Emergence of compensatory mutations reveal the importance of electrostatic interactions between HIV-1 integrase and genomic RNA

ABSTRACT HIV-1 integrase (IN) has a non-catalytic function in virion maturation through its binding to the viral RNA genome (gRNA). Allosteric integrase inhibitors (ALLINIs) and class II IN substitutions inhibit IN-gRNA binding and result in non-infectious viruses marked by mislocalization of the gRNA within virions. HIV-1 IN utilizes basic residues within its C-terminal domain (CTD) to bind to the gRNA. However, the molecular nature of how these residues mediate gRNA binding and whether other regions of IN are involved remain unknown. To address this, we have isolated compensatory substitutions in the background of a class II IN mutant virus bearing R269A/K273A substitutions within the IN-CTD. We found that the nearby D256N and D270N compensatory substitutions restored the ability of IN to bind gRNA and led to the formation of mature infectious virions. Reinstating the local positive charge of the IN-CTD through individual D256R, D256K, D278R and D279R substitutions was sufficient to restore IN-RNA binding and infectivity for the IN R269A/K273A as well as the IN R262A/R263A class II mutants. Structural modeling suggested that compensatory substitutions in the D256 residue created an additional interaction interface for gRNA binding. Finally, HIV-1 IN R269A/K273A, but not IN R262A/R263A, bearing compensatory mutations was more sensitive to ALLINIs providing key genetic evidence that specific IN residues required for RNA binding also influence ALLINI activity. Taken together, our findings highlight the essential role of CTD in gRNA binding and ALLINI sensitivity, and reveal the importance of pliable electrostatic interactions between the IN- CTD and the gRNA. IMPORTANCE In addition to its catalytic function, HIV-1 integrase (IN) binds to the viral RNA genome (gRNA) through positively charged residues within its C-terminal domain (CTD) and regulates proper virion maturation. Here we show that compensatory mutations in nearby acidic residues (i.e. D256N and D270N) restore the ability to bind gRNA for IN variants bearing substitutions in these positively charged CTD residues. Similarly, charge reversals through individual D-to-R and D-to-K substitutions at these positions enabled the respective IN mutants to bind gRNA and restore virion infectivity. Further, we show that specific residues within the IN-CTD required for RNA binding also influence sensitivity to allosteric integrase inhibitors, a class of novel IN- targeting compounds that target the non-catalytic function of IN. Taken together, our findings reveal the importance of electrostatic interactions in IN-gRNA binding and provide key evidence for a crucial role of the IN-CTD in allosteric integrase inhibitor mechanism of action.