HIV-1 cDNA integration: requirement of HMG I(Y) protein for function of preintegration complexes in vitro

HIV-1 integrase forms stable tetramers and associates with LEDGF/p75 protein in human cells

We studied human immunodeficiency virus, type 1 (HIV-1) integrase (IN) complexes derived from nuclei of human cells stably expressing the viral protein from a synthetic gene. We show that in the nuclear extracts IN exists as part of a large distinct complex with an apparent Stokes radius of 61 A, which dissociates upon dilution yielding a core molecule of 41 A. We isolated the IN complexes from cells expressing FLAG-tagged IN and demonstrated that the 41 A core is a tetramer of IN, whereas 61 A molecules are composed of IN tetramers associated with a cellular protein with an apparent molecular mass of 76 kDa. This novel integrase interacting protein was found to be identical to lens epithelium-derived growth factor (LEDGF/p75), a protein implicated in regulation of gene expression and cellular stress response. HIV-1 IN and LEDGF co-localized in the nuclei of human cells stably expressing IN. Furthermore, recombinant LEDGF robustly enhanced strand transfer activity of HIV-1 IN in vitro. Our findings indicate that the minimal IN molecule in human cells is a homotetramer, suggesting that at least an octamer of IN is required to accomplish coordinated integration of both retroviral long terminal repeats and that LEDGF is a cellular factor involved in this process.

Cofactors for human immunodeficiency virus type 1 cDNA integration in vitro

We have investigated the function of two DNA binding proteins that stimulate human immunodeficiency virus type 1 cDNA integration in vitro, the cellular HMGa1 protein and the viral nucleocapsid (NC) protein. Of the three forms of NC (NCp7, NCp9, and NCp15), we find that NCp9 is the most effective at increasing integration in vitro; thus, processing of NC may potentially modulate its activities during infection. We also found that maximal stimulation by NCp9 required roughly enough NC to coat the reactant DNAs whereas less HMGa1 was required, and the reactions displayed different optima for divalent metal cofactors and order of addition. These findings reveal probable distinct mechanisms of action in vitro.

Regulatory mechanisms by which barrier-to-autointegration factor blocks autointegration and stimulates intermolecular integration of Moloney murine leukemia virus preintegration complexes

Retroviral integration is mediated by a preintegration complex (PIC) which contains the viral DNA made by reverse transcription together with associated protein factors. Prior to association with target DNA, the PIC must avoid suicidal intramolecular integration of its viral DNA (autointegration). We have demonstrated that barrier-to-autointegration factor (BAF) blocks the autointegration of Moloney murine leukemia virus (MoMLV) PICs in vitro. In this study, we show that BAF is an authentic component of MoMLV. Analysis of the sedimentation properties of initial, salt-stripped, and BAF-reconstituted PICs reveals that the viral DNA within the PIC is reversibly compacted by BAF, consistent with the functional role of BAF in protecting the viral DNA from autointegration. Furthermore, we find that BAF can promote the association of PICs with target DNA. Thus, our data suggest that BAF plays critical roles in promoting preferential intermolecular integration by both blocking autointegration and stimulating the capture of target DNA.

Characterization of Moloney murine leukemia virus p12 mutants blocked during early events of infection

Mutations affecting either the N- or C-terminal regions of the Gag protein p12 block replication of Moloney murine leukemia virus (M-MuLV). Viruses carrying mutations in this portion of gag can mediate the assembly and release of virions but are unable to successfully carry out the early phase of the M-MuLV life cycle. Wild-type and mutant viruses were found to synthesize similar levels of linear viral DNA in both cytoplasmic and nuclear fractions, and there were no significant differences in either the density or sedimentation of the viral protein-nucleic acid complexes. Analysis of the termini of the linear viral DNAs showed that the 3' ends of the mutant viral DNA were processed normally by the integrase. Further, the preintegration complexes extracted from the cytoplasm of cells infected with the mutant viruses were competent for integration into target DNA in vitro. Nevertheless, no circular viral DNAs were detected in cells infected by the mutants, and functional proviruses were not formed. These results suggest that p12 has an unexpected role in the early phase of the life cycle and is needed after viral DNA synthesis to deliver the incoming DNA to the correct location and in the appropriate state to permit either circularization or integration of the viral DNA in vivo.

Characterization of a human immunodeficiency virus type 1 pre-integration complex in which the majority of the cDNA is resistant to DNase I digestion

The human immunodeficiency virus type 1 (HIV-1) pre-integration complex (PIC) is a cytoplasmic nucleoprotein structure derived from the core of the virion and is responsible for reverse transcription of viral RNA to cDNA, transport to the nucleus and integration of the cDNA into the genome of the infected target cell. Others have shown by Mu phage-mediated PCR footprinting that only the LTRs of the cDNA of PICs isolated early in infection are protected by bound protein, while the rest of the genome is susceptible to nuclease attack. Here, using DNase I footprinting, we confirmed that the majority of the cDNA of PICs isolated at 8.5 h after infection with cell-free virus was sensitive to digestion with DNase I and that only part of the LTRs (approximately 6% of the total cDNA) was protected. However, PICs isolated 90 min later (at 10 h post-infection) were very different in that the majority (approximately 90%) of cDNA was protected from nuclease degradation. These late PICs were integration active in vitro. We conclude that HIV-1 has at least two types of PIC, an early PIC characterized by protein bound only at the LTRs, and a late, and possibly more mature form, in which protein is bound along the length of the cDNA.

HIV-1 integration in the human genome favors active genes and local hotspots

A defining feature of HIV replication is integration of the proviral cDNA into human DNA. The selection of chromosomal targets for integration is crucial for efficient viral replication, but the mechanism is poorly understood. Here we describe mapping of 524 sites of HIV cDNA integration on the human genome sequence. Genes were found to be strongly favored as integration acceptor sites. Global analysis of cellular transcription indicated that active genes were preferential integration targets, particularly genes that were activated in cells after infection by HIV-1. Regional hotspots for integration were also found, including a 2.4 kb region containing 1% of sites. These data document unexpectedly strong biases in integration site selection and suggest how selective targeting promotes aggressive HIV replication.

Effect of Ku80 depletion on the preintegrative steps of HIV-1 replication in human cells

To gain new insights regarding the role of Ku, the DNA-PK DNA-binding component, during lentiviral DNA integration, we have investigated the HIV-1 replication in Ku80-depleted human cells. CEM4fx cells underexpressing the Ku80 factor were selected after transduction by a retroviral vector expressing the Ku80 full-length antisense sequence. De novo infection experiment with NL4.3 HIV-1 strain led to the observation that the viral replication was delayed in the Ku80-depleted cells. Early events of the replicative cycle, including nuclear import of the viral DNA, were not affected. In contrast, the formation of the 2-LTR circles was impaired, thus demonstrating the implication of Ku in HIV-1 DNA circularization, for the first time in human cells. Furthermore, the detection of integrated proviruses by an Alu-LTR-nested PCR amplification method was affected in cells underexpressing Ku80. These results suggest that this factor may also be involved in the mechanisms leading to the stable establishment of HIV-1 provirus.

HIV-1 integrase and RNase H activities as therapeutic targets

The retroviruses are a large, diverse family of enveloped RNA viruses defined by their structure, composition and replicative properties. The hallmark of the family is its replicative strategy, essential steps of which include reverse transcription of the viral RNA and the subsequent integration of this DNA into the genome of the cell. These steps are performed by two viral-encoded enzymes, reverse transcriptase (RT), which possesses DNA polymerase and ribonuclease H (RNase H) activities, and integrase (IN). These enzymes are excellent targets for retroviral therapy since they are essential for viral replication. Numerous substances capable of inhibiting the DNA polymerase activity of HIV-1 RT are available, while few specific inhibitors of RNase H activity have been described. IN is absolutely necessary for stable and productive infection of cells. Some IN inhibitors have been recently reported and are available demonstrating the potential of IN as an antiviral target. This paper is an overview of the inhibitors of RNase H and IN and describes the most promising inhibitors.

Interaction of HIV-1 integrase with DNA repair protein hRad18

We have previously shown that human immunodeficiency virus-1 (HIV-1) integrase is an unstable protein and a substrate for the N-end rule degradation pathway. This degradation pathway shares its ubiquitin-conjugating enzyme, Rad6, with the post-replication/translesion DNA repair pathway. Because DNA repair is thought to play an essential role in HIV-1 integration, we investigated whether other molecules of this DNA repair pathway could interact with integrase. We observed that co-expression of human Rad18 induced the accumulation of an otherwise unstable form of HIV-1 integrase. This accumulation occurred even though hRAD18 possesses a RING finger domain, a structure that is generally associated with E3 ubiquitin ligase function and protein degradation. Evidence for an interaction between integrase and hRad18 was obtained through reciprocal co-immunoprecipitation. Moreover we found that a 162-residue region of hRad18 (amino acids 65-226) was sufficient for both integrase stabilization and interaction. Finally, we observed that HIV-1 integrase co-localized with hRad18 in nuclear structures in a subpopulation of co-transfected cells. Taken together, these findings identify hRad18 as a novel interacting partner of HIV-1 integrase and suggest a role for post-replication/translesion DNA repair in the retroviral integration process.

A comparative study of the human T-cell leukemia virus type 2 integrase expressed in and purified from Escherichia coli and Pichia pastoris

The human T-cell leukemia virus type-2 (HTLV-2) integrase (IN) catalyzes the insertion of the viral genome into the host chromosome. HTLV-2 IN was expressed as an N-terminal hexa-histidine tagged protein in the methylotrophic yeast Pichia pastoris and as a C-terminal hexa-histidine fusion in Escherichia coli. Maximal IN expression was observed at 48h post-induction for the yeast system and 2h post-induction for E. coli. Effective purification strategies were developed using non-ionic and zwitterionic detergents for initial protein extraction, followed by a one-step nickel-chelating chromatography purification. IN from both sources was routinely greater than 90% pure with yields exceeding 1.5mg of purified IN per liter of culture for P. pastoris. The relative pI was defined for both INs, pH 5.0-5.4, by 2D-gel electrophoresis. Specific activities for IN purified from E. coli and P. pastoris were calculated from in vitro 3(') processing assays and were comparable. In vitro IN assays were also performed to optimize reaction buffer pH and metal concentrations for both 3(') processing and strand transfer assays. Strand transfer was optimal from pH 6.2-6.8, more than 1.5 pH units below the optimal 3(') processing pH of 8.3. IN from both sources showed no enhancement in activity with MnCl(2) concentrations greater than 5mM. The specific activity of P. pastoris purified IN was 0.35 product (pmol)/h/microg IN, and E. coli produced IN was 0.48 product (pmol)/h/microg IN.

Rhesus macaque resistance to mucosal simian immunodeficiency virus infection is associated with a postentry block in viral replication

Elucidation of the host factors which influence susceptibility to human immunodeficiency virus or simian immunodeficiency virus (SIV) infection and disease progression has important theoretical and practical implications. Rhesus macaque 359, a vaccine control animal, resisted two successive intravaginal challenges with SIV(mac251) and failed to seroconvert. Here, after an additional intrarectal SIVmac32H challenge, macaque 359 remained highly resistant to infection. Viral RNA (10(6) copies/ml) was observed in plasma only at week 2 postchallenge. Virus isolation and proviral DNA were positive only once at week eight postchallenge. The animal remained seronegative and cleared SIV in vivo. Its blood and lymph node cells obtained at 49 weeks after intrarectal challenge did not transmit SIV to a naive macaque. We found that the resistance of macaque 359 to SIV infection was not due to a high level of CD8(+) suppressor activity but to an inherent resistance of its CD4(+) T cells. To elucidate the basis for the unusually strong resistance of macaque 359 to SIV infection in vivo and in vitro, we investigated early events of viral infection and replication in CD4(+) cells of macaque 359, including expression and mutation screening of SIV coreceptors and analysis of viral entry and reverse transcription. Mutation screening revealed no genetic alteration in SIV coreceptors. PCR analysis revealed a significant delay in production of early in vitro reverse transcription intermediates in macaque 359 cells compared to susceptible controls, but cell fusion assays showed that SIV entered the CD4(+) CCR5(+) cells of macaque 359 as readily as cells of macaques susceptible to SIV infection. Our results suggest that the resistance of macaque 359 to SIV infection is due to a postentry block in viral replication and implicate a cellular inhibitory mechanism in its CD4(+) T cells. Identification of this host mechanism will help further elucidate the biochemistry of reverse transcription and may suggest therapeutic strategies. Determining the prevalence of this host resistance mechanism among macaques may lead to better design of SIV pathogenesis and vaccine studies.

Subcellular localization and integration activities of rous sarcoma virus reverse transcriptase

Reverse transcriptases (RTs) alphabeta and beta from avian Rous sarcoma virus (RSV) harbor an integrase domain which is absent in nonavian retroviral RTs. RSV integrase contains a nuclear localization signal which enables the enzyme to enter the nucleus of the cell in order to perform integration of the proviral DNA into the host genome. In the present study we analyzed the subcellular localization of RSV RT, since previous results indicated that RSV finishes synthesis of the proviral DNA in the nucleus. Our results demonstrate that the heterodimeric RSV RT alphabeta and the beta subunit, when expressed independently, can be detected in the nucleus, whereas the separate alpha subunit lacking the integrase domain is prevalent in the cytoplasm. These data suggest an involvement of RSV RT in the transport of the preintegration complex into the nucleus. In addition, to analyze whether the integrase domain, located at the carboxyl terminus of beta, exhibits integration activities, we investigated the nicking and joining activities of heterodimeric RSV RT alphabeta with an oligodeoxynucleotide-based assay system and with a donor substrate containing the supF gene flanked by the viral long terminal repeats. Our data show that RSV RT alphabeta is able to perform the integration reaction in vitro; however, it does so with an estimated 30-fold lower efficiency than the free RSV integrase, indicating that RSV RT is not involved in integration in vivo. Integration with RSV RT alphabeta could be stimulated in the presence of human immunodeficiency virus type 1 nucleocapsid protein or HMG-I(Y).

Constitutive association of BRCA1 and c-Abl and its ATM-dependent disruption after irradiation

BRCA1 plays an important role in mechanisms of response to double-strand breaks, participating in genome surveillance, DNA repair, and cell cycle checkpoint arrests. Here, we identify a constitutive BRCA1-c-Abl complex and provide evidence for a direct interaction between the PXXP motif in the C terminus of BRCA1 and the SH3 domain of c-Abl. Following exposure to ionizing radiation (IR), the BRCA1-c-Abl complex is disrupted in an ATM-dependent manner, which correlates temporally with ATM-dependent phosphorylation of BRCA1 and ATM-dependent enhancement of the tyrosine kinase activity of c-Abl. The BRCA1-c-Abl interaction is affected by radiation-induced modification to both BRCA1 and c-Abl. We show that the C terminus of BRCA1 is phosphorylated by c-Abl in vitro. In vivo, BRCA1 is phosphorylated at tyrosine residues in an ATM-dependent, radiation-dependent manner. Tyrosine phosphorylation of BRCA1, however, is not required for the disruption of the BRCA1-c-Abl complex. BRCA1-mutated cells exhibit constitutively high c-Abl kinase activity that is not further increased on exposure to IR. We suggest a model in which BRCA1 acts in concert with ATM to regulate c-Abl tyrosine kinase activity.

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.

HIV-1 integrase interacts with yeast microtubule-associated proteins

The human immunodeficiency virus type 1 (HIV-1) integrase (IN) mediates the insertion of viral DNA into the human genome. In addition to IN, cellular and viral proteins are associated to proviral DNA in the so-called preintegration complex (PIC). We previously reported that the expression of HIV-1 IN in yeast leads to the emergence of a lethal phenotype. This effect may be linked to the IN activity on infected human cells where integration requires the cleavage of genomic DNA. To isolate and characterize potential cellular partners of HIV-1 IN, we used it as a bait in a two-hybrid system with a yeast genomic library. IN interacted with proteins belonging to the microtubule network, or involved in the protein synthesis apparatus. We focused our interest on one of the selected inserts, L2, which corresponds to the C-end half of the yeast STU2p, a microtubule-associated protein (MAP). STU2p is an essential component of the yeast spindle pole body (SPB), which is able to bind microtubules in vitro. After expressing and purifying L2 as a recombinant protein, we showed its binding to IN by ELISA immunodetection. L2 was also able to inhibit IN activity in vitro. In addition, the effect of L2 was tested using the "lethal yeast phenotype". The coexpression of IN and the L2 peptide abolished the lethal phenotype, thus showing important in vivo interactions between IN and L2. The identification of components of the microtubule network associated with IN suggest a role of this complex in the transport of HIV-1 IN present in the PIC to the nucleus, as already described for other human viruses.

Correct integration mediated by integrase-LexA fusion proteins incorporated into HIV-1

Fusion of wild-type or truncated integrase to a sequence-specific DNA-binding protein, such as the Escherichia coli LexA repressor, results in an integration bias toward the recognition site of the DNA-binding protein in vitro. Integrase-defective HIV-1 could become integration-competent by supplying the fusion protein in trans. To understand the mechanism of complementation, the virus-host DNA junctions of cells infected with the integrase-LexA containing virus were sequenced. The characteristic hallmarks of wild-type integration were present, a 5'-TG/CA-3' at the ends of the viral sequence and a 5-bp direct repeat in the immediately flanking cellular DNA. Experiments were also carried out to determine the mechanism by which the amino- or carboxy-terminal truncated integrase fused to LexA restored integration to the integrase-mutant viral clone. Complementation experiments using purified fusion proteins in vitro, or viruses encoding a C-terminal truncated integrase and containing various fusion proteins in trans, indicated that the truncated integrase-LexA proteins are inactive per se and they restore integration by forming mixed multimers with the virally encoded mutant integrase. Correct integration of retroviral DNA by the in trans method illustrates the feasibility of introducing integrase fusion proteins into retroviral vectors to achieve site-directed integration without interfering with the attributes of the integration reaction.

Efficient concerted integration by recombinant human immunodeficiency virus type 1 integrase without cellular or viral cofactors

Replication of retroviruses requires integration of the linear viral DNA genome into the host chromosomes. Integration requires the viral integrase (IN), located in high-molecular-weight nucleoprotein complexes termed preintegration complexes (PIC). The PIC inserts the two viral DNA termini in a concerted manner into chromosomes in vivo as well as exogenous target DNA in vitro. We reconstituted nucleoprotein complexes capable of efficient concerted (full-site) integration using recombinant wild-type human immunodeficiency virus type I (HIV-1) IN with linear retrovirus-like donor DNA (480 bp). In addition, no cellular or viral protein cofactors are necessary for purified bacterial recombinant HIV-1 IN to mediate efficient full-site integration of two donor termini into supercoiled target DNA. At about 30 nM IN (20 min at 37 degrees C), approximately 15 and 8% of the input donor is incorporated into target DNA, producing half-site (insertion of one viral DNA end per target) and full-site integration products, respectively. Sequencing the donor-target junctions of full-site recombinants confirms that 5-bp host site duplications have occurred with a fidelity of about 70%, similar to the fidelity when using IN derived from nonionic detergent lysates of HIV-1 virions. A key factor allowing recombinant wild-type HIV-1 IN to mediate full-site integration appears to be the avoidance of high IN concentrations in its purification (about 125 microg/ml) and in the integration assay (<50 nM). The results show that recombinant HIV-1 IN may not be significantly defective for full-site integration. The findings further suggest that a high concentration or possibly aggregation of IN is detrimental to the assembly of correct nucleoprotein complexes for full-site integration.

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.

Inhibition of the integrases of human immunodeficiency viruses type 1 and type 2 by reverse transcriptases

We present evidence that the integrases (INs) of HIV types 1 and 2 are inhibited in vitro by the reverse transcriptases (RTs) of HIV-1, HIV-2 and murine leukaemia virus. Both 3'-end processing and 3'-end joining (strand transfer) activities of IN were affected by the RTs. Full inhibitions were accomplished with most RT and IN combinations tested at around equimolar RT/IN ratios. The disintegration activity of IN was also inhibited by RTs. Neither DNA synthesis nor the ribonuclease H (RNase H) domain of RT were involved in IN inhibition, since specific DNA polymerase inhibitors did not affect the level of IN inhibition, and the p51 isoform of HIV-1 RT (which lacks the RNase H domain) is as effective in inhibiting IN as the heterodimeric p66/p51 isoform. On the other hand, the catalytic activities of HIV RTs were not affected by the INs, showing that RTs can inhibit IN activities, whereas INs do not inhibit RTs. We postulate that sequences and/or three-dimensional protein structures common to RTs interact with INs and inhibit their activities. We show evidence for this hypothesis and discuss the possible sites of IN involved in this interaction.

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.

HIV-1 preintegration complexes preferentially integrate into longer target DNA molecules in solution as detected by a sensitive, polymerase chain reaction-based integration assay

After entering a cell and undergoing reverse transcription, the retroviral genome is contained in a preintegration complex (PIC) that mediates its integration into host cell DNA. PICs have been shown to prefer torsionally strained DNA, but the effect of target DNA length has not been previously examined. In this report, concatemerization of a repeating 105-base pair unit was used to vary target DNA length independently from basic DNA sequence, while maintaining both PICs and target DNAs in solution. Integration junctions were quantified by real-time fluorescence-monitored polymerase chain reaction amplification using primers in the viral long terminal repeat and the target DNA. Unreacted target DNA severely inhibited the post-reaction polymerase chain reaction detection step, requiring its removal using lambda exonuclease digestion. Integration into a 32-unit concatemer of target DNA was markedly more efficient than integration into a monomeric unit, indicating that longer target DNA was preferred. This substrate was used to construct a simple, robust, and adaptable assay that can serve as a method for studying the host cell factors that enhance PIC integration, and as a drug discovery platform for integration inhibitors active against PICs.

Activated peripheral CD8 lymphocytes express CD4 in vivo and are targets for infection by human immunodeficiency virus type 1

There is increasing evidence that CD8 lymphocytes may represent targets for infection by human immunodeficiency virus type 1 (HIV-1) in vivo whose destruction may contribute to the loss of immune function underlying AIDS. HIV-1 may infect thymic precursor cells destined to become CD4 and CD8 lymphocytes and contribute to the numerical decline in both subsets on disease progression. There is also evidence for the induction of CD4 expression and susceptibility to infection by HIV-1 of CD8 lymphocytes activated in vitro. To investigate the relationship between CD8 activation and infection by HIV-1 in vivo, activated subsets of CD8 lymphocytes in peripheral blood mononuclear cells (PBMCs) of HIV-seropositive individuals were investigated for CD4 expression and HIV infection. Activated CD8 lymphocytes were identified by expression of CD69, CD71, and the human leukocyte antigen (HLA) class II, the beta-chain of CD8, and the RO isoform of CD45. CD4(+) and CD4(-) CD8 lymphocytes, CD4 lymphocytes, other T cells, and non-T cells were purified using paramagnetic beads, and proviral sequences were quantified by PCR using primers from the long terminal repeat region. Frequencies of activated CD8 lymphocytes were higher in HIV-infected study subjects than in seronegative controls, and they frequently coexpressed CD4 (mean frequencies on CD69(+), CD71(+), and HLA class II(+) cells of 23, 37, and 8%, respectively, compared with 1 to 2% for nonactivated CD8 lymphocytes). The level of CD4 expression of the double-positive population approached that of mature CD4 lymphocytes. That CD4 expression renders CD8 cell susceptible to infection was indicated by their high frequency of infection in vivo; infected CD4(+) CD8 lymphocytes accounted for between 3 and 72% of the total proviral load in PBMCs from five of the eight study subjects investigated, despite these cells representing a small component of the PBMC population (<3%). Combined, these findings provide evidence that antigenic stimulation of CD8 lymphocytes in vivo induces CD4 expression that renders them susceptible to HIV infection and destruction. The specific targeting of responding CD8 lymphocytes may provide a functional explanation for the previously observed impairment of cytotoxic T-lymphocyte (CTL) function disproportionate to their numerical decline in AIDS and for the deletion of specific clones of CTLs responding to HIV antigens.

A truncation mutant of the 95-kilodalton subunit of transcription factor IIIC reveals asymmetry in Ty3 integration

Position-specific integration of the retroviruslike element Ty3 near the transcription initiation sites of tRNA genes requires transcription factors IIIB and IIIC (TFIIIB and TFIIIC). Using a genetic screen, we isolated a mutant with a truncated 95-kDa subunit of TFIIIC (TFIIIC95) that reduced the apparent retrotransposition of Ty3 into a plasmid-borne target site between two divergently transcribed tRNA genes. Although TFIIIC95 is conserved and essential, no defect in growth or transcription of tRNAs was detected in the mutant. Steps of the Ty3 life cycle, such as protein expression, proteolytic processing, viruslike particle formation, and reverse transcription, were not affected by the mutation. However, Ty3 integration into a divergent tDNA target occurred exclusively in one orientation in the mutant strain. Investigation of this orientation bias showed that TFIIIC95 and Ty3 integrase interacted in two-hybrid and glutathione S-transferase pulldown assays and that interaction with the mutant TFIIIC95 protein was attenuated. The orientation bias observed here suggests that even for wild-type Ty3, the protein complexes associated with the long terminal repeats are not equivalent in vivo.

Intracellular trafficking of retroviral genomes during the early phase of infection: viral exploitation of cellular pathways

Retroviruses enter cells through specific cell-surface receptors and then embark on a journey that ultimately leads to the establishment of the integrated proviral DNA. The steps of the journey include the reverse transcription of the viral RNA into DNA, the trafficking of the viral protein-DNA complex through the cytoplasm, the entry of the complex into the nucleus, and the insertion of the linear viral DNA into the host genome. All these steps are likely to involve specific interactions of viral proteins with host machinery. Our knowledge of the details of these interactions is very limited but is rapidly expanding, and should provide a deeper understanding of the pathways and components used by the different classes of retroviruses. This knowledge in turn should enable the development of better and more efficient retroviral vectors for use in gene therapy protocols in vivo.

Kinetics of human immunodeficiency virus type 1 (HIV) DNA integration in acutely infected cells as determined using a novel assay for detection of integrated HIV DNA

We have developed a novel linker-primer PCR assay for the detection and quantification of integrated human immunodeficiency virus type 1 (HIV) DNA. This assay reproducibly allowed the detection of 10 copies of integrated HIV DNA, in a background of 2 x 10(5) cell equivalents of human chromosomal DNA, without amplifying extrachromosomal HIV DNA. We have used this assay and a near-synchronous one-step T-cell infection model to investigate the kinetics of viral DNA accumulation following HIV infection. We report here that integrated HIV DNA started accumulating 1 h after the first appearance of extrachromosomal viral DNA and accounted for approximately 10% of the total HIV DNA synthesized in the first round of viral replication. These results highlight the efficient nature of integrase-mediated HIV integration in infected T cells.

HIV-1 reverse transcriptase and integrase enzymes physically interact and inhibit each other

Ordered molecular interactions and structural changes must take place within the human immunodeficiency virus type 1 (HIV-1) preintegration complex at various stages for successful viral replication. We demonstrate both physical and biochemical interactions between HIV-1 reverse transcriptase and integrase enzymes. This interaction may have implications on the in vivo functions of the two enzymes within the HIV-1 replication complex. It may be one of the various molecular interactions, which facilitate efficient HIV-1 replication within the target cells.

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.

Specific inhibition of human immunodeficiency virus type 1 (HIV-1) integration in cell culture: putative inhibitors of HIV-1 integrase

To study the effect of potential human immunodeficiency virus type 1 (HIV-1) integrase inhibitors during virus replication in cell culture, we used a modified nested Alu-PCR assay to quantify integrated HIV DNA in combination with the quantitative analysis of extrachromosomal HIV DNA. The two diketo acid integrase inhibitors (L-708,906 and L-731,988) blocked the accumulation of integrated HIV-1 DNA in T cells following infection but did not alter levels of newly synthesized extrachromosomal HIV DNA. In contrast, we demonstrated that L17 (a member of the bisaroyl hydrazine family of integrase inhibitors) and AR177 (an oligonucleotide inhibitor) blocked the HIV replication cycle at, or prior to, reverse transcription, although both drugs inhibited integrase activity in cell-free assays. Quercetin dihydrate (a flavone) was shown to not have any antiviral activity in our system despite reported anti-integration properties in cell-free assays. This refined Alu-PCR assay for HIV provirus is a useful tool for screening anti-integration compounds identified in biochemical assays for their ability to inhibit the accumulation of integrated HIV DNA in cell culture, and it may be useful for studying the effects of these inhibitors in clinical trials.

DNA binding induces dissociation of the multimeric form of HIV-1 integrase: a time-resolved fluorescence anisotropy study

Self-assembly of HIV-1 integrase (IN) in solution has been studied previously by time-resolved fluorescence, using tryptophan anisotropy decay. This approach provides information on the size of macromolecules via the determination of rotational correlation times (theta). We have shown that, at submicromolar concentration, IN is characterized by a long rotational correlation time (theta(20 degrees C) = 90-100 ns) corresponding to a high-order oligomeric form, likely a tetramer. In the present work, we investigated the self-assembly properties of the DNA-bound IN by using three independent fluorophores. Under enzymatic assay conditions (10(-7) M IN, 2 x 10(-8) M DNA), using either fluorescein-labeled or fluorescent guanosine analog-containing oligonucleotides that mimic a viral end long terminal repeat sequence, we found that the DNA-IN complex was characterized by shorter theta(20 degrees C) values of 15.5-19.5 and 23-27 ns, calculated from experiments performed at 25 degrees C and 37 degrees C, respectively. These results were confirmed by monitoring the Trp anisotropy decay as a function of the DNA substrate concentration: the theta of IN shifted from 90-100 ns to lower values (<30 ns) upon increasing the DNA concentration. Again, the normalized theta(20 degrees C) values were significantly higher when monitored at 37 degrees C as compared with 25 degrees C. These results indicate that upon binding the viral DNA end, the multimeric enzyme undergoes a dissociation, most likely into a homogeneous monomeric form at 25 degrees C and into a monomer-dimer equilibrium at 37 degrees C.

Targeting HIV-1 integrase

Human immunodeficiency virus Type 1 (HIV-1) integrase is an essential enzyme for the obligatory integration of the viral DNA into the infected cell chromosome. As no cellular homologue of HIV integrase has been identified, this unique HIV-1 enzyme is an attractive target for the development of new therapeutics. Treatment of HIV-1 infection and AIDS currently consists of the use of combinations of HIV-1 inhibitors directed against reverse transcriptase (RT) and protease. However, their numerous side effects and the rapid emergence of drug-resistant variants limit greatly their use in many AIDS patients. In principle, inhibitors of the HIV-1 integrase should be relatively non-toxic and provide additional benefits for AIDS chemotherapy. There have been many major advances in our understanding of the molecular mechanism of the integration reaction, although some critical aspects remain obscure. Several classes of compounds have been screened and further scrutinised for their inhibitory properties against the HIV integrase; however, there are currently no useful inhibitors available clinically for the treatment of AIDS patients. This review describes the current knowledge of the biological functions of the HIV-1 integrase and reports the major classes of integrase inhibitors identified to date.

Role of the non-homologous DNA end joining pathway in the early steps of retroviral infection

Early after infection, the retroviral RNA genome is reverse transcribed to generate a linear cDNA copy, then that copy is integrated into a chromosome of the host cell. We report that unintegrated viral cDNA is a substrate for the host cell non-homologous DNA end joining (NHEJ) pathway, which normally repairs cellular double-strand breaks by end ligation. NHEJ activity was found to be required for an end-ligation reaction that circularizes a portion of the unintegrated viral cDNA in infected cells. Consistent with this, the NHEJ proteins Ku70 and Ku80 were found to be bound to purified retroviral replication intermediates. Cells defective in NHEJ are known to undergo apoptosis in response to retroviral infection, a response that we show requires reverse transcription to form the cDNA genome but not subsequent integration. We propose that the double-strand ends present in unintegrated cDNA promote apoptosis, as is known to be the case for chromosomal double-strand breaks, and cDNA circularization removes the pro-apoptotic signal.

Sequence and analysis of the murine Hmgiy (Hmga1) gene locus

The HMGIY non-histone proteins play important roles as architectural transcription factors that regulate gene transcription in mammalian cells and also act as host-supplied cofactors necessary for retroviral integration. The genes coding for the HMGIY proteins are proto-oncogenes, and their aberrant or over-expression is correlated with both neoplastic transformation and metastatic progression in a wide variety of tumors. Here, we report the first complete sequence of the murine Hmgiy (a.k.a. Hmga1) gene and provide a detailed comparison of this with the sequence and organization of the human HMGIY gene, including an analysis of its promoter region with the previously unreported 5' upstream region of the human gene. These analyses reveal a remarkable degree of overall sequence conservation in both the protein coding and promoter regions of the murine and human genes, including conservation of the c-Myc binding site that has been demonstrated to regulate murine Hmgiy transcription (Wood et al., 2000. Mol. Cell. Biol. 20, 5490-5502). The promoters of both genes contain other conserved transcription factor binding sites that may also represent important cis-regulatory elements. Two exons present in the 5' untranslated region of the human gene, however, are missing from the murine gene, suggesting that these two closely related mammalian species regulate transcription of their Hmgiy genes in an individualistic manner.

HMGI/Y proteins: flexible regulators of transcription and chromatin structure

The mammalian HMGI/Y (HMGA) non-histone proteins participate in a wide variety of cellular processes including regulation of inducible gene transcription, integration of retroviruses into chromosomes and the induction of neoplastic transformation and promotion of metastatic progression of cancer cells. Recent advances have contributed greatly to our understanding of how the HMGI/Y proteins participate in the molecular mechanisms underlying these biological events. All members of the HMGI/Y family of 'high mobility group' proteins are characterized by the presence of multiple copies of a conserved DNA-binding peptide motif called the 'AT hook' that preferentially binds to the narrow minor groove of stretches of AT-rich sequence. The mammalian HMGI/Y proteins have little, if any, secondary structure in solution but assume distinct conformations when bound to substrates such as DNA or other proteins. Their intrinsic flexibility allows the HMGI/Y proteins to participate in specific protein-DNA and protein-protein interactions that induce both structural changes in chromatin substrates and the formation of stereospecific complexes called 'enhanceosomes' on the promoter/enhancer regions of genes whose transcription they regulate. The formation of such regulatory complexes is characterized by reciprocal inductions of conformational changes in both the HMGI/Y proteins themselves and in their interacting substrates. It may well be that the inherent flexibility of the HMGI/Y proteins, combined with their ability to undergo reversible disordered-to-ordered structural transitions, has been a significant factor in the evolutionary selection of these proteins for their functional role(s) in cells.

HIV-1 infection requires a functional integrase NLS

HIV-1 is able to infect nondividing cells productively in part because the postentry viral nucleoprotein complexes are actively imported into the nucleus. In this manuscript, we identify a novel nuclear localization signal (NLS) in the viral integrase (IN) protein that is essential for virus replication in both dividing and nondividing cells. The IN NLS stimulates the efficient nuclear accumulation of viral DNA as well as virion-derived IN protein during the initial stages of infection but is dispensable for catalytic function. Because this NLS is required for infection irrespective of target cell proliferation, we suggest that interactions between uncoated viral nucleoprotein complexes and the host cell nuclear import machinery are critical for HIV-1 infection of all cells.

Infection of the CD45RA+ (naive) subset of peripheral CD8+ lymphocytes by human immunodeficiency virus type 1 in vivo

To investigate the mechanism and functional significance of infection of CD8+ lymphocytes by human immunodeficiency virus type 1 (HIV-1) in vivo, we determined frequencies of infection, proviral conformation, and genetic relationships between HIV-1 variants infecting naive (CD45RA+) and memory (CD45RO+) peripheral blood CD4+ and CD8+ lymphocytes. Infection of CD3+ CD8+ CD45RA+ cells was detected in 9 of 16 study subjects at frequencies ranging from 30 to 1,400 proviral copies/10(6) cells, more frequently than CD3+ CD8+ lymphocytes expressing the RO isoform of CD45 (n = 2, 70 and 260 copies /10(6) cells). In agreement with previous studies, there was no evidence for a similar preferential infection of CD4+ naive lymphocytes. Proviral sequences in both CD4+ and CD8+ lymphocyte subsets were complete, as assessed by quantitation using primers from the long terminal repeat region spanning the tRNA primer binding site. In six of the seven study subjects investigated, variants infecting CD8+ lymphocytes were partially or completely genetically distinct in the V3 region from those recovered from CD4+ lymphocytes and showed a greater degree of compartmentalization than observed between naive and memory subsets of CD4+ lymphocytes. In two study subjects, arginine substitutions at position 306, associated with use of the chemokine coreceptor CXCR4, were preferentially found in CD4 lymphocytes. These population differences may have originated through different times of infection rather than necessarily indicating a difference in their biological properties. The preferential distribution of HIV-1 in naive CD8+ lymphocytes indeed suggests that infection occurred early in T-lymphocyte ontogeny, such as during maturation in the thymus. Destruction of cells destined to become CD8+ lymphocytes may be a major factor in the decline in CD8+ lymphocyte frequencies and function on disease progression and may contribute directly to the observed immunodeficiency in AIDS.

The site of HIV-1 integration in the human genome determines basal transcriptional activity and response to Tat transactivation

Because of the heterogeneity of chromatin, the site of integration of human immunodeficiency virus (HIV) in the genome could have dramatic effects on its transcriptional activity. We have used an HIV-1-derived retroviral vector, in which the green fluorescent protein is under the control of the HIV promoter, to generate by infection 34 Jurkat clonal cell lines each containing a single integration of the HIV-1 vector. In the absence of Tat, a 75-fold difference in expression level between the highest and lowest expressing clones was observed. Basal promoter activity was low in 80% of the clones and moderate to high in the remaining 20% of clones. We found that differences in expression levels are due to the integration site and are not controlled by DNA methylation or histone acetylation. Tat activated transcription in each clone, and an inverse correlation was observed between basal transcriptional activity and inducibility by Tat. These observations demonstrate that the chromatin environment influences basal HIV gene expression and that the HIV Tat protein activates transcription independently of the chromatin environment.

Characterization of intracellular reverse transcription complexes of human immunodeficiency virus type 1

To examine the early events of the life cycle of human immunodeficiency virus type 1 (HIV-1), we analyzed the intracellular complexes mediating reverse transcription isolated from acutely infected cells. Partial purification of the reverse transcription complexes (RTCs) by equilibrium density fractionation and velocity sedimentation indicated that two species of RTCs are formed but only one species is able to synthesize DNA. Most of the capsid, matrix, and reverse transcriptase (RT) proteins dissociate from the complex soon after cell infection, but Vpr remains associated with the RTC. The RTCs isolated 1, 4, and 7 h after infection are competent for reverse transcription in vitro, indicating that a small proportion of RT remains associated with them. HIV RTCs isolated early after infection have a sedimentation velocity of approximately 560S. Later, different species with a sedimentation velocity ranging from 350S to 100S appear. Nuclear-associated RTCs have a sedimentation velocity of 80S. Shortly after initiation of reverse transcription, the viral strong-stop DNA within the RTC is sensitive to nuclease digestion and becomes protected when reverse transcription is almost completed.

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.

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.

Base-pair substitutions in avian sarcoma virus U5 and U3 long terminal repeat sequences alter the process of DNA integration in vitro

We have described a reconstituted avian sarcoma virus (ASV) concerted DNA integration system with specially designed mini-donor DNA containing a supF transcription unit, a supercoiled plasmid acceptor, purified bacterially expressed ASV integrase (IN), and human high-mobility-group protein I(Y). Integration in this system is dependent upon the mini-donor DNA having IN recognition sequences at both ends and upon both ends of the same donor integrating into the acceptor DNA. The integrated DNA product exhibits all of the features associated with integration of viral DNA in vivo (P. Hindmarsh et al., J. Virol., 73:2994-3003, 1999). Individual integrants are isolated from bacteria containing drug-resistant markers with amber mutations. This system was used to evaluate the importance of sequences in the terminal U5 and U3 long terminal repeats at positions 5 and/or 6, adjacent to the conserved CA dinucleotide. Base-pair substitutions introduced at these positions in U5 result in significant reductions in recovered integrants from bacteria, due to increases in one-ended insertion events. Among the recovered integrants from reactions with mutated U5 but not U3 IN recognition sequences were products that contain large deletions in the acceptor DNA. Base-pair substitutions at positions 5 and 6 in U3 mostly reduce the efficiency of integration of the modified donor. Together, these results indicate that sequences directly 5' to the conserved CA dinucleotide are very important for the process of concerted DNA integration. Furthermore, IN interacts with U3 and U5 termini differently, and aberrant end-processing events leading to nonconcerted DNA integration are more common in U5 than in U3.

Modeling the late steps in HIV-1 retroviral integrase-catalyzed DNA integration

Model oligodeoxyribonucleotide substrates representing viral DNA integration intermediates with a gap and a two-nucleotide 5' overhang were used to examine late steps in human immunodeficiency virus, type 1 (HIV-1) retroviral integrase (IN)-catalyzed DNA integration in vitro. HIV-1 or avian myeloblastosis virus reverse transcriptase (RT) were capable of quantitatively filling in the gap to create a nicked substrate but did not remove the 5' overhang. HIV-1 IN also failed to remove the 5' overhang with the gapped substrate. However, with a nicked substrate formed by RT, HIV-1 IN removed the overhang and covalently closed the nick in a disintegration-like reaction. The efficiency of this closure reaction was very low. Such closure was not stimulated by the addition of HMG-(I/Y), suggesting that this protein only acts during the early processing and joining reactions. Addition of Flap endonuclease-1, a nuclease known to remove 5' overhangs, abolished the closure reaction catalyzed by IN. A series of base pair inversions, introduced into the HIV-1 U5 long terminal repeat sequence adjacent to and/or including the conserved CA dinucleotide, produced no or only a small decrease in the HIV-1 IN-dependent strand closure reaction. These same mutations caused a significant decrease in the efficiency of concerted DNA integration by a modified donor DNA in vitro, suggesting that recognition of the ends of the long terminal repeat sequence is required only in the early steps of DNA integration. Finally, a combination of HIV-1 RT, Flap endonuclease-1, and DNA ligase is capable of quantitatively forming covalently closed DNA with these model substrates. These results support the hypothesis that cellular enzyme(s) may catalyze the late steps of retroviral DNA integration.

Both the structure and DNA binding function of the barrier-to-autointegration factor contribute to reconstitution of HIV type 1 integration in vitro

Retroviral integration is mediated by viral preintegration complexes (PICs), and human immunodeficiency virus type 1 (HIV-1) PICs treated with high salt lose their in vitro integration activity. Barrier-to-autointegration factor (BAF) is a host protein that efficiently restores PIC activity, but the mechanism(s) by which BAF participates in HIV-1 integration remains largely unknown. Here we developed a gel shift assay to study BAF DNA binding, and analyzed 14 mutant proteins containing substitutions of conserved residues for binding and PIC reconstitution activities. Although wild-type BAF efficiently bound double-stranded DNA, binding to single-stranded DNA, RNA, or an RNA/DNA hybrid was not detected, suggesting that BAF associates with retroviral cDNA relatively late during reverse transcription. Although some of the BAF mutant proteins efficiently bound DNA, others were defective for binding. Mutants that bound DNA efficiently reconstituted HIV-1 integration, even though in one case binding was just 0.2% of wild-type BAF. Although misfolded mutants did not reconstitute integration, a structurally intact DNA binding-defective mutant displayed partial activity at high BAF concentration. We therefore conclude that both BAF protein structure and its DNA binding activity play roles in reconstituting HIV-1 integration in vitro.

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.

Repair of gaps in retroviral DNA integration intermediates

Diverse mobile DNA elements are believed to pirate host cell enzymes to complete DNA transfer. Prominent examples are provided by retroviral cDNA integration and transposon insertion. These reactions initially involve the attachment of each element 3' DNA end to staggered sites in the host DNA by element-encoded integrase or transposase enzymes. Unfolding of such intermediates yields DNA gaps at each junction. It has been widely assumed that host DNA repair enzymes complete attachment of the remaining DNA ends, but the enzymes involved have not been identified for any system. We have synthesized DNA substrates containing the expected gap and 5' two-base flap structure present in retroviral integration intermediates and tested candidate enzymes for the ability to support repair in vitro. We find three required activities, two of which can be satisfied by multiple enzymes. These are a polymerase (polymerase beta, polymerase delta and its cofactor PCNA, or reverse transcriptase), a nuclease (flap endonuclease), and a ligase (ligase I, III, or IV and its cofactor XRCC4). A proposed pathway involving retroviral integrase and reverse transcriptase did not carry out repair under the conditions tested. In addition, prebinding of integrase protein to gapped DNA inhibited repair reactions, indicating that gap repair in vivo may require active disassembly of the integrase complex.

Retroviral cDNA integration: stimulation by HMG I family proteins

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

High-mobility-group protein I can modulate binding of transcription factors to the U5 region of the human immunodeficiency virus type 1 proviral promoter

HMG I/Y appears to be a multifunctional protein that relies on in its ability to interact with DNA in a structure-specific manner and with DNA, binding transcriptional activators via distinct protein-protein interaction surfaces. To investigate the hypothesis that HMG I/Y may have a role in human immunodeficiency virus type 1 (HIV-1) expression, we have analyzed whether HMG I/Y interacts with the 5' long terminal repeat and whether this interaction can modulate transcription factor binding. Using purified recombinant HMG I, we have identified several high-affinity binding sites which overlap important transcription factor binding sites. One of these HMG I binding sites coincides with an important binding site for AP-1 located downstream of the transcriptional start site, in the 5' untranslated region at the boundary of a positioned nucleosome. HMG I binding to this composite site inhibits the binding of recombinant AP-1. Consistent with this observation, using nuclear extracts prepared from Jurkat T cells, we show that HMG I (but not HMG Y) is strongly induced upon phorbol myristate acetate stimulation and this induced HMG I appears to both selectively inhibit the binding of basal DNA-binding proteins and enhance the binding of an inducible AP-1 transcription factor to this AP-1 binding site. We also report the novel finding that a component present in this inducible AP-1 complex is ATF-3. Taken together, these results argue that HMG I may play a fundamental role in HIV-1 expression by determining the nature of transcription factor-promoter interactions.

The Brf and TATA-binding protein subunits of the RNA polymerase III transcription factor IIIB mediate position-specific integration of the gypsy-like element, Ty3

Ty3 integrates into the transcription initiation sites of genes transcribed by RNA polymerase III. It is known that transcription factors (TF) IIIB and IIIC are important for recruiting Ty3 to its sites of integration upstream of tRNA genes, but that RNA polymerase III is not required. In order to investigate the respective roles of TFIIIB and TFIIIC, we have developed an in vitro integration assay in which Ty3 is targeted to the U6 small nuclear RNA gene, SNR6. Because TFIIIB can bind to the TATA box upstream of the U6 gene through contacts mediated by TATA-binding protein (TBP), TFIIIC is dispensable for in vitro transcription. Thus, this system offers an opportunity to test the role of TFIIIB independent of a requirement of TFIIIC. We demonstrate that the recombinant Brf and TBP subunits of TFIIIB, which interact over the SNR6 TATA box, direct integration at the SNR6 transcription initiation site in the absence of detectable TFIIIC or TFIIIB subunit B". These findings suggest that the minimal requirements for pol III transcription and Ty3 integration are very similar.

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.