Viral DNA Termini Research Articles

Genetic analysis of homomeric interactions of human immunodeficiency virus type 1 integrase using the yeast two-hybrid system.

The retroviral integrase protein (IN) is responsible for catalyzing a concerted integration reaction in which the two termini of linear viral DNA are joined to host DNA. To probe the potential for IN to form protein multimers, we used the yeast two-hybrid system. The coexpression of a GAL4 DNA binding domain-IN fusion and a GAL4 activation domain-IN fusion together resulted in the successful activation of a GAL4-responsive LacZ reporter gene. The system was used to examine a variety of IN deletion mutants. The results suggest that the central region of the protein is necessary for multimerization and that the N-terminal zinc finger region is not important.

Mutational Analysis of the Sequences at the Termini of the Moloney Murine Leukemia Virus DNA Required for Integration

The insertion of retroviral DNA into the genome of the infected cell to form the integrated provirus requires the presence of short inverted repeat (IR) sequences at the viral DNA termini. To examine the sequence requirements at the IRa for integration of the Moloney murine leukemia virus, we generated a series of mutants with deletion and substitution mutations and tested their ability to replicate and form proviruses in vivo. The experiments did not detect evidence of a requirement for sequences outside the IRs, and only a very loose requirement for the IR sequences, with many point mutations well tolerated. Examination of the mutants suggests that bases very near the terminus and those approximately one turn of the DNA helix away from the terminus are important for recognition by the integrase function.

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.

Identification of amino acids in HIV-2 integrase involved in site-specific hydrolysis and alcoholysis of viral DNA termini.

The human immunodeficiency virus integrase (HIV IN) protein cleaves two nucleotides off the 3' end of viral DNA and subsequently integrates the viral DNA into target DNA. IN exposes a specific phosphodiester bond near the viral DNA end to nucleophilic attack by water or other nucleophiles, such as glycerol or the 3' hydroxyl group of the viral DNA molecule itself. Wild-type IN has a preference for water as the nucleophile; we here describe a class of IN mutants that preferentially use the 3' hydroxyl group of viral DNA as nucleophile. The amino acids that are altered in this class of mutants map near the putative active-site residues Asp-116 and Glu-152. These results support a model in which multiple amino acid side-chains are involved in presentation of the (soluble) nucleophile. IN is probably active as an oligomeric complex, in which the subunits have non-equivalent roles; we here report that nucleophile selection is determined by the subunit that supplies the active site.

Concerted integration of viral DNA termini by purified avian myeloblastosis virus integrase

Concerted integration of retroviral DNA termini, which produces a characteristic duplication of sequences at the integration site and formation of the proviral state, is a necessary step of the retroviral life cycle. We investigated the pairwise integration reaction catalyzed by purified avian retrovirus integrase by measuring the response to solution parameters and how the sequences of the viral termini, which comprise the avian imperfect inverted repeat, affect the reaction. When we optimized the reaction, an efficiency was achieved which approached that measured in systems using cytoplasmic extracts from virus-infected cells. The response of purified avian integrase to solution parameters was similar to that of the integration activity derived from cellular extracts. For strand transfer, the U3 viral terminal sequences were preferred to those of the U5 termini, a result we previously showed for the trimming reaction. That the sequence preference was the same for trimming and strand transfer may be further evidence that only one catalytic site is used for both reactions. A significant number of integration sites were sequenced. Interesting trends were found for the fidelity of the host duplications to the avian 6-bp duplication size, the clustering of the integration sites in the nonessential region of the lambda host DNA, and the sequence characteristics of the duplication sites.

Retroviral integrase functions as a multimer and can turn over catalytically.

A number of studies have demonstrated that the retroviral protein integrase (IN) alone is sufficient to carry out two discrete steps required for retroviral integration: the endonucleolytic processing of viral DNA ends and the cleavage and joining of host DNA to the processed viral DNA termini. Little is known about the biochemical and biophysical mechanisms involved in these reactions. Here, we employ in vitro assays of Rous sarcoma virus IN to demonstrate for the first time that IN is capable of multiple turnover in both the processing and joining reactions. The turnover number calculated for the processing reaction is 0.26 cleavages/min/mol of IN. Our steady state kinetic studies indicate that both the processing and joining activities require a multimeric form of IN. Ultracentrifugation analyses reveal a substrate-independent reversible equilibrium among the monomeric, dimeric, and tetrameric forms of this protein. From these results we conclude that the minimal functional unit for both the processing and joining of each viral DNA end is an IN dimer.

Human immunodeficiency virus integrase protein requires a subterminal position of its viral DNA recognition sequence for efficient cleavage

Retroviral integration requires cis-acting sequences at the termini of linear double-stranded viral DNA and a product of the retroviral pol gene, the integrase protein (IN). IN is required and sufficient for generation of recessed 3' termini of the viral DNA (the first step in proviral integration) and for integration of the recessed DNA species in vitro. Human immunodeficiency virus type 1 (HIV-1) IN, expressed in Escherichia coli, was purified to near homogeneity. The substrate sequence requirements for specific cleavage and integration of retroviral DNA were studied in a physical assay, using purified IN and short duplex oligonucleotides that correspond to the termini of HIV DNA. A few point mutations around the IN cleavage site substantially reduced cleavage; most other mutations did not have a drastic effect, suggesting that the sequence requirements are limited. The terminal 15 bp of the retroviral DNA were demonstrated to be sufficient for recognition by IN. Efficient specific cutting of the retroviral DNA by IN required that the cleavage site, the phosphodiester bond at the 3' side of a conserved CA-3' dinucleotide, be located two nucleotides away from the end of the viral DNA; however, low-efficiency cutting was observed when the cleavage site was located one, three, four, or five nucleotides away from the terminus of the double-stranded viral DNA. Increased cleavage by IN was detected when the nucleotides 3' of the CA-3' dinucleotide were present as single-stranded DNA. IN was found to have a strong preference for promoting integration into double-stranded rather than single-stranded DNA.

Circular DNA of human immunodeficiency virus: analysis of circle junction nucleotide sequences

During infection of cells by retroviruses, some of the nonintegrated viral DNA can be found as a circular form containing two tandem, directly repeated long terminal repeats. The nucleotide sequence at the point where the long terminal repeats join (the circle junction) can be used to deduce the terminal nucleotides of the linear form of the viral DNA. Comparison of the termini of linear viral DNA with sequences at the junctions between the integrated provirus and the host chromosome has revealed that for most retroviruses 2 bp are removed from each end of the linear viral DNA during integration. For human immunodeficiency virus type 1 (HIV-1), however, sequence considerations involving primer-binding sites had suggested that only 1 bp is removed during integration. We obtained the nucleotide sequences at the ends of HIV-1 DNA by using the polymerase chain reaction to amplify fragments corresponding to the HIV-1 circle junction. Of 17 clones containing amplified sequences, 10 had identical circle junctions that contained an additional 4 bp (GTAC) relative to the integrated provirus. This indicates that, as for other retroviruses, 2 bp are removed from each end of the linear HIV-1 viral DNA during integration. The remaining seven isolates contained insertions or deletions at the circle junction.

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.

Infectious circular DNA of human adenovirus type 5: regeneration of viral DNA termini from molecules lacking terminal sequences.

A series of plasmids containing the entire human adenovirus genome with viral DNA termini joined 'head to tail' has been isolated. Several plasmids were able to generate infectious virus following transfection of human cells in spite of having small deletions and rearrangements at the junctions of termini. One plasmid has lost 2 bp of DNA from one end of the viral genome and 11 bp from the other end yet produced viruses with complete wild-type sequences at both ends of the genome. We propose a model for replication of viral DNA off circular templates in which regeneration of terminal information involves translocation of primer and polymerase during initiation of DNA replication. The model suggests a novel mechanism for extension of the 5' ends of linear DNA molecules which could be applicable to chromosomal telomeres.

Signals for site-specific cleavage of HSV DNA: maturation involves two separate cleavage events at sites distal to the recognition sequences

Mature Herpes Simplex Virus (HSV) genomes are cleaved from concatemeric precursors by a site-specific mechanism. These cleavage events are probably coupled to the encapsidation process. Sequences within the terminal repeat of HSV DNA are necessary for the cleavage and packaging reactions, and are also thought to be responsible for high frequency genome isomerization events. Here we present evidence to show that two viral DNA cleavage and packaging signals reside within a 250 bp subfragment of the terminal repeat, that the termini of mature viral DNA are generated by a process involving two separate DNA cleavages at sites distal to the cleavage signals, and that the sequences between these two cleavage sites are duplicated by the DNA maturation system.

Two deletions in the Epstein-Barr virus genome of the Burkitt lymphoma nonproducer line Raji

The Epstein-Barr virus genome carried in the Burkitt lymphoma nonproducer cell line Raji was characterized by partial denaturation mapping and by hybridization of cloned viral fragments to filters containing separated Raji DNA fragments. Partial denaturation mapping revealed that the EBV DNA population of Raji cells is homogenous and that two deletions are observed in distant parts of the genome compared to linear DNA isolated from virus particles of different strains. These deletions were characterized by blot analysis. One deletion of 3.15 kb lies within HindIII-E; the second is 2.4 kb and is located close to the right terminus of linear viral DNA. The two deletions were observed in several cell lines derived from the Raji line. These deletions might contribute to the inability of Raji cells to produce EBV either spontaneously or upon induction.

Integrated adenovirus type 12 DNA in the transformed hamster cell line T637: sequence arrangements at the termini of viral DNA and mode of amplification.

Approximately 20 to 22 copies of adenovirus type 12 (Ad12) DNA per cell were integrated into the genome of the cell line T637. Only a few of these copies seemed to remain intact and colinear with virion DNA. All other persisting viral genomes exhibited deletions or inversions or both in the right-hand part of Ad12 DNA. Spontaneously arising morphological revertants of T637 cells has lost viral DNA. In most of the revertant cell lines only the intact or a part of the intact viral genome was preserved; other revertant cell lines has lost all viral DNA. In three other Ad12-transformed hamster cell lines, HA12/7, A2497-3, and CLAC3 (Stabel et al., J. Virol. 36:22-40, 1980), major rearrangements at the right end of the integrated Ad12 DNA were not found. These studies were performed to investigate the phenomena of amplification, rearrangements, and deletions of Ad12 DNA in hamster cells.

A Rous sarcoma virus provirus is flanked by short direct repeats of a cellular DNA sequence present in only one copy prior to integration.

The Rous sarcoma virus (RSV)-transformed rat cell line RSV-NRK-2 contains a single complete RSV provirus. We have obtained recombinant lambda clones that contain both ends of the RSV provirus and the flanking rat sequences. The provirus is integrated in unique DNA and is present in only one of the two homologous chromosomes. The rat sequences into which the RSV provirus integrated were also cloned from the RSV-NRK-2 cell line. The sequences of the regions involved in the recombination event have been determined and compared. Our data suggest that, compared with the sequence of viral DNA in the large circular form of unintegrated viral DNA, the provirus lacks two base pairs at each end and that the provirus is flanked by a six-base-pair direct repeat of cellular DNA. This six-base-pair repeat was apparently created during the integration event because this sequence was present only once at the integration site before the provirus was inserted. A survey of eight other independent RSV transformed rat cell lines demonstrates that, in agreement with earlier results, the RSV proviruses have entered different segments of rat cell DNA. We have also determined the sequence of a second virus DNA-host cell DNA junction from a second RSV-transformed rat cell line (RSV-NRK-4) and find that there are no obvious similarities between the two integration sites or between the integration sites and the termini of viral DNA.

Patterns of integration of viral DNA in adenovirus type 2-transformed hamster cells

The patterns of integration of viral DNA in five lines of adenovirus type 2-transformed hamster cells have been investigated. Cell lines HE1 to HE5 were obtained by in vitro transformation of hamster embryo cells by ultraviolet light-inactivated Ad2 † † Abbreviations used: Ad2, adenovirus type 2; Ad12, adenovirus type 12; Ad5, adenovirus type 5. . In all lines, segments in the central parts of the viral genome are missing. The lines HE1, HE2, HE3, HE4 and HE5 contain 2 to 4, 2 to 4, 6 to 10, about 10, and 2 to 3 genome fragment equivalents per cell, respectively. The patterns of integration in lines HE2 and HE3 are identical; however, the viral genome has been amplified in these cell lines to different extents. This result provides evidence for the post-integrational amplification of inserted viral genomes. It is also conceivable that line HE2 may have undergone losses of integrated Ad2 genomes. The persisting Ad2 genomes in lines HE2 and HE3 have deletions in parts of the EcoRI F and D fragments. The remainders of these fragments are linked to cellular DNA. The termini of the segments of the viral genome have been inverted and linked to each other. This linkage could have occurred via a circular intermediate in integration or via tandemly integrated viral genomes with subsequent deletion events. The linkage of the termini of viral DNA might be mediated by short sequences of cellular DNA. In line HE5, approximately 40% of the Ad2 genome is deleted, and the truncated segments, again comprising the terminal Ad2 DNA fragments, have been fused. The termini of the viral DNA are linked to cellular DNA. In lines HE1 and HE4 complex deletion and fusion events have altered the inserted Ad2 genomes.

Presence of protein at the termini of intracellular adenovirus type 5 DNA

Adenovirus type 5 contains linear double-stranded DNA with protein covalently attached to the ends of the molecules. The presence of protein at the termini of intracellular viral DNA in adenovirus type 5-infected cells was investigated at different stages during the replication process. The intracellular viral DNA was isolated from the nuclei by lysis in 4 M guanidine hydrochloride. Electrophoresis on agarose gels of HsuI restriction enzyme fragments and sucrose gradient centrifugation were used to detect protein on intracellular viral DNA. After uncoating parental DNA still contains protein attached to the termini of the viral genome. Replicating and mature progeny viral DNA can also be isolated in the form of DNA-protein complexes. These complexes exhibit the same properties as the DNA-protein complex isolated from purified virions. These results suggest that the protein at the termini of intracellular viral DNA is identical to the protein attached to the 5′-ends of the DNA extracted from virions and that it is possibly involved in the replication of viral DNA.

Parental adenovirus type 2 genomes recovered early or late in infection possess terminal proteins

At both early (3 h) and late (18 h) times after infection of KB cells with adenovirus 2, more than 90% of parental nuclear viral genomes exist as complexes which contain terminally linked proteins. Density shift experiments employing 5-bromo-2'-deoxyuridine indicate that these parental DNA molecules remain complexed with terminal proteins after DNA replication. The persistent linkage of proteins to the termini of intranuclear viral DNA suggests that these proteins have an essential role in adenovirus replication.

DNA of minute virus of mice: self-priming, nonpermuted, single-stranded genome with a 5'-terminal hairpin duplex.

The genome of the nondefective parvovirus minute virus of mice (MVM) is a linear DNA molecular weight 1.48 x 10(6), which is single stranded for approximately 94% of its length. In contrast to the genomes from defective parvoviruses MVM DNA does not contain a detectable inverted terminal redundancy. A combination of enzymatic and physical techniques has shown that the molecule contains a stable hairpin duplex of approximately 130 base pairs located at the 5' terminus of the genome. MVM DNA is efficiently utilized as a template-primer by a number of DNA polymerases, including reverse transcriptases. Polymerases lacking 5' to 3' exonuclease activity yield a duplex DNA product with a molecular weight 1.96 times that of the viral genome, in which the newly synthesized complementary strand is covalently attached to the template. This duplex contains an internal "nick" that can be sealed by DNA ligase to produce a self-complementary single-strand circle. The MVM DNA duplex is cleaved twice by EcoR-RI restriction endonuclease to yield three distinct fragments in molar amounts. These results suggest that the initiation of DNA synthesis in vitro occurs at a point within 100 bases of the 3' end of the genome, using the 3' terminus of viral DNA as a primer, and that the sequence of nucleotides in the genome is not permuted.