Selection of amino acid substitutions restoring activity of HIV-1 integrase mutated in its catalytic site using the yeast Saccharomyces cerevisiae

The integration of proviral DNA into the genome of the host cell is an essential step in the replication of retroviruses. This reaction is catalyzed by a viral-encoded enzyme, the integrase (IN). We have previously shown that human immunodeficiency virus type 1 (HIV-1) IN causes a lethal effect when expressed in yeast cells. This system, called yeast lethal assay, was used as a tool to study IN activity in a cellular context. The yeast lethal assay allowed the selection and characterization of mutations affecting both the lethal phenotype and the in vitro IN activities.IN mutants were produced by random PCR mutagenesis in an IN gene bearing the inactivating D116A mutation in the catalytic site. The corresponding D116A substituted IN does not lead to lethality in yeast. Subsequent selection of mutants able to restore the lethal effect of IN was carried out using the yeast lethal assay. We isolated three mutants presenting a restored phenotype. The mutated IN genes were sequenced and the corresponding proteins were purified to characterize their in vitro activities. The three mutants presented restoration of the in vitro strand transfer activity, while 3' processing was only partially restored.The three mutants differ from D116A IN by at least one amino acid substitution located in the N-terminal domain of the protein, outside of the active site. These new mutated HIV-1 INs may therefore allow a better understanding of the N-terminal domain function in the integration reaction. In addition, these results support our hypothesis that explains the lethal effect as a consequence of the nuclear damage caused by wild-type IN in yeast cells. These data also indicate that the yeast lethal assay can be used as a tool to study the retroviral integration mechanism in a cellular context and to select specific inhibitors.     

Human immunodeficiency virus integrase protein requires a subterminal position of its viral DNA recognition sequence for efficient cleavage.

Retroviral integration requires cis-acting sequences at the termini of linear double-stranded viral DNA and a product of the retroviral pol gene, the integrase protein (IN). IN is required and sufficient for generation of recessed 3' termini of the viral DNA (the first step in proviral integration) and for integration of the recessed DNA species in vitro. Human immunodeficiency virus type 1 (HIV-1) IN, expressed in Escherichia coli, was purified to near homogeneity. The substrate sequence requirements for specific cleavage and integration of retroviral DNA were studied in a physical assay, using purified IN and short duplex oligonucleotides that correspond to the termini of HIV DNA. A few point mutations around the IN cleavage site substantially reduced cleavage; most other mutations did not have a drastic effect, suggesting that the sequence requirements are limited. The terminal 15 bp of the retroviral DNA were demonstrated to be sufficient for recognition by IN. Efficient specific cutting of the retroviral DNA by IN required that the cleavage site, the phosphodiester bond at the 3' side of a conserved CA-3' dinucleotide, be located two nucleotides away from the end of the viral DNA; however, low-efficiency cutting was observed when the cleavage site was located one, three, four, or five nucleotides away from the terminus of the double-stranded viral DNA. Increased cleavage by IN was detected when the nucleotides 3' of the CA-3' dinucleotide were present as single-stranded DNA. IN was found to have a strong preference for promoting integration into double-stranded rather than single-stranded DNA.     

Moloney Murine Leukemia Virus Integrase Protein Augments Viral DNA Synthesis in Infected Cells

Mutations in the IN domain of retroviral DNA may affect multiple steps of the virus life cycle, suggesting that the IN protein may have other functions in addition to its integration function. We previously reported that the human immunodeficiency virus type 1 IN protein is required for efficient viral DNA synthesis and that this function requires specific interaction with other viral components but not enzyme (integration) activity. In this report, we characterized the structure and function of the Moloney murine leukemia virus (MLV) IN protein in viral DNA synthesis. Using an MLV vector containing green fluorescent protein as a sensitive reporter for virus infection, we found that mutations in either the catalytic triad (D184A) or the HHCC motif (H61A) reduced infectivity by approximately 1,000-fold. Mutations that deleted the entire IN (DeltaIN) or 34 C-terminal amino acid residues (Delta34) were more severely defective, with infectivity levels consistently reduced by 10,000-fold. Immunoblot analysis indicated that these mutants were similar to wild-type MLV with respect to virion production and proteolytic processing of the Gag and Pol precursor proteins. Using semiquantitative PCR to analyze viral cDNA synthesis in infected cells, we found the Delta34 and DeltaIN mutants to be markedly impaired while the D184A and H61A mutants synthesized cDNA at levels similar to the wild type. The DNA synthesis defect was rescued by complementing the Delta34 and DeltaIN mutants in trans with either wild-type IN or the D184A mutant IN, provided as a Gag-IN fusion protein. However, the DNA synthesis defect of DeltaIN mutant virions could not be complemented with the Delta34 IN mutant. Taken together, these analyses strongly suggested that the MLV IN protein itself is required for efficient viral DNA synthesis and that this function may be conserved among other retroviruses.     

Human immunodeficiency virus type 1 incorporated with fusion proteins consisting of integrase and the designed polydactyl zinc finger protein E2C can bias integration of viral DNA into a predetermined chromosomal region in human cells

In vitro studies using fusion proteins consisting of human immunodeficiency virus type 1 integrase (IN) and a synthetic polydactyl zinc finger protein E2C, a sequence-specific DNA-binding protein, showed that integration of retroviral DNA can be biased towards a contiguous 18-bp E2C-recognition site. To determine whether the fusion protein strategy can achieve site-specific integration in vivo, viruses were prepared by cotransfection and various IN-E2C fusion proteins were packaged in trans into virions. The resulting viruses incorporated with the IN-E2C fusion proteins were functional and capable of performing integration at a level ranging from 1 to 24% of that of viruses containing wild-type (WT) IN. Two of the more infectious viruses, which contained E2C fused to either the N (E2C/IN) or to the C (IN/E2C) terminus of IN, were tested for their ability to direct integration into a unique E2C-binding site present within the 5' untranslated region of erbB-2 gene on human chromosome 17. The copy number of proviral DNA was measured using a quantitative real-time nested-PCR assay, and the specificity of directed integration was determined by comparing the number of proviruses within the vicinity of the E2C-binding site to that in the whole genome. Viruses containing IN/E2C fusion proteins had sevenfold higher preference for integrating near the E2C-binding site than those viruses containing WT IN, whereas viruses containing E2C/IN had 10-fold higher preference. The results indicated that the IN-E2C fusion protein strategy is capable of directing integration of retroviral DNA into a predetermined chromosomal region in the human genome.     

Analysis of mutant Moloney murine leukemia viruses containing linker insertion mutations in the 3'' region of pol.

Twelve linker insertion mutations have been constructed in the 3' part of the pol gene of Moloney murine leukemia virus. This region of the Moloney murine leukemia virus genome encodes IN or p46pol, which is required for integration of the retroviral DNA into the host cell chromosome. Viral proteins synthesized by these mutants were used to pseudotype a neo-containing retroviral vector. Ten of twelve linker insertion mutant pseudotypes were unable to generate stable proviruses in infected mouse cells, as measured by the formation of G418-resistant colonies. Two mutants mapping at the 3' terminus of the IN-encoding region were competent for the formation of stable vector proviruses (hundreds of G418-resistant colonies per mutant pseudotype-infected plate). Representative linker insertion mutants were also tested for the ability to synthesize viral unintegrated DNA in newly infected cells. All assayed mutants were capable of synthesizing all normal forms of viral unintegrated DNA. The structure of integrated vector proviruses generated by defective and nondefective linker insertion mutants was also analyzed. All replication-competent mutants generated normal proviruses, while the few obtainable proviruses generated by replication-defective mutants were sometimes aberrant in structure. These results argue strongly (and confirm previous data) that the IN-encoding region of pol does not play a significant role in DNA synthesis, but is absolutely required for the formation of normal proviral DNA.     

A functional ribonucleoprotein complex forms around the 5' end of poliovirus RNA

The existence of a computer-predicted cloverleaf structure for the first 100 nucleotides at the 5' end of poliovirus RNA was verified by site-directed mutagenesis and by chemical and RNAase probing. Mutations that modified the cloverleaf in the positive strand but not the negative strand were lethal to the virus. This RNA cloverleaf structure binds a cellular protein and the viral proteins 3Cpro and 3Dpol. Mutations in specific regions of the RNA cloverleaf prevented this binding. Mutations in either 3Cpro or the RNA that disrupted ribonucleoprotein complex formation inhibited virus growth and selectively affected positive strand RNA accumulation. Phenotypic reversion of these mutations restored the ability to form the complex. Thus, a cloverleaf structure in poliovirus RNA plays a central role in organizing viral and cellular proteins involved in positive strand production.     

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.     

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.     

Dissecting the role of the N-terminal domain of human immunodeficiency virus integrase by trans-complementation analysis

The human immunodeficiency virus (HIV) integrase protein (IN) catalyzes two reactions required to integrate HIV DNA into the human genome: 3' processing of the viral DNA ends and integration. IN has three domains, the N-terminal zinc-binding domain, the catalytic core, and the C-terminal SH3 domain. Previously, it was shown that IN proteins mutated in different domains could complement each other. We now report that this does not require any overlap between the two complementing proteins; an N-terminal domain, provided in trans, can restore IN activity of a mutant lacking this domain. Only the zinc-coordinating form of the N-terminal domain can efficiently restore IN activity of an N-terminal deletion mutant. This suggests that interaction between different domains of IN is needed for functional multimerization. We find that the N-terminal domain of feline immunodeficiency virus IN can support IN activity of an N-terminal deletion mutant of HIV type 2 IN. These cross-complementation experiments indicate that the N-terminal domain contributes to the recognition of specific viral DNA ends.     

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.     

Human immunodeficiency virus type 1 nucleocapsid protein specifically stimulates Mg2+-dependent DNA integration in vitro.

The integrase (IN) protein of the human immunodeficiency virus mediates integration of the viral DNA into the cellular genome. In vitro, this reaction can be mimicked by using purified recombinant IN and model DNA substrates. IN mediates two reactions: an endonucleolytic cleavage at each 3' end of the proviral DNA (terminal cleavage) and the joining of the linear viral DNA to 5' phosphates in the target DNA (strand transfer). Previous investigators have shown that purified IN requires Mn2+ or Mg2+ to promote strand transfer in vitro, although Mg2+ is the likely metal cofactor in vivo. IN activity in the presence of Mg2+ in vitro requires high IN concentrations and low concentrations of salt. Here, we show that the viral nucleocapsid protein NCp7 allows efficient IN-mediated strand transfer in the presence of Mg2+ at low enzyme concentrations. This potentiating effect appears to be unique to NCp7, as other small DNA-binding proteins, while capable of stimulating integration in the presence of Mn2+, all failed to stimulate strand transfer in the presence of Mg2+.     

Both substrate and target oligonucleotide sequences affect in vitro integration mediated by human immunodeficiency virus type 1 integrase protein produced in Saccharomyces cerevisiae.

Integration of retroviral DNA into the host cell genome requires the interaction of retroviral integrase (IN) protein with the outer ends of both viral long terminal repeats (LTRs) to remove two nucleotides from the 3' ends (3' processing) and to join the 3' ends to newly created 5' ends in target DNA (strand transfer). We have purified the IN protein of human immunodeficiency virus type 1 (HIV-1) after production in Saccharomyces cerevisiae and found it to have many of the properties described for retroviral IN proteins. The protein performs both 3' processing and strand transfer reactions by using HIV-1 or HIV-2 attachment (att) site oligonucleotides. A highly conserved CA dinucleotide adjacent to the 3' processing site of HIV-1 is important for both the 3' processing and strand transfer reactions; however, it is not sufficient for full IN activity, since alteration of nucleotide sequences internal to the HIV-1 U5 CA also impairs IN function, and Moloney murine leukemia virus att site oligonucleotides are poor substrates for HIV-1 IN. When HIV-1 att sequences are positioned internally in an LTR-LTR circle junction substrate, HIV-1 IN fails to cleave the substrate preferentially at positions coinciding with correct 3' processing, implying a requirement for positioning att sites near DNA ends. The 2 bp normally located beyond the 3' CA in linear DNA are not essential for in vitro integration, since mutant oligonucleotides with single-stranded 3' or 5' extensions or with no residues beyond the CA dinucleotide are efficiently used. Selection of target sites is nonrandom when att site oligonucleotides are joined to each other in vitro. We modified an in vitro assay to distinguish oligonucleotides serving as the substrate for 3' processing and as the target for strand transfer. The modified assay demonstrates that nonrandom usage of target sites is dependent on the target oligonucleotide sequence and independent of the oligonucleotide used as the substrate for 3' processing.     

Inhibition of Moloney murine leukemia virus integration using polyamides targeting the long-terminal repeat sequences

The retroviral integrase (IN) carries out the integration of the viral DNA into the host genome. Both IN and the DNA sequences at the viral long-terminal repeat (LTR) are required for the integration function. In this report, a series of minor groove binding hairpin polyamides targeting sequences within terminal inverted repeats of the Moloney murine leukemia virus (M-MuLV) LTR were synthesized, and their effects on integration were analyzed. Using cell-free in vitro integration assays, polyamides targeting the conserved CA dinucleotide with cognate sites closest to the terminal base pairs were effective at blocking 3' processing but not strand transfer. Polyamides which efficiently inhibited 3' processing and strand transfer targeted the LTR sequences through position 9. Polyamides that inhibited integration were effective at nanomolar concentrations and showed subnanomolar affinity for their cognate LTR sites. These studies highlight the role of minor groove interactions within the LTR termini for retroviral integration.     

Mutational Scan of the Human Immunodeficiency Virus Type 2 Integrase Protein

Retroviral integrase (IN) cleaves linear viral DNA specifically near the ends of the DNA (cleavage reaction) and subsequently couples the processed ends to phosphates in the target DNA (integration reaction). In vitro, IN catalyzes the disintegration reaction, which is the reverse of the integration reaction. Ideally, we would like to test the role of each amino acid in the IN protein. We mutagenized human immunodeficiency virus type 2 IN in a random way using PCR mutagenesis and generated a set of mutants in which 35% of all residues were substituted. Mutant proteins were tested for in vitro activity, e.g., site-specific cleavage of viral DNA, integration, and disintegration. Changes in 61 of the 90 proteins investigated showed no phenotypic effect. Substitutions that changed the choice of nucleophile in the cleavage reaction were found. These clustered around the active-site residues Asp-116 and Glu-152. We also found alterations of amino acids that affected cleavage and integration differentially. In addition, we analyzed the disintegration activity of the proteins and found substitutions of amino acids close to the dimer interface that enhanced intermolecular disintegration activity, whereas other catalytic activities were present at wild-type levels. This study shows the feasibility of investigating the role of virtually any amino acid in a protein the size of IN.