Pancera at the time was working upstairs from Seder’s lab at the Vaccine Research Center, part of the NIH’s National Institute of Allergy and Infectious Diseases. She was (and still is) studying another challenging pathogen for which there is not yet a vaccine: HIV. Seder studies HIV as well, and work done in that field informed his pursuit of malaria antibodies.
“The whole scientific field has learned from all the work that has been done in HIV — learning from infected people or vaccinated people, trying to understand their immune response, and then using that information for a vaccine,” Pancera said.
A virologist by training, Pancera had shifted toward structural biology — essentially, figuring out what can be learned from how a protein is shaped. Here, too, HIV research “is really pushing the field forward,” she said, with discoveries about how antibodies bind a site on proteins exposed on the surface of the virus. Pancera had begun to think about applying this approach to the malaria parasite when she learned of Seder’s search for antibodies.
A hotbed of malaria research
After moving to Seattle and joining the Hutch’s Vaccine and Infectious Disease Division, or VIDD, in 2016, Pancera received funding from a VIDD Initiative Grant to pursue work on malaria and support from VIDD to apply for a J.B. Pendleton Charitable Trust grant for equipment. Because of her initial work on malaria, she received a subaward grant from the Bill & Melinda Gates Foundation.
She had landed in a hotbed of malaria research. The Seattle-based Gates Foundation had in 1999 almost single-handedly revitalized efforts to combat and even eradicate malaria.
Pancera’s contribution to the Nature Medicine study was to describe the molecular structure of the CIS43 antibody — found in those protected volunteers — and of the sites where it bound to portions of the parasite surface.
“The group used excellent structural and biophysical methods to analyze the binding of the antibody to the protein target in order to explain the antibodies’ neutralizing capacity,” said Dr. Sean Murphy of the Seattle-based Center for Infectious Disease Research, who designed the diagnostic tool used in the study. He added that further study of the target of the antibody could reveal ways to get a vaccine to trigger the exact antibody response.
“This is a big deal because neutralizing monoclonal antibodies have transformed the approach to HIV, and the possibility exists that they will do the same for malaria,” he said.
Next steps
NIH researchers are planning to test the CIS43 antibody in human clinical trials next year.
Pancera will continue studying CIS43 — as well as another antibody that was able to bind the same site but was not protective — to see what can be learned from their differences that might influence the design of a vaccine.
“They bind in a different way, from a different angle. Maybe that matters and maybe it doesn’t,” she said. “What excites me about structural biology is that you see things and then use what you see to try to understand the biology and possibly apply this to make vaccines. “
By puzzling out what she sees, she hopes to develop a vaccine with a group of collaborators from the NIH and the University of Washington that is more protective than RTS,S, and then test it by November 2020.