A novel human liver-chimeric mouse model developed at Oregon Health & Science University and Yecuris Corporation has made possible a research breakthrough at Seattle Biomedical Research Institute that will greatly accelerate studies of the most lethal forms of human malaria.
The study findings are published online in the Journal of Clinical Investigation. Study photos were selected to appear in "Scientific Show Stoppers" on the JCI blog.
Plasmodium falciparum, one of two human-specific malaria parasites, is a global health crisis, causing more than 216 million new infections annually and resulting in an estimated 655,000 deaths, according to the World Health Organization.
Sporozoites, the infectious form of the parasite, are spread to people through the bites of infected mosquitos and multiply in the human liver during the initial stages of infection. There, they undergo liver stage development, culminating in the formation and release of tens of thousands of merozoites, the parasitic phase of development that infects red blood cells.
Until now, there have been few data on human malaria liver stage biology due to the lack of a viable small animal model and because liver stage P. falciparum does not grow well in a dish. Consequently, most research and therapeutics to date have targeted the human blood stage of P. falciparum's development because it replicates well in culture.
The liver-to-blood stage of P. falciparum is the focus of this research because the parasite is virtually harmless, causing no disease symptoms, prior to its transition to the blood stage.
In this study, researchers at Seattle Biomedical Research Institute, Yecuris Corporation, Oregon Health & Science University and The Rockefeller University have demonstrated that a complete liver-to-blood stage infection of P. falciparum is possible using a unique immunocompromised mouse model engrafted with human liver-chimeric cells.
The mouse model, termed the FRGTM KO mouse, was developed by paper co-author and internationally accomplished stem cell researcher Markus Grompe, M.D., in the Pap- Family Pediatric Research Institute, a research arm of Oregon Health & Science University Doernbecher Children's Hospital.
In 2007 the technology was licensed to Yecuris Corporation, a biotechnology company that now produces the model and human hepatocytes on a commercial scale. As a result of this work, the FRGTM KO mouse now will be used to study new drug interventions, parasite attenuation and innate immune responses to P. falciparum liver stage infection.
The scientists also report that through the infection of the FRGTM KO mouse model, they were able to observe a previously unknown expression of proteins in liver stage development in humans that may be exploited for intervention. Equally important, they say, the FRGTM KO mouse could well provide unique opportunities for the study of another severe form of human malaria, Plasmodium vivax.
"These breakthroughs are remarkable and highlight OHSU and Yecuris' contributions to local biotechnology and research breakthroughs globally. The next generation mouse model we're developing will have a human immune system that will allow us to test not just drugs, but vaccines, which has never been done for parasitic diseases," said Grompe, Ray Hickey Chair and Director of the Pap- Family Pediatric Research Institute, OHSU Doernbecher Children's Hospital; and professor of pediatrics, and molecular and medical genetics, OHSU School of Medicine.
Grompe founded Yecuris Corporation in 2007 and is a shareholder. John Bial, who joined Yecuris in 2009, is president and chief executive officer.
"The extensive collaborative relationships and risk-taking involved in planning and executing this research is a testament to the tireless dedication of these teams to solving one of the globe's oldest killers. It also highlights how private and public funding can come together effectively to address critical challenges in global health," said Bial.
"This first demonstration of the newly developed dual humanized FRGTM KO system is a good introduction to the kinds of translational medicine benefits that we can expect to see from these technologies. We anticipate that the next frontier for these systems will be as platforms for human vaccine development and validation, which may very likely first be tested in the area of malaria," Bial explained.