A collaboration between the labs of Dr Alessandro Sette, and Dr Shane Crotty, at La Jolla Institute for Immunology is starting to fill in the massive knowledge gap with good news for vaccine developers and is providing the first cellular immunology data to help guide social distancing recommendations. The study documents a robust antiviral immune response to SARS-CoV-2 in a group of 20 adults who had recovered from COVID-19. The findings show that the body’s immune system is able to recognize SARS-CoV-2 in many ways, dispelling fears that the virus may elude ongoing efforts to create an effective vaccine.
“If we had seen only marginal immune responses, we would have been concerned,” says Sette, a professor in the Centre for Infectious Disease and Vaccine Research, and adds, “but what we see is a very robust T cell response against the spike protein, which is the target of most ongoing COVID-19 efforts, as well as other viral proteins. These findings are really good news for vaccine development.”
“All efforts to predict the best vaccine candidates and fine-tune pandemic control measures hinge on understanding the immune response to the virus,” says Crotty, also a professor in the Centre for Infectious Disease and Vaccine Research. “People were really worried that COVID-19 doesn’t induce immunity, and reports about people getting re-infected reinforced these concerns, but knowing now that the average person makes a solid immune response should largely put those concerns to rest.”
In an earlier study, Sette and his team had used bioinformatics tools to predict which fragments of SARS-CoV-2 are capable of activating human T cells. The scientists then, in this newest research, tested whether T cells isolated from adults who had recovered from COVID-19 without major problems, recognized the predicted protein fragments, or so-called peptides, from the virus itself. The scientists pooled the peptides into two big groups: The first so-called mega-pool included peptides covering all proteins in the viral genome apart from SARS-CoV-2’s “spike” protein. The second mega-pool specifically focused on the spike protein that dots the surface of the virus, since almost all of the vaccines under development right now target this coronavirus spike protein.
“We specifically chose to study people who had a normal disease course and didn’t require hospitalisation to provide a solid benchmark for what a normal immune response looks like, since the virus can do some very unusual things in some people,” says Sette. The researchers found that all COVID-19 patients had a solid CD4, or “helper,” T cell response, which helps antibody production. Almost all patients had produced virus-specific CD8, or “killer,” T cells, which eliminate virus-infected cells. “Our data show that the virus induces what you would expect from a typical, successful antiviral response,” says Crotty.
And, although these results don’t preclude that the immune response to SARS-CoV-2 may be detrimental, they provide an important baseline against which individuals’ immune responses can be compared; or, as Sette likes to put it, “if you can get a picture of something, you can discuss whether you like it or not but if there’s no picture there’s nothing to discuss.”
“We have a solid starting foundation to now ask whether there’s a difference in the type of immune response in people who have severe outcomes and require hospitalisation versus people who can recover at home or are even asymptomatic,” adds Sette. “But not only that, we now have an important tool to determine whether the immune response in people who have received an experimental vaccine resembles what you would expect to see in a protective immune response to COVID-19, as opposed to an insufficient or detrimental response.”
The teams also looked at the T cell response in blood samples that had been collected between 2015 and 2018, before SARS-CoV-2 started circulating. Many of these individuals had significant T cell reactivity against SARS-CoV-2, although they had never been exposed to SARS-CoV-2. But everybody has almost certainly seen at least three of the four common cold coronaviruses, which could explain the observed cross-reactivity.
It is still unclear, though, whether the observed cross-reactivity provides at least some level of pre-existing immunity to SARS-CoV-2 and therefore could explain why some people or geographical locations are hit harder by COVID-19.
“Given the severity of the ongoing COVID-19 pandemic, any degree of cross-reactive coronavirus immunity could have a very substantial impact on the overall course of the pandemic and is a key detail to consider for epidemiologists as they try to scope out how severely COVID-19 will affect communities in the coming months,” says Crotty.
The work was funded by the NIH NIAID, the Bill and Melinda Gates Foundation, the Johnathan and Mary Tu Foundation and internal LJI institutional funds.
Alba Grifoni, Daniela Weiskopf, Sydney I Ramirez, Jose Mateus, Jennifer M Dan, Carolyn Rydyznski Moderbacher, Stephen A Rawlings, Aaron Sutherland, Lakshmanane Premkumar, Ramesh S Jadi, Daniel Marrama, Aravinda M de Silva, April Frazier, Aaron Carlin, Jason A Greenbaum, Bjoern Peters, Florian Krammer, Davey M Smith, Shane Crotty, Alessandro Sette