Inside this issueCover storiesThe big questionsNew Kavli center for neuroscience research will untangle mysteries of the human brain Molecular gambleYale physiologist elected to National Academy of Sciences TrailblazerMagazine innovator celebrates 101 years with gifts for his medical school “family” PeopleLifelines: Expert on gene-swapping joined molecular biology at its very beginningsFor new deputy dean, focus is on top-notch care, service to patientsKidney researchers celebrate a banner yearUnconventional physician-filmmaker receives “genius” grantNew HHMI investigator says appointment liberates his scienceAwards & honorsScienceAnalysis of genome reveals clues to macular degenerationVaccinating wildlife suggests a new strategy in continuing battle against Lyme diseaseAdvances: Salmonella “syringe” ready for its close-up | Possible cancer inhibitor found in worm studyHealthA heart is repaired, the patient grows up: Program helps growing number of adult survivors of congenital diseaseMore integrated care for cancer patients, collaboration of scientists and clinicians are goals of proposed new YNHH buildingAdvances: New test easier for patients to swallow. | Study finds payoff in wider HIV testingPartnershipsPfizer and Yale join forces for research and educationA long, fruitful collaboration: Bristol-Myers Squibb and YaleDrive to cure blindness hits $5 millionClass of 1954 makes a lasting impact with scholarship giftGrants and contracts
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Vaccinating wildlife suggests a new strategy
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A scanning electron micrograph of a deer tick, a carrier of the Lyme disease bacterium. |
Entomologist Durland Fish, Ph.D., of Yale’s Department of Epidemiology and Public Health, decided to revisit the vaccine strategy, but instead of humans he targeted the white-footed mouse, a key player in the spread of Lyme disease.
Working in the woods outside New Haven, Fish and his colleagues captured nearly 1,000 wild mice and injected them with the Lyme vaccine. As reported in the Proceedings of the National Academy of Sciences, the next year the researchers found lower rates of Lyme infection in both mice and ticks in the study areas.
“This is the first field study to show that we can decrease natural infection rates for a tick-borne disease by immunizing wildlife,” says Fish. “Obviously it’s not feasible to catch all the mice in a large area and inject them, but an edible vaccine, something you could incorporate into bait, should work as well.”
Lyme disease prevention expert Joseph Piesman of the CDC hopes that Fish’s results will stimulate more studies of wildlife vaccination. “We need more options for controlling and preventing Lyme disease, and these ecological, host-targeted approaches are very important,” Piesman says.
Newborn deer ticks are infected with the Lyme disease bacterium during a single, summertime feeding on a mouse, and the bacterium spends the winter inside the tick’s gut. In spring, when the ticks feed on humans, the bacterium can be released into the bloodstream, causing Lyme disease.
According to professor of medicine Erol Fikrig, how the bacterium sets up residence in the tick during winter has been a mystery, but late last year, Fikrig’s group wrote in the journal Cell that they had discovered a receptor that serves as a docking station in the tick gut for the Lyme disease bacterium.
“If you manipulate the ticks so that they no longer have this receptor, you reduce the spirochete,” says Fikrig, who envisions the creation of a receptor-blocking vaccine that would prevent ticks from carrying the Lyme disease bacterium. 
