Characterization of human immunodeficiency virus type 1 integrase expressed in Escherichia coli and analysis of variants with amino-terminal mutations

Coordinated disintegration reactions mediated by Moloney murine leukemia virus integrase

The protein-DNA and protein-protein interactions important for function of the integrase (IN) protein of Moloney murine leukemia virus (M-MuLV) were investigated by using a coordinated-disintegration assay. A panel of M-MuLV IN mutants and substrate alterations highlighted distinctions between the intermolecular and intramolecular reactions of coordinated disintegration. Mispairing of the crossbone single-strand region and altered long terminal repeat (LTR) positioning affected the intermolecular, but not the intramolecular, reactions of coordinated disintegration. Partial components of the crossbone substrate were coordinated by M-MuLV IN, indicating a reliance on both LTR and target DNA determinants for substrate assembly. The intramolecular reaction was dependent on the presence of either the HHCC domain or a crossbone LTR 5' single-stranded tail. An M-MuLV IN mutant without the HHCC domain (Ndelta105) catalyzed reduced levels of double disintegration but not single disintegration. A separately purified HHCC domain protein (Cdelta232) stimulated double disintegration mediated by Ndelta105, suggesting a role of the N-terminal HHCC domain in stable IN-IN and IN-DNA interactions. Significantly, crossbone substrates lacking the LTR 5' tails were not recognized by the fingerless Ndelta105 protein. Collectively, these data suggest similar roles of the HHCC domain and 5' LTR tail in substrate recognition and modulation of IN activity.

Multiple roles for divalent metal ions in DNA transposition: distinct stages of Tn10 transposition have different Mg2+ requirements

Tn10 transposition takes place by a non-replicative mechanism in which the transposon is excised from donor DNA and integrated into a target site. Mg2+ is an essential cofactor in this reaction. We have examined the Mg2+ requirements at various steps in Tn10 transposition. Results presented here demonstrate that Tn10 excision can occur efficiently at a 16-fold lower Mg2+ concentration than strand transfer and that, at Mg2+ concentrations in the range of 60-fold below the wildt-ype optimum, double strand cleavage events at the two transposon ends are completely uncoupled. These experiments identify specific breakpoints in Tn10 transposition which are sensitive to Mg2+ concentration. Whereas the uncoupling of double strand cleavage events at the two transposon ends most likely reflects the inability of two separate IS10 transposase monomers in the synaptic complex to bind Mg2+, the uncoupling of transposon excision from strand transfer is expected to reflect either a conformational change in the active site or the existence of an Mg2+ binding site which functions specifically in target interactions. We also show that Mn2+ relaxes target specificity in Tn10 transposition and suppresses a class of mutants which are blocked specifically for integration. These observations can be explained by a model in which sequence-specific target site binding is tightly coupled to a conformational change in the synaptic complex which is required for catalysis of strand transfer.

Alternate strand DNA triple helix-mediated inhibition of HIV-1 U5 long terminal repeat integration in vitro

Integration of the human immunodeficiency virus (HIV) DNA into the host genome is an obligatory process in the replicative life cycle of the virus. This event is mediated in vitro by integrase, a viral protein which binds to specific sequences located on both extremities of the DNA long terminal repeats (LTRs). These sites are highly conserved in all HIV genomes and thus provide potential targets for the selective inhibition of integration. The integrase-binding site located on the HIV-1 U5 LTR end contains two adjacent purine tracts on opposite strands, 5' . . . GGAAAATCTCT-3'/3'-CCTTTTAGAGA . . . 5', in parallel orientations. A single strand oligonucleotide 5'-GGTTTTTGTGT-3' was designed to associate with these tracts via its ability to form a continuous alternate strand DNA triplex. Under neutral pH and physiological temperature, the oligonucleotide, tagged with an intercalator chromophore oxazolopyridocarbazole, formed a stable triplex with the target DNA. The occurrence of this unusual triplex was demonstrated by both DNase I footprinting and electron microscopy. The triplex inhibits the two steps of the integrase-mediated reactions, namely, the endonucleolytic cleavage of the dinucleotide 5'-GT-3' from the 3' end of the integration substrate and the integration of the substrate into the heterologous target DNA. The midpoints for both inhibition reactions were observed at oligonucleotide concentrations of 50-100 nM. We believe that these results open new possibilities for the specific targeting of viral DNA LTR ends with the view of inhibiting integration under physiological conditions.

A soluble active mutant of HIV-1 integrase: involvement of both the core and carboxyl-terminal domains in multimerization

Structural studies of human immunodeficiency virus type 1 (HIV-1) integrase have been impeded by the low solubility of the protein. By systematic replacement of hydrophobic residues, we previously identified a single amino acid change (F185K) that dramatically improved the solubility of the catalytic domain of HIV-1 integrase and enabled the structure to be determined by x-ray crystallography. We have introduced the same mutation into full-length HIV-1 integrase. The resulting recombinant protein is soluble and fully active in vitro, whereas, HIV-1 carrying the mutation is replication-defective due to improper virus assembly. Analysis of the recombinant protein by gel filtration and sedimentation equilibrium demonstrate a dimer-tetramer self-association. We find that the regions involved in multimerization map to both the catalytic core and carboxyl-terminal domains. The dramatically improved solubility of this protein make it a good candidate for structural studies.

Monoclonal antibodies against human immunodeficiency virus type 1 integrase: epitope mapping and differential effects on integrase activities in vitro

Human immunodeficiency virus type 1 (HIV-1) integrase (IN) catalyzes the integration of viral DNA into the host chromosome, an essential step in retroviral replication. As a tool to study the structure and function of this enzyme, monoclonal antibodies (MAbs) against HIV-1 IN were produced. Epitope mapping demonstrated that the 17 MAbs obtained could be divided into seven different groups, and the selection of MAbs representing these groups were tested for their effect on in vitro activities of IN. Four groups of MAbs recognized epitopes within the region of amino acids (aa) 1 to 16, 17 to 38, or 42 to 55 in and around the conserved HHCC motif near the N terminus of IN. MAbs binding to these epitopes inhibited end processing and DNA joining and either stimulated or had little effect on disintegration and reintegration activities of IN. Two MAbs binding to epitopes within the region of aa 56 to 102 in the central core or aa 186 to 250 in the C-terminal half of the protein showed only minor effects on the in vitro activities of IN. Three Mabs which recognized on epitope within the region of aa262 to 271 of HIV-1 IN cross-reacted with HIV-2 IN. MAbs binding to this epitope clearly inhibited end processing and DNA joining and stimulated or had little effect on disintegration. In contrast to the N-terminal-specific MAbs, these C-terminal-specific MAbs abolished reintegration activity of IN.

The role of manganese in promoting multimerization and assembly of human immunodeficiency virus type 1 integrase as a catalytically active complex on immobilized long terminal repeat substrates

The integration of a DNA copy of the viral genome into the genome of the host cell is an essential step in the replication of all retroviruses. Integration requires two discrete biochemical reactions; specific processing of each viral long terminal repeat terminus or donor substrate, and a DNA strand transfer step wherein the processed donor substrate is joined to a nonspecific target DNA. Both reactions are catalyzed by a virally encoded enzyme, integrase. A microtiter assay for the strand transfer activity of human immunodeficiency virus type 1 integrase which uses an immobilized oligonucleotide as the donor substrate was previously published (D. J. Hazuda, J. C. Hastings, A. L. Wolfe, and E. A. Emini, Nucleic Acids Res. 22;1121-1122, 1994). We now describe a series of modifications to the method which facilitate study of both the nature and the dynamics of the interaction between integrase and the donor DNA. The enzyme which binds to the immobilized donor is shown to be sufficient to catalyze strand transfer with target DNA substrates added subsequent to assembly; in the absence of the target substrate, the complex was retained on the donor in an enzymatically competent state. Assembly required high concentrations of divalent cation, with optimal activity achieved at 25 mM MnCl2. In contrast, preassembled complexes catalyzed strand transfer equally efficiently in either 1 or 25 mM MnCl2, indicating mechanistically distinct functions for the divalent cation in assembly and catalysis, respectively. Prior incubation of the enzyme in 25 mM MnCl2 was shown to promote the multimerization of integrase in the absence of a DNA substrate and alleviate the requirement for high concentrations of divalent cation during assembly. The superphysiological requirement for MnCl2 may, therefore, reflect an insufficiency for functional self-assembly in vitro. Subunits were observed to exchange during the assembly reaction, suggesting that multimerization can occur either before or coincident with but not after donor binding. These studies both validate and illustrate the utility of this novel methodology and suggest that the approach may be generally useful in characterizing other details of this biochemical reaction.

Human immunodeficiency virus type 1 integrase mutants retain in vitro integrase activity yet fail to integrate viral DNA efficiently during infection

The viral integrase (IN) protein is the only viral protein known to be required for integration of the human immunodeficiency virus type 1 (HIV-1) genome into the host cell DNA, a step in the viral life cycle that is essential for viral replication. To better understand the relationship between in vitro IN activity and IN-mediated integration of viral DNA in an infected cell, we characterized the effects of 13 IN mutations on viral replication in cultured cells. Using HIV-1 genomes that express the hygromycin resistance gene and do not express the HIV-1 env gene, we generated stocks of pseudotype virus coated with the murine leukemia virus amphotropic envelope glycoprotein, containing either wild-type or mutant HIV-1 IN. All mutants produced normal amounts of physical particles, as measured by reverse transcriptase activity and capsid protein (p24) concentration, but they formed three groups based on infectious titer and synthesis of viral DNA. Changes at the three highly conserved acidic residues in the IN core domain (D-64, D-116, and E-152) impair provirus formation without affecting viral DNA synthesis or the accumulation of viral DNA in the nucleus of the infected cell, a phenotype predicted by each mutant's lack of in vitro integrase activity. Mutations at positions N-120, R-199, and W-235 minimally affect in vitro integrase activity, but infectious titers are severely reduced, despite normal synthesis of viral DNA, implying a defect during integration in vivo. Mutations in the zinc binding region (H12C, H16V, and H16C), S81R, and a deletion of residues 32 through 275 yield noninfectious particles that synthesize little or no viral DNA following infection, despite wild-type levels of reverse transcriptase activity and viral RNA in the particles. The two latter classes of mutants suggest that IN can affect DNA synthesis or integration during infection in ways that are not appreciated from currently used assays in vitro.

The metal ion-induced cooperative binding of HIV-1 integrase to DNA exhibits a marked preference for Mn(II) rather than Mg(II)

In this investigation, we examine the interaction between the human immunodeficiency virus type I integrase and oligonucleotides that reflect the sequences of the extreme termini of the viral long terminal repeats (LTRs). The results of gel filtration and a detailed binding density analysis indicate that the integrase binds to the LTR as a high-order oligomer at a density equivalent to 10 +/- 0.8 integrase monomers per 21-base pair LTR. The corresponding binding isotherm displays a Hill coefficient of 2, suggesting that the binding mechanism involves the cooperative interaction between two oligomers. This interaction is quite stable, exhibiting a prolonged half-life (t1/2 approximately 13 h) in the presence of Mn2+ cations. Complexes were less stable when formed with Mg2+ (t1/2 approximately 1 h). The role of Mn2+ appears to be in the induction of the protein-protein interactions that stabilize the bound complexes. In terms of the 3'-end processing of the LTR, similar catalytic rates (kcat approximately 0.06 min-1) were obtained for the stable complex in the presence of either cation. Hence, the apparent preference observed for Mn2+ in standard in vitro integration assays can be attributed entirely to the augmentation in the DNA binding affinity of the integrase.

Conserved sequences in the carboxyl terminus of integrase that are essential for human immunodeficiency virus type 1 replication

We have previously identified a residue in the carboxyl terminus of human immunodeficiency virus type 1 integrase (HIV-1 IN), W-235, the requirement for which is only revealed in viral assays for integrase function (P. M. Cannon, W. Wilson, E. Byles, S. M. Kingsman, and A. J. Kingsman, J. Virol. 68:4768-4775, 1994). Our further analysis of this region of retroviral IN has now identified several sequence motifs which are conserved in all the retroviruses we examined, apart from human spumaretrovirus. We have made mutations within these motifs in HIV-1 IN and examined their phenotypes when reintroduced into an infectious proviral clone. The deleterious effects of several of these mutations demonstrate the importance of these regions for IN function in vivo. We observed a further discrepancy, at a motif that is only conserved in the lentiviruses, in the ability of mutants to function in in vitro and in vivo assays. Substitutions both in this region and at W-235 abolish HIV-1 infectivity but do not affect particle production, morphology, reverse transcription, or nuclear import in T-cell lines. Taken together with the in vitro data suggesting that neither of these residues is directly involved in the catalytic reactions of IN, it seems likely that we have identified regions of IN that are essential for interactions with other components of the integration machinery.

Solution conformation of a peptide corresponding to residues 151-172 of HIV-1 integrase using NMR and CD spectroscopy

The solution structure of a synthetic peptide corresponding to residues 151-172 of HIV-1 integrase has been determined by NMR and CD spectroscopy. Residues 151-172 of HIV-1 integrase were predicted to be an alpha-helix and to be responsible for the oligomerization of HIV-1 integrase. Two-dimensional 1H NMR and CD studies indicate that this synthetic peptide adopts an amphipathic alpha-helical conformation in TFE-containing solution. However, concentration-dependent CD studies reveal that this peptide motif does not form dimers or oligomers in solution as predicted. These results are in agreement with the crystal structure of the catalytic domain of HIV-1 integrase reported recently.

Directed integration of viral DNA mediated by fusion proteins consisting of human immunodeficiency virus type 1 integrase and Escherichia coli LexA protein

We tested whether the selection of target sites can be manipulated by fusing retroviral integrase with a sequence-specific DNA-binding protein. A hybrid protein that has the Escherichia coli LexA protein fused to the C terminus of the human immunodeficiency virus type 1 integrase was constructed. The fusion protein, IN1-288/LA, retained the catalytic activities in vitro of the wild-type human immunodeficiency virus type 1 integrase (WT IN). Using an in vitro integration assay that included multiple DNA fragment as the target DNA, we found that IN1-288/LA preferentially integrated viral DNA into the fragment containing a DNA sequence specifically bound by LexA protein. No bias was observed when the LexA-binding sequence was absent, when the fusion protein was replaced by WT IN, or when LexA protein was added in the reaction containing IN1-288/LA. A majority of the integration events mediated by IN1-288/LA occurred within 30 bp of DNA flanking the LexA-binding sequence. The specificity toward the LexA-binding sequence and the distribution and frequency of target site usage were unchanged when the integrase component of the fusion protein was replaced with a variant containing a truncation at the N or C terminus or both, suggesting that the domain involved in target site selection resides in the central core region of integrase. The integration bias observed with the integrase-LexA hybrid shows that one effective means of altering the selection of DNA sites for integration is by fusing integrase to a sequence-specific DNA-binding protein.

Multimerization determinants reside in both the catalytic core and C terminus of avian sarcoma virus integrase

We have shown previously that the active form of avian sarcoma virus integrase (ASV IN) is a multimer. In this report we investigate IN multimerization properties by a variety of methods that include size exclusion chromatography, chemical cross-linking, and protein overlay assays. We show that removal of the nonconserved C-terminal region of IN results in a reduced capacity for multimerization, whereas deletion of the first 38 amino acids has little effect on the oligomeric state. Binding of a full-length IN fusion protein to various IN fragments indicates that sequences in both the catalytic core (residues 50-207) and a C-terminal region (residues 201-240) contribute to IN self-association. We also observe that the isolated C-terminal fragment (residues 201-286) is capable of self-association. Finally, a single amino acid substitution in the core domain (S85G) produces a severe defect in multimerization. We conclude from these analyses that both the catalytic core and a region in the nonconserved C terminus are involved in ASV integrase multimerization. These results enhance our understanding of intergrase self-association determinants and define a major role of the C-terminal region of ASV integrase in this process.

Genetic analysis of human immunodeficiency virus type 1 integrase and the U3 att site: unusual phenotype of mutants in the zinc finger-like domain

Retroviral integration is the step which leads to establishment of the provirus, cis- and trans-acting regions of the human immunodeficiency type 1 (HIV-1) retrovirus genome, including the attachment site (att) at the ends of the unintegrated viral DNA and the conserved domains within the integrase (IN) protein, have been identified as being important for integration. We investigated the role of each of these regions in the context of an infectious HIV-1 molecular clone through point mutagenesis of the att site and the zinc finger-like and catalytic domains of IN. The effect of each mutation on integration activity was examined by using a single-step infection system with envelope-pseudotype virus. The relative integration efficiency was estimated by monitoring the levels of viral DNA over time in the infected cells. The integration activities of catalytic domain point mutants and att site deletion mutants were estimated to be 0.5 and 5% of wild-type activity, respectively. However, in contrast with previous in vitro cell-free integration studies, alteration of the highly conserved CA dinucleotide resulted in a mutant which still retained 40% of wild-type integration activity. The relative levels of expression of each mutant, as measured by a luciferase reporter gene, correlated with levels of integration. This observation is consistent with those of previous studies indicating that integration is an obligatory step for retroviral gene expression. Interestingly, we found that three different HIV-1 constructs bearing point mutations in the zinc finger-like domain synthesized much lower levels of viral DNA after infection, suggesting impairment of these mutants before or at the initiation of reverse transcription. Western blot (immunoblot) analysis demonstrated wild-type levels of reverse transcriptase within the mutant virions. In vitro endogenous reverse transcription assays indicated that all three mutants in the zinc finger-like domain had wild-type levels of reverse transcriptase activity. These data indicate that in addition to integration, IN may have an effect on the proper course of events in the viral life cycle that precede integration.

Inhibition of the integrase of human immunodeficiency virus (HIV) type 1 by anti-HIV plant proteins MAP30 and GAP31

MAP30 (Momordica anti-HIV protein of 30 kDa) and GAP31 (Gelonium anti-HIV protein of 31 kDa) are anti-HIV plant proteins that we have identified, purified, and cloned from the medicinal plants Momordica charantia and Gelonium multiflorum. These antiviral agents are capable of inhibiting infection of HIV type 1 (HIV-1) in T lymphocytes and monocytes as well as replication of the virus in already-infected cells. They are not toxic to normal uninfected cells because they are unable to enter healthy cells. MAP30 and GAP31 also possess an N-glycosidase activity on 28S ribosomal RNA and a topological activity on plasmid and viral DNAs including HIV-1 long terminal repeats (LTRs). LTRs are essential sites for integration of viral DNA into the host genome by viral integrase. We therefore investigated the effect of MAP30 and GAP31 on HIV-1 integrase. We report that both of these antiviral agents exhibit dose-dependent inhibition of HIV-1 integrase. Inhibition was observed in all of the three specific reactions catalyzed by the integrase, namely, 3' processing (specific cleavage of the dinucleotide GT from the viral substrate), strand transfer (integration), and "disintegration" (the reversal of strand transfer). Inhibition was studied by using oligonucleotide substrates with sequences corresponding to the U3 and U5 regions of HIV LTR. In the presence of 20 ng of viral substrate, 50 ng of target substrate, and 4 microM integrase, total inhibition was achieved at equimolar concentrations of the integrase and the antiviral proteins, with EC50 values of about 1 microM. Integration of viral DNA into the host chromosome is a vital step in the replicative cycle of retroviruses, including the AIDS virus. The inhibition of HIV-1 integrase by MAP30 and GAP31 suggests that impediment of viral DNA integration may play a key role in the anti-HIV activity of these plant proteins.

Mapping domains of retroviral integrase responsible for viral DNA specificity and target site selection by analysis of chimeras between human immunodeficiency virus type 1 and visna virus integrases

Human immunodeficiency virus type 1 (HIV-1) and visna virus integrases were purified from a bacterial expression system and assayed on oligonucleotide substrates derived from each terminus of human immunodeficiency virus type 1 and visna virus linear DNA. Three differences between the proteins were identified, including levels of specific 3'-end processing, patterns of strand transfer, and target site preferences. To map domains of integrase (IN) responsible for viral DNA specificity and target site selection, we constructed and purified chimeric proteins in which the N-terminal, central, and C-terminal regions of these lentiviral integrases were exchanged. All six chimeric proteins were active for disintegration, demonstrating that the active site in the central region of each chimera maintained a functional conformation. Analysis of endonucleolytic processing activity indicated that the N terminus of IN does not contribute to viral DNA specificity; this function must reside in the central region or C terminus of IN. In the viral DNA integration assay, chimeric proteins gave novel patterns of strand transfer products which did not match that of either wild-type IN. Thus, target site selection with a viral DNA terminus as nucleophile could not be mapped to regions of IN defined by these boundaries and may involve interactions between regions. In contrast, when target site preferences were monitored with a new assay in which glycerol stimulates IN-mediated cleavage of nonviral DNA, chimeras clearly segregated between the two wild-type patterns. Target site selection for this nonspecific alcoholysis activity mapped to the central region of IN. This report represents the first detailed description of functional chimeras between any two retroviral integrases.

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+.

Sequences in the human immunodeficiency virus type 1 U3 region required for in vivo and in vitro integration

A series of mutants with alterations in the U3 region of the human immunodeficiency virus type 1 long terminal repeat were made, and the effects of these mutations were evaluated both in vitro and in vivo. When the subterminal 6 to 8 nucleotides of the U3 long terminal repeat were mutated, the resulting provirus was unable to efficiently replicate in vivo, and a mutant oligonucleotide which mimicked the mutation could not be efficiently cleaved but could be joined to target DNA by wild-type recombinant integrase protein in vitro. These results suggest that this region is important in the specific recognition of the viral DNA by the integrase protein.

Monoclonal antibodies against Rous sarcoma virus integrase protein exert differential effects on integrase function in vitro

We have prepared and characterized several monoclonal antibodies (MAbs) against the Rous sarcoma virus integrase protein (IN) with the aim of employing these specific reagents as tools for biochemical and biophysical studies. The interaction of IN with the purified MAbs and their Fab fragment derivatives was demonstrated by Western blot (immunoblot), enzyme-linked immunosorbent assay, and size exclusion chromatography. A series of truncated IN proteins was used to determine regions in the protein important for recognition by the antibodies. The MAbs described here recognize epitopes that lie within the catalytic core region of IN (amino acids 50 to 207) and are likely to be conformational. A detailed functional analysis was carried out by investigating the effects of Fab fragments as well as of intact MAbs on the activities of IN in vitro. These studies revealed differential effects which fall into three categories. (i) One of the antibodies completely neutralized the processing as well as the joining activity and also reduced the DNA binding capacity as determined by a nitrocellulose filter binding assay. On the other hand, this MAb did not abolish the cleavage-ligation reaction on a disintegration substrate and the nonspecific cleavage of DNA by IN. The cleavage pattern generated by the IN-MAb complex on various DNA substrates closely resembled that produced by mutant IN proteins which show a deficiency in multimerization. Preincubation of IN with substrate protected the enzyme from inhibition by this antibody. (ii) Two other antibodies showed a general inhibition of all IN activities tested. (iii) In contrast, a fourth MAb stimulated the in vitro joining activity of IN. Size exclusion chromatography demonstrated that IN-Fab complexes from representatives of the three categories of MAbs exhibit different stoichiometric compositions that suggest possible explanations for their contrasting effects and may provide clues to the relationship between the structure and function of IN.

The DNA-binding domain of HIV-1 integrase has an SH3-like fold

We have determined the solution structure of the DNA-binding domain of HIV-1 integrase by nuclear magnetic resonance spectroscopy. In solution, this carboxyterminal region of integrase forms a homodimer, consisting of two structures that closely resemble Src-homology 3 (SH3) domains. Lys 264, previously identified by mutagenesis studies to be important for DNA binding of the integrase, as well as several adjacent basic amino acids are solvent exposed. The identification of an SH3-like domain in integrase provides a new potential target for drug design.

Substrate specificity of Ty1 integrase

Integration of the Saccharomyces cerevisiae retrotransposon Ty1 requires the element-encoded integrase (IN) protein, which is a component of cytoplasmic virus-like particles (VLPs). Using purified recombinant Ty1 IN and an oligonucleotide integration assay based on Ty1 long terminal repeat sequences, we have compared IN activity on substrates having either wild-type or altered donor ends. IN showed a marked preference for blunt-end substrates terminating in an A:T pair over substrates ending in a G:C pair or a 3' dideoxyadenosine. VLP activity on representative substrates also showed preference for donor strands which have an adenosine terminus. Staggered-end substrates showed little activity when nucleotides were removed from the end of the wild-type donor strand, but removal of one nucleotide from the complementary strand did not significantly diminish activity. Removal of additional nucleotides from the complementary strand reduced activity to minimal detection levels. These results suggest that the sequence specificity of Ty1 IN is not stringent in vitro. The absence of Ty1 IN-mediated 3' dinucleotide cleavage, a characteristic of retroviral integrases, was demonstrated by using selected substrates. In addition to the forward reaction, both recombinant IN and VLP-associated IN carry out the reverse disintegration reaction with long terminal repeat-based dumbbell substrates. Disintegration activity exhibits sequence preferences similar to those observed for the forward reaction.

Multiple effects of mutations in human immunodeficiency virus type 1 integrase on viral replication

The integration of a DNA copy of the human immunodeficiency virus type 1 (HIV-1) genome into a chromosome of an infected cell is a pivotal step in virus replication. Integration requires the activity of the virus-encoded integrase, which enters the cell as a component of the virion. Results of numerous mutagenesis studies have identified amino acid residues and protein domains of HIV-1 integrase critical for in vitro activity, but only a few of these mutants have been studied for their effects on HIV replication. We have introduced site-directed changes into an infectious DNA clone of HIV-1 and show that integrase mutations can affect virus replication at a variety of steps. We identified mutations that altered virion morphology, levels of particle-associated integrase and reverse transcriptase, and viral DNA synthesis. One replication-defective mutant virus which had normal morphology and protein composition displayed increased levels of circular viral DNA following infection of a T-cell line. This virus also had a significant titer in a CD4-positive indicator cell assay, which requires the viral Tat protein. Although unintegrated viral DNA can serve as a template for Tat expression in infected indicator cells, this level of expression is insufficient to support a spreading viral infection in CD4-positive lymphocytes.

Characterization of the human spuma retrovirus integrase by site-directed mutagenesis, by complementation analysis, and by swapping the zinc finger domain of HIV-1

The human spuma retrovirus or foamy virus integrase (HFV IN) is an enzymatically active protein consisting of domains similar to other retroviral integrases: an amino-terminal HH-CC finger, a centrally located region with the conserved D, D-35-E protein motif required for catalytic activity and oligomerization, and at least one DNA binding domain implicated in the 3' DNA processing activity and integrase. Recombinant, purified HFV IN protein carrying 10 histidine residues displays a site-specific endonuclease, an integrase, and a disintegrase activity with oligonucleotide substrates that mimic the viral long terminal repeat (LTR) ends. Site-directed mutagenesis of conserved HFV IN residues of the catalytic domain had increased endonuclease and disintegrase activities. Deletion mutants at both ends of the HFV IN protein were generated, purified, and characterized. Unexpectedly, it was found that the HFV integrase and disintegrase activities require an intact NH2-terminal sequence and that COOH-terminal deletions led to an increase in disintegrase activity. The HH-CC finger of HFV IN was exchanged with that of the human immunodeficiency virus-1 (HIV-1) IN protein. The resulting chimeric IN had a 3' processing activity that utilized the HFV LTR instead of the HIV LTR, indicating that the central domain is crucial for substrate recognition. Functional complementation of the amino-terminal deletion mutant of HFV IN was achieved by a carboxyl-terminal deletion mutant of the chimeric IN, resulting in high levels of integrase activity.

An essential interaction between distinct domains of HIV-1 integrase mediates assembly of the active multimer

Integrase mediates integration of the retroviral genome into a host cell chromosome, an essential step in the viral life cycle. In vitro, a stable complex containing only purified human immunodeficiency virus (HIV) integrase and a model viral DNA substrate processively executes the 3'-end processing and DNA joining steps in the integration reaction. We examined the relationship of three essential components of the HIV integrase: the HHCC domain, a putative zinc-finger near the N terminus; the phylogenetically conserved "DD35E" motif, which defines the catalytic domain; and a feature recognized by its sensitivity to the alkylating agent N-ethylmaleimide (NEM). HIV integrase is a multimer, and these three components can be distributed among at least two subunits of the multimeric enzyme. The components function asymmetrically in the active multimer; the DD35E motif and NEM-sensitive site are required in trans to the HHCC region. A divalent cation-dependent interaction involving the NEM-sensitive site of one integrase subunit and the HHCC region of another subunit points to a role for these two features of integrase in multimer assembly. Deletion of the HHCC domain, or modification of integrase with NEM, impaired the assembly of a stable complex between integrase and viral DNA, suggesting that this initial step in the integration pathway requires assembly of the active integrase multimer.

Inhibition of human immunodeficiency virus integrase by bis-catechols

The human immunodeficiency virus type 1 (HIV-1) integrase protein is required for the productive infection of T-lymphoid cells in culture (R. L. LaFemina, C. L. Schneider, H. L. Robbins, P. L. Callahan, K. LeGrow, E. Roth, W. A. Schleif, and E. A. Emini, J. Virol. 66:7414-7419, 1992). This observation suggests that chemical inhibitors of integrase may prevent the spread of HIV in infected individuals. In our search for such potential chemotherapeutic agents, we observed that beta-conidendrol inhibits both the sequence-dependent and sequence-independent endonucleolytic activities of integrase with comparable potencies in vitro (50% inhibitory concentration, 500 nM). Structurally related compounds tested for their abilities to inhibit integrase generated a limited structure-activity analysis which demonstrated that potency is associated with the bis-catechol structure: two pairs of adjacent hydroxyls on separate benzene rings. beta-Conidendrol did not inhibit several other endonucleases and/or phosphoryltransferases. Although beta-conidendrol was not effective in preventing HIV-1 infection in cell culture, the in vitro data demonstrate that it is possible to identify selective agents targeted against this essential HIV-1 function.

Bacterial transposases and retroviral integrases

Transposable genetic elements have adopted two major strategies for their displacement from one site to another within and between genomes. One involves passage through an RNA intermediate prior to synthesis of a DNA copy while the other is limited uniquely to DNA intermediates. For both types of element, recombination reactions involved in integration are carried out by element-specific enzymes. These are called transposases in the case of DNA elements and integrases in the case of the best-characterized RNA elements, the retroviruses and retrotransposons. In spite of major differences between these two transposition strategies, one step in the process, that of insertion, appears to be chemically identical. Current evidence suggests that the similarities in integration mechanism are reflected in amino acid sequence similarities between the integrases and many transposases. These similarities are particularly marked in a region which is thought to form part of the active site, namely the DDE motif. In the light of these relationships, we attempt here to compare mechanistic aspects of retroviral integration with transposition of DNA elements and to summarize current understanding of the functional organization of integrases and transposases.

Human immunodeficiency virus type 1 integrase: effects of mutations on viral ability to integrate, direct viral gene expression from unintegrated viral DNA templates, and sustain viral propagation in primary cells

Integrase is the only viral protein necessary for integration of retroviral DNA into chromosomal DNA of the host cell. Biochemical analysis of human immunodeficiency virus type 1 (HIV-1) integrase with purified protein and synthetic DNA substrates has revealed extensive information regarding the mechanism of action of the enzyme, as well as identification of critical residues and functional domains. Since in vitro reactions are carried out in the absence of other viral proteins and they analyze strand transfer of only one end of the donor substrate, they do not define completely the process of integration as it occurs during the course of viral infection. In an effort to further understand the role of integrase during viral infection, we initially constructed a panel of 24 HIV-1 mutants with specific alanine substitutions throughout the integrase coding region and analyzed them in a human T-cell line infection. Of these mutant viruses, 12 were capable of sustained viral replication, 11 were replication defective, and 1 was temperature sensitive for viral growth. The replication defective viruses express and correctly process the integrase and Gag proteins. Using this panel of mutants and an additional set of 18 mutant viruses, we identified nine amino acids which, when replaced with alanine, destroy integrase activity. Although none of the replication-defective mutants are able to integrate into the host genome, a subset of them with alterations in the catalytic triad are capable of Tat-mediated transactivation of an indicator gene linked to the viral long terminal repeat promoter. We present evidence that integration of the HIV-1 provirus is essential not only for productive infection of T cells but also for virus passage in both cultured peripheral blood lymphocytes and macrophage cells.

Characterization of recombinant murine leukemia virus integrase

Retroviral integration involves two DNA substrates that play different roles. The viral DNA substrate is recognized by virtue of specific nucleotide sequences near the end of a double-stranded DNA molecule. The target DNA substrate is recognized at internal sites with little sequence preference; nucleosomal DNA appears to be preferred for this role. Despite this apparent asymmetry in the sequence, structure, and roles of the DNA substrates in the integration reaction, the existence of distinct binding sites for viral and target DNA substrates has been controversial. In this report, we describe the expression in Escherichia coli and purification of Moloney murine leukemia virus integrase as a fusion protein with glutathione S-transferase, characterization of its activity by using several model DNA substrates, and the initial kinetic characterization of its interactions with a model viral DNA substrate. We provide evidence for functionally and kinetically distinct binding sites for viral and target DNA substrates and describe a cross-linking assay for DNA binding at a site whose specificity is consistent with the target DNA binding site.

Crystal structure of the catalytic domain of HIV-1 integrase: similarity to other polynucleotidyl transferases

HIV integrase is the enzyme responsible for inserting the viral DNA into the host chromosome; it is essential for HIV replication. The crystal structure of the catalytically active core domain (residues 50 to 212) of HIV-1 integrase was determined at 2.5 A resolution. The central feature of the structure is a five-stranded beta sheet flanked by helical regions. The overall topology reveals that this domain of integrase belongs to a superfamily of polynucleotidyl transferases that includes ribonuclease H and the Holliday junction resolvase RuvC. The active site region is identified by the position of two of the conserved carboxylate residues essential for catalysis, which are located at similar positions in ribonuclease H. In the crystal, two molecules form a dimer with a extensive solvent-inaccessible interface of 1300 A2 per monomer.

Juxtaposition of two viral DNA ends in a bimolecular disintegration reaction mediated by multimers of human immunodeficiency virus type 1 or murine leukemia virus integrase

Integration of retroviral DNA involves a coordinated joining of the two ends of a viral DNA molecule into precisely spaced sites on target DNA. In this study, we designed an assay that requires two separate oligonucleotides to be brought together via interactions between integrase promoters to form a "crossbones" substrate that mimics the integration intermediate. The crossbones substrate contains two viral DNA ends, each joined to one strand of target DNA and separated by a defined length of target DNA. We showed that purified integrases of human immunodeficiency virus type 1 (HIV-1) and murine leukemia virus (MLV) could mediate a concerted strand cleavage-ligation between the two half-substrates at one or both viral DNA joining sites (trans disintegration). Another major product, termed fold-back, resulted from an intramolecular attack on the phosphodiester bond at the viral-target DNA junction by the 3'-OH group of the same DNA molecule (cis disintegration). The activity of integrase on the crossbones substrate depended on the presence of viral DNA sequences. For trans disintegration, the optimal length of target DNA between the viral DNA joining sites of the crossbones substrate corresponded to the spacing between the staggered joints formed on two opposite strands of target DNA during retroviral DNA integration in vivo. The activity of integrases on crossbones did not require complementary base pairing between the two half-substrates, indicating that the half-substrates were juxtaposed solely through protein-DNA interactions. The crossbones assay, therefore, measures the ability of integrase to juxtapose two viral DNA ends, an activity which heretofore has been difficult to detect by using purified integrase in conventional assays. Certain mutant integrases that were otherwise inactive with the crossbones substrate could complement one another, indicating that no single protomer in the integrase multimer requires a complete set of functional domains either for catalytic activity or for juxtaposition of the two viral DNA ends by the active multimer.

Characterization of the minimal DNA-binding domain of the HIV integrase protein

The human immunodeficiency virus (HIV) integrase (IN) protein mediates an essential step in the retroviral lifecycle, the integration of viral DNA into human DNA. A DNA-binding domain of HIV IN has previously been identified in the C-terminal part of the protein. We tested truncated proteins of the C-terminal region of HIV-1 IN for DNA binding activity in two different assays: UV-crosslinking and southwestern blot analysis. We found that a polypeptide fragment of 50 amino acids (IN220-270) is sufficient for DNA binding. In contrast to full-length IN protein, this domain is soluble under low salt conditions. DNA binding of IN220-270 to both viral DNA and non-specific DNA occurs in an ion-independent fashion. Point mutations were introduced in 10 different amino acid residues of the DNA-binding domain of HIV-2 IN. Mutation of basic amino acid K264 results in strong reduction of DNA binding and of integrase activity.

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.

In vitro integration of retrotransposon Ty1: a direct physical assay

Retrotransposon Ty1 of Saccharomyces cerevisiae inserts a double-stranded Ty1 cDNA into the yeast genome by a reaction analogous to the integration mechanism used by retroviruses. A quantitative in vitro integration assay that directly detects integrative recombination products was developed for Ty1. Blunt-ended artificial radioactive substrates bearing Ty1 termini integrate into circular or linear target DNAs. The reaction is specific for native integrase isolated in the form of virus-like particles; virus-like particles prepared from integrase mutants were completely inactive in this assay. The products are radioactive, allowing direct detection after gel electrophoresis by autoradiography. Using this simple and amenable system, we characterized the biochemical requirements of the system and the structures of the major integration products. Two classes of products were detected: those that were the result of bona fide complete integration events (concerted reactions) and single-end joinings of substrate to target (half-reactions). Additionally, we used a genetic selection scheme to identify and characterize target sites of complete integration events into a circular target plasmid; a 5-bp target site duplication flanking the inserted DNA resembling the duplication characteristic of in vivo integration was observed.

Ty1 in vitro integration: effects of mutations in cis and in trans

Mutations within the TYB gene of Ty1 encoding integrase (IN) as well as alterations in its substrate, a linear DNA molecule, were examined for their effects on in vitro IN activity, using a recently developed physical assay. Five different codon-insertion mutations, two frameshift mutations, and one missense mutation, previously identified as transposition-deficient mutations, were tested. Virus-like particles, the source of IN, from two different protease mutants and a reverse transcriptase mutant exhibited near-normal to normal IN activity. Two frameshift mutations mapping within the phylogenetically variable C-terminal domain of IN resulted in significant in vitro IN activity. In contrast, three mutations within the amino-terminal conserved domain of IN completely abolished IN activity. When the substrate termini were mutated, we found that substrates with as few as 4 bp of Ty1 termini were capable of efficiently generating integration products. Surprisingly, certain substrates that lacked obvious similarity to Ty1 termini were also readily integrated into both linear and circular targets, whereas others were not used as substrates at all. Termini rich in adenosine residues were among the more active substrates; however, certain substrates lacking terminal adenosine residues can form small quantities of integration products, including complete integration reactions.

Ty1 in vitro integration: effects of mutations in cis and in trans

Mutations within the TYB gene of Ty1 encoding integrase (IN) as well as alterations in its substrate, a linear DNA molecule, were examined for their effects on in vitro IN activity, using a recently developed physical assay. Five different codon-insertion mutations, two frameshift mutations, and one missense mutation, previously identified as transposition-deficient mutations, were tested. Virus-like particles, the source of IN, from two different protease mutants and a reverse transcriptase mutant exhibited near-normal to normal IN activity. Two frameshift mutations mapping within the phylogenetically variable C-terminal domain of IN resulted in significant in vitro IN activity. In contrast, three mutations within the amino-terminal conserved domain of IN completely abolished IN activity. When the substrate termini were mutated, we found that substrates with as few as 4 bp of Ty1 termini were capable of efficiently generating integration products. Surprisingly, certain substrates that lacked obvious similarity to Ty1 termini were also readily integrated into both linear and circular targets, whereas others were not used as substrates at all. Termini rich in adenosine residues were among the more active substrates; however, certain substrates lacking terminal adenosine residues can form small quantities of integration products, including complete integration reactions.

In vitro integration of retrotransposon Ty1: a direct physical assay

Retrotransposon Ty1 of Saccharomyces cerevisiae inserts a double-stranded Ty1 cDNA into the yeast genome by a reaction analogous to the integration mechanism used by retroviruses. A quantitative in vitro integration assay that directly detects integrative recombination products was developed for Ty1. Blunt-ended artificial radioactive substrates bearing Ty1 termini integrate into circular or linear target DNAs. The reaction is specific for native integrase isolated in the form of virus-like particles; virus-like particles prepared from integrase mutants were completely inactive in this assay. The products are radioactive, allowing direct detection after gel electrophoresis by autoradiography. Using this simple and amenable system, we characterized the biochemical requirements of the system and the structures of the major integration products. Two classes of products were detected: those that were the result of bona fide complete integration events (concerted reactions) and single-end joinings of substrate to target (half-reactions). Additionally, we used a genetic selection scheme to identify and characterize target sites of complete integration events into a circular target plasmid; a 5-bp target site duplication flanking the inserted DNA resembling the duplication characteristic of in vivo integration was observed.

Molecular dynamics simulation of a leucine zipper motif predicted for the integrase of human immunodeficiency virus type 1

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 1 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 alpha-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 beta-turn is also included as a negative control. At the beginning of the search, two starting conformations--namely, the standard right-handed alpha-helix and the fully stretched conformations--are generated for each peptide. Structures generated as standard alpha-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 alpha-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 alpha-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.

Human immunodeficiency virus type 1 integrase: effect on viral replication of mutations at highly conserved residues

Sequence comparisons of the integrase (IN) proteins from different retroviruses have identified several highly conserved residues. We have introduced mutations at 16 of these sites into the integrase gene of human immunodeficiency virus type 1 and analyzed the phenotypes of the resulting viruses. The viruses were all normal for p24 content and reverse transcriptase activity. In addition, all of the mutants could infect T-cell lines and undergo reverse transcription, as assessed by PCR analysis. Most of the mutant viruses also had normal Western blot (immunoblot) profiles, although three of the mutations resulted in reduced signals for IN relative to the wild type on the immunoblots and mutation of residue W235 completely abolished recognition of the protein by pooled sera from human immunodeficiency virus type 1-positive patients. Mutations that have previously been shown to abolish activity in in vitro studies produced noninfectious viruses. The substitution of W235 was notable in producing a noninfectious virus, despite previous reports of this residue being nonessential for IN activity in vitro (A.D. Leavitt, L. Shiue, and H.E. Varmus, J. Biol. Chem. 268:2113-2119, 1993). In addition, we have identified four highly conserved residues that can be mutated without any affect on viral replication in T-cell lines.

A stable complex between integrase and viral DNA ends mediates human immunodeficiency virus integration in vitro

Retroviral replication depends on integration of the viral genome into a chromosome of the host cell. The steps in this process are orchestrated in vivo by a large nucleoprotein complex and are catalyzed by the retroviral enzyme integrase. Several biochemical properties of the in vivo nucleoprotein complex were reproduced in vitro with purified integrase of human immunodeficiency virus type 1 and model viral DNA substrates. A stable complex between integrase and viral DNA was detected as an early intermediate in the integration reaction. After formation of this initial complex, the enzyme processively catalyzed the 3' end processing and strand transfer steps in the reaction. Complexes containing only purified integrase and the model viral DNA end were stable under a variety of conditions and efficiently used nonviral DNA molecules as integration targets. These complexes required a divalent cation for their formation, and their stability was highly dependent on the 5'-terminal dinucleotide of the viral DNA, for which no functional role has previously been defined. Thus, interactions between integrase and the extreme ends of the viral DNA molecule may be sufficient to account for the stability of the in vivo integration complex.

Retroviral integration: in vitro host site selection by avian integrase

Viral integrase catalyzes the integration of the linear viral DNA genome into the chromatin of the infected host cell, an essential step in the life cycle of retroviruses. The reaction produces a characteristic small duplication of host sequences at the site of integration, implying that there is a close juxtaposition of the viral DNA ends during a concerted integration event. We have used an in vitro assay to measure the concerted integration of virus-like plasmid DNA into naked lambda DNA catalyzed by virion purified avian integrase. In contrast to in vivo avian integration, which has strong fidelity for a 6-bp duplication, purified avian integrase in the context of this assay produced a distribution of duplication sizes, with the 6-bp size dominating. The metal cofactor Mg2+ induced increased fidelity for the 6-bp duplication relative to that with Mn2+. The immediate sequence of the host site may also influence duplication size in that we found sites that sustained multiple independent integration events producing the same duplication size. Additionally, for each set of cloned integration sites (5, 6, and 7 bp), a unique but similar symmetrical pattern of G/C and A/T sequence biases was found. Using duplex oligonucleotides as target substrates, we tested the significance of the 6-bp G/C and A/T pattern for site selection. In the context of this assay, which is likely dominated by the integration of only one viral end, the 6-bp pattern was not preferred. Instead, integration was predominantly into the 3' ends of the oligonucleotides. The combined results of the lambda and oligonucleotide assays indicated that although host site selection has properties in common with recognition of the viral DNA termini, the nonrandom sequence preferences seen for host site selection were not identical to the sequence requirements for long terminal repeat recognition.

Substrate features important for recognition and catalysis by human immunodeficiency virus type 1 integrase identified by using novel DNA substrates

The integrase encoded by human immunodeficiency virus type 1 (HIV-1) is required for integration of viral DNA into the host cell chromosome. In vitro, integrase mediates a concerted cleavage-ligation reaction (strand transfer) that results in covalent attachment of viral DNA to target DNA. With a substrate that mimics the strand transfer product, integrase carries out disintegration, the reverse of the strand transfer reaction, resolving this integration intermediate into its viral and target DNA parts. We used a set of disintegration substrates to study the catalytic mechanism of HIV-1 integrase and the interaction between the protein and the viral and target DNA sequence. One substrate termed dumbbell consists of a single oligonucleotide that can fold to form a structure that mimics the integration intermediate. Kinetic analysis using the dumbbell substrate showed that integrase turned over, establishing that HIV-1 integrase is an enzyme. Analysis of the disintegration activity on the dumbbell substrate and its derivatives showed that both the viral and target DNA parts of the molecule were required for integrase recognition. Integrase recognized target DNA asymmetrically: the target DNA upstream of the viral DNA joining site played a much more important role than the downstream target DNA in protein-DNA interaction. The site of transesterification was determined by both the DNA sequence of the viral DNA end and the structure of the branched substrate. Using a series of disintegration substrates with various base modifications, we found that integrase had relaxed structural specificity for the hydroxyl group used in transesterification and could tolerate distortion of the double-helical structure of these DNA substrates.

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.

In vitro activities of purified visna virus integrase

Although integration generally is considered a critical step in the retrovirus life cycle, it has been reported that visna virus, which causes degenerative neurologic disease in sheep, can productively infect sheep choroid plexus cells without detectable integration. To ascertain whether the integrase (IN) of visna virus is an inherently defective enzyme and to create tools for further study of integration of the phylogenetically related human immunodeficiency virus type 1 (HIV-1), we purified visna virus IN by using a bacterial expression system and applied various in vitro oligonucleotide-based assays to studying this protein. We found that visna virus IN demonstrates the full repertoire of in vitro functions characteristic of retroviral integrases. In particular, visna virus IN exhibits site-specific endonuclease activity following the invariant CA found two nucleotides from the 3' ends of viral DNA (processing activity), joins processed oligonucleotides to various sites on other oligonucleotides (strand transfer or integration activity), and reverses the integration reaction by resolving a complex that mimics one end of viral DNA integrated into host DNA (disintegration activity). In addition, although it has been reported that purified HIV-1 IN cannot specifically nick visna virus DNA ends, purified visna virus IN does specifically process and integrate HIV-1 DNA ends.

Rous sarcoma virus integrase protein: mapping functions for catalysis and substrate binding

Rous sarcoma virus (RSV), like all retroviruses, encodes an integrase protein that is responsible for covalently joining the reverse-transcribed viral DNA to host DNA. We have probed the organization of functions within RSV integrase by constructing mutant derivatives and assaying their activities in vitro. We find that deletion derivatives lacking the amino-terminal 53 amino acids, which contain the conserved H-X(3-7)-H-X(23-32)-C-X(2)-C (HHCC) Zn(2+)-binding motif, are greatly impaired in their ability to carry out two reactions characteristic of integrase proteins: specific cleavage of the viral DNA termini and DNA strand transfer. Deletion mutants lacking the carboxyl-terminal 69 amino acids are also unable to carry out these reactions. However, all deletion mutants that retain the central domain are capable of carrying out disintegration, an in vitro reversal of the normal DNA strand transfer reaction, indicating that the catalytic center probably lies within this central region. Another conserved motif, D-X(39-58)-D-X(35)-E, is found in this central domain. These findings with RSV integrase closely parallel previous findings with human immunodeficiency virus integrase, indicating that a modular catalytic domain is a general feature of this family of proteins. Surprisingly, and unlike results obtained so far with human immunodeficiency virus integrase, efficient strand transfer activity can be restored to a mutant RSV integrase lacking the amino-terminal HHCC domain by fusion to various short peptides. Furthermore, these fusion proteins retain the substrate specificity of RSV integrase. These data support a model in which the integrase activities required for strand transfer in vitro, including substrate recognition, multimerization, and catalysis, all lie primarily outside the amino-terminal HHCC domain.

Intermolecular disintegration and intramolecular strand transfer activities of wild-type and mutant HIV-1 integrase

We report the activities of HIV integrase protein on a novel DNA substrate, consisting of a pair of gapped duplex molecules. Integrase catalyzed an intermolecular disintegration reaction that requires positioning of a pair of the gapped duplexes in a configuration that resembles the intgration intermediate. However, the major reaction resulted from an intramolecular reaction involving a single gapped duplex, giving rise to a hairpin. Surprisingly, a deletion mutant of integrase that lacks both the amino and carboxyl terminal regions still catalyzed the intermolecular disintegration reaction, but supported only a very low level of the intramolecular reaction. The central core region of integrase is therefore sufficient to both bind the gapped duplex DNA and juxtapose a pair of such molecules through protein-protein interactions. We suggest that the branched DNA structures of the previously reported disintegration substrate, and the intermolecular disintegration substrate described here, assist in stabilizing protein-protein interactions that otherwise require the amino and carboxy terminal regions of integrase.

Activities of the feline immunodeficiency virus integrase protein produced in Escherichia coli

Retroviral DNA integration requires the activity of at least one viral protein, the integrase (IN) protein. We cloned and expressed the integrase gene of feline immunodeficiency virus (FIV) in Escherichia coli as a fusion to the malE gene and purified the IN fusion protein by affinity chromatography. The protein is active in site-specific cleavage of the viral DNA ends, DNA strand transfer, and disintegration. FIV IN has a relaxed viral DNA substrate requirement: it cleaves and integrates FIV DNA termini, human immunodeficiency virus DNA ends, and Moloney murine leukemia virus DNA ends with high efficiencies. In the cleavage reaction, IN exposes a specific phosphodiester bond near the viral DNA end to nucleophilic attack. In vitro, either H2O, glycerol, or the 3' OH group of the viral DNA terminus can serve as nucleophile in this reaction. We found that FIV IN preferentially uses the 3' OH ends of the viral DNA as nucleophile, whereas HIV IN protein preferentially uses H2O and glycerol as nucleophiles.

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.