Coronavirus: Few vaccines prevent infection – here's why that's not a problem

Vaccines are a marvel of medicine. Few interventions can claim to have saved as many lives. But it may surprise you to know that not all vaccines provide the same level of protection. Some vaccines stop you getting symptomatic disease, but others stop you getting infected too. The latter is known as "sterilizing immunity." With sterilizing immunity, the virus can't even gain a toehold in the body because the immune system stops the virus entering cells and replicating.

There is a subtle yet important difference between preventing disease and preventing infection. A vaccine that "just" prevents disease might not stop you from transmitting the disease to others—even if you feel fine. But a vaccine that provides sterilizing immunity stops the virus in its tracks.

In an ideal world, all vaccines would induce sterilizing immunity. In reality, it is actually extremely difficult to produce vaccines that stop virus infection altogether. Most vaccines that are in routine use today do not achieve this. For example, vaccines targeting rotavirus, a common cause of diarrhea in infants, are only capable of preventing severe disease. But this has still proven invaluable in controlling the virus. In the US, there has been almost 90% fewer cases of rotavirus-associated hospital visits since the vaccine was introduced in 2006. A similar situation occurs with the current poliovirus vaccines, yet there is hope this virus could be eradicated globally.

The first SARS-CoV-2 vaccines to be licensed have been shown to be highly effective at reducing disease. Despite this, we don't yet know whether these vaccines can induce sterilizing immunity. It is expected that data addressing this question will be available from the ongoing vaccine clinical trials soon. Although even if sterilizing immunity is induced initially, this may change over time as immune responses wane and viral evolution occurs.

Immunity in individuals

What would a lack of sterilizing immunity mean for those vaccinated with the new COVID vaccines? Quite simply it means that if you encounter the virus after vaccination, you may get infected but show no symptoms. This is because your vaccine-induced immune response is not able to stop every virus particle from replicating.

It is generally understood that a particular type of antibody known as a "neutralizing antibody" is needed for sterilizing immunity. These antibodies block virus entry into cells and prevent all replication. However, the infecting virus may have to be identical to the vaccine virus in order to induce the perfect antibody.

Thankfully, our immune responses to vaccines involve many different cells and components of the immune system. Even if the antibody response isn't optimal, other aspects of immune memory can kick in when the virus invades. These include cytotoxic T cells and non-neutralizing antibodies. Viral replication will be slowed and consequently disease reduced.

We know this from years of study on influenza vaccines. These vaccines typically induce protection from disease, but not necessarily protection from infection. This is largely due to the different strains of influenza that circulate—a situation that may also occur with SARS-CoV-2. It is reassuring to note that flu vaccines, despite being unable to induce sterilizing immunity, are still extremely valuable at controlling the virus.

Immunity in a population

In the absence of sterilizing immunity, what effect might SARS-CoV-2 vaccines have on the spread of a virus through a population? If asymptomatic infections are possible after vaccination, there has been concern that SARS-CoV-2 will simply continue to infect as many people as before. Is this possible?

Asymptomatically infected people typically produce virus at lower levels. Though there is not a perfect relationship, usually more virus equals more disease. Therefore, vaccinated people are less likely to transmit enough virus to cause severe disease. This in turn means that the people getting infected in this situation are going to transmit less virus to the next susceptible person. This has been neatly shown experimentally using a vaccine targeting a different virus in chickens; when only part of a flock was vaccinated, unvaccinated birds still showed milder disease and produced less virus.

So, while sterilizing immunity is often the ultimate goal of vaccine design, it is rarely achieved. Fortunately, this hasn't stopped many different vaccines substantially reducing the number of cases of virus infections in the past. By reducing disease levels in individuals, this also reduces virus spread through populations, and this will hopefully bring the current pandemic under control.

This article is republished from The Conversation under a Creative Commons license. Read the original article.