the UK through genetic analysis, and it looks like they came from overseas. However, as not allcases end up being sequenced to see which variant they are, it’s possible that mu’s prevalence in the UK could be higher.
How dangerous is it?
The key questions are whether mu is more transmissible than the currently dominant variant, delta, and whether it can cause more severe disease.
Mu has a mutation called P681H, first reported in the alpha variant, that is potentially responsiblefor faster transmission. However, this study is still in preprint, meaning its findings have yet to be formally reviewed by other scientists. We can’t be sure of P681H’s effects on the virus’s behaviour just yet.
Mu also has the mutations E484K and K417N, which are associated with being able to evade antibodies against the coronavirus – the evidence on this is more concrete. These mutations also occur in the beta variant, and so it’s possible that mu might behave like beta, which some vaccines are less effective against.
Mu also has other mutations – including R346K and Y144T – whose consequences are unknown, hence the need for further analysis.
But can mu actually evade pre-existing immunity? As yet there’s only limited information on this, with a study from a lab in Rome showing that the Pfizer/BioNTech vaccine was less effective against mu compared to other variants when tested in a lab-based experiment. Despite this, the study still considered the protection offered against mu by the vaccine to be robust. Really, we don’t yet know whether mu’s mutations will translate into increased infection and disease.
Striking reports on mu have been appearing, though. In late July, a news station in Florida reportedthat 10% of samples sequenced at the University of Miami were mu. In early August, Reuters reported that seven fully vaccinated residents of a nursing home in Belgium had died from an outbreak of mu. However, these are limited snapshots of the variant’s behaviour.
What happens next?
Mu is the first new variant to be added to the WHO’s list since June.
When a variant is designated of interest, the WHO carries out a comparative analysis of the characteristics of the new variant, assessing how it compares to others that are also being monitored by asking its member states to gather information on the variant’s incidence and effects. This is currently underway, and means that Public Health England is keeping a close eye on it.
The designation of mu as a VOI reflects the widespread concern over the possibility of new variants emerging that might prove problematic. The more transmissible delta variant taking hold in many countries, especially among the unvaccinated, shows how quickly and significantly viral variants can change the course of the pandemic.
Every time the virus reproduces inside someone there’s a chance of it mutating and a new variant emerging. This is a numbers game. It’s a random process, a bit like rolling dice. The more you roll, the greater the chance of new variants appearing. The main way to stop variants is global vaccination.
The emergence of mu reminds us of how important that goal remains. Many people, especially in developing countries, remain unvaccinated. We must get vaccines to these countries as quickly as possible, both to help the people there who are vulnerable but also to stop new variants from emerging. Otherwise, our exit from the pandemic will be set back, possibly for months on end.
Written by Luke O’Neill, Professor, Biochemistry, Trinity College Dublin.
This article was first published in The Conversation.