ABSTRACT
The catalytic core domain (CCD) of human immunodeficiency virus type 1 (HIV-1) integrase (IN) harbors the enzyme active site and binds viral and chromosomal DNA during integration. Thirty-five CCD mutant viruses were constructed, paying particular attention to conserved residues in the Phe139-Gln146 flexible loop and abutting Ser147-Val165 amphipathic alpha helix that were implicated from previous in vitro work as important for DNA binding. Defective viruses were typed as class I mutants (specifically blocked at integration) or pleiotropic class II mutants (additional particle assembly and/or reverse transcription defects). Whereas HIV-1P145A and HIV-1Q146K grew like the wild type, HIV-1N144K and HIV-1Q148L were class I mutants, reinforcing previous results that Gln-148 is important for DNA binding and uncovering for the first time an important role for Asn-144 in integration. HIV-1Q62K, HIV-1H67E, HIV-1N120K, and HIV-1N155K were also class I mutants, supporting findings that Gln-62 and Asn-120 interact with viral and target DNA, respectively, and suggesting similar integration-specific roles for His-67 and Asn-155. Although results from complementation analyses established that IN functions as a multimer, the interplay between active-site and CCD DNA binding functions was unknown. By using Vpr-IN complementation, we determined that the CCD protomer that catalyzes integration also preferentially binds to viral and target DNA. We additionally characterized E138K as an intramolecular suppressor of Gln-62 mutant virus and IN. The results of these analyses highlight conserved CCD residues that are important for HIV-1 replication and integration and define the relationship between DNA binding and catalysis that occurs during integration in vivo.
Docking and Molecular Dynamics Calculations of Some Previously Studied and newly Designed Ligands to Catalytic Core Domain of HIV-1 Integrase and an Investigation to Effects of Conformational Changes of Protein on Docking Results
