Integrase Function Research Articles

Integration of Visna Virus DNA Occurs and May Be Necessary for Productive Infection

Proviral integration is thought to be an obligate step of the retroviral replication cycle but the lentivirus visna has been reported to replicate in sheep choroid plexus (SCP) cultures in the absence of proviral integration. Because of new evidence that visna virus has a functional integrase, we reexamined visna virus infection of SCP cultures and found that proviral integration does indeed occur in this setting. While the majority of viral DNA remains unintegrated, integrated proviruses arise early in infection and accumulate over time. The sequences of the resulting host–virus DNA junctions show that, like other retroviruses, visna loses terminal nucleotides from its DNA upon integration. However, unlike other retroviruses, in over half the host–U3 junctions analyzed only a single nucleotide was lost such that the universally conserved CA dinucleotide, two nucleotides from the end of unintegrated viral DNA, did not directly abut host sequences in the provirus. We analyzed the role of integration in visna replication by introducing a series of five mutations into the integrase gene of molecularly cloned visna virus LV1-1KS1. Each mutation abolished viral replication, suggesting that integration may be an obligatory step in replication. We also documented productive infection of SCP cultures in which cell division had been blocked by g-irradiation. The ability of visna to integrate and to replicate in nondividing cells points to the possible utility of visna-based vectors for gene transfer into differentiated cells.

HIV-1 infection of nondividing cells through the recognition of integrase by the importin/karyopherin pathway.

The karyophilic properties of the HIV-1 nucleoprotein complex facilitate infection of nondividing cells such as macrophages and quiescent T lymphocytes, and allow the in vivo delivery of transgenes by HIV-derived retroviral vectors into terminally differentiated cells such as neurons. Although the viral matrix (MA) and Vpr proteins have previously been shown to play important roles in this process, we demonstrate here that integrase, the enzyme responsible for mediating the integration of the viral genome in the host cell chromosome, can suffice to connect the HIV-1 preintegration complex with the cell nuclear import machinery. This novel function of integrase reflects the recognition of an atypical bipartite nuclear localization signal by the importin/karyopherin pathway.

Petunia Vein-Clearing Virus: A Plant Pararetrovirus with the Core Sequences for an Integrase Function

Petunia vein-clearing virus (PVCV) is a plant pararetrovirus that has some features of retrotransposons. It encapsidates dsDNA and has isometric particles and inclusion bodies similar to those of caulimoviruses. The PVCV genome of 7205 bp has two large ORFs in the transcribed strand and a methionine tRNA primer-binding site in its 663-bp intergenic region. The N-terminal position of the large protein (126 kDa) encoded by ORF I has similarity to the movement protein of caulimoviruses. Toward the C-terminus of this same polyprotein are the two distinctive sequence elements [HHCC and DD(35)E] of the integrase function of retroviruses and retrotransposons. ORF II of PVCV encodes a protein of 125 kDa with domains for an RNA-binding element, common to thegaggene of retroelements, followed by consensus sequences for an acid protease, reverse transcriptase, and ribonuclease H. Hence, thegagequivalent (capsid protein) andpolgene of PVCV are part of the same polyprotein. Phylogenetic comparison of the reverse transcriptase of PVCV with that of various other retroelements grouped PVCV between caulimoviruses and the Ty3/gypsyretrotransposons, suggesting that PVCV is a divergent member of the caulimoviruses.

Complementation of integrase function in HIV-1 virions.

Proviral integration is essential for HIV-1 replication and represents an important potential target for antiviral drug design. Although much is known about the integration process from studies of purified integrase (IN) protein and synthetic target DNA, provirus formation in virally infected cells remains incompletely understood since reconstituted in vitro assays do not fully reproduce in vivo integration events. We have developed a novel experimental system in which IN-mutant HIV-1 molecular clones are complemented in trans by Vpr-IN fusion proteins, thereby enabling the study of IN function in replicating viruses. Using this approach we found that (i) Vpr-linked IN is efficiently packaged into virions independent of the Gag-Pol polyprotein, (ii) fusion proteins containing a natural RT/IN processing site are cleaved by the viral protease and (iii) only the cleaved IN protein complements IN-defective HIV-1 efficiently. Vpr-mediated packaging restored IN function to a wide variety of IN-deficient HIV-1 strains including zinc finger, catalytic core and C-terminal domain mutants as well as viruses from which IN was completely deleted. Furthermore, trans complemented IN protein mediated a bona fide integration reaction, as demonstrated by the precise processing of proviral ends (5'-TG...CA-3') and the generation of an HIV-1-specific (5 bp) duplication of adjoining host sequences. Intragenic complementation between IN mutants defective in different protein domains was also observed, thereby providing the first evidence for IN multimerization in vivo.

Reversion of a human immunodeficiency virus type 1 integrase mutant at a second site restores enzyme function and virus infectivity.

The integration of a DNA copy of the retroviral RNA genome into the host cell genome is essential for viral replication. The virion-associated integrase protein, encoded by the 3' end of the viral pol gene, is required for integration. Stable virus-producing T-cell lines were established for replication-defective human immunodeficiency virus type 1 carrying single amino acid substitutions at conserved residues in the catalytic domain of integrase. Phenotypically reverted virus was detected 12 weeks after transfection with the integrase mutant carrying the P-109-->S mutation (P109S). Unlike the defective P109S virus, the revertant virus (designated P109SR) grew in CD4+ SupT1 cells. In addition to the Ser substitution at Pro-109, P109SR had a second substitution of Ala for Thr at position 125 in integrase. Site-directed mutagenesis was used to show that the P109S T125A genotype was responsible for the P109SR replication phenotype. The T125A substitution also rescued the in vitro enzyme activities of recombinant P109S integrase protein. P109S integrase did not display detectable 3' processing or DNA strand transfer activity, although 5 to 10% of wild-type disintegration activity was detected. P109S T125A integrase displayed nearly wild-type levels of 3' processing, DNA strand transfer, and disintegration activities, confirming that T125A is a second-site intragenic suppressor of P109S. P109S integrase ran as a large aggregate on a size exclusion column, whereas wild-type integrase ran as a monomer and P109S T125A integrase ran as a mixed population. Pro-109 and Thr-125 are not immediately adjacent in the crystal structure of the integrase catalytic domain. We suggest that the T125A substitution restores integrase function by stabilizing a structural alteration(s) induced by the P109S mutation.

Expression of functional HIV-1 integrase in the yeast Saccharomyces cerevisiae leads to the emergence of a lethal phenotype: potential use for inhibitor screening

Expression of functional HIV-1 integrase in the yeast Saccharomyces cerevisiae leads to the emergence of a lethal phenotype: potential use for inhibitor screening

Expression of functional HIV-1 integrase in the yeast Saccharomyces cerevisiae leads to the emergence of a lethal phenotype: potential use for inhibitor screening.

The integrase of the human immunodeficiency virus type 1 (HIV-1) has been expressed in yeast in order to investigate its potential lethal effect mediated by DNA damage. To this end, we have constructed an expression plasmid containing the retroviral integrase gene under the control of the inducible promotor ADH2/GAPDH which is regulated by the glucose concentration of the medium. Haploid yeast strain W303-1A did not appear to be clearly sensitive to HIV-1 integrase expression. However, disruption of the RAD 52 gene, which is involved in the repair of double-strand DNA breaks, strongly increased the deleterious effects of the retroviral enzyme in this yeast strain. The diploid strain constructed with W303-1A and an isogenic strain of the opposite mating type also showed a strong sensitivity to the HIV-1 integrase. Under yeast culture conditions allowing moderate integrase synthesis, the deleterious effect was totally abolished by missense integrase mutations, which are known to abolish HIV-1 integrase activities in vitro. We conclude that the lethal phenotype due to HIV-1 integrase expression in yeast may be closely related to the HIV-1 integration reaction in infected human cells, and that yeast may be a useful tool to study the HIV-1 integration process and to screen drugs capable of inhibiting HIV-1 integration in vivo.

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.

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.

Site-specific integration of the phage phi CTX genome into the Pseudomonas aeruginosa chromosome: characterization of the functional integrase gene located close to and upstream of attP.

The site-specific integration of the phage phi CTX genome, which carries the gene for a pore-forming cytotoxin, into the Pseudomonas aeruginosa chromosome was analysed. The 1,167 bp integrase gene, int, located immediately upstream of the attachment site, attP, was characterized using plasmid constructs, harbouring the integration functions, and serving as an integration probe in both P. aeruginosa and Escherichia coli. The attP plasmids p1000/p400 in the presence of the int plasmid pIBH and attP-int plasmids pINT/pINTS can be stably integrated into the P. aeruginosa chromosome. Successful recombination between the attP plasmid p1000 and the attB plasmid p5.1, in the presence of the int plasmid pIBH in E. coli HB101 showed that the int gene is active in trans in E. coli. The int gene product was detected as a 43 kDa protein in E. coli maxicells harbouring pINT. Proposed integration arm regions downstream of attP are not necessary for the integration process. pINT and phage phi CTX could be integrated together into P. aeruginosa chromosomal DNA, yielding double integrates.

Genetic structures associated with spread of the type Ia trimethoprim-resistant dihydrofolate reductase gene amongst Escherichia coli strains isolated in the Nottingham area of the United Kingdom.

DNA probes for specific integrase genes were used to study 122 R plasmids encoding the predominant trimethoprim-insusceptible type Ia dihydrofolate reductase (DHFR) found in clinical isolates of Escherichia coli. The predominance of the type Ia DHFR was thought to result from the location of its gene on transposon Tn7, but of trimethoprim R plasmids carrying this gene that were collected between 1978 and 1983, between 1987 and 1988, and during 1992, only 49/60 (81.6%), 30/43 (69.8%) and 9/19 (47.4%) respectively hybridized with a probe for the Tn7 integrase gene. It has been suggested that novel genetic elements termed 'integrons' may play an important role in the dissemination of antibiotic resistance genes. Known integrons encode an integrase similar to that encoded by transposon Tn21, and 28 Tn7-negative plasmids (10/60 from 1978-83, 10/43 from 1987-8 and 8/19 from 1992) showed homology with a probe specific for the Tn21 integrase gene. Six plasmids were negative with both probes. It is concluded that Tn7 has played an important role in the dissemination of the gene encoding the type Ia DHFR amongst clinical isolates of E. coli in the Nottingham region of the UK, but that other genetic structures, some of which seem to have an integrase function similar to that of known integrons, may be playing an increasingly significant role.

Mutational Analysis of the Sequences at the Termini of the Moloney Murine Leukemia Virus DNA Required for Integration

The insertion of retroviral DNA into the genome of the infected cell to form the integrated provirus requires the presence of short inverted repeat (IR) sequences at the viral DNA termini. To examine the sequence requirements at the IRa for integration of the Moloney murine leukemia virus, we generated a series of mutants with deletion and substitution mutations and tested their ability to replicate and form proviruses in vivo. The experiments did not detect evidence of a requirement for sequences outside the IRs, and only a very loose requirement for the IR sequences, with many point mutations well tolerated. Examination of the mutants suggests that bases very near the terminus and those approximately one turn of the DNA helix away from the terminus are important for recognition by the integrase function.

Identification of discrete functional domains of HIV-1 integrase and their organization within an active multimeric complex.

HIV-1 integrase protein possesses the 3' processing and DNA strand transfer activities that are required to integrate HIV DNA into a host chromosome. The N-, C-terminal and core domains of integrase are necessary for both activities in vitro. We find that certain pairs of mutant integrase proteins, which are inactive when each protein is assayed alone, can support near wild type levels of activity when both proteins are present together in the reaction mixture. This complementation implies that HIV-1 integrase functions as a multimer and has enabled us to probe the organization of the functional domains within active mixed multimers. We have identified a minimal set of functional integrase domains that are sufficient for 3' processing and DNA strand transfer and find that some domains are contributed in trans by separate monomers within the functional complex.

Site-directed mutagenesis of HIV-1 integrase demonstrates differential effects on integrase functions in vitro.

The retroviral integrase (IN) protein is essential for integration of retroviral DNA into the host cell genome. To identify functional domains within the protein and to assess the importance of conserved residues, we performed site-directed mutagenesis of HIV-1 IN and analyzed the mutants in vitro for IN-mediated activities: 3' processing (att site-specific nuclease activity), strand transfer (the joining of att site oligonucleotides to target DNA), disintegration (the reverse of strand transfer), and integration site selection. Changing the conserved residue His-16 either to Cys or to Val in a proposed zinc-finger region had minimal effect on IN activities. Alteration of two highly conserved amino acid residues, Asp-116-->Ile and Glu-152-->Gly, each resulted in complete or nearly complete loss of 3' processing, strand transfer, and disintegration, whereas alteration of another conserved residue, Trp-235-->Glu, had no demonstrable effect on any of the activities in vitro. Two mutants, Asp-64-->Val and Arg-199-->Cys delta, each demonstrated differential effects on IN activities. Asp-64-->Val has no demonstrable strand transfer or disintegration activity yet maintains 3' processing activity at a diminished level. Arg-199-->Cys delta, which lacks part of the carboxyl terminus of IN, has impaired strand transfer activity without loss of disintegration activity. Use of a target site selection assay showed that all of our mutants with strand transfer activity maintain the same integration pattern as wild type IN. We conclude that not all highly conserved IN residues are essential for IN activities in vitro, zinc coordination by the proposed zinc-finger domain may not be required for the activities assayed, alteration of single residues can yield differential effects on IN activities, and target site selection into naked DNA is not necessarily altered by changes in strand transfer activity.

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.

Active nuclear import of human immunodeficiency virus type 1 preintegration complexes.

After cell infection by the human immunodeficiency virus type 1 (HIV-1), nascent viral DNA in the form of a high molecular weight nucleoprotein preintegration complex must be transported to the nucleus of the host cell prior to integration of viral DNA with the host genome. The mechanism used by retroviruses for nuclear targeting of preintegration complexes and dependence on cell division has not been established. Our studies show that, after infection, the preintegration complex of HIV-1 was rapidly transported to the nucleus of the host cell by a process that required ATP but was independent of cell division. Functional HIV-1 integrase, an essential component of the preintegration complex, was not required for nuclear import of these complexes. The ability of HIV-1 to use host cell active transport processes for nuclear import of the viral preintegration complex obviates the requirement for host cell division in establishment of the integrated provirus. These findings are pertinent to our understanding of early events in the life cycle of HIV-1 and to the mode of HIV-1 replication in terminally differentiated nondividing cells such as macrophages (monocytes, tissue macrophages, follicular dendritic cells, and microglial cells).

Conjugative transposition of Tn916 requires the excisive and integrative activities of the transposon-encoded integrase.

Transposon Tn916 is a 16.4-kb broad-host-range conjugative transposon originally detected in the chromosome of Enterococcus faecalis DS16. Transposition of Tn916 and related transposons involves excision of a free, nonreplicative, covalently closed circular intermediate that is substrate for integration. Excisive recombination requires two transposon-encoded proteins, Xis-Tn and Int-Tn, whereas the latter protein alone is sufficient for integration. Here we report that conjugative transposition of Tn916 requires the presence of a functional integrase in both donor and recipient strains. We have constructed a mutant, designated Tn916-int1, by replacing the gene directing synthesis of Int-Tn by an allele inactivated in vitro. In mating experiments, transfer of Tn916-int1 from Bacillus subtilis to E. faecalis was detected only when the transposon-encoded integrase was supplied by trans-complementation in both the donor and the recipient. These results suggest that conjugative transposition of Tn916 requires circularization of the element in the donor followed by transfer and integration of the nonreplicative intermediate in the recipient.

Gene organization and transcription of TED, a lepidopteran retrotransposon integrated within the baculovirus genome.

A single copy of the retrotransposon TED, from the moth Trichoplusia ni (a lepidopteran noctuid), was identified within the DNA genome of the baculovirus Autographa californica nuclear polyhedrosis virus. Determination of the complete nucleotide sequence (7,510 base pairs) of the integrated copy indicated that TED belongs to the family of retrotransposons that includes Drosophila melanogaster elements 17.6 and gypsy and thus represents the first nondipteran member of this invertebrate group to be identified. The internal portion of TED, flanked by long terminal repeats (LTRs), is composed of three long open reading frames comparable in size and location to the gag, pol, and env genes of the vertebrate retroviruses. Sequence similarity with the dipteran elements was the highest within individual domains of TED open reading frame 2 (pol region) that are also conserved among the retroviruses and encode protease, reverse transcriptase, and integrase functions, respectively. Mapping the 5' and 3' termini of TED RNAs indicated that the LTRs have a retroviral U3-R-U5 structural organization that is capable of directing the synthesis of transcripts that represent potential substrates for reverse transcription and intermediates in transposition. Abundant RNAs were also initiated from a site within the 5' LTR that matches the consensus motif for the promoter of late, hyperexpressed baculovirus genes. The presence of this viruslike promoter within TED and its subsequent activation only after integration within the viral genome suggest a possible symbiotic relationship with the baculovirus that could extend transposon host range.

Gene Organization and Transcription of TED, a Lepidopteran Retrotransposon Integrated within the Baculovirus Genome

A single copy of the retrotransposon TED, from the moth Trichoplusia ni (a lepidopteran noctuid), was identified within the DNA genome of the baculovirus Autographa californica nuclear polyhedrosis virus. Determination of the complete nucleotide sequence (7,510 base pairs) of the integrated copy indicated that TED belongs to the family of retrotransposons that includes Drosophila melanogaster elements 17.6 and gypsy and thus represents the first nondipteran member of this invertebrate group to be identified. The internal portion of TED, flanked by long terminal repeats (LTRs), is composed of three long open reading frames comparable in size and location to the gag, pol, and env genes of the vertebrate retroviruses. Sequence similarity with the dipteran elements was the highest within individual domains of TED open reading frame 2 (pol region) that are also conserved among the retroviruses and encode protease, reverse transcriptase, and integrase functions, respectively. Mapping the 5' and 3' termini of TED RNAs indicated that the LTRs have a retroviral U3-R-U5 structural organization that is capable of directing the synthesis of transcripts that represent potential substrates for reverse transcription and intermediates in transposition. Abundant RNAs were also initiated from a site within the 5' LTR that matches the consensus motif for the promoter of late, hyperexpressed baculovirus genes. The presence of this viruslike promoter within TED and its subsequent activation only after integration within the viral genome suggest a possible symbiotic relationship with the baculovirus that could extend transposon host range.

Characterization of a transpositionally active Ty3 element and identification of the Ty3 integrase protein

Ty3 is a Saccharomyces cerevisiae retrotransposon associated with tRNA genes. Two Ty3 elements have been cloned and characterized. The complete nucleotide sequence for one element, Ty3-2, was reported previously (L. J. Hansen, D. L. Chalker, and S. B. Sandmeyer, Mol. Cell. Biol. 9:5245-5256, 1988). However, this element is incapable of autonomous transposition. The complete DNA sequence of a transpositionally competent Ty3 element, Ty3-1, is presented here. Its sequence translates into two overlapping open reading frames, TYA3-1 and TYB3-1, which encode proteins with homology to the proteins specified by the retroviral gag and pol genes, respectively. Comparison of the Ty3-1 nucleotide sequence to Ty3-2 suggests that the TYB3-2 open reading frame of Ty3-2 is truncated by the deletion of a single nucleotide, which causes a frameshift mutation. Restoration of the reading frame with insertion of a single adenine by site-directed mutagenesis converted Ty3-2 into a transpositionally active element, Ty3-2(+ A). Western blot analysis with antibodies made against synthetic peptides identified integrase (IN) proteins in viruslike particle preparations from cells expressing Ty3 elements. Cells expressing Ty3-1 and Ty3-2 (+A) produce antibody-reactive proteins with approximate molecular masses of 61 and 58 kilodaltons (kDa), while cells expressing Ty3-2 produce reactive proteins of approximately 52 and 49 kDa. Together, these data show that the 61- or 58-kDa protein, or both, provides the integrase function of Ty3.