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The rapid development of vaccines that protect against COVID was a remarkable scientific achievement that saved millions of lives. The vaccines have demonstrated substantial success in reducing death and serious illness after COVID infection.

Despite this success, the effects of the pandemic have been devastating, and it is critical to consider how to protect against future pandemic threats. As well as SARS-CoV-2 (the virus that causes COVID), previously unknown coronaviruses have been responsible for the deadly outbreaks of SARS (2003) and MERS (2012 outbreak with ongoing cases). Meanwhile, several circulating bat coronaviruses have been identified as having the potential to infect humans – which could cause future outbreaks.

My colleagues and I have recently shown, in mice, that a single, relatively simple vaccine can protect against a range of coronaviruses – even ones that are yet to be identified. This is a step towards our goal of what is known as “proactive vaccinology”, where vaccines are developed against pandemic threats before they can infect humans.

Conventional vaccines use a single antigen (part of a virus that triggers an immune response) that typically protects against that virus and that virus alone. They tend not to protect against diverse known viruses, or viruses that have not yet been discovered.

In previous research, we have shown the success of “mosaic nanoparticles” at raising immune responses to different coronaviruses. These mosaic nanoparticles use a type of protein superglue technology that irreversibly links two different proteins together.

This “superglue” is used to decorate a single nanoparticle with multiple receptor-binding domains – a key part of a virus located on the spike protein – that come from different viruses. The vaccine is focused on a sub-group of coronaviruses called sarbecoviruses that includes the viruses that cause COVID, SARS and several bat viruses that have the potential to infect humans.

As a virus evolves, some parts of it change while other parts remain the same. Our vaccine incorporates evolutionarily related receptor-binding domains (RBDs), so a single vaccine trains the immune system to respond to the parts of the virus that remain unchanged. This protects against the viruses that are represented in the vaccine and, critically, also protects against related viruses that are not included in the vaccine.

Despite this success with mosaic nanoparticles, the vaccine was complex, making it difficult to produce on a large scale.