Analysis of mutant Moloney murine leukemia viruses containing linker insertion mutations in the 3' region of pol

Biochemical characteristics of functional domains using feline foamy virus integrase mutants

We constructed deletion mutants and seven point mutants by polymerase chain reaction to investigate the specificity of feline foamy virus integrase functional domains. Complementation reactions were performed for three enzymatic activities such as 3'-end processing, strand transfer, and disintegration. The complementation reactions with deletion mutants showed several activities for 3'-end processing and strand transfer. The conserved central domain and the combination of the N-terminal or C-terminal domains increased disintegration activity significantly. In the complementation reactions between deletion and point mutants, the combination between D107V and deletion mutants revealed 3'-end processing activities, but the combination with others did not have any activity, including strand transfer activities. Disintegration activity increased evenly, except the combination with glutamic acid 200. These results suggest that an intact central domain mediates enzymatic activities but fails to show these activities in the absence of the N-terminal or C-terminal domains.

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

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

Retroviral DNA integration--mechanism and consequences

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

Moloney murine leukemia virus integrase protein augments viral DNA synthesis in infected cells

Mutations in the IN domain of retroviral DNA may affect multiple steps of the virus life cycle, suggesting that the IN protein may have other functions in addition to its integration function. We previously reported that the human immunodeficiency virus type 1 IN protein is required for efficient viral DNA synthesis and that this function requires specific interaction with other viral components but not enzyme (integration) activity. In this report, we characterized the structure and function of the Moloney murine leukemia virus (MLV) IN protein in viral DNA synthesis. Using an MLV vector containing green fluorescent protein as a sensitive reporter for virus infection, we found that mutations in either the catalytic triad (D184A) or the HHCC motif (H61A) reduced infectivity by approximately 1,000-fold. Mutations that deleted the entire IN (DeltaIN) or 34 C-terminal amino acid residues (Delta34) were more severely defective, with infectivity levels consistently reduced by 10,000-fold. Immunoblot analysis indicated that these mutants were similar to wild-type MLV with respect to virion production and proteolytic processing of the Gag and Pol precursor proteins. Using semiquantitative PCR to analyze viral cDNA synthesis in infected cells, we found the Delta34 and DeltaIN mutants to be markedly impaired while the D184A and H61A mutants synthesized cDNA at levels similar to the wild type. The DNA synthesis defect was rescued by complementing the Delta34 and DeltaIN mutants in trans with either wild-type IN or the D184A mutant IN, provided as a Gag-IN fusion protein. However, the DNA synthesis defect of DeltaIN mutant virions could not be complemented with the Delta34 IN mutant. Taken together, these analyses strongly suggested that the MLV IN protein itself is required for efficient viral DNA synthesis and that this function may be conserved among other retroviruses.

Minimal core domain of HIV-1 integrase for biological activity

The human immunodeficiency virus type-1 (HIV-1) integrase (IN) mediates insertion of viral DNA into human DNA, which is an essential step in the viral life cycle. In order to study minimal core domain in HIV-1 IN protein, we constructed nine deletion mutants by using PCR amplification. The constructs were expressed in Escherichia coli, and the proteins were subsequently purified and analyzed in terms of biological activity such as enzymatic and DNA-binding activities. The mutant INs with an N-terminal or C-terminal deletion showed strong disintegration activity though they failed to show endonucleolytic and strand transfer activities, indicating that the disintegration reaction does not require the fine structure of the HIV-1 IN protein. In the DNA-binding analysis using gel mobility shift assay and UV cross-linking method, it was found that both the central and C-terminal domains are essential for proper DNA-IN protein interaction although the central or C-terminal domain alone was able to be in close contact with DNA substrate. Therefore, our results suggest that the C-terminal domain act as a DNA-holding motive, which leads to proper interaction for enzymatic reaction between the IN protein and DNA.

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

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

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

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

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

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

The role of manganese in promoting multimerization and assembly of human immunodeficiency virus type 1 integrase as a catalytically active complex on immobilized long terminal repeat substrates

The integration of a DNA copy of the viral genome into the genome of the host cell is an essential step in the replication of all retroviruses. Integration requires two discrete biochemical reactions; specific processing of each viral long terminal repeat terminus or donor substrate, and a DNA strand transfer step wherein the processed donor substrate is joined to a nonspecific target DNA. Both reactions are catalyzed by a virally encoded enzyme, integrase. A microtiter assay for the strand transfer activity of human immunodeficiency virus type 1 integrase which uses an immobilized oligonucleotide as the donor substrate was previously published (D. J. Hazuda, J. C. Hastings, A. L. Wolfe, and E. A. Emini, Nucleic Acids Res. 22;1121-1122, 1994). We now describe a series of modifications to the method which facilitate study of both the nature and the dynamics of the interaction between integrase and the donor DNA. The enzyme which binds to the immobilized donor is shown to be sufficient to catalyze strand transfer with target DNA substrates added subsequent to assembly; in the absence of the target substrate, the complex was retained on the donor in an enzymatically competent state. Assembly required high concentrations of divalent cation, with optimal activity achieved at 25 mM MnCl2. In contrast, preassembled complexes catalyzed strand transfer equally efficiently in either 1 or 25 mM MnCl2, indicating mechanistically distinct functions for the divalent cation in assembly and catalysis, respectively. Prior incubation of the enzyme in 25 mM MnCl2 was shown to promote the multimerization of integrase in the absence of a DNA substrate and alleviate the requirement for high concentrations of divalent cation during assembly. The superphysiological requirement for MnCl2 may, therefore, reflect an insufficiency for functional self-assembly in vitro. Subunits were observed to exchange during the assembly reaction, suggesting that multimerization can occur either before or coincident with but not after donor binding. These studies both validate and illustrate the utility of this novel methodology and suggest that the approach may be generally useful in characterizing other details of this biochemical reaction.

Genetic analysis of human immunodeficiency virus type 1 integrase and the U3 att site: unusual phenotype of mutants in the zinc finger-like domain

Retroviral integration is the step which leads to establishment of the provirus, cis- and trans-acting regions of the human immunodeficiency type 1 (HIV-1) retrovirus genome, including the attachment site (att) at the ends of the unintegrated viral DNA and the conserved domains within the integrase (IN) protein, have been identified as being important for integration. We investigated the role of each of these regions in the context of an infectious HIV-1 molecular clone through point mutagenesis of the att site and the zinc finger-like and catalytic domains of IN. The effect of each mutation on integration activity was examined by using a single-step infection system with envelope-pseudotype virus. The relative integration efficiency was estimated by monitoring the levels of viral DNA over time in the infected cells. The integration activities of catalytic domain point mutants and att site deletion mutants were estimated to be 0.5 and 5% of wild-type activity, respectively. However, in contrast with previous in vitro cell-free integration studies, alteration of the highly conserved CA dinucleotide resulted in a mutant which still retained 40% of wild-type integration activity. The relative levels of expression of each mutant, as measured by a luciferase reporter gene, correlated with levels of integration. This observation is consistent with those of previous studies indicating that integration is an obligatory step for retroviral gene expression. Interestingly, we found that three different HIV-1 constructs bearing point mutations in the zinc finger-like domain synthesized much lower levels of viral DNA after infection, suggesting impairment of these mutants before or at the initiation of reverse transcription. Western blot (immunoblot) analysis demonstrated wild-type levels of reverse transcriptase within the mutant virions. In vitro endogenous reverse transcription assays indicated that all three mutants in the zinc finger-like domain had wild-type levels of reverse transcriptase activity. These data indicate that in addition to integration, IN may have an effect on the proper course of events in the viral life cycle that precede integration.

Integrase mutants of human immunodeficiency virus type 1 with a specific defect in integration

A previous genetic analysis of the human immunodeficiency virus type 1 integrase protein failed to identify single amino acid substitutions that only block the integration of viral DNA (C.-G. Shin, B. Taddeo, W.A. Haseltine, and C.M. Farnet, J. Virol. 68:1633-1642, 1994). Additional substitutions of amino acids that are highly conserved among retroviral integrases were constructed in human immunodeficiency virus type 1 and analyzed for their effects on viral protein synthesis and processing, virion morphology, and viral DNA synthesis and integration in an attempt to identify mutants with a specific defect in integration. Four single amino acid substitutions resulted in replication defective viruses. Conservative, single amino acid substitutions of the two invariant aspartic acid residues found in all retroviral integrases prevented the integration of viral DNA and had no detectable effect on the other stages in the viral replication cycle, indicating that these mutants exhibited a specific defect in integration. Mutations at two positions, S-81 and P-109, blocked the integration of viral DNA but also resulted in the production of viral particles that exhibited reduced reverse transcriptase activity, suggesting additional defects in viral replication. Substitution of the highly conserved amino acid T66 had no effect on viral replication in a CD4+ human T-cell line. This analysis extends the range of possible phenotypes that may be produced by single amino acid substitutions in conserved residues of the integrase protein.

Human immunodeficiency virus type 1 integrase: effect on viral replication of mutations at highly conserved residues

Sequence comparisons of the integrase (IN) proteins from different retroviruses have identified several highly conserved residues. We have introduced mutations at 16 of these sites into the integrase gene of human immunodeficiency virus type 1 and analyzed the phenotypes of the resulting viruses. The viruses were all normal for p24 content and reverse transcriptase activity. In addition, all of the mutants could infect T-cell lines and undergo reverse transcription, as assessed by PCR analysis. Most of the mutant viruses also had normal Western blot (immunoblot) profiles, although three of the mutations resulted in reduced signals for IN relative to the wild type on the immunoblots and mutation of residue W235 completely abolished recognition of the protein by pooled sera from human immunodeficiency virus type 1-positive patients. Mutations that have previously been shown to abolish activity in in vitro studies produced noninfectious viruses. The substitution of W235 was notable in producing a noninfectious virus, despite previous reports of this residue being nonessential for IN activity in vitro (A.D. Leavitt, L. Shiue, and H.E. Varmus, J. Biol. Chem. 268:2113-2119, 1993). In addition, we have identified four highly conserved residues that can be mutated without any affect on viral replication in T-cell lines.

Genetic analysis of the human immunodeficiency virus type 1 integrase protein

Single-amino-acid changes in a highly conserved central region of the human immunodeficiency virus type 1 (HIV-1) integrase protein were analyzed for their effects on viral protein synthesis, virion morphogenesis, and viral replication. Alteration of two amino acids that are invariant among retroviral integrases, D116 and E152 of HIV-1, as well as a mutation of the highly conserved amino acid S147 blocked viral replication in two CD4+ human T-cell lines. Mutations of four other highly conserved amino acids in the region had no detectable effect on viral replication, whereas mutations at two positions, N117 and Y143, resulted in viruses with a delayed-replication phenotype. Defects in virion precursor polypeptide processing, virion morphology, or viral DNA synthesis were observed for all of the replication-defective mutants, indicating that changes in integrase can have pleiotropic effects on viral replication.

Role of the His-Cys finger of Moloney murine leukemia virus integrase protein in integration and disintegration

Retroviral integrases mediate site-specific endonuclease and transesterification reactions in the absence of exogenous energy. The basis for the sequence specificity in these integrase-viral DNA recognition processes is unknown. Structural analogs of the disintegration substrate were made to analyze the disintegration reaction mechanism for the Moloney murine leukemia virus (M-MuLV) integrase (IN). Modifications in the target DNA portion of the disintegration substrate decreased enzymatic activity, while substitution of the highly conserved CA in the viral long terminal repeat portion had no effect on activity. The role of the His-Cys finger region in catalysis was addressed by N-ethylmaleimide (NEM) modification of the cysteine residues of M-MuLV IN as well as by mutations. Both integration activities, 3' processing, and strand transfer, were completely inhibited by NEM modification of M-MuLV IN, while disintegration activity was only partially sensitive. However, structural analogs of the disintegration substrates that were modified in the target DNA and had the conserved CA removed were not active with NEM-treated M-MuLV IN. In addition, mutants made in the His-Cys region of M-MuLV IN were examined and found to also be completely blocked in integration but not disintegration activity. These data suggest that the domains of M-MuLV IN that are required for the forward integration reaction substrate differ from those required for the reverse disintegration reaction substrate.

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.

Fv-1 restriction and its effects on murine leukemia virus integration in vivo and in vitro

We have investigated the mechanisms by which alleles at the mouse Fv-1 locus restrict replication of murine leukemia viruses. Inhibition of productive infection is closely paralleled by reduced accumulation of integrated proviral DNA as well as by reduced levels of linear viral DNA in a cytoplasmic fraction. Nevertheless, viral DNA is present at nearly normal levels in a nuclear fraction, and total amounts of viral DNA are only mildly affected in restrictive infections, suggesting a block in integration to account for reduced levels of proviral DNA. However, integrase (IN)-dependent trimming of 3' ends of viral DNA occurs normally in vivo during restrictive infections, demonstrating that not all IN-mediated events are prevented in vivo. Furthermore, viral integration complexes present in nuclear extracts of infected restrictive cells are fully competent to integrate their DNA into a heterologous target in vitro. Thus, the Fv-1-dependent activity that restricts integration in vivo may be lost in vitro; alternatively, Fv-1 restriction may prevent a step required for integration in vivo that is bypassed in vitro.

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.

Both substrate and target oligonucleotide sequences affect in vitro integration mediated by human immunodeficiency virus type 1 integrase protein produced in Saccharomyces cerevisiae

Integration of retroviral DNA into the host cell genome requires the interaction of retroviral integrase (IN) protein with the outer ends of both viral long terminal repeats (LTRs) to remove two nucleotides from the 3' ends (3' processing) and to join the 3' ends to newly created 5' ends in target DNA (strand transfer). We have purified the IN protein of human immunodeficiency virus type 1 (HIV-1) after production in Saccharomyces cerevisiae and found it to have many of the properties described for retroviral IN proteins. The protein performs both 3' processing and strand transfer reactions by using HIV-1 or HIV-2 attachment (att) site oligonucleotides. A highly conserved CA dinucleotide adjacent to the 3' processing site of HIV-1 is important for both the 3' processing and strand transfer reactions; however, it is not sufficient for full IN activity, since alteration of nucleotide sequences internal to the HIV-1 U5 CA also impairs IN function, and Moloney murine leukemia virus att site oligonucleotides are poor substrates for HIV-1 IN. When HIV-1 att sequences are positioned internally in an LTR-LTR circle junction substrate, HIV-1 IN fails to cleave the substrate preferentially at positions coinciding with correct 3' processing, implying a requirement for positioning att sites near DNA ends. The 2 bp normally located beyond the 3' CA in linear DNA are not essential for in vitro integration, since mutant oligonucleotides with single-stranded 3' or 5' extensions or with no residues beyond the CA dinucleotide are efficiently used. Selection of target sites is nonrandom when att site oligonucleotides are joined to each other in vitro. We modified an in vitro assay to distinguish oligonucleotides serving as the substrate for 3' processing and as the target for strand transfer. The modified assay demonstrates that nonrandom usage of target sites is dependent on the target oligonucleotide sequence and independent of the oligonucleotide used as the substrate for 3' processing.

DNA binding properties of the integrase proteins of human immunodeficiency viruses types 1 and 2

Integration of retroviral DNA into the host chromosome requires the integrase protein (IN). We overexpressed the IN proteins of human immunodeficiency viruses types 1 and 2 (HIV-1 and HIV-2) in E. coli and purified them. Both proteins were found to specifically cut two nucleotides off the ends of linear viral DNA, and to integrate viral DNA into target DNA. This demonstrates that HIV IN is the only protein required for integration of HIV DNA. Although the two types of IN proteins have only 53% amino acid sequence similarity, they act with equal efficiency on both type 1 and type 2 viral DNA. Binding of IN to DNA was tested: purified IN does not bind very specifically to viral DNA ends. Nevertheless, only viral DNA ends are cleaved and integrated. We interpret this as follows: in vitro quick aspecific binding to DNA is followed by slow specific cutting and integration. IN can not find viral DNA ends in the presence of an excess of aspecific DNA; in vivo this is not required since the IN protein is in constant proximity of viral DNA in the viral core particle.

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.

Transfer RNA genes are genomic targets for de Novo transposition of the yeast retrotransposon Ty3

Insertions of the yeast element Ty3 resulting from induced retrotransposition were characterized in order to identify the genomic targets of transposition. The DNA sequences of the junctions between Ty3 and flanking DNA were determined for two insertions of an unmarked element. Each insertion was at position -17 from the 5' end of a tRNA-coding sequence. Ninety-one independent insertions of a marked Ty3 element were studied by Southern blot analysis. Pairs of independent insertions into seven genomic loci accounted for 14 of these insertions. The DNA sequence flanking the insertion site was determined for at least one member of each pair of integrated elements. In each case, insertion was at position -16 or -17 relative to the 5' end of one of seven different tRNA genes. This proportion of genomic loci used twice for Ty3 integration is consistent with that predicted by a Poisson distribution for a number of genomic targets roughly equivalent to the estimated number of yeast tRNA genes. In addition, insertions upstream of the same tRNA gene in one case were at different positions, but in all cases were in the same orientation. Thus, genomic insertions of Ty3 in a particular orientation are apparently specified by the target, while the actual position of the insertion relative to the tRNA-coding sequence can vary slightly.

Analysis of mutations in the integration function of Moloney murine leukemia virus: effects on DNA binding and cutting

The 3' terminus of the pol gene of Moloney murine leukemia virus encodes the integration (IN) protein, required for the establishment of the integrated provirus. A series of six linker insertion mutations and two single-base substitutions were generated within the region encoding the IN protein. Mutations were initially generated within an Escherichia coli plasmid expressing the IN protein, and the resulting variants were assayed for DNA-binding activity. Mutations which altered conserved cysteine residues within a potential DNA finger-binding motif resulted in lower or variable DNA binding, which appeared to be the result of variable protein folding. Upon renaturation, these proteins were able to nonspecifically bind DNA in a manner similar to that of the other mutant IN proteins and the parent. When reconstructed back into full-length virus, seven of the eight mutations were lethal. All mutants produced a stable IN protein in virions and mediated normal conversion of the retroviral RNA to its three DNA forms. Fine-structure analysis of the linear double-stranded viral DNA indicated that all seven lethal alterations within the IN protein blocked the formation of the 3' recessed termini that normally precedes integration.

Characterization of a transpositionally active Ty3 element and identification of the Ty3 integrase protein

Ty3 is a Saccharomyces cerevisiae retrotransposon associated with tRNA genes. Two Ty3 elements have been cloned and characterized. The complete nucleotide sequence for one element, Ty3-2, was reported previously (L. J. Hansen, D. L. Chalker, and S. B. Sandmeyer, Mol. Cell. Biol. 9:5245-5256, 1988). However, this element is incapable of autonomous transposition. The complete DNA sequence of a transpositionally competent Ty3 element, Ty3-1, is presented here. Its sequence translates into two overlapping open reading frames, TYA3-1 and TYB3-1, which encode proteins with homology to the proteins specified by the retroviral gag and pol genes, respectively. Comparison of the Ty3-1 nucleotide sequence to Ty3-2 suggests that the TYB3-2 open reading frame of Ty3-2 is truncated by the deletion of a single nucleotide, which causes a frameshift mutation. Restoration of the reading frame with insertion of a single adenine by site-directed mutagenesis converted Ty3-2 into a transpositionally active element, Ty3-2(+ A). Western blot analysis with antibodies made against synthetic peptides identified integrase (IN) proteins in viruslike particle preparations from cells expressing Ty3 elements. Cells expressing Ty3-1 and Ty3-2 (+A) produce antibody-reactive proteins with approximate molecular masses of 61 and 58 kilodaltons (kDa), while cells expressing Ty3-2 produce reactive proteins of approximately 52 and 49 kDa. Together, these data show that the 61- or 58-kDa protein, or both, provides the integrase function of Ty3.

Sequence-specific binding of DNA by the Moloney murine leukemia virus integrase protein

Genetic studies have indicated that integration of retroviral DNA into the host genome depends on the presence of the inverted repeats at the free termini of the long terminal repeats on the unintegrated DNA and on the product of the 3' end of the pol gene (the integrase [IN] protein). While the precise function of the Moloney murine leukemia virus IN protein is uncertain, others have shown that it is a DNA-binding protein and functions in the processing of the inverted repeats prior to integration. By using site-directed mutagenesis, we cloned and expressed the IN protein in Escherichia coli. Crude extracts of total cellular protein were fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transferred to nitrocellulose filters, denatured in guanidine, renatured, and incubated with oligonucleotide probes. Single- and double-stranded oligonucleotides corresponding to the termini of unintegrated linear viral DNA were specifically bound by the IN protein in this assay. These data suggest that the role of the Moloney IN protein in the early steps of integration involves sequence-specific recognition of the DNA sequences found at the ends of the long terminal repeats.

Avian retrovirus integration protein: structure-functional analysis of viable mutants

A replication-competent avian retrovirus mutant, containing a single amino acid substitution at amino acid residue 115 in the 3' endonuclease (IN) region of the polymerase (pol) gene, was characterized. DNA transfection experiments demonstrated that the mutant virus exhibited a delayed growth phenotype at 41 degrees while replicating efficiently at 35 degrees. Examination of virus-infected cells at the molecular level demonstrated that the mutant virus at either temperature was capable of synthesizing viral DNA as efficiently as wild-type Rous sarcoma virus, strain Prague A. This result suggested that the same mutation, which was also present in the IN moeity of the polymerase beta polypeptide, did not affect DNA synthesis. Further analyses demonstrated that at either temperature the mutant virus integrated its DNA at about 10-20% of wild-type level, although possibly less efficiently at 41 degrees than at 35 degrees. The mutation at residue 115 (Pro to Ser) appeared to lower the ability of IN to function in the integration of viral DNA relative to wild-type virus. No definitive conclusion could be made as to whether IN in this mutant possessed a temperature-sensitive lesion which caused the observed replication defect at 41 degrees.

The avian retroviral integration protein cleaves the terminal sequences of linear viral DNA at the in vivo sites of integration

The purified integration protein (IN) of avian myeloblastosis virus is shown to nick double-stranded oligodeoxynucleotide substrates that mimic the ends of the linear form of viral DNA. In the presence of Mg2+, nicks are created 2 nucleotides from the 3' OH ends of both the U5 plus strand and the U3 minus strand. Similar cleavage is observed in the presence of Mn2+ but only when the extent of the reaction is limited. Neither the complementary strands nor sequences representing the termini of human immunodeficiency virus type 1 DNA were cleaved at analogous positions. Analysis of a series of substrates containing U5 base substitutions has defined the sequence requirements for site-selective nicking; nucleotides near the cleavage site are most critical for activity. The minimum substrate size required to demonstrate significant activity corresponds to the nearly perfect 15-base terminal inverted repeat. This in vitro activity of IN thus produces viral DNA ends that are joined to host DNA in vivo and corresponds to an expected early step in the integrative recombination reaction. These results provide the first enzymatic support using purified retroviral proteins for a linear DNA precursor to the integrated provirus.

Structure of the termini of DNA intermediates in the integration of retroviral DNA: dependence on IN function and terminal DNA sequence

Linear retroviral DNA, the major precursor to the integrated provirus of the murine leukemia viruses, contains a mixture of two structures at its ends: some termini are full-length and blunt, and some have recessed 3' strands. A temporal study of the end structures showed that the proportion of the DNA with recessed ends increases during the course of infection, and suggests that the blunt ends are precursors to the recessed ends. We have examined the DNA structures of the ends of retroviral mutants defective in the integration (IN) function. The results show that the formation of the recessed ends requires the presence of IN. Finally, we have analyzed the structures at the ends of mutant genomes with alterations in the terminal DNA sequence. The exact position of the recessed 3' end can be recessed one, two, or four nucleotides relative to the 5' end. In all cases the position of the recessed 3' end correlates perfectly with, and thus presumably determines, the site of joining to the target DNA.