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.     

Retroviral cDNA integration: stimulation by HMG I family proteins

To replicate, a retrovirus must synthesize a cDNA copy of the viral RNA genome and integrate that cDNA into a chromosome of the host. We have investigated the role of a host cell cofactor, HMG I(Y) protein, in integration of human immunodeficiency virus type 1 (HIV-1) and Moloney murine leukemia virus (MoMLV) cDNA. Previously we reported that HMG I(Y) cofractionates with HIV-1 preintegration complexes (PICs) isolated from freshly infected cells. PICs depleted of required components by treatment with high concentrations of salt could be reconstituted by addition of purified HMG I(Y) in vitro. Here we report studies using immunoprecipitation that indicate that HMG I(Y) is associated with MoMLV preintegration complexes. In mechanistic studies, we show for both HIV-1 and MoMLV that each HMG I(Y) monomer must contain multiple DNA binding domains to stimulate integration by HMG I(Y)-depleted PICs. We also find that HMG I(Y) can condense model HIV-1 or MoMLV cDNA in vitro as measured by stimulation of intermolecular ligation. This reaction, like reconstitution of integration, depends on the presence of multiple DNA binding domains in each HMG I(Y) monomer. These data suggest that binding of multivalent HMG I(Y) monomers to multiple cDNA sites compacts retroviral cDNA, thereby promoting formation of active integrase-cDNA complexes.     

Sites of retroviral DNA integration: From basic research to clinical applications

One of the most crucial steps in the life cycle of a retrovirus is the integration of the viral DNA (vDNA) copy of the RNA genome into the genome of an infected host cell. Integration provides for efficient viral gene expression as well as for the segregation of viral genomes to daughter cells upon cell division. Some integrated viruses are not well expressed, and cells latently infected with human immunodeficiency virus type 1 (HIV-1) can resist the action of potent antiretroviral drugs and remain dormant for decades. Intensive research has been dedicated to understanding the catalytic mechanism of integration, as well as the viral and cellular determinants that influence integration site distribution throughout the host genome. In this review, we summarize the evolution of techniques that have been used to recover and map retroviral integration sites, from the early days that first indicated that integration could occur in multiple cellular DNA locations, to current technologies that map upwards of millions of unique integration sites from single in vitro integration reactions or cell culture infections. We further review important insights gained from the use of such mapping techniques, including the monitoring of cell clonal expansion in patients treated with retrovirus-based gene therapy vectors, or patients with acquired immune deficiency syndrome (AIDS) on suppressive antiretroviral therapy (ART). These insights span from integrase (IN) enzyme sequence preferences within target DNA (tDNA) at the sites of integration, to the roles of host cellular proteins in mediating global integration distribution, to the potential relationship between genomic location of vDNA integration site and retroviral latency.     

Fusion proteins consisting of human immunodeficiency virus type 1 integrase and the designed polydactyl zinc finger protein E2C direct integration of viral DNA into specific sites

In order to establish a productive infection, a retrovirus must integrate the cDNA of its RNA genome into the host cell chromosome. While this critical process makes retroviruses an attractive vector for gene delivery, the nonspecific nature of integration presents inherent hazards and variations in gene expression. One approach to alleviating the problem involves fusing retroviral integrase to a sequence-specific DNA-binding protein that targets a defined chromosomal site. We prepared proteins consisting of wild-type or truncated human immunodeficiency virus type 1 (HIV-1) integrase fused to the synthetic polydactyl zinc finger protein E2C. The purified fusion proteins bound specifically to the 18-bp E2C recognition sequence as analyzed by DNase I footprinting. The fusion proteins were catalytically active and biased integration of retroviral DNA near the E2C-binding site in vitro. The distribution was asymmetric, and the major integration hot spots were localized within a 20-bp region upstream of the C-rich strand of the E2C recognition sequence. Integration bias was not observed with target plasmids bearing a mutated E2C-binding site or when HIV-1 integrase and E2C were added to the reaction as separate proteins. The results demonstrate that the integrase-E2C fusion proteins offer an efficient approach and a versatile framework for directing the integration of retroviral DNA into a predetermined DNA site.     

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.     

Site-specific integration of retroviral DNA in human cells using fusion proteins consisting of human immunodeficiency virus type 1 integrase and the designed polydactyl zinc-finger protein E2C

During the life cycle of retroviruses, establishment of a productive infection requires stable joining of a DNA copy of the viral RNA genome into host cell chromosomes. Retroviruses are thus promising vectors for the efficient and stable delivery of genes in therapeutic protocols. Integration of retroviral DNA is catalyzed by the viral enzyme integrase (IN), and one salient feature of retroviral DNA integration is its lack of specificity, as many chromosomal sites can serve as targets for integration. Despite the promise for success in the clinic, one major drawback of the retrovirus-based vector is that any unintended insertion events from the therapy can potentially lead to deleterious effects in patients, as demonstrated by the development of malignancies in both animal and human studies. One approach to directing integration into predetermined DNA sites is fusing IN to a sequence-specific DNA-binding protein, which results in a bias of integration near the recognition site of the fusion partner. Encouraging results have been generated in vitro and in vivo using fusion protein constructs of human immunodeficiency virus type 1 IN and E2C, a designed polydactyl zinc-finger protein that specifically recognizes an 18-base pair DNA sequence. This review focuses on the method for preparing infectious virions containing the IN fusion proteins and on the quantitative PCR assays for determining integration site specificity. Efforts to engineer IN to recognize specific target DNA sequences within the genome may lead to development of effective retroviral vectors that can safely deliver gene-based therapeutics in a clinical setting.     

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.     

Irreversible inhibition of human immunodeficiency virus type 1 integrase by dicaffeoylquinic acids

Human immunodeficiency virus type 1 (HIV-1) and other retroviruses require integration of a double-stranded DNA copy of the RNA genome into the host cell chromosome for productive infection. The viral enzyme, integrase, catalyzes the integration of retroviral DNA and represents an attractive target for developing antiretroviral agents. We identified several derivatives of dicaffeoylquinic acids (DCQAs) that inhibit HIV-1 replication in tissue culture and catalytic activities of HIV-1 integrase in vitro. The specific step at which DCQAs inhibit the integration in vitro and the mechanism of inhibition were examined in the present study. Titration experiments with different concentrations of HIV-1 integrase or DNA substrate found that the effect of DCQAs was exerted on the enzyme and not the DNA. In addition to HIV-1, DCQAs also inhibited the in vitro activities of MLV integrase and truncated variants of feline immunodeficiency virus integrase, suggesting that these compounds interacted with the central core domain of integrase. The inhibition on retroviral integrases was relatively specific, and DCQAs had no effect on several other DNA-modifying enzymes and phosphoryltransferases. Kinetic analysis and dialysis experiments showed that the inhibition of integrase by DCQAs was irreversible. The inhibition did not require the presence of a divalent cation and was unaffected by preassembling integrase onto viral DNA. The results suggest that the irreversible inhibition by DCQAs on integrase is directed toward conserved amino acid residues in the central core domain during catalysis.     

Structural and Functional Role of INI1 and LEDGF in the HIV-1 Preintegration Complex

Integration of the HIV-1 cDNA into the human genome is catalyzed by the viral integrase (IN) protein. Several studies have shown the importance of cellular cofactors that interact with integrase and affect viral integration and infectivity. In this study, we produced a stable complex between HIV-1 integrase, viral U5 DNA, the cellular cofactor LEDGF/p75 and the integrase binding domain of INI1 (INI1-IBD), a subunit of the SWI/SNF chromatin remodeling factor. The stoichiometry of the IN/LEDGF/INI1-IBD/DNA complex components was found to be 4/2/2/2 by mass spectrometry and Fluorescence Correlation Spectroscopy. Functional assays showed that INI1-IBD inhibits the 3′ processing reaction but does not interfere with specific viral DNA binding. Integration assays demonstrate that INI1-IBD decreases the amount of integration events but inhibits by-product formation such as donor/donor or linear full site integration molecules. Cryo-electron microscopy locates INI1-IBD within the cellular DNA binding site of the IN/LEDGF complex, constraining the highly flexible integrase in a stable conformation. Taken together, our results suggest that INI1 could stabilize the PIC in the host cell, by maintaining integrase in a stable constrained conformation which prevents non-specific interactions and auto integration on the route to its integration site within nucleosomes, while LEDGF organizes and stabilizes an active integrase tetramer suitable for specific vDNA integration. Moreover, our results provide the basis for a novel type of integrase inhibitor (conformational inhibitor) representing a potential new strategy for use in human therapy.     

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.     

Stereospecificity of reactions catalyzed by HIV-1 integrase

The retroviral integrase catalyzes two successive chemical reactions essential for integration of the retroviral genome into a host chromosome: 3' end processing, in which a dinucleotide is cleaved from each 3' end of the viral DNA; and the integration reaction itself, in which the resulting recessed 3' ends of the viral DNA are joined to the host DNA. We have examined the stereospecificity of human immunodeficiency virus type 1 integrase for phosphorothioate substrates in these reactions and in a third reaction, disintegration, which is macroscopically the reverse of integration. Integrase preferentially catalyzed end processing and integration of a substrate with the (R(p))-phosphorothioate stereoisomer at the reaction center and disintegration of a substrate with an (S(p))-phosphorothiate at the reaction center. These results suggest a model for the architecture of the active site of integrase, and its interactions with key features of the viral and target DNA.     

In VitroAssays for Activities of Retroviral Integrase

Integration of retroviral DNA, an essential step during the retroviral life cycle, is mediated by the viral protein integrase. Simplein vitroassays for measuring integrase activities are described, including catalysis (3′-end processing, 3′-end joining, disintegration), juxtaposition of viral DNA ends, DNA binding, and target site selection. The described assays will be useful in elucidating the molecular mechanism of retroviral integration and screening for integrase inhibitors as potential anti-retroviral drugs.     

An amino acid in the central catalytic domain of three retroviral integrases that affects target site selection in nonviral DNA

Integrase can insert retroviral DNA into almost any site in cellular DNA; however, target site preferences are noted in vitro and in vivo. We recently demonstrated that amino acid 119, in the alpha2 helix of the central domain of the human immunodeficiency virus type 1 integrase, affected the choice of nonviral target DNA sites. We have now extended these findings to the integrases of a nonprimate lentivirus and a more distantly related alpharetrovirus. We found that substitutions at the analogous positions in visna virus integrase and Rous sarcoma virus integrase changed the target site preferences in five assays that monitor insertion into nonviral DNA. Thus, the importance of this protein residue in the selection of nonviral target DNA sites is likely to be a general property of retroviral integrases. Moreover, this amino acid might be part of the cellular DNA binding site on integrase proteins.