A mutation at one end of Moloney murine leukemia virus DNA blocks cleavage of both ends by the viral integrase in vivo

Multifaceted HIV integrase functionalities and therapeutic strategies for their inhibition

Antiretroviral inhibitors that are used to manage HIV infection/AIDS predominantly target three enzymes required for virus replication: reverse transcriptase, protease, and integrase. Although integrase inhibitors were the last among this group to be approved for treating people living with HIV, they have since risen to the forefront of treatment options. Integrase strand transfer inhibitors (INSTIs) are now recommended components of frontline and drug-switch antiretroviral therapy formulations. Integrase catalyzes two successive magnesium-dependent polynucleotidyl transferase reactions, 3' processing and strand transfer, and INSTIs tightly bind the divalent metal ions and viral DNA end after 3' processing, displacing from the integrase active site the DNA 3'-hydroxyl group that is required for strand transfer activity. Although second-generation INSTIs present higher barriers to the development of viral drug resistance than first-generation compounds, the mechanisms underlying these superior barrier profiles are incompletely understood. A separate class of HIV-1 integrase inhibitors, the allosteric integrase inhibitors (ALLINIs), engage integrase distal from the enzyme active site, namely at the binding site for the cellular cofactor lens epithelium-derived growth factor (LEDGF)/p75 that helps to guide integration into host genes. ALLINIs inhibit HIV-1 replication by inducing integrase hypermultimerization, which precludes integrase binding to genomic RNA and perturbs the morphogenesis of new viral particles. Although not yet approved for human use, ALLINIs provide important probes that can be used to investigate the link between HIV-1 integrase and viral particle morphogenesis. Herein, I review the mechanisms of retroviral integration as well as the promises and challenges of using integrase inhibitors for HIV/AIDS management.

Integration of the hybrid adenoretroviral vector AdLTR-luc involves both MoMLV elements flanking the transgene

Vector delivery is still a bottleneck for gene therapy. To overcome some disadvantages of adenoviral and retroviral vectors, we developed a hybrid vector. This hybrid vector, AdLTR-luc, was created by adding two elements from Moloney murine leukemia virus (MoMLV) flanking the luciferase cDNA into an E1/E3-deleted, replication deficient serotype 5 adenovirus vector (Zheng et al., Nature Biotechnol, 2000), and demonstrated that the MoMLV element upstream of the luciferase cDNA was broken during the integration event. The purpose of the current study was to determine if the MoMLV element downstream of the luciferase cDNA was also broken when integration occurred. We used the same A5 cell clones (#10 and 11) from the earlier the paper along with restriction endonuclease digestions, plus Southern hybridization, and PCR. Southern hybridization indicated that the luciferase cDNA was intact in the cloned cells. Results from Xho I and Sal I digestions showed that integration occurred in cloned cells. Southern hybridizations after Nco I digestion suggested that there was a break in both MoMLV elements, upstream and downstream of the luciferase cDNA. After DNA digestion with Not I, hybridization analyses indicated that the MoMLV upstream element was broken during integration. Digestion of genomic DNA with either Xba I/Kpn I, Bam HI/Sac I, or Bam HI/Nco I demonstrated that the MoMLV downstream element was also broken during integration. A PCR assay was unable to amplify the junctional region between the downstream MoMLV element and the adenoviral E2B gene, consistent with a break in that element. Although AdLTR-luc integration is atypical (Zheng et al., Nature Biotechnol, 2000), the present results suggest that both MoMLV elements have important roles in this event.

HIV DNA integration

Retroviruses are distinguished from other viruses by two characteristic steps in the viral replication cycle. The first is reverse transcription, which results in the production of a double-stranded DNA copy of the viral RNA genome, and the second is integration, which results in covalent attachment of the DNA copy to host cell DNA. The initial catalytic steps of the integration reaction are performed by the virus-encoded integrase (IN) protein. The chemistry of the IN-mediated DNA breaking and joining steps is well worked out, and structures of IN-DNA complexes have now clarified how the overall complex assembles. Methods developed during these studies were adapted for identification of IN inhibitors, which received FDA approval for use in patients in 2007. At the chromosomal level, HIV integration is strongly favored in active transcription units, which may promote efficient viral gene expression after integration. HIV IN binds to the cellular factor LEDGF/p75, which promotes efficient infection and tethers IN to favored target sites. The HIV integration machinery must also interact with many additional host factors during infection, including nuclear trafficking and pore proteins during nuclear entry, histones during initial target capture, and DNA repair proteins during completion of the DNA joining steps. Models for some of the molecular mechanisms involved have been proposed, but important details remain to be clarified.

Fidelity of target site duplication and sequence preference during integration of xenotropic murine leukemia virus-related virus

Xenotropic murine leukemia virus (MLV)-related virus (XMRV) is a new human retrovirus associated with prostate cancer and chronic fatigue syndrome. The causal relationship of XMRV infection to human disease and the mechanism of pathogenicity have not been established. During retrovirus replication, integration of the cDNA copy of the viral RNA genome into the host cell chromosome is an essential step and involves coordinated joining of the two ends of the linear viral DNA into staggered sites on target DNA. Correct integration produces proviruses that are flanked by a short direct repeat, which varies from 4 to 6 bp among the retroviruses but is invariant for each particular retrovirus. Uncoordinated joining of the two viral DNA ends into target DNA can cause insertions, deletions, or other genomic alterations at the integration site. To determine the fidelity of XMRV integration, cells infected with XMRV were clonally expanded and DNA sequences at the viral-host DNA junctions were determined and analyzed. We found that a majority of the provirus ends were correctly processed and flanked by a 4-bp direct repeat of host DNA. A weak consensus sequence was also detected at the XMRV integration sites. We conclude that integration of XMRV DNA involves a coordinated joining of two viral DNA ends that are spaced 4 bp apart on the target DNA and proceeds with high fidelity.

Avian sarcoma and leukemia virus (ASLV) integration in vitro: mutation or deletion of integrase (IN) recognition sequences does not prevent but only reduces the efficiency and accuracy of DNA integration

Integrase (IN) is the enzyme responsible for provirus integration of retroviruses into the host cell genome. We used an Avian Sarcoma and Leukemia Viruses (ASLV) integration assay to investigate the way in which IN integrates substrates mutated or devoid of one or both IN recognition sequences. We found that replacing U5 by non-viral sequences (U5del) or U3 by a mutated sequence (pseudoU3) resulted in two and three fold reduction of two-ended integration (integration of the two ends from a donor DNA) respectively, but had a slight effect on concerted integration (integration of both ends at the same site of target DNA). Further, IN was still able to integrate the viral ends of the double mutant (pseudoU3/U5del) in a two-ended and concerted integration reaction. However, efficiency and accuracy (i.e. fidelity of size duplication and of end cleavage) of integration were reduced.

Mechanisms of human immunodeficiency virus type 1 concerted integration related to strand transfer inhibition and drug resistance

The "strand transfer inhibitors" of human immunodeficiency virus type-1 (HIV-1) integrase (IN), so named because of their pronounced selectivity for inhibiting strand transfer over 3' OH processing, block virus replication in vivo and ex vivo and prevent concerted integration in vitro. We explored the kinetics of product formation and strand transfer inhibition within reconstituted synaptic complexes capable of concerted integration. Synaptic complexes were formed with viral DNA donors containing either two blunt ends, two 3'-OH-processed ends, or one of each. We determined that one blunt end within a synaptic complex is a sufficient condition for low-nanomolar-range strand transfer inhibition with naphthyridine carboxamide inhibitors L-870,810 and L-870,812. We further explored the catalytic properties and drug resistance profiles of a set of clinically relevant strand transfer inhibitor-resistant HIV-1 IN mutants. The diketo acids and naphthyridine carboxamides, mechanistically similar but structurally distinct strand transfer inhibitors, each select for a distinct set of drug resistance mutations ex vivo. The S153Y and N155S IN resistance mutants were selected with the diketo acid L-841,411, and the N155H mutant was selected with L-810,812. Each mutant exhibited some degree of catalytic impairment relative to the activity of wild type IN, although the N155H mutant displayed near-wild-type IN activities. The resistance profiles indicated that the S153Y mutation potentiates susceptibility to L-870,810 and L-870,812, while the N155S mutation confers resistance to L-870,810 and L-870,812. The N155H mutation confers resistance to L-870,810 and potentiates susceptibility to L-841,411. This study illuminates the interrelated mechanisms of concerted integration, strand transfer inhibition, and resistance to strand transfer inhibitors.

Mutations in the U5 sequences adjacent to the primer binding site do not affect tRNA cleavage by rous sarcoma virus RNase H but do cause aberrant integrations in vivo

In most retroviruses, the first nucleotide added to the tRNA primer becomes the right end of the U5 region in the right long terminal repeat (LTR); the removal of this tRNA primer by RNase H defines the right end of the linear double-stranded DNA. Most retroviruses have two nucleotides between the 5' end of the primer binding site (PBS) and the CA dinucleotide that will become the end of the integrated provirus. However, human immunodeficiency virus type 1 (HIV-1) has only one nucleotide at this position, and HIV-2 has three nucleotides. We changed the two nucleotides (TT) between the PBS and the CA dinucleotide of the Rous sarcoma virus (RSV)-derived vector RSVP(A)Z to match the HIV-1 sequence (G) and the HIV-2 sequence (GGT), and we changed the CA dinucleotide to TC. In all three mutants, RNase H removes the entire tRNA primer. Sequence analysis of RSVP(HIV2) proviruses suggests that RSV integrase can remove three nucleotides from the U5 LTR terminus of the linear viral DNA during integration, although this mutation significantly reduced virus titer, suggesting that removing three nucleotides is inefficient. However, the results obtained with RSVP(HIV1) and RSVP(CATC) show that RSV integrase can process and integrate the normal U3 LTR terminus of a linear DNA independently of an aberrant U5 LTR terminus. The aberrant end can then be joined to the host DNA by unusual processes that do not involve the conserved CA dinucleotide. These unusual events generate either large duplications or, less frequently, deletions in the host genomic DNA instead of the normal 5- to 6-base duplications.

Identification of amino acids in HIV-1 and avian sarcoma virus integrase subsites required for specific recognition of the long terminal repeat Ends

A tetramer model for HIV-1 integrase (IN) with DNA representing 20 bp of the U3 and U5 long terminal repeats (LTR) termini was assembled using structural and biochemical data and molecular dynamics simulations. It predicted amino acid residues on the enzyme surface that can interact with the LTR termini. A separate structural alignment of HIV-1, simian sarcoma virus (SIV), and avian sarcoma virus (ASV) INs predicted which of these residues were unique. To determine whether these residues were responsible for specific recognition of the LTR termini, the amino acids from ASV IN were substituted into the structurally equivalent positions of HIV-1 IN, and the ability of the chimeras to 3 ' process U5 HIV-1 or ASV duplex oligos was determined. This analysis demonstrated that there are multiple amino acid contacts with the LTRs and that substitution of ASV IN amino acids at many of the analogous positions in HIV-1 IN conferred partial ability to cleave ASV substrates with a concomitant loss in the ability to cleave the homologous HIV-1 substrate. HIV-1 IN residues that changed specificity include Val(72), Ser(153), Lys(160)-Ile(161), Gly(163)-Val(165), and His(171)-Leu(172). Because a chimera that combines several of these substitutions showed a specificity of cleavage of the U5 ASV substrate closer to wild type ASV IN compared with chimeras with individual amino acid substitutions, it appears that the sum of the IN interactions with the LTRs determines the specificity. Finally, residues Ser(153) and Val(72) in HIV-1 IN are among those that change in enzymes that develop resistance to naphthyridine carboxamide- and diketo acid-related inhibitors in cells. Thus, amino acid residues involved in recognition of the LTRs are among these positions that change in development of drug resistance.

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.

A novel function for spumaretrovirus integrase: an early requirement for integrase-mediated cleavage of 2 LTR circles

Retroviral integration is central to viral persistence and pathogenesis, cancer as well as host genome evolution. However, it is unclear why integration appears essential for retrovirus production, especially given the abundance and transcriptional potential of non-integrated viral genomes. The involvement of retroviral endonuclease, also called integrase (IN), in replication steps apart from integration has been proposed, but is usually considered to be accessory. We observe here that integration of a retrovirus from the spumavirus family depends mainly on the quantity of viral DNA produced. Moreover, we found that IN directly participates to linear DNA production from 2-LTR circles by specifically cleaving the conserved palindromic sequence found at LTR-LTR junctions. These results challenge the prevailing view that integrase essential function is to catalyze retroviral DNA integration. Integrase activity upstream of this step, by controlling linear DNA production, is sufficient to explain the absolute requirement for this enzyme. The novel role of IN over 2-LTR circle junctions accounts for the pleiotropic effects observed in cells infected with IN mutants. It may explain why 1) 2-LTR circles accumulate in vivo in mutants carrying a defective IN while their linear and integrated DNA pools decrease; 2) why both LTRs are processed in a concerted manner. It also resolves the original puzzle concerning the integration of spumaretroviruses. More generally, it suggests to reassess 2-LTR circles as functional intermediates in the retrovirus cycle and to reconsider the idea that formation of the integrated provirus is an essential step of retrovirus production.

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.

Foamy virus integration

It had been suggested that during integration of spumaretroviruses (foamy viruses) the right (U5) end of the cDNA is processed, while the left (U3) remains uncleaved. We confirmed this hypothesis by sequencing two-long terminal repeat (LTR) circle junctions of unintegrated DNA. Based on an infectious foamy virus molecular clone, a set of constructs harboring mutations at the 5' end of the U3 region in the 3' LTR was analyzed for particle export, reverse transcription, and replication. Following transient transfection some mutants were severely impaired in generating infectious virus, while others replicated almost like the wild type. The replication competence of the mutants was unrelated to the cleavability of the newly created U3 end. This became obvious with two mutants both belonging to the high-titer type. One mutant containing a dinucleotide artificially transferred from the right to the left end was trimmed upon integration, while another one with an unrelated dinucleotide in that place was not. The latter construct in particular showed that the canonical TG motif at the beginning of the provirus is not essential for foamy virus integration.

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.

The terminal nucleotide of the Mu genome controls catalysis of DNA strand transfer

Members of the transposase/retroviral-integrase superfamily use a single active site to perform at least two reactions during transposition of a DNA transposon or a retroviral cDNA. They hydrolyze a DNA sequence at the end of the mobile DNA and then join this DNA end to a target DNA (a reaction called DNA strand transfer). Critical to understanding the mechanism of recombination is elucidating how these distinct reactions are orchestrated by the same active site. Here we find that DNA substrates terminating in a dideoxynucleotide allow Mu transposase to hydrolyze a target DNA, combining aspects of both natural reactions. Analyses of the sequence preferences for target hydrolysis and of the structure of the cleaved product indicate that this reaction is promoted by the active site in the conformation that normally promotes DNA strand transfer. Dissecting the DNA requirements for target hydrolysis reveals that the ribose of the last nucleotide of the Mu DNA activates transposase's catalytic potential, even when this residue is not a direct chemical participant. These findings provide insight into the molecular mechanism insuring that DNA strand transfer ordinarily occurs rather than inappropriate DNA cleavage. The required presence of the terminal nucleotide in the transposase active site creates a great advantage for the attached 3'OH to serve as nucleophile.

Naturally occurring substitutions of the human T-cell leukemia virus type 1 3' LTR influence strand-transfer reaction

Having isolated somatically mutated HTLV-1 3' LTR sequences from six infected individuals, the effect of these mutations on the integration process in vitro was investigated. Double-strand pre-processed HTLV-1 3' LTR ends (53-54 bp) were used in an in vitro strand-transfer reaction, together with HTLV-1 purified integrase and using a synthetic double-strand naked DNA oligonucleotide as target. Integration efficiency was measured by a fluorescent PCR assay. No significant difference in the pattern of strand transfer was observed between the distinct patients consensus sequences. For each patient, the effect of acquired somatic mutations was then assessed by comparing the strand-transfer efficiency of the mutated sequences (n=8, each harboring one to two substitutions) with that of the corresponding patient consensus sequence. Five somatic mutations or deletions at positions 7, 10, 21, 30, and 53 from the proviral 3' end did not alter the reaction efficiency. By contrast, a single G-->A transition at position 52 was found to result in 33% gain of function. Furthermore, a C-->T transition at 41 bp from the provirus 3' end decreased the reaction efficiency by 80%. This is the first study investigating the effect of naturally acquired substitutions on the strand-transfer capacity of long LTR sequences in vitro. Disproving the hitherto assumed opinion that integration specificity is restricted to the extreme boundary of the LTR end, i.e. the last 12-20 bp of the unintegrated provirus, the present results demonstrate that naturally occurred substitutions of the HTLV-1 LTR can alter significantly its strand-transfer capacity.

HIV-1 integrase interaction with U3 and U5 terminal sequences in vitro defined using substrates with random sequences

Successful integration of viral genome into a host chromosome depends on interaction between viral integrase and its recognition sequences. We have used a reconstituted concerted human immunodeficiency virus, type 1 (HIV-1), integration system to analyze the role of integrase (IN) recognition sequences in formation of the IN-viral DNA complex capable of concerted integration. HIV-1 integrase was presented with substrates that contained all 4 bases at 8 mismatched positions that define the inverted repeat relationship between U3 and U5 long terminal repeats (LTR) termini and at positions 17-19, which are conserved in the termini. Evidence presented indicates that positions 17-20 of the IN recognition sequences are needed for a concerted DNA integration mechanism. All 4 bases were found at each randomized position in sequenced concerted DNA integrants, although in some instances there were preferences for specific bases. These results indicate that integrase tolerates a significant amount of plasticity as to what constitutes an IN recognition sequence. By having several positions randomized, the concerted integrants were examined for statistically significant relationships between selections of bases at different positions. The results of this analysis show not only relationships between different positions within the same LTR end but also between different positions belonging to opposite DNA termini.

Presteady-state analysis of avian sarcoma virus integrase. II. Reverse-polarity substrates identify preferential processing of the U3-U5 pair

The integrase-catalyzed insertion of the retroviral genome into the host chromosome involves two reactions in vivo: 1) the binding and endonucleolytic removal of the terminal dinucleotides of the viral DNA termini and 2) the recombination of the ends with the host DNA. Kukolj and Skalka (Kukolj, G., and Skalka, A. M. (1995) Genes Dev. 9, 2556-2567) have previously shown that tethering of the termini enhances the endonucleolytic activities of integrase. We have used 5'-5' phosphoramidites to design reverse-polarity tethers that allowed us to examine the reactivity of two viral long terminal repeat-derived sequences when concurrently bound to integrase and, additionally, developed presteady-state assays to analyze the initial exponential phase of the reaction, which is a measure of the amount of productive nucleoprotein complexes formed during preincubation of integrase and DNA. Furthermore, the reverse-polarity tether circumvents the integrase-catalyzed splicing reaction (Bao, K., Skalka, A. M., and Wong, I. (2002) J. Biol. Chem. 277, 12089-12098) that obscures accurate analysis of the reactivities of synapsed DNA substrates. Consequently, we were able to establish a lower limit of 0.2 s(-1) for the rate constant of the processing reaction. The analysis showed the physiologically relevant U3/U5 pair of viral ends to be the preferred substrate for integrase with the U3/U3 combination favored over the U5/U5 pair.

Changes in the mechanism of DNA integration in vitro induced by base substitutions in the HIV-1 U5 and U3 terminal sequences

We have reconstituted concerted human immunodeficiency virus type 1 (HIV-1) integration with specially designed mini-donor DNA, a supercoiled plasmid acceptor, purified bacterial-derived HIV-1 integrase (IN), and host HMG-I(Y) protein (Hindmarsh, P., Ridky, T., Reeves, R., Andrake, M., Skalka, A. M., and Leis, J. (1999) J. Virol. 73, 2994-3003). Integration in this system is dependent upon the mini donor DNA having IN recognition sequences at both ends and the reaction products have all of the features associated with integration of viral DNA in vivo. Using this system, we explored the relationship between the HIV-1 U3 and U5 IN recognition sequences by analyzing substrates that contain either two U3 or two U5 terminal sequences. Both substrates caused severe defects to integration but with different effects on the mechanism indicating that the U3 and the U5 sequences are both required for concerted DNA integration. We have also used the reconstituted system to compare the mechanism of integration catalyzed by HIV-1 to that of avian sarcoma virus by analyzing the effect of defined mutations introduced into U3 or U5 ends of the respective wild type DNA substrates. Despite sequence differences between avian sarcoma virus and HIV-1 IN and their recognition sequences, the consequences of analogous base pair substitutions at the same relative positions of the respective IN recognition sequences were very similar. This highlights the common mechanism of integration shared by these two different viruses.

Asymmetric processing of human immunodeficiency virus type 1 cDNA in vivo: implications for functional end coupling during the chemical steps of DNA transposition

Retroviral integration, like all forms of DNA transposition, proceeds through a series of DNA cutting and joining reactions. During transposition, the 3' ends of linear transposon or donor DNA are joined to the 5' phosphates of a double-stranded cut in target DNA. Single-end transposition must be avoided in vivo because such aberrant DNA products would be unstable and the transposon would therefore risk being lost from the cell. To avoid suicidal single-end integration, transposons link the activity of their transposase protein to the combined functionalities of both donor DNA ends. Although previous work suggested that this critical coupling between transposase activity and DNA ends occurred before the initial hydrolysis step of retroviral integration, work in the related Tn10 and V(D)J recombination systems had shown that end coupling regulated transposase activity after the initial hydrolysis step of DNA transposition. Here, we show that integrase efficiently hydrolyzed just the wild-type end of two different single-end mutants of human immunodeficiency virus type 1 in vivo, which, in contrast to previous results, proves that two functional DNA ends are not required to activate integrase's initial hydrolysis activity. Furthermore, despite containing bound protein at their processed DNA ends, these mutant viruses did not efficiently integrate their singly cleaved wild-type end into target DNA in vitro. By comparing our results to those of related DNA recombination systems, we propose the universal model that end coupling regulates transposase activity after the first chemical step of DNA transposition.

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.

DNase protection analysis of retrovirus integrase at the viral DNA ends for full-site integration in vitro

Retrovirus intasomes purified from virus-infected cells contain the linear viral DNA genome and integrase (IN). Intasomes are capable of integrating the DNA termini in a concerted fashion into exogenous target DNA (full site), mimicking integration in vivo. Molecular insights into the organization of avian myeloblastosis virus IN at the viral DNA ends were gained by reconstituting nucleoprotein complexes possessing intasome characteristics. Assembly of IN-4.5-kbp donor complexes capable of efficient full-site integration appears cooperative and is dependent on time, temperature, and protein concentration. DNase I footprint analysis of assembled IN-donor complexes capable of full-site integration shows that wild-type U3 and other donors containing gain-of-function attachment site sequences are specifically protected by IN at low concentrations (<20 nM) with a defined outer boundary mapping ~20 nucleotides from the ends. A donor containing mutations in the attachment site simultaneously eliminated full-site integration and DNase I protection by IN. Coupling of wild-type U5 ends with wild-type U3 ends for full-site integration shows binding by IN at low concentrations probably occurs only at the very terminal nucleotides (<10 bp) on U5. The results suggest that assembly requires a defined number of avian IN subunits at each viral DNA end. Among several possibilities, IN may bind asymmetrically to the U3 and U5 ends for full-site integration in vitro.

The nicking step in V(D)J recombination is independent of synapsis: implications for the immune repertoire

In all of the transposition reactions that have been characterized thus far, synapsis of two transposon ends is required before any catalytic steps (strand nicking or strand transfer) occur. In V(D)J recombination, there have been inconclusive data concerning the role of synapsis in nicking. Synapsis between two 12-substrates or between two 23-substrates has not been ruled out in any studies thus far. Here we provide the first direct tests of this issue. We find that immobilization of signals does not affect their nicking, even though hairpinning is affected in a manner reflecting its known synaptic requirement. We also find that nicking is kinetically a unireactant enzyme-catalyzed reaction. Time courses are no different between nicking seen for a 12-substrate alone and a reaction involving both a 12- and a 23-substrate. Hence, synapsis is neither a requirement nor an effector of the rate of nicking. These results establish V(D)J recombination as the first example of a DNA transposition-type reaction in which catalytic steps begin prior to synapsis, and the results have direct implications for the order of the steps in V(D)J recombination, for the contribution of V(D)J recombination nicks to genomic instability, and for the diversification of the immune repertoire.

Characterization of a replication-defective human immunodeficiency virus type 1 att site mutant that is blocked after the 3' processing step of retroviral integration

Two activities of retroviral integrase, 3' processing and DNA strand transfer, are required to integrate viral cDNA into a host cell chromosome. Integrase activity has been analyzed in vitro using purified protein and recombinant DNA substrates that model the U3 and U5 ends of viral cDNA or by using viral preintegration complexes (PICs) that form during virus infection. Numerous studies have investigated changes in integrase or viral DNA for effects on both 3' processing and DNA strand transfer activities using purified protein, but similar analyses have not been carried out using PICs. Here, we analyzed PICs from human immunodeficiency virus type 1 (HIV-1) strain 604del, an integration-defective mutant lacking 26 bp of U5, and revE1, a revertant of 604del containing an additional 19-bp deletion, for levels of 3' processing activity that occurred in infected cells and for levels of in vitro DNA strand transfer activity. Whereas revE1 supported one-third to one-half of the level of wild-type DNA strand transfer activity, the level of 604del DNA strand transfer activity was undetectable. Surprisingly, integrase similarly processed the 3' ends of 604del and revE1 in vivo. We therefore conclude that 604del is blocked in its ability to replicate in cells after the 3' processing step of retroviral integration. Whereas Western blotting showed that wild-type, revE1, and 604del PICs contained similar levels of integrase protein, Mu-mediated PCR footprinting revealed only minimal protein-DNA complex formation at the ends of 604del cDNA. We propose that 604del is replication defective because proteins important for DNA strand transfer activity do not stably associate with this cDNA after in vivo 3' processing by integrase.

Avian retrovirus DNA internal attachment site requirements for full-site integration in vitro

Concerted integration of retrovirus DNA termini into the host chromosome in vivo requires specific interactions between the cis-acting attachment (att) sites at the viral termini and the viral integrase (IN) in trans. In this study, reconstruction experiments with purified avian myeloblastosis virus (AMV) IN and retrovirus-like donor substrates containing wild-type and mutant termini were performed to map the internal att DNA sequence requirements for concerted integration, here termed full-site integration. The avian retrovirus mutations were modeled after internal att site mutations studied at the in vivo level with human immunodeficiency virus type 1 (HIV-1) and murine leukemia virus (MLV). Systematic overlapping 4-bp deletions starting at nucleotide positions 7, 8, and 9 in the U3 terminus had a decreasing detrimental gradient effect on full-site integration, while more internal 4-bp deletions had little or no effect. This decreasing detrimental gradient effect was measured by the ability of mutant U3 ends to interact with wild-type U3 ends for full-site integration in trans. Modification of the highly conserved C at position 7 on the catalytic strand to either A or T resulted in the same severe decrease in full-site integration as the 4-bp deletion starting at this position. These studies suggest that nucleotide position 7 is crucial for interactions near the active site of IN for integration activity and for communication in trans between ends bound by IN for full-site integration. The ability of AMV IN to interact with internal att sequences to mediate full-site integration in vitro is similar to the internal att site requirements observed with MLV and HIV-1 in vivo and with their preintegration complexes in vitro.

Identification of critical amino acid residues in human immunodeficiency virus type 1 IN required for efficient proviral DNA formation at steps prior to integration in dividing and nondividing cells

Human immunodeficiency virus type 1 integrase (HIV-1 IN) is thought to have several putative roles at steps prior to integration, such as reverse transcription and nuclear transport of the preintegration complex (PIC). Here, we investigated new functional aspects of HIV-1 IN in the context of the viral replication cycle through point mutagenesis of Ser, Thr, Tyr, Lys, and Arg residues conserved in IN, some of which are located at possible phosphorylation sites. Our results showed that mutations of these Ser or Thr residues had no effect on reverse transcription and nuclear transport of PIC but had a slight effect on integration. Of note, mutations in the conserved KRK motif (amino acids 186 to 189), proposed previously as a putative nuclear localization signal (NLS) of HIV-1 IN, did not affect the karyophilic property of HIV-1 IN as shown by using a green fluorescent protein fusion protein expression system. Instead, these KRK mutations resulted in an almost complete lack of viral gene expression due to the failure to complete reverse transcription. This defect was complemented by supplying wild-type IN in trans, suggesting a trans-acting function of the KRK motif of IN in reverse transcription. Mutation at the conserved Tyr 143 (Y143G) resulted in partial impairment of completion of reverse transcription in monocyte-derived macrophages (MDM) but not in rhabdomyosarcoma cells. Similar effects were obtained by introducing a stop codon in the vpr gene (DeltaVpr), and additive effects of both mutations (Y143G plus DeltaVpr) were observed. In addition, these mutants did not produce two-long terminal repeat DNA, a surrogate marker for nuclear entry, in MDM. Thus, the possible impairment of Y143G might occur during the nuclear transport of the PIC. Taken together, our results identified new functional aspects of the conserved residues in HIV-1 IN: i) the KRK motif might have a role in efficient reverse transcription in both dividing and nondividing cells but not in the NLS function; ii) Y143 might be an important residue for maintaining efficient proviral DNA formation in nondividing cells.

Replication of lengthened Moloney murine leukemia virus genomes is impaired at multiple stages

It has been assumed that RNA packaging constraints limit the size of retroviral genomes. This notion of a retroviral "headful" was tested by examining the ability of Moloney murine leukemia virus genomes lengthened by 4, 8, or 11 kb to participate in a single replication cycle. Overall, replication of these lengthened genomes was 5- to 10-fold less efficient than that of native-length genomes. When RNA expression and virion formation, RNA packaging, and early stages of replication were compared, long genomes were found to complete each step less efficiently than did normal-length genomes. To test whether short RNAs might facilitate the packaging of lengthy RNAs by heterodimerization, some experiments involved coexpression of a short packageable RNA. However, enhancement of neither long vector RNA packaging nor long vector DNA synthesis was observed in the presence of the short RNA. Most of the proviruses templated by 12 and 16 kb vectors appeared to be full length. Most products of a 19. 2-kb vector contained deletions, but some integrated proviruses were around twice the native genome length. These results demonstrate that lengthy retroviral genomes can be packaged and that genome length is not strictly limited at any individual replication step. These observations also suggest that the lengthy read-through RNAs postulated to be intermediates in retroviral transduction can be packaged directly without further processing.

Genomic integration and gene expression by a modified adenoviral vector

A replication-deficient recombinant adenovirus encoding luciferase was constructed using 5' and 3' long terminal repeat (LTR) sequences of the Moloney murine leukemia virus. Gene expression was observed in cultured cells in vitro and in submandibular gland, cortex, and caudate nucleus for as long as three months in vivo. The vector integrated randomly into the genome of both dividing and nondividing cells as determined by fluorescence in situ hybridization (FISH) (10-15% of cells in vitro and 5% in rat spleen in vivo), gene walking, Southern hybridization, and polymerase chain reaction (PCR), in the absence of transcomplementing reverse transcriptase or integrase activity. The new vector combines the high titer and versatility of adenoviral vectors with the long-term gene expression and integration of retroviral vectors.

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.

Integrating DNA: transposases and retroviral integrases

Transposable elements appear quite disparate in their organization and in the types of genetic rearrangements they promote. In spite of this diversity, retroviruses and many transposons of both prokaryotes and eukaryotes show clear similarities in the chemical reactions involved in their transposition. This is reflected in the enzymes, integrases and transposases, that catalyze these reactions and that are essential for the mobility of the elements. In this chapter, we examine the structure-function relationships between these enzymes and the different ways in which the individual steps are assembled to produce a complete transposition cycle.

Organization and dynamics of the Mu transpososome: recombination by communication between two active sites

Movement of transposable genetic elements requires the cleavage of each end of the element genome and the subsequent joining of these cleaved ends to a new target DNA site. During Mu transposition, these reactions are catalyzed by a tetramer of four identical transposase subunits bound to the paired Mu DNA ends. To elucidate the organization of active sites within this tetramer, the subunit providing the essential active site DDE residues for each cleavage and joining reaction was determined. We demonstrate that recombination of the two Mu DNA ends is catalyzed by two active sites, where one active site promotes both cleavage and joining of one Mu DNA end. This active site uses all three DDE residues from the subunit bound to the transposase binding site proximal to the cleavage site on the other Mu DNA end (catalysis in trans). In addition, we uncover evidence that the catalytic activity of these two active sites is coupled such that the coordinated joining of both Mu DNA ends is favored during recombination. On the basis of these results, we propose that the DNA joining stage requires a cooperative transition within the transposase-DNA complex. The cooperative utilization of active sites supplied in trans by Mu transposase provides an example of how mobile elements can ensure concomitant recombination of distant DNA sites.

Coupled integration of human immunodeficiency virus type 1 cDNA ends by purified integrase in vitro: stimulation by the viral nucleocapsid protein

Integration of retroviral cDNA involves coupled joining of the two ends of the viral genome at precisely spaced positions in the host cell DNA. Correct coupled joining is essential for viral replication, as shown, for example, by the finding that viral mutants defective in coupled joining are defective in integration and replication. To date, reactions with purified human immunodeficiency virus type 1 (HIV-1) integrase protein in vitro have supported mainly uncoupled joining of single cDNA ends. We have analyzed an activity stimulating coupled joining present in HIV-1 virions, which led to the finding that the HIV-1 nucleocapsid (NC) protein can stimulate coupled joining more than 1,000-fold under some conditions. The requirements for stimulating coupled joining were investigated in assays with mutant NC proteins, revealing that mutations in the zinc finger domains can influence stimulation of integration. These findings (i) provide a means for assembling more authentic integrase complexes for mechanistic studies, (ii) reveal a new activity of NC protein in vitro, (iii) indicate a possible role for NC in vivo, and (iv) provide a possible method for identifying a new class of inhibitors that disrupt coupled joining.

Retrovirus DNA termini bound by integrase communicate in trans for full-site integration in vitro

Integration of linear retrovirus DNA involves the concerted insertion of the viral termini (full-site integration) into the host chromosome. We investigated the interactions that occur between long terminal repeat (LTR) termini bound by avian retrovirus integrase (IN) for full-site integration in vitro. Wild-type (wt) or mutant LTR donors that possess gain-of-function ("G") or loss-of-function ("L") for full-site integration activity were used. G LTR termini are characterized as having significantly higher strand transfer activity than the wt and the L LTR termini. L LTR mutations are classified as partially or extremely defective for strand transfer activity. The L mutations were further classified by their ability to either permit or block the assembly of G or wt LTR termini into nucleoprotein complexes capable of full-site strand transfer. We demonstrated that avian myeloblastosis virus IN bound to G LTR termini increased the incorporation of partially defective L LTR termini into nucleoprotein complexes that were capable of full-site integration. The observed full-site integration activity of these assembled nucleoprotein complexes appeared to be influenced by each individual IN-LTR complex in trans. In contrast, extremely defective L LTR termini exhibited the ability to effectively block the assembly of wt LTR termini into nucleoprotein complexes capable of full-site strand transfer. Data from nonspecific DNA competition experiments suggested that IN had an apparent higher affinity for G LTR donor termini than for partially defective L LTR donor termini as measured by full-site integration activity. However, assembled nucleoprotein complexes containing either two G or two L LTR donors were stable, having a similar half-life of approximately 2 h on ice. The results suggest that LTR termini bound by IN exhibit an allosteric effect to modulate full-site integration in vitro. Similar regulatory controls also appear to exist in vivo between the wt U3 and wt U5 LTR termini in retroviruses as well as purified retrovirus preintegration complexes that promoted full-site integration in vitro.

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.

In vivo analysis of retroviral integrase structure and function

There are two retroviral integration loci. One encodes the transacting IN protein, which is cleaved from the carboxyl terminus of the Gag-Pol polyprotein precursor during virus assembly. The second locus is the cis-acting attachment (att) site, comprising the terminal sequences at the U3 and U5 ends of linear viral cDNA. Integrase and att site mutant viruses can be blocked at different steps of the viral replication cycle. Class I IN mutants are blocked specifically at the integration step. Class II IN mutants, on the other hand, display pleiotropic defects, most notably in virion morphogenesis and/or reverse transcription. Mutations in the U5 end att site can also disrupt reverse transcription in addition to integration. It is prudent to use caution when interpreting results of in vivo mutagenesis experiments that target retroviral IN and the att site.

HMG protein family members stimulate human immunodeficiency virus type 1 and avian sarcoma virus concerted DNA integration in vitro

We have reconstituted concerted human immunodeficiency virus type 1 (HIV-1) integration in vitro with specially designed mini-donor HIV-1 DNA, a supercoiled plasmid acceptor, purified bacterium-derived HIV-1 integrase (IN), and host HMG protein family members. This system is comparable to one previously described for avian sarcoma virus (ASV) (A. Aiyar et al., J. Virol. 70:3571-3580, 1996) that was stimulated by the presence of HMG-1. Sequence analyses of individual HIV-1 integrants showed loss of 2 bp from the ends of the donor DNA and almost exclusive 5-bp duplications of the acceptor DNA at the site of integration. All of the integrants sequenced were inserted into different sites in the acceptor. These are the features associated with integration of viral DNA in vivo. We have used the ASV and HIV-1 reconstituted systems to compare the mechanism of concerted DNA integration and examine the role of different HMG proteins in the reaction. Of the three HMG proteins examined, HMG-1, HMG-2, and HMG-I(Y), the products formed in the presence of HMG-I(Y) for both systems most closely match those observed in vivo. Further analysis of HMG-I(Y) mutants demonstrates that the stimulation of integration requires an HMG-I(Y) domain involved in DNA binding. While complexes containing HMG-I(Y), ASV IN, and donor DNA can be detected in gel shift experiments, coprecipitation experiments failed to demonstrate stable interactions between HMG-I(Y) and ASV IN or between HMG-I(Y) and HIV-1 IN.

Effects of 3' untranslated region mutations on plus-strand priming during moloney murine leukemia virus replication

A conserved purine-rich motif located near the 3' end of retroviral genomes is involved in the initiation of plus-strand DNA synthesis. We mutated sequences both within and flanking the Moloney murine leukemia virus polypurine tract (PPT) and determined the effects of these alterations on viral DNA synthesis and replication. Our results demonstrated that both changes in highly conserved PPT positions and a mutation that left only the cleavage-proximal half of the PPT intact led to delayed replication and reduced the colony-forming titer of replication defective retroviral vectors. A mutation that altered the cleavage proximal half of the PPT and certain 3' untranslated region mutations upstream of the PPT were incompatible with or severely impaired viral replication. To distinguish defects in plus-strand priming from other replication defects and to assess the relative use of mutant and wild-type PPTs, we examined plus-strand priming from an ectopic, secondary PPT inserted in U3. The results demonstrated that the analyzed mutations within the PPT primarily affected plus-strand priming whereas mutations upstream of the PPT appeared to affect both plus-strand priming and other stages of viral replication.

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.

Footprints on the viral DNA ends in moloney murine leukemia virus preintegration complexes reflect a specific association with integrase

Retroviral DNA integration is mediated by the preintegration complex, a large nucleoprotein complex derived from the core of the infecting virion. We previously have used Mu-mediated PCR to probe the nucleoprotein organization of Moloney murine leukemia virus preintegration complexes. A region of protection spans several hundred base pairs at each end of the viral DNA, and strong enhancements are present near the termini. Here, we show that these footprints reflect a specific association between integrase and the viral DNA ends in functional preintegration complexes. Barrier-to-autointegration factor, a cellular protein that blocks autointegration of Moloney murine leukemia virus DNA, also plays an indirect role in generating the footprints at the ends of the viral DNA. We have exploited Mu-mediated PCR to examine the effect of mutations at the viral DNA termini on complex formation. We find that a replication competent mutant with a deletion at one end of the viral DNA still exhibits a strong enhancement about 20 bp from the terminus of the mutant DNA end. The site of the enhancement therefore appears to be at a fixed distance from the ends of the viral DNA. We also find that a mutation at one end of the viral DNA, which renders the virus incompetent for replication, abolishes the enhancements and protection at both the U3 and U5 ends. A pair of functional viral DNA ends therefore are required to interact before the chemical step of 3' end processing.

Mutations in the human immunodeficiency virus type 1 integrase D,D(35)E motif do not eliminate provirus formation

The core domain of human immunodeficiency virus type 1 (HIV-1) integrase (IN) contains a D,D(35)E motif, named for the phylogenetically conserved glutamic acid and aspartic acid residues and the invariant 35 amino acid spacing between the second and third acidic residues. Each acidic residue of the D,D(35)E motif is independently essential for the 3'-processing and strand transfer activities of purified HIV-1 IN protein. Using a replication-defective viral genome with a hygromycin selectable marker, we recently reported that a mutation at any of the three residues of the D,D(35)E motif produces a 10(3)- to 10(4)-fold reduction in infectious titer compared with virus encoding wild-type IN (A. D. Leavitt et al., J. Virol. 70:721-728. 1996). The infectious titer, as measured by the number of hygromycin-resistant colonies formed following infection of cells in culture, was less than a few hundred colonies per microg of p24. To understand the mechanism by which the mutant virions conferred hygromycin resistance, we characterized the integrated viral DNA in cells infected with virus encoding mutations at each of the three residues of the D,D(35)E motif. We found the integrated viral DNA to be colinear with the incoming viral genome. DNA sequencing of the junctions between integrated viral DNA and host DNA showed that (i) the characteristic 5-bp direct repeat of host DNA flanking the HIV-1 provirus was not maintained, (ii) integration often produced a deletion of host DNA, (iii) integration sometimes occurred without the viral DNA first undergoing 3'-processing, (iv) integration sites showed a strong bias for a G residue immediately adjacent to the conserved viral CA dinucleotide, and (v) mutations at each of the residues of the D,D(35)E motif produced essentially identical phenotypes. We conclude that mutations at any of the three acidic residues of the conserved D,D(35)E motif so severely impair IN activity that most, if not all, integration events by virus encoding such mutations are not IN mediated. IN-independent provirus formation may have implications for anti-IN therapeutic agents that target the IN active site.

Implication of a central cysteine residue and the HHCC domain of Moloney murine leukemia virus integrase protein in functional multimerization

Moloney murine leukemia virus (M-MuLV) IN-IN protein interactions important for catalysis of strand transfer and unimolecular and bimolecular disintegration reactions were investigated by using a panel of chemically modified M-MuLV IN proteins. Functional complementation of an HHCC-deleted protein (Ndelta105) by an independent HHCC domain (Cdelta232) was severely compromised by NEM modification of either subunit. Productive Ndelta105 IN-DNA interactions with a disintegration substrate lacking a long terminal repeat 5'-single-stranded tail also required complementation by a functional HHCC domain. Virus encoding the C209A M-MuLV IN mutation exhibited delayed virion production and replication kinetics.

Molecular mechanisms in retrovirus DNA integration

The integrase protein of retroviruses catalyzes the insertion of the viral DNA into the genomes of the cells that they infect. Integrase is necessary and sufficient for this recombination reaction in vitro; however, the enzyme's activity appears to be modulated in vivo by viral and cellular components included in the nucleoprotein pre-integration complex. In addition to integrase, cis-acting sequences at the ends of the viral DNA are important for integration. Solution of the structures of the isolated N- and C-terminal domains of HIV-1 integrase by nuclear magnetic resonance (NMR) and the available crystal structures of the catalytic core domains from human immunodeficiency virus type-1 (HIV-1) and avian sarcoma virus (ASV) integrases are providing a structural basis for understanding some aspects of the integration reaction. The role of the evolutionarily conserved acidic amino acids in the D,D(35)E motif as metal-coordinating residues that are critical for catalysis, has been confirmed by the metal-integrase (core domain) complexes of ASV integrase. The central role that integrase plays in the life cycle of the virus makes it an attractive target for the design of drugs against retroviral diseases such as AIDS. To this end, several compounds have been screened for inhibitory effects against HIV-1 integrase. These include DNA intercalators, peptides, RNA ligands, and small organic compounds such as bis-catechols, flavones, and hydroxylated arylamides. Although the published inhibitors are not very potent, they serve as valuable leads for the development of the next generation of tight-binding analogues that are more specific to integrase. In addition, new approaches are being developed, exemplified by intracellular immunization studies with conformation-sensitive inhibitory monoclonal antibodies against HIV-1 integrase. Increased knowledge of the mechanism of retroviral DNA integration should provide new strategies for the design of effective antivirals that inhibit integrase in the future.

A mutation in integrase can compensate for mutations in the simian immunodeficiency virus att site

Sequences at the left terminus of U3 in the left long terminal repeat (LTR) and at the right terminus of U5 in the right LTR are important for integration of retroviral DNA. In the infectious pathogenic molecular clone of simian immunodeficiency virus strain mac239 (SIVmac239), 10 of the 12 terminal base pairs form an imperfect inverted repeat structure (5' TGGAAGGGATTT 3' [nucleotides 1 to 12] and 3' ACGATCCCTAAA 5' [nucleotides 10279 to 10268]). Nineteen different mutant forms of SIVmac239 proviral DNA with changes at one or more of the positions in each of the 12-terminal-base-pair regions were constructed. Viral replication was severely or completely compromised with nine of these mutants. Revertants appeared 40 to 50 days after transfection in two independent experiments with mutant 7, which contained changes of AGG to TAC at positions 5 to 7 in U3 and TCC to GAA at positions 10275 to 10273 in U5. Virus produced at these times from mutant 7 transfection replicated upon reinfection with only a slight delay when compared to the wild type. Sequence analysis of the LTR and integrase regions from infected cultures revealed two predominant changes: G to A at position 10275 in U5 and Glu to Lys at position 136 in integrase. Derivatives of clone 7 in which these changes were introduced individually and together were constructed by site-specific mutagenesis. Each change individually restored replication capacity only partially. However, the combination of both mutations restored replicative capacity to that of the original revertants. These results indicate that changes in integrase can compensate for mutations in the terminal nucleotides of the SIV LTR. The results further indicate that resistance to integrase inhibitors may include both integrase and LTR mutations.

Crystal structure of the specific DNA-binding domain of Tc3 transposase of C.elegans in complex with transposon DNA

The crystal structure of the complex between the N-terminal DNA-binding domain of Tc3 transposase and an oligomer of transposon DNA has been determined. The specific DNA-binding domain contains three alpha-helices, of which two form a helix-turn-helix (HTH) motif. The recognition of transposon DNA by the transposase is mediated through base-specific contacts and complementarity between protein and sequence-dependent deformations of the DNA. The HTH motif makes four base-specific contacts with the major groove, and the N-terminus makes three base-specific contacts with the minor groove. The DNA oligomer adopts a non-linear B-DNA conformation, made possible by a stretch of seven G:C base pairs at one end and a TATA sequence towards the other end. Extensive contacts (seven salt bridges and 16 hydrogen bonds) of the protein with the DNA backbone allow the protein to probe and recognize the sequence-dependent DNA deformation. The DNA-binding domain forms a dimer in the crystals. Each monomer binds a separate transposon end, implying that the dimer plays a role in synapsis, necessary for the simultaneous cleavage of both transposon termini.

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.

Utilization of nonhomologous minus-strand DNA transfer to generate recombinant retroviruses

During reverse transcription, minus-strand DNA transfer connects the sequences located at the two ends of the viral RNA to generate a long terminal repeat. It is thought that the homology in the repeat (R) regions located at the two ends of the viral RNA sequences facilitate minus-strand DNA transfer. In this report, the effects of diminished R-region homology on DNA synthesis and virus titer were examined. A retrovirus vector, PY31, was constructed to contain the 5' and 3' cis-acting elements from Moloney murine sarcoma virus and spleen necrosis virus. These two viruses are genetically distinct, and the two R regions contain little homology. In one round of replication, the PY31 titer was approximately 3,000-fold lower than that of a control vector with highly homologous R regions. The molecular characteristics of the junctions of minus-strand DNA transfer were analyzed in both unintegrated DNA and integrated proviruses. Short stretches of homology were found at the transfer junctions and were likely to be used to facilitate minus-strand DNA transfer. Both minus-strand strong-stop DNA and weak-stop DNA were observed to mediate strand transfer. The ability of PY31 to complete reverse transcription indicates that minus-strand DNA transfer can be used to join sequences from two different viruses to form recombinant viruses. These results suggest the provocative possibility that genetically distinct viruses can interact through this mechanism.

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

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