A recent research identifies how HIV—the virus that causes AIDS—hijacks the body's own defenses to promote infection. This finding could one day reduce the spread of the HIV/AIDS pandemic.
Dr. Krogan conducted this research in his laboratory at the University of California, San Francisco (UCSF)—a leading medical school with which Gladstone is affiliated—where Dr. Krogan is an associate professor of cellular and molecular pharmacology and an affiliate of the California Institute for Quantitative Biosciences (QB3). Since joining Gladstone as an associate investigator in June, Dr. Krogan has served as a unique, collaborative bridge between the two institutions in the field of systems biology, an area in which scientists perform advanced, computational analysis of large-scale data sets that are drawn from complex biological systems.
AdvertisementIn his companion papers being published online today in Nature, Dr. Krogan describes how HIV commandeers restriction factors—a class of human proteins that have evolved to block viruses such as HIV—to weaken the body's defenses and enhance the virulence of HIV infection.
"One of the keys to HIV's success is how quickly it can evolve new attack strategies—and the way in which it uses our own proteins against us is a prime example of that," said Dr. Krogan. "However, now that we've shed light on this complex process, we are one step closer to developing new drugs that will help us pull ahead in this evolutionary arms race."
AIDS has killed more than 25 million people around the world since first being identified some 30 years ago. In the United States alone, more than one million people live with HIV/AIDS at an annual cost of $34 billion. Dr. Krogan's experiments show promise for the development of more effective antiretroviral therapies for people with HIV. Further, they have laid the foundation for future research at Gladstone.
In his experiments, Dr. Krogan performed a two-part investigation of protein interactions. First, he conducted a systematic, global analysis of all potential interactions that occur between proteins made by the body (human proteins) and proteins made by the virus (HIV proteins). Second, he whittled down these ~500 interactions to the one that appeared most likely to fuel HIV infection: the interaction between the human protein CBFß and the HIV protein Vif.
Normally during HIV infection, a restriction factor called APOBEC3G acts as a molecular roadblock, preventing the virus from reaching its target—the CD4 T white blood cells that are a major component of the immune system. But Dr. Krogan found that when the HIV protein Vif binds to the human protein CBFß, Vif is strengthened and APOBEC3G degrades. This degradation weakens ABOBEC3G's ability to stop HIV and the virus is free to infect the CD4 T cells.
"This is the first comprehensive look at how HIV interacts globally with components of the cell," said Judith H. Greenberg, PhD, acting director of the National Institutes of Health's National Institute of General Medical Sciences, which partially supported this research through its AIDS-related structural biology program. "The work is a good example of how biophysical studies can improve our understanding of disease and point the way to the exploration of potential therapeutic targets."