Abstract
Allosteric HIV-1 integrase (IN) inhibitors (ALLINIs) are a promising class of antiretroviral agents for clinical development. Although ALLINIs promote aberrant IN multimerization and inhibit IN interaction with its cellular cofactor LEDGF/p75 with comparable potencies in vitro, their primary mechanism of action in infected cells is through inducing aberrant multimerization of IN. Crystal structures have shown that ALLINIs bind at the IN catalytic core domain dimer interface and bridge two interacting subunits. However, how these interactions promote higher-order protein multimerization is not clear. Here, we used mass spectrometry-based protein footprinting to monitor surface topology changes in full-length WT and the drug-resistant A128T mutant INs in the presence of ALLINI-2. These experiments have identified protein-protein interactions that extend beyond the direct inhibitor binding site and which lead to aberrant multimerization of WT but not A128T IN. Specifically, we demonstrate that C-terminal residues Lys-264 and Lys-266 play an important role in the inhibitor induced aberrant multimerization of the WT protein. Our findings provide structural clues for exploiting IN multimerization as a new, attractive therapeutic target and are expected to facilitate development of improved inhibitors.
Highlights
Allosteric integrase (IN) inhibitors (ALLINIs) promote aberrant protein multimerization
We used mass spectrometry-based protein footprinting to monitor surface topology changes in full-length WT and the drugresistant A128T mutant INs in the presence of ALLINI-2. These experiments have identified protein-protein interactions that extend beyond the direct inhibitor binding site and which lead to aberrant multimerization of WT but not A128T IN
Our studies show that ALLINI-2 binding promotes protein-protein interactions that extend beyond the direct inhibitor binding site and lead to aberrant multimerization of WT but not A128T IN
Summary
Allosteric integrase (IN) inhibitors (ALLINIs) promote aberrant protein multimerization. Crystal structures have shown that ALLINIs bind at the IN catalytic core domain dimer interface and bridge two interacting subunits How these interactions promote higher-order protein multimerization is not clear. We have used MS-based protein footprinting to monitor ALLINI-2 induced surface topology changes in full-length WT and A128T INs. Our studies show that ALLINI-2 binding promotes protein-protein interactions that extend beyond the direct inhibitor binding site and lead to aberrant multimerization of WT but not A128T IN. Our studies show that ALLINI-2 binding promotes protein-protein interactions that extend beyond the direct inhibitor binding site and lead to aberrant multimerization of WT but not A128T IN These findings further our understanding of HIV-1 IN multimerization as a therapeutic target and will facilitate development of improved antiretroviral agents
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