Defining nucleic acid-binding properties of avian retrovirus integrase by deletion analysis

Multimodal Functionalities of HIV-1 Integrase

Integrase is the retroviral protein responsible for integrating reverse transcripts into cellular genomes. Co-packaged with viral RNA and reverse transcriptase into capsid-encased viral cores, human immunodeficiency virus 1 (HIV-1) integrase has long been implicated in reverse transcription and virion maturation. However, the underlying mechanisms of integrase in these non-catalytic-related viral replication steps have remained elusive. Recent results have shown that integrase binds genomic RNA in virions, and that mutational or pharmacological disruption of integrase-RNA binding yields eccentric virion particles with ribonucleoprotein complexes situated outside of the capsid shell. Such viruses are defective for reverse transcription due to preferential loss of integrase and viral RNA from infected target cells. Parallel research has revealed defective integrase-RNA binding and eccentric particle formation as common features of class II integrase mutant viruses, a phenotypic grouping of viruses that display defects at steps beyond integration. In light of these new findings, we propose three new subclasses of class II mutant viruses (a, b, and c), all of which are defective for integrase-RNA binding and particle morphogenesis, but differ based on distinct underlying mechanisms exhibited by the associated integrase mutant proteins. We also assess how these findings inform the role of integrase in HIV-1 particle maturation.

Retroviral integrase: Structure, mechanism, and inhibition

The retroviral protein Integrase (IN) catalyzes concerted integration of viral DNA into host chromatin to establish a permanent infection in the target cell. We learned a great deal about the mechanism of catalytic integration through structure/function studies over the previous four decades of IN research. As one of three essential retroviral enzymes, IN has also been targeted by antiretroviral drugs to treat HIV-infected individuals. Inhibitors blocking the catalytic integration reaction are now state-of-the-art drugs within the antiretroviral therapy toolkit. HIV-1 IN also performs intriguing non-catalytic functions that are relevant to the late stages of the viral replication cycle, yet this aspect remains poorly understood. There are also novel allosteric inhibitors targeting non-enzymatic functions of IN that induce a block in the late stages of the viral replication cycle. In this chapter, we will discuss the function, structure, and inhibition of retroviral IN proteins, highlighting remaining challenges and outstanding questions.

The Old and the New: Prospects for Non-Integrating Lentiviral Vector Technology

Lentiviral vectors have been developed and used in multiple gene and cell therapy applications. One of their main advantages over other vectors is the ability to integrate the genetic material into the genome of the host. However, this can also be a disadvantage as it may lead to insertional mutagenesis. To address this, non-integrating lentiviral vectors (NILVs) were developed. To generate NILVs, it is possible to introduce mutations in the viral enzyme integrase and/or mutations on the viral DNA recognised by integrase (the attachment sites). NILVs are able to stably express transgenes from episomal DNA in non-dividing cells or transiently if the target cells divide. It has been shown that these vectors are able to transduce multiple cell types and tissues. These characteristics make NILVs ideal vectors to use in vaccination and immunotherapies, among other applications. They also open future prospects for NILVs as tools for the delivery of CRISPR/Cas9 components, a recent revolutionary technology now widely used for gene editing and repair.

A C-terminal "Tail" Region in the Rous Sarcoma Virus Integrase Provides High Plasticity of Functional Integrase Oligomerization during Intasome Assembly

The retrovirus integrase (IN) inserts the viral cDNA into the host DNA genome. Atomic structures of five different retrovirus INs complexed with their respective viral DNA or branched viral/target DNA substrates have indicated these intasomes are composed of IN subunits ranging from tetramers, to octamers, or to hexadecamers. IN precursors are monomers, dimers, or tetramers in solution. But how intasome assembly is controlled remains unclear. Therefore, we sought to unravel the functional mechanisms in different intasomes. We produced kinetically stabilized Rous sarcoma virus (RSV) intasomes with human immunodeficiency virus type 1 strand transfer inhibitors that interact simultaneously with IN and viral DNA within intasomes. We examined the ability of RSV IN dimers to assemble two viral DNA molecules into intasomes containing IN tetramers in contrast to one possessing IN octamers. We observed that the last 18 residues of the C terminus ("tail" region) of IN (residues 1-286) determined whether an IN tetramer or octamer assembled with viral DNA. A series of truncations of the tail region indicated that these 18 residues are critical for the assembly of an intasome containing IN octamers but not for an intasome containing IN tetramers. The C-terminally truncated IN (residues 1-269) produced an intasome that contained tetramers but failed to produce an intasome with octamers. Both intasomes have similar catalytic activities. The results suggest a high degree of plasticity for functional multimerization and reveal a critical role of the C-terminal tail region of IN in higher order oligomerization of intasomes, potentially informing future strategies to prevent retroviral integration.

Mutations in the catalytic core or the C-terminus of murine leukemia virus (MLV) integrase disrupt virion infectivity and exert diverse effects on reverse transcription

Understanding of the structures and functions of the retroviral integrase (IN), a key enzyme in the viral replication cycle, is essential for developing antiretroviral treatments and facilitating the development of safer gene therapy vehicles. Thus, four MLV IN-mutants were constructed in the context of a retroviral vector system, harbouring either a substitution in the catalytic centre, deletions in the C-terminus, or combinations of both modifications. IN-mutants were tested for their performance in different stages of the viral replication cycle: RNA-packaging; RT-activity; transient and stable infection efficiency; dynamics of reverse transcription and nuclear entry. All mutant vectors packaged viral RNA with wild-type efficiencies and displayed only slight reductions in RT-activity. Deletion of either the IN C-terminus alone, or in addition to part of the catalytic domain exerted contrasting effects on intracellular viral DNA levels, implying that IN influences reverse transcription in more than one direction.

Versican in the developing brain: lamina-specific expression in interneuronal subsets and role in presynaptic maturation

Chondroitin sulfate proteoglycans (CSPGs) of the extracellular matrix help stabilize synaptic connections in the postnatal brain and impede regeneration after injury. Here, we show that a CSPG of the lectican family, versican, also promotes presynaptic maturation in the developing brain. In the embryonic chick optic tectum, versican is expressed selectively by subsets of interneurons confined to the retinorecipient laminae, in which retinal axons arborize and form synapses. It is a major receptor for the Vicia villosa B4 lectin (VVA), shown previously to inhibit invasion of the retinorecipient lamina by retinal axons (Inoue and Sanes, 1997). In vitro, versican promotes enlargement of presynaptic varicosities in retinal axons. Depletion of versican in ovo, by RNA interference, results in retinal arbors with smaller than normal varicosities. We propose that versican provides a lamina-specific cue for presynaptic maturation and discuss the related but distinct effects of versican depletion and VVA blockade.

A three-dimensional model of the human immunodeficiency virus type 1 integration complex

While the general features of HIV-1 integrase function are understood, there is still uncertainty about the composition of the integration complex and how integrase interacts with viral and host DNA. We propose an improved model of the integration complex based on current experimental evidence including a comparison with the homologous Tn5 transposase containing bound DNA and an analysis of DNA binding sites using Goodford's GRID. Our model comprises a pair of integrase dimers, two strands of DNA to represent the viral DNA ends and a strand of bent DNA representing the host chromosome. In our model, the terminal four base pairs of each of the viral DNA strands interact with the integrase dimer providing the active site, while bases one turn away interact with a flexible loop (residues 186-194) on the second integrase dimer. We propose that residues E152, Q148 and K156 are involved in the specific recognition of the conserved CA dinucleotide and that the active site mobile loop (residues 140-149) stabilises the integration complex by acting as a barrier to separate the two viral DNA ends. In addition, the residues responsible for DNA binding in our model show a high level of amino acid conservation.

Genetic analyses of conserved residues in the carboxyl-terminal domain of human immunodeficiency virus type 1 integrase

Results of in vitro assays identified residues in the C-terminal domain (CTD) of human immunodeficiency virus type 1 (HIV-1) integrase (IN) important for IN-IN and IN-DNA interactions, but the potential roles of these residues in virus replication were mostly unknown. Sixteen CTD residues were targeted here, generating 24 mutant viruses. Replication-defective mutants were typed as class I (blocked at integration) or class II (additional reverse transcription and/or assembly defects). Most defective viruses (15 of 17) displayed reverse transcription defects. In contrast, replication-defective HIV-1(E246K) synthesized near-normal cDNA levels but processing of Pr55(gag) was largely inhibited in virus-producing cells. Because single-round HIV-1(E246K.Luc(R-)) transduced cells at approximately 8% of the wild-type level, we concluded that the late-stage processing defect contributed significantly to the overall replication defect of HIV-1(E246K). Results of complementation assays revealed that the CTD could function in trans to the catalytic core domain (CCD) in in vitro assays, and we since determined that certain class I and class II mutants defined a novel genetic complementation group that functioned in cells independently of IN domain boundaries. Seven of eight novel Vpr-IN mutant proteins efficiently trans-complemented class I active-site mutant virus, demonstrating catalytically active CTD mutant proteins during infection. Because most of these mutants inefficiently complemented a class II CCD mutant virus, the majority of CTD mutants were likely more defective for interactions with cellular and/or viral components that affected reverse transcription and/or preintegration trafficking than the catalytic activity of the IN enzyme.

Retroviral DNA integration--mechanism and consequences

Integration of retroviral cDNA into the host cell chromosome is an essential step in its replication. This process is catalyzed by the retroviral integrase protein, which is conserved among retroviruses and retrotransposons. Integrase binds viral and host DNA in a complex, called the preintegration complex (PIC), with other viral and cellular proteins. While the PIC is capable of directing integration of the viral DNA into any chromosomal location, different retroviruses have clear preferences for integration in or near particular chromosomal features. The determinants of integration site selection are under investigation but may include retrovirus-specific interactions between integrase and tethering factors bound to the host cell chromosomes. Research into the mechanisms of retroviral integration site selection has shed light on the phenomena of insertional mutagenesis and viral latency.

Mutations in the C-terminal domain of ALSV (Avian Leukemia and Sarcoma Viruses) integrase alter the concerted DNA integration process in vitro

Integrase (IN) is the retroviral enzyme responsible for the integration of the DNA copy of the retroviral genome into the host cell DNA. The C-terminal domain of IN is involved in DNA binding and enzyme multimerization. We previously performed single amino acid substitutions in the C-terminal domain of the avian leukemia and sarcoma viruses (ALSV) IN. Here, we modelled these IN mutants and analysed their ability to mediate concerted DNA integration (in an in vitro assay) as well as to form dimers (by size exclusion chromatography and protein-protein cross-linking). Mutations of residues located at the dimer interface (V239, L240, Y246, V257 and K266) have the greatest effects on the activity of the IN. Among them: (a) the L240A mutation resulted in a decrease of integration efficiency that was concomitant with a decrease of IN dimerization; (b) the V239A, V249A and K266A mutants preferentially mediated non-concerted DNA integration rather than concerted DNA integration although they were found as dimers. Other mutations (V260E and Y246W/DeltaC25) highlight the role of the C-terminal domain in the general folding of the enzyme and, hence, on its activity. This study points to the important role of residues at the IN C-terminal domain in the folding and dimerization of the enzyme as well as in the concerted DNA integration of viral DNA ends.

Differential multimerization of Moloney murine leukemia virus integrase purified under nondenaturing conditions

Retroviral integrases (IN) catalyze the integration of the reverse-transcribed viral DNA into the host genome, an essential process leading to virus replication. For Moloney murine leukemia virus (M-MuLV) IN, the limited solubility of the recombinant protein has restricted the development of biophysical and structural analyses. Herein, recombinant M-MuLV IN proteins, either full length or two nonoverlapping domain constructs, were purified under non-denaturing conditions from solubilized bacterial extracts by Ni(2+)-NTA resins. Additionally, WT IN was further purified by heparin chromatography. All of the purified proteins were shown to be active and stable. WT M-MuLV IN chromatographed with a peak corresponding with a dimer by gel filtration chromatography. In contrast, the single point mutant C209A IN migrated predominantly as a tetramer. For both proteins, fractions in equilibrium between dimers and tetramers were competent to assemble concerted two-end integrations and yielded a unique strand-transfer profile in the presence of a 28-mer U5 oligonucleotide substrate, indicative of a distinct conformation within the synaptic complex. This specific target-site selection was not observed with a shorter 20-mer U5 substrate. These studies provide the foundation for biophysical and structural analysis on M-MuLV IN and the mechanism of retroviral integration.

Reversion of the lethal phenotype of an HIV-1 integrase mutant virus by overexpression of the same integrase mutant protein

The human immunodeficiency virus type 1 (HIV-1) integrase (IN) is essential for integration of viral DNA into host cell chromatin. We have reported previously (Priet, S., Navarro, J. M., Gros, N., Querat, G., and Sire, J. (2003) J. Biol. Chem. 278, 4566-4571) that IN also plays a role in the packaging of the host uracil DNA glycosylase UNG2 into viral particles and that the region of IN encompassing residues 170-180 was responsible for the interaction with UNG2 and for its packaging into virions. In this work, we aimed to investigate the replication of HIV-1 viruses rendered deficient in virion-associated UNG2 by single or double point mutations in the region 170-180 of IN. We show that the L172A/K173A IN mutant virus was deficient for UNG2 packaging and was defective for replication because of a blockage at the stage of proviral DNA integration in host cell DNA. In vitro assays using long term repeat mimics, however, demonstrate that the L172A/K173A IN mutant was catalytically active. Moreover, trans-complementation experiments show that the viral propagation of L172A/K173A viruses could be rescued by the overexpression of Vpr.L172A/K173A IN fusion protein in a dose-dependent manner and that this rescue is independent of UNG2 packaging. Altogether, our data indicate that L172A/K173A mutations of IN induce a subtle defect in the function of IN, which nevertheless dramatically impairs viral replication. Unexpectedly, this blockage of replication could be overcome by forcing the packaging of higher amounts of this same mutated integrase. This is the first study reporting that blockage of the integration process of HIV-1 provirus carrying a mutation of IN could be alleviated by increasing amounts of IN even carrying the same mutations.

Target integration by a chimeric Sp1 zinc finger domain-Moloney murine leukemia virus integrase in vivo

A specificity protein 1 (Sp1) zinc finger domain containing two tandem zinc fingers was fused to the C terminus of the integrase (IN) protein of the Moloney murine leukemia virus (MuLV). The integrity of the MuLV IN was completely preserved, since the fusion was conducted at the last amino acid residue of the protein. The vector pMIN-Sp1, which carried the fused MuLV IN-Sp1 zinc finger domain gene, was cotransfected with a wild-type MuLV vector pMLV-K to NIH/3T3 cells. A nonradioactive reverse transcriptase assay was performed on culture supernatants collected from the cotransfected cells to confirm the production of recombinant viruses. The expression of the fusion protein and the integration of the MuLV genome by the fusion protein were confirmed by a Northern and then a Southern hybridization analysis on the total RNA or genomic DNA extracted from cells infected by viruses collected from the supernatants of the cotransfected cells. Regions of the host chromosome that were selected by the fusion protein as the integration targets were sequenced using the TOPO(TM) cloning method on a series of PCR products generated with a nested set of primers. The percentage of positive clones screened that contained the DNA-binding sequence of the fused Sp1 zinc finger domain was around 13% (5 out of 39 clones). It was found that the Sp1 DNA-binding sequence was only present in regions that were proximal to one of the long terminal repeats of the integrated viral genome, suggesting that the fusion protein could select a target sequence for integration. The host flanking sequences determined for all the positive clones were also used as queries to perform a BLAST search on the GenBank mouse EST entries. Although matching scores for sequences of some of the clones computed were more significant than others, it was difficult to judge whether or not the integration in these clones had been targeted to some gene sequences. Most of the integration sites might exist in the introns, since we found that the probability of the gene sequences containing an Sp1 DNA-binding site was low.

In search of authentic inhibitors of HIV-1 integration

Current strategies for the treatment of HIV infection are based on cocktails of drugs that target the viral reverse transcriptase or protease enzymes. At present, the clinical benefit of this combination therapy for HIV-infected patients is considerable, although it is not clear how long this effect will last taking into account the emergence of multiple drug-resistant viral strains. Addition of new anti-HIV drugs targeting additional steps of the viral replication cycle may increase the potency of inhibition and prevent resistance development. During HIV replication, integration of the viral genome into the cellular chromosome is an essential step catalysed by the viral integrase. Although HIV integrase is an attractive target for antiviral therapy, so far all research efforts have led to the identification of only one series of compounds that selectively inhibit the integration step during HIV replication, namely the diketo acids. In this review we try to address the question why it has proven so difficult to find potent and selective integrase inhibitors. We point to potential pitfalls in defining an inhibitor as an authentic integrase inhibitor, and propose new strategies and technologies for the discovery of authentic HIV integration inhibitors.

Role of the nonspecific DNA-binding region and alpha helices within the core domain of retroviral integrase in selecting target DNA sites for integration

Retroviral integrase plays an important role in choosing host chromosomal sites for integration of the cDNA copy of the viral genome. The domain responsible for target site selection has been previously mapped to the central core of the protein (amino acid residues 49-238). Chimeric integrases between human immunodeficiency virus type 1 (HIV-1) and feline immunodeficiency virus (FIV) were prepared to examine the involvement of a nonspecific DNA-binding region (residues 213-266) and certain alpha helices within the core domain in target site selection. Determination of the distribution and frequency of integration events of the chimeric integrases narrowed the target site-specifying motif to within residues 49-187 and showed that alpha 3 and alpha 4 helices (residues 123-166) were not involved in target site selection. Furthermore, the chimera with the alpha 2 helix (residues 118-121) of FIV identity displayed characteristic integration events from both HIV-1 and FIV integrases. The results indicate that the alpha 2 helix plays a role in target site preference as either part of a larger or multiple target site-specifying motif.

Assembly and catalysis of concerted two-end integration events by Moloney murine leukemia virus integrase

Retroviral integration results in the stable and coordinated insertion of the two termini of the linear viral DNA into the host genome. An in vitro concerted two-end integration reaction catalyzed by the Moloney murine leukemia virus (M-MuLV) integrase (IN) was used to investigate the binding and coordination of the two viral DNA ends. Comparison of the two-end integration and strand transfer assays indicates that zinc is required for efficient concerted integration utilizing plasmid DNA as target. Complementation assays using a pair of nonoverlapping integrase domains, consisting of the HHCC domain and the core/C-terminal region, yielded products containing the correct 4-base target site duplication. The efficiency of the coordinated two-end integration varied depending on the order of addition of the individual protein and DNA components in the complementation assay. Two-end integration was most efficient when the long terminal repeat (LTR) was premixed with either the target DNA or the HHCC domain. The preference for two-end integration through preincubation of the HHCC finger with the viral DNA supports the role of this domain in the recognition and/or positioning of the LTR.

Molecular genetics and target site specificity of retroviral integration

Integration is an essential step in the life cycle of retroviruses, resulting in the stable joining of the viral cDNA to the host cell chromosomes. While this critical process makes retroviruses an attractive vector for gene delivery, it also presents a potential hazard. The sites where integration occurs are nonspecific. Therefore,it is possible that integration of retroviral DNA will affect host gene expression and disrupt normal cellular functions. The mechanism by which integration sites are chosen is not well understood, and is influenced by several factors, including DNA sequence and structure, DNA-binding proteins, DNA methylation, and transcription. Integrase, the viral enzyme responsible for catalyzing integration, also plays a key role in controlling the choice of target sites. The integrase domain responsible for target site selection has been mapped to the central core region. A better understanding of the interaction between the target-specifying motif of integrase and the target DNA may allow a means to manipulate integration into particular chromosomal sites. Another approach to directing integration is to fuse integrase with a sequence-specific DNA-binding protein, which results in a bias of integration in vitro into the recognition site of the fusion partner. Successful incorporation of the fusion protein into infectious virions and the identification of optimal proteins that can be fused to integrase will advance the development of site-specific vectors. Retroviruses are promising for the delivery of genes in experimental and therapeutic protocols. A better understanding of integration will aid in the design of safer and more effective gene transfer vectors.

Integrase-lexA fusion proteins incorporated into human immunodeficiency virus type 1 that contains a catalytically inactive integrase gene are functional to mediate integration

Purified fusion proteins made up of a retroviral integrase and a sequence-specific DNA-binding protein have been tested in in vitro assays for their ability to direct integration into specific target sites. To determine whether these fusion proteins can be incorporated into human immunodeficiency virus type 1 (HIV-1) and are functional to mediate integration, we used an in trans approach to deliver various integrase-LexA proteins to an integrase-defective virus containing an integrase mutation at aspartate residue 64. Integrase-LexA, integrase-LexA DNA-binding domain, or N- or C-terminally truncated integrase-LexA proteins were fused to the HIV-1 accessory protein, Vpr. Coexpression of the Vpr fusion proteins and an integrase-defective HIV-1 molecular clone by a producer cell line resulted in efficient incorporation of the fusion protein into the integrase-mutated virus. In addition, each of these viruses was infectious and capable of performing integration, as determined by two independent cellular assays that measure reporter gene expression. With the exception of the N-terminally truncated integrase fused to LexA, which was at about 1%, all of the fusion proteins restored integration to a similar level, at 17 to 24% of that of the wild-type virus. The low level observed with the N-terminally truncated integrase fused to LexA is consistent with previous results implying that the N terminus of integrase is involved in multiple steps of the retroviral life cycle. These data indicate that the integrase-fusion proteins retain catalytic function in the integrase-mutated viruses and demonstrate the feasibility of incorporating integrase fusion proteins into HIV-1 for the development of site-directed retroviral vectors.

Refined solution structure of the dimeric N-terminal HHCC domain of HIV-2 integrase

The solution structure of the dimeric N-terminal domain of HIV-2 integrase (residues 1-55, named IN(1-55)) has been determined using NMR spectroscopy. The structure of the monomer, which was already reported previously [Eijkelenboom et al. (1997) Curr. Biol., 7, 739-746], consists of four alpha-helices and is well defined. Helices alpha1, alpha2 and alpha3 form a three-helix bundle that is stabilized by zinc binding to His12, His16, Cys40 and Cys43. The dimer interface is formed by the N-terminal tail and the first half of helix alpha3. The orientation of the two monomeric units with respect to each other shows considerable variation. 15N relaxation studies have been used to characterize the nature of the intermonomeric disorder. Comparison of the dimer interface with that of the well-defined dimer interface of HIV-1 IN(1-55) shows that the latter is stabilized by additional hydrophobic interactions and a potential salt bridge. Similar interactions cannot be formed in HIV-2 IN(1-55) [Cai et al. (1997) Nat. Struct. Biol., 4, 567-577], where the corresponding residues are positively charged and neutral ones.

Retroviral DNA integration

DNA integration is a unique enzymatic process shared by all retroviruses and retrotransposons. During integration, double-stranded linear viral DNA is inserted into the host genome in a process catalyzed by the virus-encoded integrase (IN). The mechanism involves a series of nucleophilic attacks, the first of which removes the terminal 2 bases from the 3' ends of the long terminal repeats and of the second which inserts the viral DNA into the host genome. IN specifically recognizes the DNA sequences at the termini of the viral DNA, juxtaposing both ends in an enzyme complex that inserts the viral DNA into a single site in a concerted manner. Small duplications of the host DNA, characteristic of the viral IN, are found at the sites of insertion. At least two host proteins, HMG-I(Y) and BAF, have been shown to increase the efficiency of the integration reaction.

Targeting human immunodeficiency virus (HIV) type 2 integrase protein into HIV type 1

Integrase (IN) is the only retroviral enzyme necessary for the integration of retroviral cDNA into the host cell's chromosomes. The structure and function of IN is highly conserved. The human immunodeficiency virus type 2 (HIV-2) IN has been shown to efficiently support 3' processing and strand transfer of HIV-1 DNA substrate in vitro. To determine whether HIV-2 IN protein (IN(2)) could substitute for HIV-1 IN function in vivo, we used HIV-1 Vpr to deliver the IN(2) into IN mutant HIV-1 virions by expression in trans as a Vpr-IN fusion protein. Trans-complementation with IN(2) markedly increased the infectivity of IN-minus HIV-1. Compared with the homologous trans-IN protein, infectivity was increased to a level of 16%. Since IN has been found to play a role in reverse transcription (Wu et al., J. Virol. 73:2126-2135, 1999), cells infected with IN(2)-complemented HIV-1 were analyzed for DNA products of reverse transcription. DNA levels of approximately 18% of that of wild type were detected. The homologous trans-IN protein restored the synthesis of viral cDNA to approximately 86% of that of wild-type virus. By complementing integration-defective HIV-1 IN mutant viruses, which were not impaired in cDNA synthesis, the trans-IN(2) protein was shown to support integration up to a level of 55% compared with that of the homologous trans-IN protein. The delivery of heterologous IN protein into HIV-1 particles in trans offers a novel approach to understand IN protein function in vivo.

Substrate recognition by retroviral integrases

Substrate recognition by the retroviral IN enzyme is critical for retroviral integration. To catalyze this recombination event, IN must recognize and act on two types of substrates, viral DNA and host DNA, yet the necessary interactions exhibit markedly different degrees of specificity. Although particular sequences at the viral DNA termini are recognized by IN, many host DNA sequences can serve as the target for integration. Over the last decade, both in vitro and in vivo data have contributed to our understanding of how IN recognizes its substrates. This review provides an overview of the sequence and structure requirements for recognition of viral and host DNA by different retroviral INs and discusses recent progress in mapping protein domains involved in these interactions.

Crystal structures of catalytic core domains of retroviral integrases and role of divalent cations in enzymatic activity

Crystal structures of the enzymatically competent catalytic domains of HIV-1 and ASV IN have been solved in the last few years. The structure of HIV-1 IN has been described only for apoenzyme and for a complex with Mg2+, whereas the structure of ASV IN has been presented as the apoenzyme, in the presence of divalent cations (Mn2+, Mg2+, Ca2+, Zn2+, and Cd2+), and with an inhibitor. A single ion of Mn2+, Mg2+, or Ca2+ interacts with the two aspartate side chains of the D,D(35)E catalytic center in octahedral coordination with four water molecules. However, two ions of Zn2+ or Cd2+ bind to the active site of IN with tetrahedral and octahedral coordination, respectively. Only small adjustments take place in the active site of ASV IN on binding of the metal cofactor(s), which are absolutely required for the activity of this enzyme. The placement of the side chains and metal ions in the active site is very similar to that observed even in distant members of this superfamily of polynucleotidyltransferases. Here the role of divalent cations in the enzymatic activity of IN and the search for inhibitors of this enzyme are discussed.

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.

Functional interactions of the HHCC domain of moloney murine leukemia virus integrase revealed by nonoverlapping complementation and zinc-dependent dimerization

The retroviral integrase (IN) is required for the integration of viral DNA into the host genome. The N terminus of IN contains an HHCC zinc finger-like motif, which is conserved among all retroviruses. To study the function of the HHCC domain of Moloney murine leukemia virus IN, the first N-terminal 105 residues were expressed independently. This HHCC domain protein is found to complement a completely nonoverlapping construct lacking the HHCC domain for strand transfer, 3' processing and coordinated disintegration reactions, revealing trans interactions among IN domains. The HHCC domain protein binds zinc at a 1:1 ratio and changes its conformation upon binding to zinc. The presence of zinc within the HHCC domain stimulates selective integration processes. Zinc promotes the dimerization of the HHCC domain and protects it from N-ethylmaleimide modification. These studies dissect and define the requirement for the HHCC domain, the exact function of which remains unknown.

Mutations in nonconserved domains of Ty3 integrase affect multiple stages of the Ty3 life cycle

Ty3, a retroviruslike element of Saccharomyces cerevisiae, transposes into positions immediately upstream of RNA polymerase III-transcribed genes. The Ty3 integrase (IN) protein is required for integration of the replicated, extrachromosomal Ty3 DNA. In retroviral IN, a conserved core region is sufficient for strand transfer activity. In this study, charged-to-alanine scanning mutagenesis was used to investigate the roles of the nonconserved amino- and carboxyl-terminal regions of Ty3 IN. Each of the 20 IN mutants was defective for transposition, but no mutant was grossly defective for capsid maturation. All mutations affecting steady-state levels of mature IN protein resulted in reduced levels of replicated DNA, even when polymerase activity was not grossly defective as measured by exogenous reverse transcriptase activity assay. Thus, IN could contribute to nonpolymerase functions required for DNA production in vivo or to the stability of the DNA product. Several mutations in the carboxyl-terminal domain resulted in relatively low levels of processed 3' ends of the replicated DNA, suggesting that this domain may be important for binding of IN to the long terminal repeat. Another class of mutants produced wild-type amounts of DNA with correctly processed 3' ends. This class could include mutants affected in nuclear entry and target association. Collectively, these mutations demonstrate that in vivo, within the preintegration complex, IN performs a central role in coordinating multiple late stages of the retrotransposition life cycle.

Purification of recombinant Rous sarcoma virus integrase possessing physical and catalytic properties similar to virion-derived integrase

Recombinant Rous sarcoma virus integrase cloned from the Prague A (PrA) virus strain was expressed in Escherichia coli. Here we report the detailed purification procedure resulting in an apparently homogeneous integrase. Recombinant PrA integrase was compared at both the protein structural and the catalytic levels to avian myeloblastosis virus integrase purified from virions. Both proteins exist minimally in a dimeric state at low nanomolar concentrations as analyzed by glycerol gradient sedimentation and protein crosslinking studies. Likewise, both proteins have similar specific activities for full-site (concerted integration reaction) and half-site strand transfer activities using linear 480-bp retrovirus-like donor substrates that contain wild-type or mutant termini. They respond similarly to high NaCl concentrations ( approximately 350 mM) as well as aprotic solvents for efficient full-site strand transfer. The data suggest that recombinant integrase proteins with physical and catalytic properties similar to the virion counterpart can be purified using these techniques and will faithfully and efficiently promote the full-site integration reaction in vitro.

Structure-based mutational analysis of the C-terminal DNA-binding domain of human immunodeficiency virus type 1 integrase: critical residues for protein oligomerization and DNA binding

The C-terminal domain of human immunodeficiency virus type 1 (HIV-1) integrase (IN) is a dimer that binds to DNA in a nonspecific manner. The structure of the minimal region required for DNA binding (IN220-270) has been solved by nuclear magnetic resonance spectroscopy. The overall fold of the C-terminal domain of HIV-1 IN is similar to those of Src homology region 3 domains. Based on the structure of IN220-270, we studied the role of 15 amino acid residues potentially involved in DNA binding and oligomerization by mutational analysis. We found that two amino acid residues, arginine 262 and leucine 234, contribute to DNA binding in the context of IN220-270, as indicated by protein-DNA UV cross-link analysis. We also analyzed mutant proteins representing portions of the full-length IN protein. Amino acid substitution of residues located in the hydrophobic dimer interface, such as L241A and L242A, results in the loss of oligomerization of IN; consequently, the levels of 3' processing, DNA strand transfer, and intramolecular disintegration are strongly reduced. These results suggest that dimerization of the C-terminal domain of IN is important for correct multimerization of IN.

A chimeric Ty3/Moloney murine leukemia virus integrase protein is active in vivo

This report describes the results of experiments to determine whether chimeras between a retrovirus and portions of Ty3 are active in vivo. A chimera between Ty3 and a Neo(r)-marked Moloney murine leukemia virus (M-MuLV) was constructed. The C-terminal domain of M-MuLV integrase (IN) was replaced with the C-terminal domain of Ty3 IN. The chimeric retroviruses were expressed from an amphotrophic envelope packaging cell line. The virus generated was used to infect the human fibrosarcoma cell line HT1080, and cells in which integration had occurred were selected by G418 resistance. Three independently integrated viruses were rescued. In each case, the C-terminal Ty3 IN sequences were maintained and short direct repeats of the genomic DNA flanked the integration site. Sequence analysis of the genomic DNA flanking the insertion did not identify a tRNA gene; therefore, these integration events did not have Ty3 position specificity. This study showed that IN sequences from the yeast retrovirus-like element Ty3 can substitute for M-MuLV IN sequences in the C-terminal domain and contribute to IN function in vivo. It is also one of the first in vivo demonstrations of activity of a retrovirus encoding an integrase chimera. Studies of chimeras between IN species with distinctive integration patterns should complement previous work by expanding our understanding of the roles of nonconserved domains.

Efficient gap repair catalyzed in vitro by an intrinsic DNA polymerase activity of human immunodeficiency virus type 1 integrase

Cleavage and DNA joining reactions, carried out by human immunodeficiency virus type 1 (HIV-1) integrase, are necessary to effect the covalent insertion of HIV-1 DNA into the host genome. For the integration of HIV-1 DNA into the cellular genome to be completed, short gaps flanking the integrated proviral DNA must be repaired. It has been widely assumed that host cell DNA repair enzymes are involved. Here we report that HIV-1 integrase multimers possess an intrinsic DNA-dependent DNA polymerase activity. The activity was characterized by its dependence on Mg2+, resistance to N-ethylmaleimide, and inhibition by 3'-azido-2',3'-dideoxythymidine-5'-triphosphate, coumermycin A1, and pyridoxal 5'-phosphate. The enzyme efficiently utilized poly(dA)-oligo(dT) or self-annealing oligonucleotides as a template primer but displayed relatively low activity with gapped calf thymus DNA and no activity with poly(dA) or poly(rA)-oligo(dT). A monoclonal antibody binding specifically to an epitope comprised of amino acids 264 to 273 near the C terminus of HIV-1 integrase severely inhibited the DNA polymerase activity. A deletion of 50 amino acids at the C terminus of integrase drastically altered the gel filtration properties of the DNA polymerase, although the level of activity was unaffected by this mutation. The DNA polymerase efficiently extended a hairpin DNA primer up to 19 nucleotides on a T20 DNA template, although addition of the last nucleotide occurred infrequently or not at all. The ability of integrase to repair gaps in DNA was also investigated. We designed a series of gapped molecules containing a single-stranded region flanked by a duplex U5 viral arm on one side and by a duplex nonviral arm on the other side. Molecules varied structurally depending on the size of the gap (one, two, five, or seven nucleotides), their content of T's or C's in the single-stranded region, whether the CA dinucleotide in the viral arm had been replaced with a nonviral sequence, or whether they contained 5' AC dinucleotides as unpaired tails. The results indicated that the integrase DNA polymerase is specifically designed to repair gaps efficiently and completely, regardless of gap size, base composition, or structural features such as the internal CA dinucleotide or unpaired 5'-terminal AC dinucleotides. When the U5 arm of the gapped DNA substrate was removed, leaving a nongapped DNA template-primer, the integrase DNA polymerase failed to repair the last nucleotide in the DNA template effectively. A post-gap repair reaction did depend on the CA dinucleotide. This secondary reaction was highly regulated. Only two nucleotides beyond the gap were synthesized, and these were complementary to and dependent for their synthesis on the CA dinucleotide. We were also able to identify a specific requirement for the C terminus of integrase in the post-gap repair reaction. The results are consistent with a direct role for a heretofore unsuspected DNA polymerase function of HIV-1 integrase in the repair of short gaps flanking proviral DNA integration intermediates that arise during virus infection.

The application of a homologous recombination assay revealed amino acid residues in an LTR-retrotransposon that were critical for integration

Retroviruses and their relatives, the LTR-retrotransposons, possess an integrase protein (IN) that is required for the insertion of reverse transcripts into the genome of host cells. Schizosaccharomyces pombe is the host of Tf1, an LTR-retrotransposon with integration activity that can be studied by using techniques of yeast genetics. In this study, we sought to identify amino acid substitutions in Tf1 that specifically affected the integration step of transposition. In addition to seeking amino acid substitutions in IN, we also explored the possibility that other Tf1 proteins contributed to integration. By comparing the results of genetic assays that monitored both transposition and reverse transcription, we were able to seek point mutations throughout Tf1 that blocked transposition but not the synthesis of reverse transcripts. These mutant versions of Tf1 were candidates of elements that possessed defects in the integration step of transposition. Five mutations in Tf1 that resulted in low levels of integration were found to be located in the IN protein: two substitutions in the N-terminal Zn domain, two in the catalytic core, and one in the C-terminal domain. These results suggested that each of the three IN domains was required for Tf1 transposition. The potential role of these five amino acid residues in the function of IN is discussed. Two of the mutations that reduced integration mapped to the RNase H (RH) domain of Tf1 reverse transcriptase. The Tf1 elements with the RH mutations produced high levels of reverse transcripts, as determined by recombination and DNA blot analysis. These results indicated that the RH of Tf1 possesses a function critical for transposition that is independent of the accumulation of reverse transcripts.

Avian retrovirus U3 and U5 DNA inverted repeats. Role Of nonsymmetrical nucleotides in promoting full-site integration by purified virion and bacterial recombinant integrases

The U3 and U5 termini of linear retrovirus DNA contain imperfect inverted repeats that are necessary for the concerted insertion of the termini into the host chromosome by viral integrase. Avian myeloblastosis virus integrase can efficiently insert the termini of retrovirus-like DNA donor substrates (480 base pairs) by a concerted mechanism (full-site reaction) into circular target DNA in vitro. The specific activities of virion-derived avian myeloblastosis virus integrase and bacterial recombinant Rous sarcoma virus (Prague A strain) integrase (approximately 50 nM or less) appear similar upon catalyzing the full-site reaction with 3'-OH recessed wild type or mutant donor substrates. We examined the role of the three nonsymmetrical nucleotides located at the 5th, 8th, and 12th positions in the U3 and U5 15-base pair inverted repeats for their ability to modify the full-site and simultaneously, the half-site strand transfer reactions. Our data suggest that the nucleotide at the 5th position appears to be responsible for the 3-5-fold preference for wild type U3 ends over wild type U5 ends by integrase for concerted integration. Additional mutations at the 5th or 6th position, or both, of U3 or U5 termini significantly increased (approximately 3 fold) the full-site reactions of mutant donors over wild type donors.

In vitro assays for activities of retroviral integrase

Integration of retroviral DNA, an essential step during the retroviral life cycle, is mediated by the viral protein integrase. Simple in vitro assays 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.

A metal-induced conformational change and activation of HIV-1 integrase

Retroviral integrases are composed of three independently folding domains whose organization relevant to one another is largely unknown. As an approach to understanding its structure, we have investigated the effect of the required metal cofactor(s), Mn2+ or Mg2+, on the conformation of human immunodeficiency virus type 1 (HIV-1) integrase (IN) using monoclonal antibodies (mAbs) that are specific for each of these three domains. Upon the addition of increasing concentrations of the divalent cations to immobilized HIV-1 IN in ELISA assays, binding of mAbs specific for either the C-terminal domain or for an epitope in the catalytic core domain was lost, whereas binding of an N terminus-specific mAb was unaffected. Size exclusion chromatography of a nonaggregating derivative of HIV-1 IN showed that the oligomeric state of the protein did not change under conditions in which recognition of the core and C terminus-specific mAbs was lost. Preincubation with Mn2+ increased the resistance of HIV-1 IN to proteolytic digestion and produced a digestion pattern that was significantly different from that observed with the apoprotein. A derivative that lacked the N-terminal domain, IN(50-288), exhibited the same metal-dependent changes observed with the full-length protein, whereas the isolated catalytic core domain IN(50-212) did not. From this we conclude that the metal-induced conformational change comprises a reorganization of the core and C-terminal domains. Preincubation with Mn2+ increased the specific activity of HIV-1 IN 5-fold. Enzymatic activity was inhibited by the conformation-sensitive C terminus-specific mAb, but this inhibition was reduced greatly if the enzyme was first preincubated with metal ions. Thus, it appears that apo-HIV-1 IN exists predominantly in an inactive conformation that is converted into a catalytically competent form upon the addition of metal ions.

Equivalent inhibition of half-site and full-site retroviral strand transfer reactions by structurally diverse compounds

In vitro assay systems which use recombinant retroviral integrase (IN) and short DNA oligonucleotides fail to recapitulate the full-site integration reaction as it is known to occur in vivo. The relevance of using such circumscribed in vitro assays to define inhibitors of retroviral integration has not been formerly demonstrated. Therefore, we analyzed a series of structurally diverse inhibitors with respect to inhibition of both half-site and full-site strand transfer reactions with either recombinant or virion-produced IN. Half-site and full-site reactions catalyzed by avian myeloblastosis virus and human immunodeficiency virus type 1 (HIV-1) IN from virions are shown to be equivalently sensitive to inhibition by compounds which inhibit half-site reactions catalyzed by the recombinant HIV-1 IN. These studies therefore support the utility of using in vitro assays employing either recombinant or virion-derived IN to identify inhibitors of integration.

Functional domains of Moloney murine leukemia virus integrase defined by mutation and complementation analysis

Retroviral integrases perform two catalytic steps, 3' processing and strand transfer, that result in the stable insertion of the retroviral DNA into the host genome. Mutant M-MuLV integrases were constructed to define the functional domains important for 3' processing, strand transfer, and disintegration by in vitro assays. N-terminal mutants had no detectable 3' processing activity, and only one mutant which lacks the HHCC domain, Ndelta105, had strand transfer activity. Strand transfer mediated by Ndelta105 showed preference for one site in the target DNA. Disintegration activity of N-terminal mutants decreased only minimally. In contrast, all C-terminal mutants truncated by more than 28 amino acids had no integration or disintegration activity. Activity on a single-strand disintegration substrate did not require a functional HHCC domain but did require most of the C-terminal region. Complementation analysis found that the HHCC region alone was able to function in trans to a promoter containing only the DD(35)E and C-terminal regions and to enhance integration site selection. Increasing the reducing conditions or adding the HHCC domain to Ndelta105 reaction mixtures restored the wild-type strand transfer activity and range of target sites. The reducing agent affected Cys-209 in the DD(35)E region. The presence of C-209 was required for complementation of Ndelta105 by the HHCC region.

Ty3 integrase mutants defective in reverse transcription or 3'-end processing of extrachromosomal Ty3 DNA

Ty3, a retroviruslike element in Saccharomyces cerevisiae, encodes an integrase (IN) which is essential for position-specific transposition. The Ty3 integrase contains the highly conserved His-Xaa(3-7)-His-Xaa(23-32)-Cys-Xaa(2)-Cys and Asp, Asp-Xaa(35)-Glu [D,D(35)E] motifs found in retroviral integrases. Mutations were introduced into the coding region for the Ty3 integrase to determine the effects in vivo of changes in conserved residues of the putative catalytic triad D,D(35)E and the nonconserved carboxyl-terminal region. Ty3 viruslike particles were found to be associated with significant amounts of linear DNA of the approximate size expected for a full-length reverse transcription product and with plus-strand strong-stop DNA. The full-length, preintegrative DNA has at each 3' end 2 bp that are removed prior to or during integration. Such 3'-end processing has not been observed for other retroviruslike elements. A mutation at either D-225 or E-261 of the Ty3 integrase blocked transposition and prevented processing of the 3' ends of Ty3 DNA in vivo, suggesting that the D,D(35)E region is part of the catalytic domain of Ty3 IN. Carboxyl-terminal deletions of integrase caused a dramatic reduction in the amount of Ty3 DNA in vivo and a decrease in reverse transcriptase activity in vitro but did not affect the apparent size or amount of the 55-kDa reverse transcriptase in viruslike particles. The 115-kDa viruslike particle protein, previously shown to react with antibodies to Ty3 integrase, was shown to be a reverse transcriptase-IN fusion protein. These results are consistent with a role for the integrase domain either in proper folding of reverse transcriptase or as part of a heterodimeric reverse transcriptase molecule.

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.

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.

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.

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.

Solution structure of the DNA binding domain of HIV-1 integrase

The solution structure of the DNA binding domain of HIV-1 integrase (residues 220-270) has been determined by multidimensional NMR spectroscopy. The protein is a dimer in solution, and each subunit is composed of a five-stranded beta-barrel with a topology very similar to that of the SH3 domain. The dimer is formed by a stacked beta-interface comprising strands 2, 3, and 4, with the two triple-stranded antiparallel beta-sheets, one from each subunit, oriented antiparallel to each other. One surface of the dimer, bounded by the loop between strands beta 1 and beta 2, forms a saddle-shaped groove with dimensions of approximately 24 x 23 x 12 A in cross section. Lys264, which has been shown from mutational data to be involved in DNA binding, protrudes from this surface, implicating the saddle-shaped groove as the potential DNA binding site.

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.

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.

Detection and characterization of a functional complex of human immunodeficiency virus type 1 integrase and its DNA substrate by UV cross-linking

To analyze the association of the human immunodeficiency virus type 1 integrase (IN) protein with DNA substrates, we applied a shortwave UV cross-linking method to the in vitro integration system. Three photoadduct bands were detected on sodium dodecyl sulfate-polyacrylamide gels. The appearances of these photoadducts were examined with various substrates and under several incubation conditions. Our data suggest that one of these photoadducts is derived from the sequence- and strand-specific bound state of the early phase of the integration reaction before the 3' processing reaction. We also show that most of the photoadduct complexes are competent for integration even after UV irradiation.