Infectious Disease

Firdausi Qadri of International Centre for Diarrhoeal Disease Research (ICDDR,B) in Bangladesh proposes that the presence of parasites in the guts of people who receive enteric vaccines diminishes the resulting immune response. Qadri hopes that by providing children with antihelminthic and anti-giardiasis drugs prior to administration of an oral typhoid vaccine, a robust immune response can be mounted.

Enterotoxigenic Escherichia coli (ETEC) cause diarrhea by producing two distinct enterotoxins that attack intestinal cells. Adrienne Paton and colleagues at the University of Adelaide in Australia propose to develop a harmless probiotic bacterium capable of binding and neutralizing both these enterotoxins by mimicking their respective receptors, thereby preventing disease.

Peter Ngure of Daystar University in Kenya seeks to develop a biological control for sandflies using fungi found in the local soil in Kenya. These entomopathogenic fungi, which attach like parasites onto adult insects and larvae and kill them, will be harvested and cultured to isolate virulent strains that can eradicate sandflies, which are responsible for the spread of visceral leishmaniasis.

James Shorter of The University of Pennsylvania in the U.S. will engineer enzymes that disassemble protein fibrils found in semen, which are known to allow for the transmission of HIV infection. The ability to reverse fibril formation could block sexual transmission of HIV and provide a new weapon against the global HIV/AIDS pandemic.

Jun Zhu and Mark Goulian of the University of Pennsylvania in the U.S. propose to use phage display technology to engineer a commensal "sentinel" bacteria that be introduced into the gut flora. Bacterial toxins would be detected by the sentinel commensal, which would bind to the toxin and express enzymes to destroy it.

Gregory Moseley, Stephen Rawlinson and David Jans at Monash University in Australia will engineer a live virus with a self-destruct sequence for use in a vaccine. This virus would be identical to a wild-type virus, but contain destabilizing domains fused to key proteins that can be regulated to first allow the virus to replicate and induce an immune response, and then be destroyed.

Sheng He Huang of Children's Hospital, Los Angeles in the U.S. will use a bioinformatics approach to study how microbial infections, including HIV, use dynamic processes of symbiosis and pathogenesis to thrive in host cells.

Jason Rasgon of the Johns Hopkins Bloomberg School of Public Health in the U.S. will engineer a virus to express a scorpion toxin that kills mosquitoes. After infecting mosquito larvae, the virus will express the killer gene when the insect becomes old enough to reproduce, but not old enough to transmit the malaria parasite. By allowing the mosquito to reproduce, the virus not only will be transmitted vertically to the next generation, but will also significantly slow the evolution of resistance to the gene.

Kathleen Sienko of the University of Michigan in the U.S. has developed a prototype circumcision tool for use in traditional ceremonies in Africa, and seeks to demonstrate the functionality, cultural suitability, and potential for low-cost mass production of the device. Such a tool could increase the circumcision rates leading to lower rates of HIV transmission in the region.

Christine Hrycyna and Jean Chmielewski of Purdue University in the U.S. will develop novel dimeric drugs designed to block a key protein in the malaria parasite that limits the accumulation of anti-malarials in the parasite's digestive system. By inhibiting this protein, this new therapy could eliminate drug resistance in malaria parasites.