The intasome is the basic recombination unit of retroviral integration, comprising the integrase protein and the ends of the viral DNA made by reverse transcription. Clinical inhibitors preferentially target the DNA-bound form of integrase as compared with the free protein, highlighting the critical requirement for detailed understanding of HIV-1 intasome structure and function. Although previous biochemical studies identified integrase residues that contact the DNA, structural details of protein-protein and protein-DNA interactions within the functional intasome were lacking. The recent crystal structure of the prototype foamy virus (PFV) integrase-viral DNA complex revealed numerous details of this related integration machine. Structures of drug-bound PFV intasomes moreover elucidated the mechanism of inhibitor action. Herein we present a model for the HIV-1 intasome assembled using the PFV structure as template. Our results pinpoint previously identified protein-DNA contacts within the quaternary structure and reveal hitherto unknown roles for Arg20 and Lys266 in DNA binding and integrase function. Models for clinical inhibitors bound at the HIV-1 integrase active site were also constructed and compared with previous studies. Our findings highlight the structural basis for HIV-1 integration and define the mechanism of its inhibition, which should help in formulating new drugs to inhibit viruses resistant to first-in-class compounds.HIV/AIDS | integrase | integration | drug resistance | raltegravir
Integrase is an essential retroviral enzyme, catalyzing the stable integration of reverse transcribed DNA into cellular DNA. Several aspects of the integration mechanism, including the length of host DNA sequence duplication flanking the integrated provirus, which can be from 4 to 6 bp, and the nucleotide preferences at the site of integration, are thought to cluster among the different retroviral genera. To date only the spumavirus prototype foamy virus integrase has provided diffractable crystals of integrase-DNA complexes, revealing unprecedented details on the molecular mechanisms of DNA integration. Here, we characterize five previously unstudied integrase proteins, including those derived from the alpharetrovirus lymphoproliferative disease virus (LPDV), betaretroviruses Jaagsiekte sheep retrovirus (JSRV), and mouse mammary tumor virus (MMTV), epsilonretrovirus walleye dermal sarcoma virus (WDSV), and gammaretrovirus reticuloendotheliosis virus strain A (Rev-A) to identify potential novel structural biology candidates. Integrase expressed in bacterial cells was analyzed for solubility, stability during purification, and, once purified, 3′ processing and DNA strand transfer activities in vitro. We show that while we were unable to extract or purify accountable amounts of WDSV, JRSV, or LPDV integrase, purified MMTV and Rev-A integrase each preferentially support the concerted integration of two viral DNA ends into target DNA. The sequencing of concerted Rev-A integration products indicates high fidelity cleavage of target DNA strands separated by 5 bp during integration, which contrasts with the 4 bp duplication generated by a separate gammaretrovirus, the Moloney murine leukemia virus (MLV). By comparing Rev-A in vitro integration sites to those generated by MLV in cells, we concordantly conclude that the spacing of target DNA cleavage is more evolutionarily flexible than are the target DNA base contacts made by integrase during integration. Given their desirable concerted DNA integration profiles, Rev-A and MMTV integrase proteins have been earmarked for structural biology studies.
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