Chromosomal integration of LTR-flanked DNA in yeast expressing HIV-1 integrase: down regulation by RAD51

HIV-1 integrase (IN) is the key enzyme catalyzing the proviral DNA integration step. Although the enzyme catalyzes the integration step accurately in vitro, whether IN is sufficient for in vivo integration and how it interacts with the cellular machinery remains unclear. We set up a yeast cellular integration system where integrase was expressed as the sole HIV-1 protein and targeted the chromosomes. In this simple eukaryotic model, integrase is necessary and sufficient for the insertion of a DNA containing viral LTRs into the genome, thereby allowing the study of the isolated integration step independently of other viral mechanisms. Furthermore, the yeast system was used to identify cellular mechanisms involved in the integration step and allowed us to show the role of homologous recombination systems. We demonstrated physical interactions between HIV-1 IN and RAD51 protein and showed that HIV-1 integrase activity could be inhibited both in the cell and in vitro by RAD51 protein. Our data allowed the identification of RAD51 as a novel in vitro IN cofactor able to down regulate the activity of this retroviral enzyme, thereby acting as a potential cellular restriction factor to HIV infection.     

Cellular co-factors of HIV-1 integration

To achieve productive infection, the reverse transcribed cDNA of human immunodeficiency virus type 1 (HIV-1) is inserted in the host cell genome. The main protein responsible for this reaction is the viral integrase. However, studies indicate that the virus is assisted by cellular proteins, or co-factors, to achieve integration into the infected cell. The barrier-to-autointegration factor (BAF) might prevent autointegration. Its ability to bridge DNA and the finding that the nuclear lamina-associated polypeptide-2alpha interacts with BAF suggest a role in nuclear structure organization. Integrase interactor 1 was found to directly interact with HIV-1 integrase and to activate its DNA-joining activity, and the high mobility group chromosomal protein A1 might approximate both long terminal repeat (LTR) ends and facilitate integrase binding by unwinding the LTR termini. Furthermore, the lens-epithelium-derived growth factor (LEDGF; also known as p75) seems to tether HIV-1 integrase to the chromosomes. Although a direct role in integration has only been demonstrated for LEDGF/p75, to date, each validated cellular co-factor for HIV-1 integration could constitute a promising new target for antiviral therapy.     

Nucleoprotein Intermediates in HIV-1 DNA Integration Visualized by Atomic Force Microscopy

Integration of HIV-1 (human immunodeficiency virus type 1) DNA into the genome of the host cell is an essential step in the viral replication cycle that is mediated by the virally encoded integrase protein. We have used atomic force microscopy to study stable complexes formed between HIV-1 integrase and viral DNA and their interaction with host DNA. A tetramer of integrase stably bridges a pair of viral DNA ends, consistent with previous analysis by gel electrophoresis. The intasome, composed of a tetramer of integrase bridging a pair of viral DNA ends, is highly stable to high ionic strength that would strip more loosely associated integrase from internal regions of the viral DNA. We also observed tetramers of integrase associated with single viral DNA ends; time-course experiments suggest that these may be intermediates in intasome assembly. Strikingly, integrase tetramers are only observed in tight association with viral DNA ends. The self-association properties of intasomes suggest that the integrase tetramer within the intasome is different from the integrase tetramer formed at high concentration in solution in the absence of viral DNA. Finally, the integration product remains tightly bound by the integrase tetramer, but the 3′ ends of the target DNA in the complex are not restrained and are free to rotate, resulting in relaxation of initially supercoiled target DNA.     

Retroviral DNA integration: reaction pathway and critical intermediates

The key DNA cutting and joining steps of retroviral DNA integration are carried out by the viral integrase protein. Structures of the individual domains of integrase have been determined, but their organization in the active complex with viral DNA is unknown. We show that HIV-1 integrase forms stable synaptic complexes in which a tetramer of integrase is stably associated with a pair of viral DNA ends. The viral DNA is processed within these complexes, which go on to capture the target DNA and integrate the viral DNA ends. The joining of the two viral DNA ends to target DNA occurs sequentially, with a stable intermediate complex in which only one DNA end is joined. The integration product also remains stably associated with integrase and likely requires disassembly before completion of the integration process by cellular enzymes. The results define the series of stable nucleoprotein complexes that mediate retroviral DNA integration.     

Specific and Independent Recognition of U3 and U5 att Sites by Human Immunodeficiency Virus Type 1 Integrase In Vivo

The retroviral attachment (att) sites at viral DNA ends are cis-acting regions essential for proviral integration. To investigate the sequence features of att important for human immunodeficiency virus type 1 (HIV-1) integration in vivo, we generated a series of 25 att mutants of HIV-1 by mutagenesis of the U3, U5, or both boundaries of att. Our results indicated that the terminal 11 or 12 bp of viral DNA are sufficient for specific recognition by HIV-1 integrase (IN) and suggested that IN might recognize each att site independently in vivo.     

Activity of recombinant HIV-1 integrase on mini-HIV DNA

Integration of the human immunodeficiency virus type 1 (HIV-1) cDNA into the genome of a human cell is an essential step in the viral replication cycle. Understanding of the integration process has been facilitated by the development of in vitro assays using specific oligonucleotides and recombinant integrase. However, understanding of the biology of retroviral integration will require in vitro and in vivo model systems using long DNA substrates that mimic the HIV cDNA. We have now studied the activity of recombinant HIV-1 integrase on a linear 4.7 kb double-stranded DNA, containing flanking regions of approximately 200 bp that represent the intact ends of the HIV-1 long terminal repeat (LTR) sequences (mini-HIV). The strand transfer products of the integration reaction can be directly visualized after separation in agarose gels by ethidium bromide staining. The most prominent reaction product resulted from integration of one LTR end into another LTR end (U5 into U5 and U5 into U3). Sequence analysis of the reaction products showed them to be products of legitimate integration preceded by correct processing of the viral LTR ends. Hotspots for integration were detected. Electron microscopy revealed the presence of a range of reaction products resulting from single or multiple integration events. The binding of HIV-1 integrase to mini-HIV DNA was visualized. Oligomers of integrase seem to induce DNA looping whereby the enzyme often appears to be bound to the DNA substrate that adopts the structure of a three-site synapsis that is reminiscent of the Mu phage transposase complex.     

Chromatinized templates reveal the requirement for the LEDGF/p75 PWWP domain during HIV-1 integration in vitro

Integration is an essential step in the retroviral lifecycle, and the lentiviral integrase binding protein lens epithelium-derived growth factor (LEDGF)/p75 plays a crucial role during human immunodeficiency virus type 1 (HIV-1) cDNA integration. In vitro, LEDGF/p75 stimulates HIV-1 integrase activity into naked target DNAs. Here, we demonstrate that this chromatin-associated protein also stimulates HIV-1 integration into reconstituted polynucleosome templates. Activation of integration depended on the LEDGF/p75-integrase interaction with either type of template. A differential requirement for the dominant DNA and chromatin-binding elements of LEDGF/p75 was however observed when using naked DNA versus polynucleosomes. With naked DNA, the complete removal of these N-terminal elements was required to abate cofactor function. With polynucleosomes, activation mainly depended on the PWWP domain, and to a lesser extent on nearby AT-hook DNA-binding motifs. GST pull-down assays furthermore revealed a role for the PWWP domain in binding to nucleosomes. These results are completely consistent with recent ex vivo studies that characterized the PWWP and integrase-binding domains of LEDGF/p75 as crucial for restoring HIV-1 infection to LEDGF-depleted cells. Our studies therefore establish novel in vitro conditions, highlighting chromatinized DNA as target acceptor templates, for physiologically relevant studies of LEDGF/p75 in lentiviral cDNA integration.     

In vitro initial attachment of HIV-1 integrase to viral ends: control of the DNA specific interaction by the oligomerization state

HIV-1 integrase (IN) oligomerization and DNA recognition are crucial steps for the subsequent events of the integration reaction. Recent advances described the involvement of stable intermediary complexes including dimers and tetramers in the in vitro integration processes, but the initial attachment events and IN positioning on viral ends are not clearly understood. In order to determine the role of the different IN oligomeric complexes in these early steps, we performed in vitro functional analysis comparing IN preparations having different oligomerization properties. We demonstrate that in vitro IN concerted integration activity on a long DNA substrate containing both specific viral and nonspecific DNA sequences is highly dependent on binding of preformed dimers to viral ends. In addition, we show that IN monomers bound to nonspecific DNA can also fold into functionally different oligomeric complexes displaying nonspecific double-strand DNA break activity in contrast to the well known single strand cut catalyzed by associated IN. Our results imply that the efficient formation of the active integration complex highly requires the early correct positioning of monomeric integrase or the direct binding of preformed dimers on the viral ends. Taken together the data indicates that IN oligomerization controls both the enzyme specificity and activity.     

HIV-1 integrase crosslinked oligomers are active in vitro

The oligomeric state of active human immunodeficiency virus type 1 (HIV-1) integrase (IN) has not been clearly elucidated. We analyzed the activity of the different purified oligomeric forms of recombinant IN obtained after stabilization by platinum crosslinking. The crosslinked tetramer isolated by gel chromatography was able to catalyze the full-site integration of the two viral LTR ends into a target DNA in vitro, whereas the isolated dimeric form of the enzyme was involved in the processing and integration of only one viral end. Accurate concerted integration by IN tetramers was confirmed by cloning and sequencing. Kinetic studies of DNA-integrase complexes led us to propose a model explaining the formation of an active complex. Our data suggest that the tetrameric IN bound to the viral DNA ends is the minimal complex involved in the concerted integration of both LTRs and should be the oligomeric form targeted by future inhibitors.     

In Vitro HIV-1 LTR Integration into T-Cell Activation Gene CD27 Segment and the Decoy Effect of Modified-Sequence DNA

Integration into the host genome is an essential step in the HIV-1 life cycle. However, the host genome sequence that is favored by HIV-1 during integration has never been documented. Here, we report that CD27, a T cell activation gene, includes a sequence that is a target for in vitro HIV-1 cDNA integration. This sequence has a high affinity for integrase, and the target nucleotides responsible for this higher affinity were identified using a crystal microbalance assay. In experiments involving a segment of the CD27 gene, integration converged in the target nucleotides and flanking sequence DNA, indicating that integration is probably dependent upon the secondary structure of the substrate DNA. Notably, decoy modified CD27 sequence DNAs in which the target nucleotides were replaced suppressed integration when accompanying the original CD27 sequence DNA. Our identified CD27 sequence DNA is useful for investigating the biochemistry of integrase and for in vitro assessment of integrase-binding inhibitors.     

Integrase residues that determine nucleotide preferences at sites of HIV-1 integration: implications for the mechanism of target DNA binding

Retroviruses favor target-DNA (tDNA) distortion and particular bases at sites of integration, but the mechanism underlying HIV-1 selectivity is unknown. Crystal structures revealed a network of prototype foamy virus (PFV) integrase residues that distort tDNA: Ala188 and Arg329 interact with tDNA bases, while Arg362 contacts the phosphodiester backbone. HIV-1 integrase residues Ser119, Arg231, and Lys258 were identified here as analogs of PFV integrase residues Ala188, Arg329 and Arg362, respectively. Thirteen integrase mutations were analyzed for effects on integrase activity in vitro and during virus infection, yielding a total of 1610 unique HIV-1 integration sites. Purine (R)/pyrimidine (Y) dinucleotide sequence analysis revealed HIV-1 prefers the tDNA signature (0)RYXRY(4), which accordingly favors overlapping flexible dinucleotides at the center of the integration site. Consistent with roles for Arg231 and Lys258 in sequence specific and non-specific binding, respectively, the R231E mutation altered integration site nucleotide preferences while K258E had no effect. S119A and S119T integrase mutations significantly altered base preferences at positions −3 and 7 from the site of viral DNA joining. The S119A preference moreover mimicked wild-type PFV selectivity at these positions. We conclude that HIV-1 IN residue Ser119 and PFV IN residue Ala188 contact analogous tDNA bases to effect virus integration.     

Stimulation of human flap endonuclease 1 by human immunodeficiency virus type 1 integrase: possible role for flap endonuclease 1 in 5'-end processing of human immunodeficiency virus type 1 integration intermediates

Human immunodeficiency virus type 1 (HIV-1) DNA integration intermediates consist of viral and host DNA segments separated by a 5-nucleotide gap adjacent to a 5'-AC unpaired dinucleotide. These short-flap (pre-repair) integration intermediates are structurally similar to DNA loci undergoing long-patch base excision repair in mammalian cells. The cellular proteins flap endonuclease 1 (FEN-1), proliferating cell nuclear antigen, replication factor C, DNA ligase I and DNA polymerase delta are required for the repair of this type of DNA lesion. The role of FEN-1 in the base excision repair pathway is to cleave 5'-unpaired flaps in forked structures so that DNA ligase can seal the single-stranded breaks that remain following gap repair. The rate of excision by FEN-1 of 5'-flaps from short- and long-flap oligonucleotide substrates that mimic pre- and post-repair HIV-1 integration intermediates, respectively, and the effect of HIV-1 integrase on these reactions were examined in the present study. Cleavage of 5'-flaps by FEN-1 in pre-repair HIV-1 integration intermediates was relatively inefficient and was further decreased 3-fold by HIV-1 integrase. The rate of removal of 5'-flaps by FEN-1 from post-repair HIV-1 integration intermediates containing relatively long (7-nucleotide) unpaired 5'-tails and short (1-nucleotide) gaps was increased 3-fold relative to that seen with pre-repair substrates and was further stimulated 5- to 10-fold by HIV-1 integrase. Overall, post-repair structures were cleaved 18 times more effectively in the presence of HIV-1 integrase than pre-repair structures. The site of cleavage was 1 or 2 nucleotides 3' of the branch point and was unaffected by HIV-1 integrase. Integrase alone had no detectable activity in removing 5'-flaps from either pre- or post-repair substrates.     

Recombinant human immunodeficiency virus type 1 integrase exhibits a capacity for full-site integration in vitro that is comparable to that of purified preintegration complexes from virus-infected cells

Retrovirus preintegration complexes (PIC) in virus-infected cells contain the linear viral DNA genome (approximately 10 kbp), viral proteins including integrase (IN), and cellular proteins. After transport of the PIC into the nucleus, IN catalyzes the concerted insertion of the two viral DNA ends into the host chromosome. This successful insertion process is termed "full-site integration." Reconstitution of nucleoprotein complexes using recombinant human immunodeficiency virus type 1 (HIV-1) IN and model viral DNA donor substrates (approximately 0.30 to 0.48 kbp in length) that are capable of catalyzing efficient full-site integration has proven difficult. Many of the products are half-site integration reactions where either IN inserts only one end of the viral donor substrate into a circular DNA target or into other donors. In this report, we have purified recombinant HIV-1 IN at pH 6.8 in the presence of MgSO4 that performed full-site integration nearly as efficiently as HIV-1 PIC. The size of the viral DNA substrate was significantly increased to 4.1 kbp, thus allowing for the number of viral DNA ends and the concentrations of IN in the reaction mixtures to be decreased by a factor of approximately 10. In a typical reaction at 37 degrees C, recombinant HIV-1 IN at 5 to 10 nM incorporated 30 to 40% of the input DNA donor into full-site integration products. The synthesis of full-site products continued up to approximately 2 h, comparable to incubation times used with HIV-1 PIC. Approximately 5% of the input donor was incorporated into the circular target producing half-site products with no significant quantities of other integration products produced. DNA sequence analysis of the viral DNA-target junctions derived from wild-type U3 and U5 coupled reactions showed an approximately 70% fidelity for the HIV-1 5-bp host site duplications. Recombinant HIV-1 IN successfully utilized a mutant U5 end containing additional nucleotide extensions for full-site integration demonstrating that IN worked properly under nonideal active substrate conditions. The fidelity of the 5-bp host site duplications was also high with these coupled mutant U5 and wild-type U3 donor ends. These studies suggest that recombinant HIV-1 IN is at least as capable as native IN in virus particles and approaching that observed with HIV-1 PIC for catalyzing full-site integration.     

DNA binding properties of the integrase proteins of human immunodeficiency viruses types 1 and 2.

Integration of retroviral DNA into the host chromosome requires the integrase protein (IN). We overexpressed the IN proteins of human immunodeficiency viruses types 1 and 2 (HIV-1 and HIV-2) in E. coli and purified them. Both proteins were found to specifically cut two nucleotides off the ends of linear viral DNA, and to integrate viral DNA into target DNA. This demonstrates that HIV IN is the only protein required for integration of HIV DNA. Although the two types of IN proteins have only 53% amino acid sequence similarity, they act with equal efficiency on both type 1 and type 2 viral DNA. Binding of IN to DNA was tested: purified IN does not bind very specifically to viral DNA ends. Nevertheless, only viral DNA ends are cleaved and integrated. We interpret this as follows: in vitro quick aspecific binding to DNA is followed by slow specific cutting and integration. IN can not find viral DNA ends in the presence of an excess of aspecific DNA; in vivo this is not required since the IN protein is in constant proximity of viral DNA in the viral core particle.     

Structural insights into the retroviral DNA integration apparatus

Retroviral replication depends on successful integration of the viral genetic material into a host cell chromosome. Virally encoded integrase, an enzyme from the DDE(D) nucleotidyltransferase superfamily, is responsible for the key DNA cutting and joining steps associated with this process. Insights into the structural and mechanistic aspects of integration are directly relevant for the development of antiretroviral drugs. Recent breakthroughs have led to biochemical and structural characterization of the principal integration intermediates revealing the tetramer of integrase that catalyzes insertion of both 3' viral DNA ends into a sharply bent target DNA. This review discusses the mechanism of retroviral DNA integration and the mode of action of HIV-1 integrase strand transfer inhibitors in light of the recent visualization of the prototype foamy virus intasome, target DNA capture and strand transfer complexes.