Irradiation preserves T cell responses in bacterial vaccine
Using gamma radiation to inactivate bacteria for the preparation of vaccines, instead of traditional heat or chemical methods of inactivation, appears to create a vaccine that is more effective than so-called "killed" vaccines against disease, and has the added advantage of a longer storage life than "live" vaccines, according to researchers at the University of California, San Diego (UCSD) School of Medicine. Their findings, published in the July 26 issue of the journal Immunity, could result in more potent vaccines that are relatively inexpensive to produce, easy to store, and that can be transported without refrigeration.
In experiments with mice, the researchers, led by Eyal Raz, M.D., Professor of Medicine at UCSD's School of Medicine and Joshua Fierer, M.D., UCSD Professor of Medicine and Chief, Infectious Diseases Section, VA San Diego Healthcare System, demonstrated that a vaccine made with irradiated Listeria monocytogenes (LM) bacteria provided much better protection against disease than vaccine made from heat-killed bacteria. Listeria is a food-borne pathogen that can cause severe meningitis and systemic illness in immuno-compromised individuals. It is on a list of agents that could potentially be used in bioterrorist attacks, compiled by the National Institutes of Health.
To test the irradiated LM, mice were vaccinated with either heat-killed or irradiated vaccine, and then given lethal doses of LM bacteria. All of the unvaccinated or heat-killed vaccinated mice died, but 80% of those vaccinated with the irradiated vaccine survived. Protection against infection lasted more than one year after vaccination with irradiated LM.
"Irradiation is a technically simple process that retains structural features of the bacterial pathogen without destroying the natural antigens or the intrinsic adjuvants. Therefore, a strong immune response is induced in the vaccinated host," said Sandip Datta, M.D., assistant professor in UCSD's Department of Medicine and lead author of the study.
The inactivation, or attenuation, of pathogens has been a strategy for vaccine development since Louis Pasteur first attempted vaccinations nearly 150 years ago. Vaccines are designed to stimulate the immune system to protect against micro-organisms such as viruses or bacteria, by introducing a small amount of the virus or bacteria into the body. When this foreign substance invades the body, the immune system activates certain cells to destroy the invader. If the body is re-invaded by the virus or bacteria in the future, the memory cells will be reactivated and respond faster and more powerfully to destroy the virus.
Immunization with attenuated live micro-organisms promotes a strong immune response, but there are safety, storage and transportation issues with these live vaccines. Immunizations using killed bacteria are very safe, but they don't work as well in eliciting a protective immune response.
"Irradiation destroys the DNA, making the bacteria unable to replicate so it cannot establish an infection," said Raz. "But some residual metabolic activity may survive, so the irradiated bacteria can still find its natural target in the host."
The researchers further showed that, unlike heat-killed bacteria, irradiated bacteria retain the ability to activate the immune system through Toll-like receptors. Toll-like receptors detect signature molecules produced by microbes and help hosts recognize they are under attack by bacteria and trigger an inflammatory response against the bacteria. These receptors are the "sentinels" of the body's innate immune system, and they activate the acquired immune system that provides long-term, specific immunity against a pathogen. The ability of Listeria to activate these receptors appears to be intact after gamma-irradiation.
The researchers speculate that heat-killed bacteria may target an entirely different pathway, because the bacterial molecules that engage these surface cell receptors have been destroyed.
Vaccination with a freeze-dried powder formulation of the irradiated bacteria– a product with the potential to be easily and inexpensively stored and transported, then reconstituted just before use – was also shown to protect mice against lethal infection.
These findings could result in the mass production of more affordable, more effective vaccines for resource-poor regions where vaccines are most needed. The technology could also greatly expedite vaccine production and distribution during epidemic outbreaks, bioterrorist attacks or other biothreats, according to the researchers.
"The resulting vaccines using irradiation might be the next-best approach, after those produced using live bacteria. But they would be very safe, simple and inexpensive to produce," said Raz. "This might not be the ideal vaccine, but its practicality is beyond imagination."
The research team is experimenting with several other bacterial strains in addition to LM. They noted that there is a potential that the process may also work to produce a vaccine against Staphylococcus aureus, an important human pathogen that causes drug-resistant staph infections.
Additional contributors to the paper include Tomoko Hayashi, Samuel S. Shin, Ivan Mihajlov, Agnes Fermin and Donald G. Guiney from the UCSD Department of Medicine; and Sharon Okamoto of the San Diego VA Medical Center.
Funding for the project was provided by the National Institutes of Health.
Last reviewed: By John M. Grohol, Psy.D. on 21 Feb 2009
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