Eternal Shield
By MONASH
UNIVERSITY
 |
| DAVIDE BONAZZI/SALZMAN ART |
In a paper published in the journal Immunity, researchers from Monash University’s Central Clinical School have made a significant discovery that could revolutionize the longevity of vaccine efficacy.
The team discovered that the key to long-lasting immunity after vaccination might lie in the generation of a unique subtype of immune cell that produces antibodies indefinitely.
The research also revealed
that there’s a maximum number of these long-lasting cells the body can maintain
at any one time, typically residing in special sites like the bone marrow.
The COVID-19 pandemic illustrates how variable vaccines can be in their length of efficacy, with regular boosters needed to keep people protected. In comparison, the immunity generated by a single vaccination against the measles virus can last decades.
It has always remained a scientific mystery as to why only some vaccines lead to life-long protection.
Now a paper published in the journal, Immunity, led by Prof. David Tarlinton and Dr. Marcus Robinson, both from Monash University’s Central Clinical School in Melbourne, Australia, has found that the clue likely lies in the body producing a unique subtype of an immune cell in response to some but not other vaccinations.
The
finding could revolutionize how all vaccines could be made to be longer
lasting.
Vaccines trick our immune cells into thinking the body has been infected. In response, we produce antibodies to fight off what is perceived as an infection.
According to Dr. Robinson, “most vaccines work by generating high levels of antibodies against these invaders, but how long these antibodies persist in the body is highly variable by vaccine,” he said.
“Now we
know that the clue is in whether vaccines generate a special subtype of immune
cell that produces antibody for long times to fight off infection
indefinitely.”
Using an animal model, the researchers studied the lifespan of antibody-secreting cells, identifying surface markers on these cells that indicated longevity. The scientists used a method called ‘timestamping’, which effectively tracks individual antibody-secreting cells across their entire lifespan.
“We found those cells with particular markers on
them were more likely to be long lasting. They also expressed really distinct
patterns of genes, so we think longevity is programmed into the cell.” Dr.
Robinson said.
“It is these cells we need to target when developing
vaccines we want to provide long-lasting protection.”
Importantly the researchers also found that there is a
maximum number of these long-lasting antibody-secreting cells the body can hold
at any one time, and they generally reside in special sites in tissues like the
bone marrow – so improved vaccines will need to focus on maintaining these
reservoirs of long acting cells, according to Dr. Robinson.
Reference: “Intrinsically determined turnover underlies
broad heterogeneity in plasma-cell lifespan” by
Marcus James Robinson, Zhoujie Ding, Mark R. Dowling, Danika L. Hill, Rosela H.
Webster, Craig McKenzie, Catherine Pitt, Kristy O’Donnell, Jesse Mulder, Erica
Brodie, Philip D. Hodgkin, Nick C. Wong, Isaak Quast and David M. Tarlinton, 9
May 2023, Immunity.
DOI:
10.1016/j.immuni.2023.04.015
