Genetic analysis of the human immunodeficiency virus type 1 integrase protein.

Single-amino-acid changes in a highly conserved central region of the human immunodeficiency virus type 1 (HIV-1) integrase protein were analyzed for their effects on viral protein synthesis, virion morphogenesis, and viral replication. Alteration of two amino acids that are invariant among retroviral integrases, D116 and E152 of HIV-1, as well as a mutation of the highly conserved amino acid S147 blocked viral replication in two CD4+ human T-cell lines. Mutations of four other highly conserved amino acids in the region had no detectable effect on viral replication, whereas mutations at two positions, N117 and Y143, resulted in viruses with a delayed-replication phenotype. Defects in virion precursor polypeptide processing, virion morphology, or viral DNA synthesis were observed for all of the replication-defective mutants, indicating that changes in integrase can have pleiotropic effects on viral replication.     

Monoclonal antibodies against the minimal DNA-binding domain in the carboxyl-terminal region of human immunodeficiency virus type 1 integrase

Integrase of human immunodeficiency virus type 1 (HIVIN) consists of 288 amino acids, and its minimum DNA-binding domain (MDBD) (amino acids [aa] 220 to 270) is required for the integration reaction. We produced and characterized four murine monoclonal antibodies (MAbs) to the MDBD of HIVIN (strain LAI). Immunoblot and enzyme-linked immunosorbent assays with truncated HIVINs showed that those MAbs recognized sequential epitopes within the MDBD (aa 228 to 236, 237 to 252, 253 to 261, and 262 to 270). Their binding to HIVIN inhibited terminal cleavage and strand transfer activities but not disintegration activity in vitro. This collection of MAbs is useful for studying the structure and function of the MDBD by complementing mutational analyses and other biochemical studies.     

The human immunodeficiency virus integrase protein

The DNA integration step in the replication cycle of the human immunodeficiency virus (HIV) has been recognized as an important target in antiviral strategies. There are two main reasons for this. First, integration of HIV DNA into the human genome is required for replication of this retrovirus. Second, since the integration reaction does not have an obvious cellular counterpart, drugs that specifically inhibit integration may not be toxic for the cell. Here, we focus on the only protein known to be required for retroviral integration, the integrase (IN) protein.     

Differential divalent cation requirements uncouple the assembly and catalytic reactions of human immunodeficiency virus type 1 integrase.

Previous in vitro analyses have shown that the human immunodeficiency virus type 1 (HIV-1) integrase uses either manganese or magnesium to assemble as a stable complex on the donor substrate and to catalyze strand transfer. We now demonstrate that subsequent to assembly, catalysis of both 3' end processing and strand transfer requires a divalent cation cofactor and that the divalent cation requirements for assembly and catalysis can be functionally distinguished based on the ability to utilize calcium and cobalt, respectively. The different divalent cation requirements manifest by these processes are exploited to uncouple assembly and catalysis, thus staging the reaction. Staged 3' end processing and strand transfer assays are then used in conjunction with exonuclease III protection analysis to investigate the effects of integrase inhibitors on each step in the reaction. Analysis of a series of related inhibitors demonstrates that these types of compounds affect assembly and not either catalytic process, therefore reconciling the apparent disparate results obtained for such inhibitors in assays using isolated preintegration complexes. These studies provide evidence for a distinct role of the divalent cation cofactor in assembly and catalysis and have implications for both the identification and characterization of integrase inhibitors.     

Efficient magnesium-dependent human immunodeficiency virus type 1 integrase activity.

The integrase protein from human immunodeficiency virus type 1 (HIV-1) has generally been reported to require Mn2+ for efficient in vitro activity. We have reexamined the divalent metal ion requirements of HIV-1 integrase and find that the protein is capable of promoting efficient 3' processing and DNA strand transfer with either Mn2+ or Mg2+. The metal ion preference depended upon the reaction conditions. HIV-1 integrase displayed significantly less nonspecific nuclease activity in reaction mixtures containing Mg2+ than it did under the previously described reaction conditions with mixtures containing Mn2+.     

Substrate specificity of recombinant human immunodeficiency virus integrase protein.

Recombinant human immunodeficiency virus type 1 (HIV-1) integrase (IN) produced in Escherichia coli efficiently cleaves two nucleotides from the 3' end of synthetic oligonucleotide substrates which mimic the termini of HIV-1 proviral DNA. Efficient cleavage was restricted to HIV-1 substrates and did not occur with substrates derived from other retroviruses. Mutagenesis of the U5 long terminal repeat (LTR) terminus revealed only moderate effects of mutations outside the terminal four bases of the U5 LTR and highlighted the critical nature of the conserved CA dinucleotide motif shared by all retroviral termini. Integration of the endonuclease cleavage products occurs subsequent to cleavage, and evidence that the cleavage and integration reactions may be uncoupled is presented. Competition cleavage reactions demonstrated that IN-mediated processing of an LTR substrate could be inhibited by competition with LTR and non-LTR oligonucleotides.     

DNA substrate requirements for different activities of the human immunodeficiency virus type 1 integrase protein.

The integrase protein (IN) of human immunodeficiency virus type 1 removes two nucleotides from both 3' ends of the viral DNA (donor cleavage) and subsequently couples the newly generated 3' OH groups to phosphates in the target DNA (integration). The sequence requirements of IN for cleavage as well as for integration of viral DNA substrates have previously been studied by mutational analyses and by adduct interference assays. We extended these studies by analysis of heteroduplex oligonucleotide substrates and by missing-base analysis. We found for some base pairs that mutation of only one of the two bases and not the other affected IN activity. These base pairs center around the cleavage site. Besides donor cleavage and integration, IN can also perform "intermolecular disintegration," which has been described as the reversal of the integration reaction. We found that this reaction is independent of viral DNA sequences. In addition, the optimum spacing between the integration sites in intermolecular disintegration does not reflect the spacing found in vivo. These results indicate that this reaction is not the exact reversal of integration but rather is a sequence-independent phosphoryl transfer reaction between gapped DNA duplex molecules.     

The human polycomb group EED protein interacts with the integrase of human immunodeficiency virus type 1

Human EED, a member of the superfamily of WD-40 repeat proteins and of the Polycomb group proteins, has been identified as a cellular partner of the human immunodeficiency virus type 1 (HIV-1) matrix (MA) protein (R. Peytavi et al., J. Biol. Chem. 274:1635-1645, 1999). In the present study, EED was found to interact with HIV-1 integrase (IN) both in vitro and in vivo in yeast. In vitro, data from mutagenesis studies, pull-down assays, and phage biopanning suggested that EED-binding site(s) are located in the C-terminal domain of IN, between residues 212 and 264. In EED, two putative discrete IN-binding sites were mapped to its N-terminal moiety, at a distance from the MA-binding site, but EED-IN interaction also required the integrity of the EED last two WD repeats. EED showed an apparent positive effect on IN-mediated DNA integration reaction in vitro, in a dose-dependent manner. In situ analysis by immunoelectron microscopy (IEM) of cellular distribution of IN and EED in HIV-1-infected cells (HeLa CD4(+) cells or MT4 lymphoid cells) showed that IN and EED colocalized in the nucleus and near nuclear pores, with maximum colocalization events occurring at 6 h postinfection (p.i.). Triple colocalizations of IN, EED, and MA were also observed in the nucleoplasm of infected cells at 6 h p.i., suggesting the ocurrence of multiprotein complexes involving these three proteins at early steps of the HIV-1 virus life cycle. Such IEM patterns were not observed with a noninfectious, envelope deletion mutant of HIV-1.     

Incorporation of functional human immunodeficiency virus type 1 integrase into virions independent of the Gag-Pol precursor protein.

Retroviral integrase (IN) is expressed and incorporated into virions as part of the Gag-Pol polyprotein precursor. IN catalyzes integration of the proviral DNA into host cell chromosomes during the early stages of the virus life cycle, and as a component of Gag-Pol, it is involved in virion morphogenesis during late stages. It is unknown whether the scheme, conserved among retroviruses, for expressing and incorporating IN as a component of the Gag-Pol precursor protein is necessary for its function in the infected cell after viral entry. We have developed human immunodeficiency virus (HIV) virion-associated accessory proteins (Vpr and Vpx) as vehicles to deliver both foreign and viral proteins into the virus particle by their expression in trans as heterologous fusion proteins (X. Wu, et al., J. Virol. 69:3389-3398, 1995; X. Wu, et al., J. Virol. 70:3378-3384, 1996; X. Wu, et al., EMBO J. 16:5113-5122, 1977). To analyze IN function independent of its expression as a part of Gag-Pol, we expressed and incorporated IN into HIV type 1 (HIV-1) virions in trans as a fusion partner of Vpr (Vpr-IN). Our results demonstrate that the Vpr-IN fusion protein is efficiently incorporated into virions and then processed by the viral protease to liberate the IN protein. Virus derived from IN-minus provirus is noninfectious. However, this defect is overcome by trans complementation with the Vpr-IN fusion protein. Moreover, complemented virions are able to replicate through a complete cycle of infection, including formation of the provirus (integration). These results show, for the first time, that full IN function can be provided in trans, independent of its expression and incorporation into virions as a component of Gag-Pol. This finding also indicates that the IN domain of Gag-Pol is not required for the formation of infectious virions when IN is provided in trans. The ability to incorporate functional IN into retroviral particles in trans will provide unique opportunities to explore the function of this critical enzyme in a biologically relevant context, i.e., in infected cells as part of the nucleoprotein/preintegration complex.     

Multiple integrase functions are required to form the native structure of the human immunodeficiency virus type I intasome.

Mu-mediated polymerase chain reaction footprinting was used to investigate the protein-DNA structure of human immunodeficiency virus type I (HIV-I) preintegration complexes. Preintegration complexes were partially purified from cells after using an established coculture infection technique as well as a novel technique using cell-free supernatant from transfected cells as the source of virus. Footprinting revealed that bound proteins protected the terminal 200-250 base pairs of each viral end from nuclease attack. Bound proteins also caused strong transpositional enhancements near each end of HIV-I. In contrast, regions of viral DNA internal to the ends did not show evidence of strong protein binding. The end regions of preintegrative HIV-I apparently form a unique nucleoprotein structure, which we term the intasome to distinguish it from the greater preintegration complex. Our novel system also allowed us to analyze the structure and function of preintegration complexes isolated from cells infected with integrase mutant viruses. Complexes were derived from viruses defective for either integrase catalysis, integrase binding to the viral DNA substrate, or an unknown function in the carboxyl-terminal domain of the integrase protein. None of these mutant complexes supported detectable integration activity. Despite the presence of the mutant integrase proteins in purified samples, none of these nucleoprotein complexes displayed the native intasome structure detected in wild-type preintegration complexes. We conclude that multiple integrase functions are required to form the native structure of the HIV-I intasome in infected cells.     

Concerted integration of retrovirus-like DNA by human immunodeficiency virus type 1 integrase.

The integration of linear retrovirus DNA by the viral integrase (IN) into the host chromosome occurs by a concerted mechanism (full-site reaction). IN purified from avian myeloblastosis virus and using retrovirus-like DNA restriction fragments (487 bp in length) as donors and circular DNA (pGEM-3) as the target can efficiently catalyze that reaction. Nonionic detergent lysates of purified human immunodeficiency virus type 1 (HIV-1) virions were also capable of catalyzing the concerted integration reaction. The donor substrates were restriction fragments (469 bp) containing either U3-U5 (H-2 donor) or U5-U5 (H-5 donor) long terminal repeat sequences at their ends. As was shown previously with bacterially expressed HIV-1 IN, the U5 terminus of H-2 was preferred over the U3 terminus by virion-associated IN. The reactions involving two donors per circular target by HIV-1 IN preferred Mg2+ over Mn2+. Both metal ions were equally effective for the circular half-site reaction involving only one donor molecule. The linear 3.8-kbp recombinant products produced from two donor insertions into pGEM were genetically selected, and the donor-target junctions of individual recombinants were sequenced. A total of 55% of the 87 sequenced recombinants had host site duplications of between 5 and 7 bp, with the HIV-1 5-bp-specific duplication predominating. The other recombinants that migrated at the linear 3.8-kbp position were mainly small deletions that were grouped into four sets of 17, 27, 40, and 47 bp, each having a periodicity mimicking a turn of the DNA helix. Aprotic solvents (dimethyl sulfoxide and 1,4-dioxane) enhanced both the half-site and the linear 3.8-kbp strand transfer reactions which favored low-salt conditions (30 mM NaCl). The order of addition of the donor and target during preincubation with HIV-1 IN on ice did not affect the quantity of linear 3.8-kbp recombinants relative to that of the circular half-site products that were produced; only the quantity of donor-donor versus donor-target recombinants was affected. The presence of Mg2+ in the preincubation mixtures containing donor and target substrates was not necessary for the stability of preintegration complexes on ice or at 22 degrees C. Comparisons of the avian and HIV-1 concerted integration reactions are discussed.     

Identification of conserved amino acid residues critical for human immunodeficiency virus type 1 integrase function in vitro.

We have probed the structural organization of the human immunodeficiency virus type 1 integrase protein by limited proteolysis and the functional organization by site-directed mutagenesis of selected amino acid residues. A central region of the protein was relatively resistant to proteolysis. Proteins with altered amino acids in this region, or in the N-terminal part of the protein that includes a putative zinc-binding motif, were purified and assayed for 3' processing, DNA strand transfer, and disintegration activities in vitro. In general, these mutations had parallel effects on 3' processing and DNA strand transfer, suggesting that integrase may utilize a single active site for both reactions. The only proteins that were completely inactive in all three assays contained mutations at conserved amino acids in the central region, suggesting that this part of the protein may be involved in catalysis. In contrast, none of the mutations in the N-terminal region resulted in a protein that was inactive in all three assays, suggesting that this part of integrase may not be essential for catalysis. The disintegration reaction was particularly insensitive to these amino acid substitutions, indicating that some function that is important for 3' processing and DNA strand transfer may be dispensable for disintegration.     

Folding of the multidomain human immunodeficiency virus type-I integrase.

Protein folding conditions were established for human immunodeficiency virus integrase (IN) obtained from purified bacterial inclusion bodies. IN was denatured by 6 M guanidine.HCl-5 mM dithiothreitol, purified by gel filtration, and precipitated by ammonium sulfate. The reversible solvation of precipitated IN by 6 M guanidine.HCl allowed for wide variation of protein concentration in the folding reaction. A 6-fold dilution of denatured IN by 1 M NaCl buffer followed by dialysis produced enzymatically active IN capable of 3' OH end processing, strand transfer, and disintegration using various human immunodeficiency virus-1 (HIV-1) long terminal repeat DNA substrates. The specific activities of folded IN preparations for these enzymatic reactions were comparable to those of soluble IN purified directly from bacteria. The subunit composition and enzymatic activities of IN were affected by the folding conditions. Standard folding conditions were defined in which monomers and protein aggregates sedimenting as dimers and tetramers wree produced. These protein aggregates were enzymatically active, whereas monomers had reduced strand transfer activity. Temperature modifications of the folding conditions permitted formation of mainly monomers. Upon assaying, these monomers were efficient for strand transfer and disintegration, but the oligomeric state of IN under the conditions of the assay is determinate. Our results suggest that monomers of the multidomain HIV-1 IN are folded correctly for various catalytic activities, but the conditions for specific oligomerization in the absence of catalytic activity are undefined.     

Formation of a stable complex between the human immunodeficiency virus integrase protein and viral DNA.

The integrase (IN) protein of the human immunodeficiency virus (HIV) mediates two distinct reactions: (i) specific removal of two nucleotides from the 3' ends of the viral DNA and (ii) integration of the viral DNA into target DNA. Although IN discriminates between specific (viral) DNA and nonspecific DNA in physical in vitro assays, a sequence-specific DNA-binding domain could not be identified in the protein. A nonspecific DNA-binding domain, however, was found at the C terminus of the protein. We examined the DNA-binding characteristics of HIV-1 IN, and found that a stable complex of IN and viral DNA is formed in the presence of Mn2+. The IN-viral DNA complex is resistant to challenge by an excess of competitor DNA. Stable binding of IN to the viral DNA requires that the protein contains an intact N-terminal domain and active site (in the central region of the protein), in addition to the C-terminal DNA-binding domain.     

Molecular dynamics simulation of a leucine zipper motif predicted for the integrase of human immunodeficiency virus type I

We have used the molecular dynamics (MD) simulation package AMBER4 to search the conformation of a peptide predicted as a leucine zipper motif for the human immunodeficiency virus type I integrase protein (HIV IN-LZM). The peptide is composed of 22 amino acid residues and its location is from Val 151 to Leu 172. The searching procedure also includes two known α-helices that served as positive controls—namely, a 22-residue GCN4-p1 (LZM) and a 20-residue poly(L -alanine) (PLA). A 21-residue peptide extracted from a cytochrome C crystal (CCC-t) with determined conformation as a β-turn is also included as a negative control. At the beginning of the search, two starting conformations—namely, the standard right-handed α-helix and the fully stretched conformations—are generated for each peptide. Structures generated as standard α-helix are equilibrated at room temperature for 90 ps while structures generated as a fully stretched one are equilibrated at 600 K for 120 ps. The CCC-t and PLA helices are nearly destroyed from the beginning of equilibration. However, for both the HIV IN-LZM and the GCN4-p1 LZM structures, there is substantial helicity being retained throughout the entire course of equilibration. Although helix propagation profiles calculated indicate that both peptides possess about the same propensity to form an α-helix, the HIV IN-LZM helix appears to be more stable than the GCN4-p1 one as judged by a variety of analyses on both structures generated during the equilibration course. The fact that predicted HIV IN-LZM can exist as an α-helix is also supported by the results of high temperature equilibration run on the fully stretched structures generated. In this run, the RMS deviations between the backbone atoms of the structures with the lowest potential energy (PE) identified within every 2 ps and the structure with the lowest PE searched in the same course of simulation are calculated. For both the HIV IN-LZM and the GCN4-p1 LZM, these rms values decrease with the decrease of PE, which indicates that both structures are closer in conformations as their PEs are moved deeper into the PE well. © 1994 John Wiley & Sons, Inc.