Unraveling retrovirus integration

Crystal structures of oligonucleotides including the integrase processing site of the Moloney murine leukemia virus

In the first step of retroviral integration, integrase cleaves the linear viral DNA within its long terminal repeat (LTR) immediately 3′ to the CA dinucleotide step, resulting in a reactive 3′ OH on one strand and a 5′ two base overhang on the complementary strand. In order to investigate the structural properties of the 3′ end processing site within the Moloney murine leukemia virus (MMLV) LTR d(TCTTTCATT), a host-guest crystallographic method was employed to determine the structures of four self-complementary 16 bp oligonucleotides including LTR sequences (underlined), d(TTTCATTGCAATGAAA), d(CTTTCATTAATGAAAG), d(TCTTTCATATGAAAGA) and d(CACAATGATCATTGTG), the guests, complexed with the N-terminal fragment of MMLV reverse transcriptase, the host. The structures of the LTR-containing oligonucleotides were compared to those of non-LTR oligonucleotides crystallized in the same lattice. Properties unique to the CA dinucleotide step within the LTR sequence, independent of its position from the end of the duplex, include a positive roll angle and negative slide value. This propensity for the CA dinucleotide step within the MMLV LTR sequence to adopt only positive roll angles is likely influenced by the more rigid, invariable 3′ and 5′ flanking TT dinucleotide steps and may be important for specific recognition and/or cleavage by the MMLV integrase.

Functional oligomeric state of avian sarcoma virus integrase

Retroviral integrase, one of only three enzymes encoded by the virus, catalyzes the essential step of inserting a DNA copy of the viral genome into the host during infection. Using the avian sarcoma virus integrase, we demonstrate that the enzyme functions as a tetramer. In presteady-state active site titrations, four integrase protomers were required for a single catalytic turnover. Volumetric determination of integrase-DNA complexes imaged by atomic force microscopy during the initial turnover additionally revealed substrate-induced assembly of a tetramer. These results suggest that tetramer formation may be a requisite step during catalysis with ramifications for antiviral design strategies targeting the structurally homologous human immunodeficiency virus, type 1 (HIV-1) integrase.

Characterization of the self association of Avian sarcoma virus integrase by analytical ultracentrifugation

Retroviral integration protein (IN) has been shown to be both necessary and sufficient for the integration of reverse-transcribed retroviral DNA into the host cell DNA. It has been demonstrated that self-assembly of IN is essential for proper function. Analytical ultracentrifugation was used to determine the stoichiometry and free energy of self-association of a full-length IN in various solvents at 23.3 degrees C. Below 8% glycerol, an association stoichiometry of monomer-dimer-tetramer is observed. At salt concentrations above 500 mM, dimer is the dominant species over a wide range of protein concentrations. However, as physiological salt concentrations are approached, tetramer formation is favored. The addition of glycerol to 500 mM NaCl, 20 mM Tris (pH 8.4), 2 mM beta-mercaptoethanol significantly enhances dimer formation with little effect on tetramer formation. Furthermore, as electrostatic shielding is increased by increasing the ionic strength or decreasing the cation size, dimer formation is strengthened while tetramer formation is weakened. Taken together, the data support a model in which dimer formation includes favorable buried surface interactions which are opposed by charge-charge repulsion, while favorable electrostatic interactions contribute significantly to tetramer formation.

The regional integration of retroviral sequences into the mosaic genomes of mammals

We have reviewed here three sets of data concerning the integration of retroviral sequences in the mammalian genome: (i) our experimental localization of a number of proviruses integrated in isochores characterized by different GC levels; (ii) results from other laboratories on the localization of retroviral sequences in open chromatin regions and/or next to CpG islands; and (iii) our compositional analysis of genes located in the neighborhood of integrated retroviral sequences. The three sets of data have provided a very consistent picture in that a compartmentalized, isopycnic integration of expressed proviruses appears to be the rule ('isopycnic' refers to the compositional match between viral and host sequences around the integration site). The results reviewed here suggest that: (i) integration of proviral sequences is targeted initially towards 'open chromatin regions'; while these exist in both GC-rich and GC-poor isochores, the 'open chromatin regions' of GC-rich isochores are the main targets for integration of retroviral sequences because of their much greater abundance; (ii) isopycnicity is associated with stability of integration; indeed, even non-expressed integrated retroviral sequences tend to show an isopycnic localization in the genome; (iii) transcription of integrated viral sequences (like transcription of host genes) appears to be associated, as a rule, with an isopycnic localization, as indicated by transcribed sequences that show an isopycnic integration and act in trans; (iv) selection plays a role in the choice of specific sites within an isopycnic region; in exceptional cases [such as mouse mammary tumor virus (MMTV) activating GC-rich oncogenes], selection may override isopycnicity.

Micromorphology of cytoplasmic nucleoprotein complexes harboring an extrachromosomal DNA closely related to avian myeloblastosis virus core-bound DNA

Nucleoprotein (NP) complexes constituting the three basic components (A, B, C) of the postmicrosomal sediment (POMS) of chicken leukemic myeloblasts (CHLMs) which contain extrachromosomal DNA closely related to avian myeloblastosis virus DNA were analyzed electron microscopically. It was shown that these NP complexes resemble micromorphologically, depending on the origin of their POMS components, NP structures involved in three successive stages of early DNA synthesis. Nucleic acids harbored in these NP complexes exhibited micromorphological features typical for replicative structures. It was confirmed electron microscopically that the extrachromosomal DNA of CHLMs replicative in nature and of three length classes is organized into special NP complexes, each of which, as demonstrated, represents a unique reaction machinery of early DNA synthesis.

A rapid and quantitative assay for inhibition of 3' cleavage activity of HIV-1 integrase

The human immunodeficiency virus-1 (HIV-1) integrase catalyzes the specific removal of two nucleotides at either 3' end of each long terminal repeat (LTR) sequence of the proviral DNA duplex. The most commonly used in vitro assays for integrase employ 5' end 32P-labeled double-stranded oligonucleotides and the product of integrase-associated endonuclease activity is visualized by denaturing gel electrophoresis followed by autoradiography. We report here a simple assay system based upon the liberation of [35S]GT dinucleotide from the 3' end of a double-stranded U5 LTR sequence derived from HIV-1. The uncleaved labeled substrate and the unlabeled large product are removed by adsorption to polyethyleneimine cellulose followed by centrifugation. The small labeled GT dinucleotide product released in the supernatant is quantitated in terms of counts released as a function of time. Since the method is rapid and quantitative, it should be useful in the kinetic evaluation of inhibitors of the 3' cleavage activity of HIV-1 integrase.

Unintegrated bovine leukemia virus DNA: association with viral expression and disease

The correlation between bovine leukemia virus (BLV) unintegrated DNA, viral expression, and stage of disease was determined in cattle naturally infected with BLV. The concomitant presence of unintegrated BLV DNA with viral transcriptional activity was observed in 53% (18 of 34) of hematologically normal, BLV-seropositive cattle and in 100% (10 of 10) of BLV-seropositive cattle with the preneoplastic syndrome persistent lymphocytosis. In vitro studies suggested that accumulation of unintegrated BLV DNA resulted from a process of reinfection rather than intracellular reverse transcription of newly synthesized BLV RNA. Interestingly, unintegrated BLV DNA was not detected in tumor cells from cattle with BLV-associated lymphocytic leukemia/malignant lymphoma despite viral transcriptional activity in 100% (eight of eight) of these cattle. Thus, the presence of unintegrated BLV DNA differentiated nonneoplastic from neoplastic conditions in BLV-infected cattle. These results demonstrate that unintegrated viral DNA serves as a marker of disease progression in BLV-infected cattle but is not necessarily associated with induction or maintenance of the neoplastic state.

Efficient retroviral infection of mammalian cells is blocked by inhibition of poly(ADP-ribose) polymerase activity

Integration of proviral DNA into the host cell genome is a characteristic feature of the retroviral life cycle. This process involves coordinate DNA strand break formation and rejoining reactions. The full details of the integration process are not yet fully understood. However, the endonuclease and DNA strand-joining activities of the virus-encoded integrase protein (IN) are thought to act in concert with other, as-yet-unidentified, endogenous nuclear components which are involved in the DNA repair process. The nuclear enzyme poly(ADP-ribose) polymerase (PARP), which is dependent on DNA strand breaks for its activity, is involved in the efficient repair of DNA strand breaks, and maintenance of genomic integrity, in nucleated eukaryotic cells. In the present work, we examine the possible involvement of PARP in the retroviral life cycle and demonstrate that inhibition of PARP activity, by any one of three independent mechanisms, blocks the infection of mammalian cells by recombinant retroviral vectors. This requirement for PARP activity appears to be restricted to processes involved in the integration of provirus into the host cell DNA. PARP inhibition does not affect viral entry into the host cell, reverse transcription of the viral RNA genome, postintegration synthesis of viral gene products, synthesis of the viral RNA genome, or the generation of infective virions. Therefore, efficient retroviral infection of mammalian cells is blocked by inhibition or PARP activity.

Zinc stimulates Mg2+-dependent 3'-processing activity of human immunodeficiency virus type 1 integrase in vitro

Human immunodeficiency virus type 1 integrase (HIV-1 IN) catalyzes both 3'-donor processing and strand transfer reactions. Previous studies have determined that the N-terminal region, a putative zinc finger, is capable of binding Zn2+. The function of zinc coordination to this domain, however, is still unknown. In this report, we present evidence that Mg2+-dependent 3'-donor processing by HIV-1 IN is enhanced by the addition of Zn2+ in vitro. This activity is inhibited in the presence of the chelator 1,10-phenanthroline (OP). In addition, the Mg2+-dependent 3'-donor processing activity is more sensitive to the concentration of IN than is the Mn2+-dependent activity. A combination of dimethyl sulfoxide (DMSO) and poly(ethylene glycol) (PEG) was found to further activate the Mg2+-dependent 3'-donor processing activity while diminishing the Mn2+-dependent activity. These results suggest factors such as substrate-length, concentration of IN, Zn2+ coordination, and protein-protein interactions are important for efficient and specific donor processing activity with Mg2+ in vitro.

Sequences in the human immunodeficiency virus type 1 U3 region required for in vivo and in vitro integration

A series of mutants with alterations in the U3 region of the human immunodeficiency virus type 1 long terminal repeat were made, and the effects of these mutations were evaluated both in vitro and in vivo. When the subterminal 6 to 8 nucleotides of the U3 long terminal repeat were mutated, the resulting provirus was unable to efficiently replicate in vivo, and a mutant oligonucleotide which mimicked the mutation could not be efficiently cleaved but could be joined to target DNA by wild-type recombinant integrase protein in vitro. These results suggest that this region is important in the specific recognition of the viral DNA by the integrase protein.

Characterization of recombinant murine leukemia virus integrase

Retroviral integration involves two DNA substrates that play different roles. The viral DNA substrate is recognized by virtue of specific nucleotide sequences near the end of a double-stranded DNA molecule. The target DNA substrate is recognized at internal sites with little sequence preference; nucleosomal DNA appears to be preferred for this role. Despite this apparent asymmetry in the sequence, structure, and roles of the DNA substrates in the integration reaction, the existence of distinct binding sites for viral and target DNA substrates has been controversial. In this report, we describe the expression in Escherichia coli and purification of Moloney murine leukemia virus integrase as a fusion protein with glutathione S-transferase, characterization of its activity by using several model DNA substrates, and the initial kinetic characterization of its interactions with a model viral DNA substrate. We provide evidence for functionally and kinetically distinct binding sites for viral and target DNA substrates and describe a cross-linking assay for DNA binding at a site whose specificity is consistent with the target DNA binding site.

Juxtaposition of two viral DNA ends in a bimolecular disintegration reaction mediated by multimers of human immunodeficiency virus type 1 or murine leukemia virus integrase

Integration of retroviral DNA involves a coordinated joining of the two ends of a viral DNA molecule into precisely spaced sites on target DNA. In this study, we designed an assay that requires two separate oligonucleotides to be brought together via interactions between integrase promoters to form a "crossbones" substrate that mimics the integration intermediate. The crossbones substrate contains two viral DNA ends, each joined to one strand of target DNA and separated by a defined length of target DNA. We showed that purified integrases of human immunodeficiency virus type 1 (HIV-1) and murine leukemia virus (MLV) could mediate a concerted strand cleavage-ligation between the two half-substrates at one or both viral DNA joining sites (trans disintegration). Another major product, termed fold-back, resulted from an intramolecular attack on the phosphodiester bond at the viral-target DNA junction by the 3'-OH group of the same DNA molecule (cis disintegration). The activity of integrase on the crossbones substrate depended on the presence of viral DNA sequences. For trans disintegration, the optimal length of target DNA between the viral DNA joining sites of the crossbones substrate corresponded to the spacing between the staggered joints formed on two opposite strands of target DNA during retroviral DNA integration in vivo. The activity of integrases on crossbones did not require complementary base pairing between the two half-substrates, indicating that the half-substrates were juxtaposed solely through protein-DNA interactions. The crossbones assay, therefore, measures the ability of integrase to juxtapose two viral DNA ends, an activity which heretofore has been difficult to detect by using purified integrase in conventional assays. Certain mutant integrases that were otherwise inactive with the crossbones substrate could complement one another, indicating that no single protomer in the integrase multimer requires a complete set of functional domains either for catalytic activity or for juxtaposition of the two viral DNA ends by the active multimer.

Protection of retroviral DNA from autointegration: involvement of a cellular factor

An essential step in the retrovirus life cycle is integration of a DNA copy of the viral genome into a host chromosome. After reverse transcription, there can be a delay of many hours before the viral DNA is integrated. It is important for the retrovirus to ensure that the viral DNA does not integrate into itself during this period; such autointegration is a suicidal process that would result in destruction of the viral genome. Understanding of the mechanism that blocks autointegration of the viral DNA may lead to insights into how to inhibit viral replication by inducing the viral DNA to autointegrate. Evidence is presented in this report that viral nucleoprotein complexes isolated from cells infected with Moloney murine leukemia virus exhibit a barrier to autointegration. The barrier can be disrupted by high salt treatment and, subsequently, restored by addition of factors provided by a host cell extract. Our data indicate an involvement of host machinery in protecting retroviral DNA from autointegration.

Formation of a stable complex between the human immunodeficiency virus integrase protein and viral DNA

The integrase (IN) protein of the human immunodeficiency virus (HIV) mediates two distinct reactions: (i) specific removal of two nucleotides from the 3' ends of the viral DNA and (ii) integration of the viral DNA into target DNA. Although IN discriminates between specific (viral) DNA and nonspecific DNA in physical in vitro assays, a sequence-specific DNA-binding domain could not be identified in the protein. A nonspecific DNA-binding domain, however, was found at the C terminus of the protein. We examined the DNA-binding characteristics of HIV-1 IN, and found that a stable complex of IN and viral DNA is formed in the presence of Mn2+. The IN-viral DNA complex is resistant to challenge by an excess of competitor DNA. Stable binding of IN to the viral DNA requires that the protein contains an intact N-terminal domain and active site (in the central region of the protein), in addition to the C-terminal DNA-binding domain.

In vitro integration of retrotransposon Ty1: a direct physical assay

Retrotransposon Ty1 of Saccharomyces cerevisiae inserts a double-stranded Ty1 cDNA into the yeast genome by a reaction analogous to the integration mechanism used by retroviruses. A quantitative in vitro integration assay that directly detects integrative recombination products was developed for Ty1. Blunt-ended artificial radioactive substrates bearing Ty1 termini integrate into circular or linear target DNAs. The reaction is specific for native integrase isolated in the form of virus-like particles; virus-like particles prepared from integrase mutants were completely inactive in this assay. The products are radioactive, allowing direct detection after gel electrophoresis by autoradiography. Using this simple and amenable system, we characterized the biochemical requirements of the system and the structures of the major integration products. Two classes of products were detected: those that were the result of bona fide complete integration events (concerted reactions) and single-end joinings of substrate to target (half-reactions). Additionally, we used a genetic selection scheme to identify and characterize target sites of complete integration events into a circular target plasmid; a 5-bp target site duplication flanking the inserted DNA resembling the duplication characteristic of in vivo integration was observed.

In vitro integration of retrotransposon Ty1: a direct physical assay

Retrotransposon Ty1 of Saccharomyces cerevisiae inserts a double-stranded Ty1 cDNA into the yeast genome by a reaction analogous to the integration mechanism used by retroviruses. A quantitative in vitro integration assay that directly detects integrative recombination products was developed for Ty1. Blunt-ended artificial radioactive substrates bearing Ty1 termini integrate into circular or linear target DNAs. The reaction is specific for native integrase isolated in the form of virus-like particles; virus-like particles prepared from integrase mutants were completely inactive in this assay. The products are radioactive, allowing direct detection after gel electrophoresis by autoradiography. Using this simple and amenable system, we characterized the biochemical requirements of the system and the structures of the major integration products. Two classes of products were detected: those that were the result of bona fide complete integration events (concerted reactions) and single-end joinings of substrate to target (half-reactions). Additionally, we used a genetic selection scheme to identify and characterize target sites of complete integration events into a circular target plasmid; a 5-bp target site duplication flanking the inserted DNA resembling the duplication characteristic of in vivo integration was observed.

Insertional mutagenesis in transgenic mice

Increasing numbers of transgenic mouse lines have resulted in several dozens of mutants created by insertional mutagenesis. The advantages of different vector systems and the problems associated with the analysis of mutations and the cloning of the affected genes are discussed in this review.

Substrate features important for recognition and catalysis by human immunodeficiency virus type 1 integrase identified by using novel DNA substrates

The integrase encoded by human immunodeficiency virus type 1 (HIV-1) is required for integration of viral DNA into the host cell chromosome. In vitro, integrase mediates a concerted cleavage-ligation reaction (strand transfer) that results in covalent attachment of viral DNA to target DNA. With a substrate that mimics the strand transfer product, integrase carries out disintegration, the reverse of the strand transfer reaction, resolving this integration intermediate into its viral and target DNA parts. We used a set of disintegration substrates to study the catalytic mechanism of HIV-1 integrase and the interaction between the protein and the viral and target DNA sequence. One substrate termed dumbbell consists of a single oligonucleotide that can fold to form a structure that mimics the integration intermediate. Kinetic analysis using the dumbbell substrate showed that integrase turned over, establishing that HIV-1 integrase is an enzyme. Analysis of the disintegration activity on the dumbbell substrate and its derivatives showed that both the viral and target DNA parts of the molecule were required for integrase recognition. Integrase recognized target DNA asymmetrically: the target DNA upstream of the viral DNA joining site played a much more important role than the downstream target DNA in protein-DNA interaction. The site of transesterification was determined by both the DNA sequence of the viral DNA end and the structure of the branched substrate. Using a series of disintegration substrates with various base modifications, we found that integrase had relaxed structural specificity for the hydroxyl group used in transesterification and could tolerate distortion of the double-helical structure of these DNA substrates.

HIV-1 integrase blocks infection of bacteria by single-stranded DNA and RNA bacteriophages

Expression of human immunodeficiency virus-1 integrase in Escherichia coli, at levels that had no effect on bacterial cell growth, blocked plaque formation by bacteriophages having single-stranded genomic DNA (M13) or RNA (R17, Q beta, PRR1). Plaque formation by phages having double-stranded genomic DNA (T4, PR4) was unaffected. Integrase also inhibited infection by the phagemid M13KO7, but it had no effect on production of phage once infection by M13KO7 was established. This result indicated that integrase affects an early stage in infection. Integrase also inhibited phage production following transfection by either single-stranded or double-stranded (replicative form) M13 DNA, it blocked M13 DNA replication, as assayed by incorporation of radioactive nucleotides into DNA, and it failed to affect bacterial pilus function. These data suggest that integrase interacts in vivo with phage nucleic acid, a conclusion supported by studies in which integrase was shown to have a DNA-binding activity in its C-terminal portion. This portion of integrase was both necessary and sufficient for interference of plaque formation by M13 in the present study. Expression of the N-terminal portion of integrase at the same level as intact integrase had little effect on phage growth, indicating that expression of foreign protein in general was not responsible for the inhibitory effect. The simple bacteriophage assay described is potentially useful for identifying integrase mutants that lack single-stranded DNA binding activity.

Activities of the feline immunodeficiency virus integrase protein produced in Escherichia coli

Retroviral DNA integration requires the activity of at least one viral protein, the integrase (IN) protein. We cloned and expressed the integrase gene of feline immunodeficiency virus (FIV) in Escherichia coli as a fusion to the malE gene and purified the IN fusion protein by affinity chromatography. The protein is active in site-specific cleavage of the viral DNA ends, DNA strand transfer, and disintegration. FIV IN has a relaxed viral DNA substrate requirement: it cleaves and integrates FIV DNA termini, human immunodeficiency virus DNA ends, and Moloney murine leukemia virus DNA ends with high efficiencies. In the cleavage reaction, IN exposes a specific phosphodiester bond near the viral DNA end to nucleophilic attack. In vitro, either H2O, glycerol, or the 3' OH group of the viral DNA terminus can serve as nucleophile in this reaction. We found that FIV IN preferentially uses the 3' OH ends of the viral DNA as nucleophile, whereas HIV IN protein preferentially uses H2O and glycerol as nucleophiles.

Molecular mechanism of retroviral DNA integration

The integration of retroviral DNA appears to be obligatory for the efficient replication of retroviruses in their respective host cells. During a natural infection, integration takes place in a process that includes biochemically and temporally discrete steps. These are: (1) the removal of two nucleotides from the 3' ends of newly synthesized linear viral DNA in the host cell cytoplasm; (2) transport of the trimmed viral DNA to the nucleus within a viral protein/DNA complex; and (3) insertion of the viral DNA into host cell DNA via a concerted cleavage and ligation reaction. The cleavage of viral DNA and its subsequent joining to host DNA are catalyzed by the retroviral enzyme, integrase (IN). Elucidation of the mechanistic details of these catalytic activities of IN has relied heavily upon the use of relatively simple in vitro assays which recapitulate the in vivo reactions. These assays and the information derived from them should also facilitate the search for potential inhibitors of IN with the ultimate goal of providing a means to halt retroviral infections, such as that which causes the acquired immunodeficiency syndrome (AIDS), effectively.

Rapid solution assays for retroviral integration reactions and their use in kinetic analyses of wild-type and mutant Rous sarcoma virus integrases

A rapid method for quantitating products of the oligodeoxynucleotide processing reaction in vitro has been developed to facilitate enzymatic studies of the retroviral integrases. Unlike earlier procedures, this assay does not depend on polyacrylamide gel electrphoresis but separates products by batch adsorption to PEI-cellulose. A joining assay has also been modified, to facilitate measurement of the two distinct steps in the integration reaction under parallel conditions. Since these methods allow quantitation of numerous samples in a short period of time, they are especially useful for investigation of kinetic parameters and to measure the effects of possible inhibitors of integrase. These assay systems were used to examine the enzymatic activity of wild-type Rous sarcoma virus integrase and selected mutant proteins with substitutions of single conserved amino acids. In contrast to previous studies, reactions were performed under conditions of substrate excess, and rates, rather than yields of product generated after a given period of incubation, were determined. The results showed that substitutions of several highly conserved residues in what is most likely an evolutionarily conserved catalytic domain of the integrases resulted in a 4- to 10-fold decrease in the apparent rate of processing relative to wild type, under optimized standard conditions. Changing an invariant acidic residue reduced the rate by approximately 60-fold. When joining activity was determined, the relative effects of the substitutions tested generally paralleled the results with processing. However, with both wild-type and mutant integrase proteins, the linear phase of the joining reaction was preceded by what appears to be an exponential "burst" phase.

Transcription termination and polyadenylation in retroviruses

The provirus structure of retroviruses is bracketed by long terminal repeats (LTRs). The two LTRs (5' and 3') are identical in nucleotide sequence and organization. They contain signals for transcription initiation as well as termination and cleavage polyadenylation. As in eukaryotic pre-mRNAs, the two common signals, the polyadenylation signal, AAUAAA, or a variant AGUAAA, and the G+U-rich sequence are present in all retroviruses. However, the AAUAAA sequence is present in the U3 region in some retroviruses and in the R region in other retroviruses. As in animal cell RNAs, both AAUAAA and G+U-rich sequences apparently contribute to the 3'-end processing of retroviral RNAs. In addition, at least in a few cases examined, the sequences in the U3 region determine the efficiency of 3'-end processing. In retroviruses in which the AAUAAA is localized in the R region, the poly(A) signal in the 3' LTR but not the 5' LTR must be selectively used for the production of genomic RNA. It appears that the short distance between the 5' cap site and polyadenylation signal in the 5' LTR precludes premature termination and polyadenylation. Since 5' and 3' LTRs are identical in sequence and structural organization yet function differently, it is speculated that flanking cellular DNA sequences, chromatin structure, and binding of transcription factors may be involved in the functional divergence of 5' and 3' LTRs of retroviruses.

Endonucleolytic cleavages and DNA-joining activities of the integration protein of human foamy virus

The bacterial expression plasmids, pET3b and pET16b, that contain the integrase domain of the human foamy virus (HFV) reverse transcriptase were constructed and expressed in Escherichia coli. The histidine-tagged HFV IN protein was purified to near homogeneity by single-step Ni2+ chelate affinity chromatography. HFV-specific proteins of 39 and 120 kDa from virus-infected cells reacted with antisera raised against the recombinant IN protein. Purified recombinant HFV IN protein was active as an endonuclease specifically cleaving two nucleotides from a 20-bp oligodeoxynucleotide substrate that mimics the authentic 5' ends of HFV DNA. Substrates with mutations relatively close to the cleavage site were less efficiently cleaved or not cleaved at all compared with the HFV U5 DNA end. The purified recombinant protein was active as integrase with double-stranded oligodeoxynucleotide substrates. The reverse reaction of DNA strand transfer, the disintegration activity, was shown by efficient cleavage of an intermediate Y-shaped oligodeoxynucleotide. In the presence of Mn2+ as the preferred divalent cation, oligodeoxynucleotides were specifically and efficiently cleaved. In contrast, endonucleolytic cleavages in the presence of Mg2+ ions led to a broad range of reaction products with the His-tagged HFV IN protein. After further purification of the HFV IN by cation-exchange chromatography, the unspecific degradation of oligonucleotide substrate in the presence of Mg2+ was not detectable.

BARE-1, a copia-like retroelement in barley (Hordeum vulgare L.)

Retroviruses and retrotransposons make up the broad class of retroelements replicating and transposing via reverse transcriptase. Retroelements have recently been found to be ubiquitous in the plants. We report here the isolation, sequence and analysis of a retroelement from barley (Hordeum vulgare L.) with all the features of a copia-like retrotransposon. This is named BARE-1 (for BArley RetroElement 1), the first such element described for barley. BARE-1 is 12,088 bp, with long terminal repeats (LTRs) of 1829 bp containing perfect 6 bp inverted repeats at their ends and flanked by 4 bp direct repeats in the host DNA. Between the long terminal repeats is an internal domain with a derived amino acid sequence of 1285 residues, bearing homology to the gag, pro, int and rt domains of retroviruses and both plant and non-plant copia-like retrotransposons. Cultivated barley contains about 5000 elements in the genome similar to the BARE-1 putative gag domain, but ten-fold more hybridizing to rt or LTR probes. The particular BARE-1 element reported here appears to be inactive, as the putative protein-coding domain is interrupted by four stop codons and a frameshift. In addition, the 3' LTR is 4% divergent from the 5' LTR and contains a 3135 bp insertion. Nevertheless, we have recently detected transcripts hybridizing to BARE-1 on northern blots, presumably from active copies. Analysis of BARE-1 expression and function in barley is currently underway.

Characterization of a DNA binding domain in the C-terminus of HIV-1 integrase by deletion mutagenesis

The integrase (IN) protein of human immunodeficiency virus type 1 (HIV-1) catalyzes site-specific cleavage of 2 bases from the viral long terminal repeat (LTR) sequence yet it binds DNA with little DNA sequence specificity. We have previously demonstrated that the C-terminal half of IN (amino acids 154-288) possesses a DNA binding domain. In order to further characterize this region, a series of clones expressing truncated forms of IN as N-terminal fusion proteins in E.coli were constructed and analyzed by Southwestern blotting. Proteins containing amino acids 1-263, 1-248 and 170-288 retained the ability to bind DNA, whereas a protein containing amino acids 1-180 showed no detectable DNA binding. This defines a DNA binding domain contained within amino acids 180-248. This region contains an arrangement of 9 lysine and arginine residues each separated by 2-4 amino acids (KxxxKxxxKxxxxRxxxRxxRxxxxKxxxKxxxK), spanning amino acids 211-244, which is conserved in all HIV-1 isolates. A clone expressing full-length IN with a C-terminal fusion of 16 amino acids was able to bind DNA comparably to a cloned protein with a free C-terminus, and an IN-specific monoclonal antibody which recognizes an epitope contained within amino acids 264-279 was unable to block DNA binding, supporting the evidence that a region necessary for binding lies upstream of amino acid 264.

Domains of the integrase protein of human immunodeficiency virus type 1 responsible for polynucleotidyl transfer and zinc binding

The integrase protein of human immunodeficiency virus type 1 carries out a set of polynucleotidyl transfer reactions that result in the covalent attachment of the retroviral cDNA to host DNA. We have analyzed the activities of a set of deletion derivatives of the integrase protein. The analysis reveals that a central domain of only 137 amino acids is sufficient in vitro to catalyze a subset of the reactions carried out by the complete protein. This polypeptide contains an amino acid sequence motif, Asp-Xaa39-58-Asp-Xaa35-Glu (DX39-58DX35E, where X and the subscript indicate the intervening amino acids between the invariant acidic residues), that is found in the integrases of retroviruses and retrotransposons and also the transposase proteins of some bacterial transposable elements. We also find that the integrase protein can bind Zn2+, and the histidine and cysteine residues of another conserved motif (HX3-7HX23-32CX2C) are required for efficient Zn2+ binding. The activities displayed by deletion mutants suggest to us possible functions for the various parts of integrase.

Identification of the catalytic and DNA-binding region of the human immunodeficiency virus type I integrase protein

The integrase (IN) protein of the human immunodeficiency virus (HIV) is required for specific cleavage of the viral DNA termini, and subsequent integration of the viral DNA into target DNA. To identify the various domains of the IN protein we generated a series of IN deletion mutants as fusions to maltose-binding protein (MBP). The deletion mutants were tested for their ability to bind DNA, to mediate site-specific cleavage of the viral DNA ends, and to carry out integration and disintegration reactions. We found that the DNA-binding region resides between amino acids 200 and 270 of the 288-residues HIV-1 IN protein. The catalytic domain of the protein was mapped between amino acids 50 and 194. For the specific activities of IN, cleavage of the viral DNA and integration, both the DNA-binding domain and the conserved amino-terminal region of IN are required. These regions are dispensable however, for disintegration activity.

Characterization of human immunodeficiency virus type 1 integrase expressed in Escherichia coli and analysis of variants with amino-terminal mutations

Replication of a retroviral genome depends upon integration of the viral DNA into a chromosome of the host cell. The integration reaction is mediated by integrase, a viral enzyme. Human immunodeficiency virus type 1 integrase was expressed in Escherichia coli and purified to near homogeneity. Optimum conditions for the integration and 3'-end-processing activities of integrase were characterized by using an in vitro assay with short, double-stranded oligonucleotide substrates. Mutants containing amino acid substitutions within the HHCC region, defined by phylogenetically conserved pairs of histidine and cysteine residues near the N terminus, were constructed and characterized by using three assays: 3'-end processing, integration, and the reverse of the integration reaction (or disintegration). Mutations in the conserved histidine and cysteine residues abolished both integration and processing activities. Weak activity in both assays was retained by two other mutants containing substitutions for less highly conserved amino acids in this region. All mutants retained activity in the disintegration assay, implying that the active site for DNA cleavage-ligation is not located in this domain and that the HHCC region is not the sole DNA-binding domain in the protein. However, the preferential impairment of processing and integration rather than disintegration by mutations in the HHCC region is consistent with a role for this domain in recognizing features of the viral DNA. This hypothesis is supported by the results of disintegration assays performed with altered substrates. The results support a model involving separate viral and target DNA-binding sites on integrase.

Insertional mutations in mammals and mammalian cells

The retroposon sequences, their mechanisms of transposition and the occurrence of insertional mutation in the mammalian genome are reviewed. Insertional mutations fall into two broad categories: those due to the disruption of a gene following the physical integration of a foreign DNA sequence result in loss of gene product and would be expected to be associated with a recessive mutation. A second class of insertional mutation is well documented in which upon integration the promoter/enhancer activities inherent in the retroposon genome exert their influence on neighboring genes. This promoter/enhancer activity of integrated retroposons may have effects over relatively long distances and thus limit the possibilities of establishing an association between retroposon integration and mutation. It is emphasized that a systematic search for insertional mutations in the mammalian genome involves an extensive two-dimensional array of possible retroposon sequences and mutant alleles. Present results represent only a small portion of the total array. Future studies promise to be fruitful in efforts to isolate genes through insertional tagging, to characterize the mechanisms of retroposon transposition, as well as to study the stability of the mammalian genome.

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

The integration of retroviral DNA proceeds through two steps: trimming of the termini to expose new 3' OH ends, and the transfer of those ends to the phosphates of target DNA. We have examined the ability of the Moloney murine leukemia virus integrase protein (IN) to trim the termini of the preintegrative DNA of mutant viruses with alterations in the U3 inverted repeat. The mutant terminus of one replication-defective viral DNA, containing a 7-bp deletion in the U3 inverted repeat, was not trimmed to produce the normal recessed end. Remarkably, the other terminus of this mutant DNA was also not trimmed, even though its sequence is wild type. This finding suggests that the IN protein requires the presence of two good ends before becoming properly activated to trim either one.

Characterization of a stable eukaryotic cell line expressing the Rous sarcoma virus integrase

The Rous sarcoma virus integration protein (IN) is required for efficient integration of viral DNA into the host genome. IN was expressed in mouse C127 cells using a bovine papillomavirus vector. This system utilizes the mouse metallothionein promoter and the SV40 late polyadenylation signal for efficient expression of IN. A stable cell line derived from a single hygromycin-resistant colony was characterized. The expression of IN increased significantly upon Zn2+ induction of the metallothionein promoter, but did not respond to "superinduction" protocols. Full-length nonphosphorylated IN was the major product of expression. A minor product resulting from initiation of translation at an internal Met codon was also produced. The expressed IN did not exhibit the polypeptide heterogeneity at its COOH-terminus nor phosphorylation as is seen when IN is immunoprecipitated from virions. Using subcellular fractionation and indirect immunofluorescence, IN was primarily localized to nuclei and in some cells appeared to concentrate at discrete loci within the nuclei.

The N-terminal region of HIV-1 integrase is required for integration activity, but not for DNA-binding

HIV-1 integrase binds to both double- and single-stranded DNA with Kd-values of around 20 nM, irrespective of sequence similarities with the termini of the viral LTR. For integration activity, however, the correct LTR sequence of the substrate is required. The putative zinc-binding site present at the N-terminus of the protein is not essential for DNA binding, since deletion mutants of the protein lacking this sequence show similar affinity towards DNA as the wild-type; however, these mutants are not capable of performing the LTR-cleavage and integration reactions. Thus, it appears that the N-terminal part of the integrase is essential for catalytic activity.

Identification of amino acid residues critical for endonuclease and integration activities of HIV-1 IN protein in vitro

HIV-IN protein, tagged with a hexahistidine tail was expressed in Escherichia coli and purified by a one-step nickel chelate affinity chromatography procedure. The purified IN protein was characterized in terms of its endonuclease and integrase properties in vitro. Specific cleavage and integration of HIV U5 LTR ends were observed in the presence of 2-5 mM Mg2+ or Ca2+. In the presence of 2 mM Mn2+, cleavage and integration occurred at additional sites indicating a decreased specificity. The properties of mutant IN proteins were examined in vitro. Deletion of 39 amino acids from the N-terminus and a minimum of 25 residues from the C-terminus impaired IN-mediated cleavage and integration activities. The results of site-directed mutagenesis experiments showed that residues critical for IN function are highly conserved. Mutations of conserved residues Asp64, Pro109, Asp116, and Glu152 adversely affected IN function in vitro. Mutations of nonconserved residues Gly189 and Thr112 had no effect. Mutation of a conserved Thr115 to Ala caused a near complete loss of Mg(2+)-dependent integration activity, but only partially effected endonucleolytic cleavage activity of IN. These results suggest that not all conserved residues are involved in both endonucleolytic cleavage and integration activities of HIV-IN.

Integration of human immunodeficiency virus DNA: adduct interference analysis of required DNA sites

The integration (IN) protein encoded by human immunodeficiency virus directs the integration of viral DNA into host DNA. We have probed the DNA sites required for the function of IN protein by attaching adducts to model DNA substrates and assaying their effects on integration in vitro. These experiments reveal that modifications in a short region on both DNA strands at the ends of the viral DNA block IN protein function. Modification of the target DNA near the point of DNA strand transfer also blocks IN protein function. Further experiments suggest that distinct subsets of the identified interactions are important for separate steps in the integration process.

Reversal of integration and DNA splicing mediated by integrase of human immunodeficiency virus

In retroviral integration, the viral integration protein (integrase) mediates a concerted DNA cleavage-ligation reaction in which the target DNA is cleaved and the resulting 5' ends of target DNA are joined to the 3' ends of viral DNA. Through an oligonucleotide substrate that mimics the recombination intermediate formed by this initial cleavage-ligation reaction, the purified integrase of human immunodeficiency virus was shown to promote the same reaction in reverse, a process called disintegration. Analysis of a set of structurally related substrates showed that integrase could promote a range of DNA cleavage-ligation reactions. When the viral DNA component of the disintegration substrate was single-stranded, integrase could mediate a DNA splicing reaction analogous to RNA splicing.

HIV-1 DNA integration: mechanism of viral DNA cleavage and DNA strand transfer

Retroviral DNA integration involves a coordinated set of DNA cutting and joining reactions. Linear viral DNA is cleaved at each 3' end to generate the precursor ends for integration. The resulting recessed 3' ends are inserted into target DNA by a subsequent DNA strand transfer reaction. Purified HIV-1 integration protein carries out both of these steps in vitro. Two novel forms of the dinucleotide cleaved from HIV-1 DNA were identified and one, a cyclic dinucleotide, was used to analyze the stereochemical course of viral DNA cleavage. Both viral DNA cleavage and DNA strand transfer display inversion at chiral phosphorothioates during the course of the reaction. These results suggest that both reactions occur by a one-step mechanism without involvement of a covalent protein-DNA intermediate.

trans-acting viral protease is necessary and sufficient for activation of avian leukosis virus reverse transcriptase

The structural and enzymatic components of retroviral cores are formed by proteolytic cleavage of precursor polypeptides, mediated by the viral protease (PR). We described previously the construction of PR-defective avian leukosis viruses. These mutant viruses are noninfectious, and their major internal components are the uncleaved gag and gag-pol polyproteins (Pr76gag and Pr180gag-pol). The reverse transcriptase (RT) activity associated with the PR-defective virions is approximately 500-fold reduced relative to that of wild-type virions, suggesting that specific cleavages activate RT activity. To gain a better understanding of the role that PR plays in the processing and activation of RT, we performed complementation experiments wherein wild-type or PR mutant gag precursors were separately coexpressed with frame-corrected wild-type or PR mutant gag-pol precursors. The results demonstrate that, as in other retrovirus systems, gag-pol precursors can be assembled into virions only when they are rescued by a gag precursor. If the gag precursor is wild type, then the rescued Pr180gag-pol is completely and properly matured, irrespective of whether its embedded PR domain is wild type or mutant. In both cases, the virions produced are fully and equally infectious. This indicates that an active-site mutation in the PR domain of the gag-pol precursor has no effect on avian leukosis virus infectivity when particles are assembled from wild-type gag precursors. In contrast, if the gag precursor has an active-site mutation in PR or is deleted for PR, then the virions are noninfectious and the gag and gag-pol precursors remain unprocessed, even if the embedded PR domain of Pr180gag-pol is wild type. Thus, in this system, virion-associated Pr180gag-pol displays no detectable cis- or trans-acting PR activity. As assayed with an exogenous template, virions with processed gag-pol polyprotein display high levels of RT activity while those with unprocessed Pr180gag-pol display greatly reduced RT activity. These results demonstrate that during virion assembly, the PR supplied by a gag precursor is both necessary and sufficient for trans-activation of RT through proteolytic maturation of copackaged gag-pol polyprotein.

Quiescent T lymphocytes as an inducible virus reservoir in HIV-1 infection

To better understand the basis for human immunodeficiency virus type 1 (HIV-1) persistence and latency, the form in which viral DNA exists in the peripheral T lymphocyte reservoir of infected individuals was investigated. In asymptomatic individuals, HIV-1 was harbored predominantly as full-length, unintegrated complementary DNA. These extrachromosomal DNA forms retained the ability to integrate upon T cell activation in vitro. In patients with acquired immunodeficiency syndrome (AIDS), there was an increase in integrated relative to extrachromosomal DNA forms. By analysis of DNA from patient lymphocyte subpopulations depleted of human lymphocyte antigen-Dr receptor-positive cells, quiescent T cells were identified as the source of extrachromosomal HIV-1 DNA. Thus quiescent T lymphocytes may be a major and inducible HIV-1 reservoir in infected individuals.

Development of an acid-soluble assay for measuring retrovirus integrase 3'-OH terminal nuclease activity

A quantitative and efficient assay was developed to measure the 3'-OH terminal DNA endonuclease activity of the avian myeloblastosis virus (AMV) integrase protein. A retroviral-like linearized plasmid containing long terminal repeat (LTR) sequences at its recessed 3'-OH termini was filled in and labeled with the Escherichia coli Klenow DNA polymerase fragment. The 32P-labeled nucleotide was located at the penultimate position. The labeled linearized plasmid or restriction fragments derived from it were incubated with AMV IN and release of the label was quantitated by conversion to acid-soluble counts. The structure of the released product was characterized on 23% sequencing gels. Results indicate that AMV integration protein is functioning as an endonuclease releasing a dinucleotide and that the activity is stoichiometric with a preference for the cleavage of the U3 LTR terminus over that of the U5 LTR terminus.

A rapid in vitro assay for HIV DNA integration

Retroviruses synthesize a double stranded DNA copy of their RNA genome after infection of a permissive cell and subsequent integration of this DNA copy into the host genome is necessary for normal viral replication. Integration occurs by a specialized DNA recombination reaction, mediated by the viral IN protein. Because this reaction has no known cellular counterpart, it is a particularly attractive target in the search for specific inhibitors with low toxicity that may serve as therapeutic antiviral agents. We present a simple assay system that is suitable for screening potential inhibitors of HIV DNA integration. Only short oligonucleotides matching one end of HIV DNA and purified HIV IN protein are required as substrates. Furthermore, since each step of the assay can be carried out in the wells of microtiter plates, large numbers of reactions can be processed simultaneously.

Mutational analysis of the carboxyl terminus of the Moloney murine leukemia virus integration protein

The integration protein (IN) is required for retrovirus DNA integration into the host DNA. The function of the C terminus of the Moloney murine leukemia virus IN protein was examined. The terminal 28 amino acids were found to be nonessential. A linker insertion at position 6025, within a 36-amino-acid insertion not found in any other retrovirus, also produced viable virus.

Relationship of avian retrovirus DNA synthesis to integration in vitro

An in vitro integration system derived from avian leukosis virus-infected cells supports both intra- and intermolecular integration of the viral DNA. In the absence of polyethylene glycol, intramolecular integration of viral DNA molecules into themselves (autointegration) was preferred. In the presence of polyethylene glycol, integration into an exogenously supplied DNA target was greatly promoted. Analysis of integration intermediates revealed that the strand transfer mechanisms of both reactions were identical to those of retroviruses and some transposons: each 3' end of the donor molecule is joined to a 5' end of the cleaved target DNA. The immediate integration precursor appears to be linear viral DNA with the 3' ends shortened by 2 nucleotides. Finally, in the avian system, most cytoplasmic viral DNA appears to be incomplete and further DNA synthesis is required for integration in vitro.