Stanford Research Shows Why Second Dose of COVID-19 Vaccine Shouldn’t Be Skipped
By
The second dose of a COVID-19 vaccine
induces a powerful boost to a part of the immune system that provides broad
antiviral protection, according to a study led by investigators at the Stanford
University School of Medicine.
By Lalo Alcaraz
The finding strongly
supports the view that the second shot should not be skipped.
“Despite their outstanding
efficacy, little is known about how exactly RNA vaccines work,”
said Bali Pulendran, PhD, professor of pathology and of microbiology and
immunology. “So we probed the immune response induced by one of them in
exquisite detail.”
The study, published July 12
in Nature, was
designed to find out exactly what effects the vaccine, marketed by Pfizer Inc.,
has on the numerous components of the immune response.
The researchers analyzed
blood samples from individuals inoculated with the vaccine. They counted
antibodies, measured levels of immune-signaling proteins and characterized the
expression of every single gene in the genome of 242,479 separate immune cells’
type and status.
“The world’s attention has recently been fixed on COVID-19 vaccines, particularly on the new RNA vaccines,” said Pulendran, the Violetta L. Horton Professor II.
Uncharted territory
“This is the first time RNA
vaccines have ever been given to humans, and we have no clue as to how they do
what they do: offer 95% protection against COVID-19,” said Pulendran.
Traditionally, the chief
immunological basis for approval of new vaccines has been their ability to
induce neutralizing antibodies: individualized proteins, created by immune
cells called B cells, that can tack themselves to a virus and block it from
infecting cells.
“Antibodies are easy to
measure,” Pulendran said. “But the immune system is much more complicated than
that. Antibodies alone don’t come close to fully reflecting its complexity and
potential range of protection.”
Pulendran and his colleagues
assessed goings-on among all the immune cell types influenced by the vaccine:
their numbers, their activation levels, the genes they express and the proteins
and metabolites they manufacture and secrete upon inoculation.
One key immune-system
component examined by Pulendran and his colleagues was T cells:
search-and-destroy immune cells that don’t attach themselves to viral particles
as antibodies do but rather probe the body’s tissues for cells bearing telltale
signs of viral infections. On finding them, they tear those cells up.
In addition, the innate immune system, an assortment of first-responder cells, is now understood to be of immense importance. It’s the body’s sixth sense, Pulendran said, whose constituent cells are the first to become aware of a pathogen’s presence.
Although they’re not good at distinguishing among separate pathogens, they secrete “starting gun” signaling proteins that launch the response of the adaptive immune system — the B and T cells that attack specific viral or bacterial species or strains.
During the week or so it takes for the adaptive
immune system to rev up, innate immune cells perform the mission-critical task
of holding incipient infections at bay by gobbling up — or firing noxious
substances, albeit somewhat indiscriminately, at — whatever looks like a
pathogen to them.
A different type of vaccine
The Pfizer vaccine, like the
one made by Moderna Inc., works quite differently from the classic vaccines
composed of live or dead pathogens, individual proteins or carbohydrates that
train the immune system to zero in on a particular microbe and wipe it out. The
Pfizer and Moderna vaccines instead contain genetic recipes for manufacturing
the spike protein that SARS-CoV-2, the virus that
causes COVID-19, uses to latch on to cells it infects.
In December 2020, Stanford
Medicine began inoculating people with the Pfizer vaccine. This spurred
Pulendran’s desire to assemble a complete report card on the immune response to
it.
The team selected 56 healthy
volunteers and drew blood samples from them at multiple time points preceding
and following the first and second shots. The researchers found that the first
shot increases SARS-CoV-2-specific antibody levels, as expected, but not nearly
as much as the second shot does. The second shot also does things the first
shot doesn’t do, or barely does.
“The second shot has
powerful beneficial effects that far exceed those of the first shot,” Pulendran
said. “It stimulated a manifold increase in antibody levels, a terrific T-cell
response that was absent after the first shot alone, and a strikingly enhanced
innate immune response.”
Unexpectedly, Pulendran
said, the vaccine — particularly the second dose — caused the massive
mobilization of a newly discovered group of first-responder cells that are
normally scarce and quiescent.
First identified in a recent
vaccine study led by Pulendran, these cells — a small subset of generally
abundant cells called monocytes that express high levels of antiviral genes —
barely budge in response to an actual COVID-19 infection. But the Pfizer
vaccine induced them.
This special group of
monocytes, which are part of the innate museum, constituted only 0.01% of all
circulating blood cells prior to vaccination. But after the second
Pfizer-vaccine shot, their numbers expanded 100-fold to account for a full 1%
of all blood cells. In addition, their disposition became less inflammatory but
more intensely antiviral. They seem uniquely capable of providing broad
protection against diverse viral infections, Pulendran said.
“The extraordinary increase
in the frequency of these cells, just a day following booster immunization, is
surprising,” Pulendran said. “It’s possible that these cells may be able to
mount a holding action against not only SARS-CoV-2 but against other viruses as
well.”
Reference: “Systems
vaccinology of the BNT162b2 mRNA vaccine in humans” by Prabhu S. Arunachalam,
Madeleine K. D. Scott, Thomas Hagan, Chunfeng Li, Yupeng Feng, Florian Wimmers,
Lilit Grigoryan, Meera Trisal, Venkata Viswanadh Edara, Lilin Lai, Sarah Esther
Chang, Allan Feng, Shaurya Dhingra, Mihir Shah, Alexandra S. Lee, Sharon
Chinthrajah, Sayantani B. Sindher, Vamsee Mallajosyula, Fei Gao, Natalia Sigal,
Sangeeta Kowli, Sheena Gupta, Kathryn Pellegrini, Gregory Tharp, Sofia
Maysel-Auslender, Sydney Hamilton, Hadj Aoued, Kevin Hrusovsky, Mark Roskey,
Steven E. Bosinger, Holden T. Maecker, Scott D. Boyd, Mark M. Davis, Paul J.
Utz, Mehul S. Suthar, Purvesh Khatri, Kari C. Nadeau and Bali Pulendran, 12
July 2021, Nature.
DOI: 10.1038/s41586-021-03791-x
Pulendran is a member of the
Institute for Immunity Transplantation & Infection and Stanford Bio-X and a
faculty fellow of Stanford ChEM-H.
The work was funded by the National Institutes of Health (grants U19AI090023, U19AI057266, U24AI120134, P51OD011132, S10OD026799, R01AI123197-04, U01AI150741-01S1 and AI057229), Open Philanthropy, the Sean Parker Cancer Institute, the Soffer Endowment, the Violetta Horton Endowment, Stanford University, the Henry Gustav Floren Trust, the Parker Foundation, the Cooperative Centers on Human Immunology and the Crown Foundation.
Stanford’s Institute for
Immunity, Transplantation and Infection also supported the work.