The evolution of resistance to currently prescribed HIV-1 protease inhibitors is devastating to patients and is surprising given the way these drugs work. Protease inhibitors are all small-molecule, competitive, active-site inhibitors--low molecular weight compounds that fit squarely in the center of the active site of HIV-1 protease and prevent protein processing that is essential to the replication of the virus. It would seem as though mutations occurring in the protease that prevent drug binding and result in drug resistance would also prevent normal substrate binding, and thus compensatory changes in the substrate would be required for the virus to survive. However, research from the lab of Celia Schiffer at the University of Massachusetts Medical School has revealed a common structural theme in protease inhibitor resistance. By comparing the structures of several substrate-protease complexes, they establish a "substrate envelope" to define the three-dimensional shape that is shared by all the substrates as they are bound in the active site. They then go on to define an "inhibitor envelope" that shows how numerous protease inhibitors fit only partially within the substrate envelope. Where the inhibitors protrude beyond the confines of the substrate envelope, there is the potential for unique molecular contacts to the protease. Also, when the protease mutates at unique sites that contact the inhibitor envelope but not the substrate envelope, drug resistance emerges. This general principle offers a rational basis for combating drug resistance more aggressively by preventing a common mode of escape. Such a tool would be of enormous benefit in the worldwide fight against AIDS.
Nancy M. King, Moses Prabu-Jeyabalan, Ellen A. Nalivaika, and Celia A. Schiffer: "Combating Susceptibility to Drug Resistance: Lessons from HIV-1 Protease"
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Published in Chemistry & Biology, Volume 11, Number 10, October 2004, pages 1351–1360.
Journal
Chemistry & Biology
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