New variants of SARS-CoV-2 have now evaded New Zealand’s border protections twice
to spread into the community.
In the most recent outbreak, which placed Auckland into an alert level 3 lockdown, there are three active community
cases of the more infectious B.1.1.7 lineage
While we have seen the virus mutate over the entire course of the pandemic, it was not until mid-December 2020 that variants with measurably different behaviour
There are several reasons for this, including the continued exponential rise in cases globally. Every COVID-19 case
gives the virus a chance to mutate, and if the number of infections continues to rise, more new variants are likely to
emerge.Pressure to mutate
The genetic code of SARS-CoV-2 is a string of RNA of about 30,000 bases, or letters. When the virus enters our cells, it
hijacks them to make thousands of copies of itself, but the copying process is not perfect.
Mistakes, or mutations, happen on average once every couple of weeks in any chain of transmission. Most are changes in a
single letter and don’t result in a notable difference, but some will change the physical form of the virus, with
possible knock-on effects to how the new variant behaves.
We know about these variants thanks to the sequencing efforts from different countries and their open sharing of this
knowledge. The variants that have arisen recently
— known as B.1.1.7
(first identified in the UK), B.1.351
(identified in South Africa) and P.1
(identified in Brazil) — all have a large number of mutations that have physically altered the virus.
This graph shows the frequency of SARS-CoV-2 sequences deposited on the global database GISAID (visualised by
Nextstrain). The three ribbons at the bottom right correspond to variants P.1 (red, also known as 501Y.V1), B.1.1.7
(orange, also known as 501Y.V2), and B.1.351 (yellowy-orange, also known as 501Y.V1). Nextstrain
, CC BY-SA
A number of these changes are on the outside of the virus, in the spike proteins it uses to infect cells. Such changes
can also undermine our immune system’s ability to detect these new versions of the virus when it has only seen the old
The most obvious reason why new variants have been emerging recently is that the number of global cases increased
massively in the last quarter of 2020. There were about 35 million cases recorded worldwide in the first nine months of
2020, but it took just two months to double that number. We are well on the way to doubling that number again
soon.Evading rising levels of immunity
A second reason is that the virus is responding to immunity that has started to build up in the population. Our immune
system plays an important role in driving which mutations survive and are transmitted.
The immune system is constantly trying to identify and kill the virus, which can only infect new people if it escapes
detection. While mutations occur randomly, ones that lead to a more transmissible variant or those that escape our
immune system are preferentially selected and more likely to persist.
The mutations that characterise B.1.1.7, B.1.351 and P.1 have been shown to spread faster
(especially B.1.1.7) and initial evidence points to a difference in the immune response
(though not in B.1.1.7).
Another indication that immunity plays a big role is that the B.1.351 and P.1 variants came to prominence in areas with
large first waves of COVID-19 where the population developed higher levels of immunity.
Special lighting will honour victims of COVID-19 during the cancelled carnival period in Rio de Janeiro. Wagner
P.1 was identified in Brazil where up to 70% of the population
were infected during the first wave. B.1.351 quickly became the dominant strain in the Eastern Cape region of South
Africa which was similarly hard hit.
The new variants could infect a greater number of people than the original wild type of the virus, which might infect
only people who had never been infected before.
This is one of the reasons why historically herd immunity for a new virus has not occurred through “natural disease
progression” but only through vaccination.
The final part of the story is the fact that two of these variants (B.1.1.7 and P.1) differ by as many as 25 mutations
from the closest known SARS-CoV-2 sequences. This is very unusual given that most viral sequences we see are within just
a few mutations of others.
Such a rapid increase in diversity has been observed in chronic COVID-19 infections in immunocompromised hosts
. Most people are ill for a week or two, but a few have to fight the disease for months. During that time, the virus
continues to evolve, sometimes very quickly as a weakened immune system presents all sorts of challenges to the virus
but fails to kill it off.
This kind of infection presents a “training ground” for the virus, as it continually adapts.Will we see more new variants?
As long as the virus is around, it will continue to mutate. With vaccine protection and natural immunity in a growing
number of people, there is greater pressure on virus variants that evade our immune defences.
The rate of new mutations varies greatly between viruses. The overall mutation rate of SARS-CoV-2 is about half that of
the influenza virus and much slower than HIV. But the overall mutation rate doesn’t tell us everything. What really
matters is the rate of mutations that physically alter the virus.
There is some early evidence this rate is about the same in SARS-CoV-2 as in influenza viruses
. One reason for this is that SARS-CoV-2 has only recently jumped to people and is not yet “optimised” to spread in
Essentially the original virus was only a few mutations away from better fitness, and there may be further easy changes
that could make it even better adapted to humans. Once the virus is through this initial adaptation phase, there will be
fewer opportunities for easy, fitness-improving changes and new variants may appear less frequently.
The variants that have been characterised so far are likely only a small subset of those in circulation. It is no
coincidence they are known from countries with comprehensive sequencing programmes (notably the UK).
But the new variants are not the main driver of transmission globally. Most of the world is still susceptible to any
variant of SARS-CoV-2, including the original version. The protective measures we have used successfully in Aotearoa to
control the virus continue to work for any variant.
The best way to protect against all current variants and to prevent the emergence of further variants is to drive down
the number of cases through ongoing control measures and vaccination.