Efficient insertion from an internal long terminal repeat (LTR)-LTR sequence on a reticuloendotheliosis virus vector is imprecise and cell specific.

To examine the fidelity and efficiency of integration from a covalently closed long terminal repeat (LTR)-LTR sequence in vivo, we isolated individual spleen necrosis virus proviruses that arose following infection of chicken embryo fibroblasts (CEFs) and sequenced the provirus-cell DNA junctions. Some but not all CEF preparations allowed efficient insertion from the internal sequence. Moreover, in contrast to integration from the normal ends of the viral DNA, which occurs with precision with respect to the viral DNA, insertion from the internal sequence was not precise. In particular, there were short deletions of variable size from the viral DNA and these proviruses were not flanked by short direct repeats. Although this imprecise insertion can be efficient in CEFs, such integration is very inefficient in two other cell types (D17 and QT47) that support the replication of reticuloendotheliosis viruses. Thus, it is possible that there is a cell-specific factor(s) in CEFs required for efficient but imprecise insertion or, alternatively, D17 and QT47 cells contain a factor that abrogates integration from an internal LTR-LTR junction. Virus particles released from CEFs do not efficiently use the LTR-LTR junction following infection of D17 cells. Therefore, if there is a CEF-specific factor required for insertion, it does not appear to be transferred through particles.     

Removal of 3'-OH-terminal nucleotides from blunt-ended long terminal repeat termini by the avian retrovirus integration protein.

The avian myeloblastosis virus integration protein (IN) was capable of removing a specific set of 3'-OH-terminal nucleotides from blunt-ended long terminal repeat (LTR) substrates which resembled linear viral DNA in vivo. The 3'-OH-recessed ends map to the in vivo site of integration on linear viral DNA. The linear DNA plasmid substrate was formed by the generation of a unique DraI restriction enzyme site (TTT/AAA) at the circle junction of a 330-bp tandem LTR-LTR insert. IN preferentially released the three T nucleotides from the minus strand of the U3 LTR substrate compared with its ability to remove the three T nucleotides from the plus strand of the U5 LTR substrate. It was also observed that IN was capable of cleaving a non-LTR DNA substrate containing sequence homology to the U5 LTR terminus.     

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.     

Avian sarcoma and leukosis virus pol-endonuclease recognition of the tandem long terminal repeat junction: minimum site required for cleavage is also required for viral growth.

Integration of retroviral DNA is a site-specific reaction involving an endonuclease encoded by the viral pol gene (pol-endo). In vitro the pol-endo from avian sarcoma and leukosis viruses (ASLVs) cleaves both DNA strands near the U5-U3 junction of tandem long terminal repeats (LTR-LTR junction) in single-stranded and replicative form (RF)-I substrates. We have reported previously that the sequences that are required for cleavage of single-stranded substrates by the alpha beta form of the pol-endo differ for the plus and minus strands (G. Duyk, M. Longiaru, D. Cobrinik, R. Kowal, P. deHaseth, A. M. Skalka, and J. Leis, J. Virol. 56:589-599, 1985). This is not the case with RF-I substrates, in which a maximum of 22 base pairs of U5 and 8 base pairs of U3 were required for alpha beta pol-endo cleavage in each strand. Insertion of a palindromic octanucleotide (CATCGATG) at the LTR-LTR junction abolished cleavage in RF-I but not in single-stranded DNA substrates. Deletion of the four nucleotides (TTAA) at the junction prevented cleavage in the plus strand of RF-I DNA, but did not affect cleavage of single-stranded DNA. Furthermore, the alpha beta form of ASLV pol-endo did not recognize heterologous LTR-LTR junction sequences from the reticuloendotheliosis virus or Moloney murine leukemia virus in either substrate form, despite their sequence and structural similarities to the ASLV junction. These results support a role for a sequence-specific interaction between the ASLV pol-endo and the LTR-LTR junction domains that are required for cleavage. By using the infectious Rous sarcoma virus clone pATV8-K, we introduced a set of deletions into the U5 region that would be incorporated into the LTR-LTR junction on viral replication. In the unintegrated provirus, the deletions started 43 base pairs from the LTR-LTR junction and extended various lengths toward the junction. Results of transfection studies with these clones indicated that the U5 sequences that are required for virus production in vivo correspond to those that are required for cleavage of RF-I DNA in vitro.     

Circles with two tandem LTRs are precursors to integrated retrovirus DNA

Infection of susceptible cells by retroviruses results in the synthesis of linear DNA with two long terminal repeats (LTRs), circular DNA with a single LTR, and circular DNA with two tandem LTRs. To determine which of these unintegrated molecules serves as the precursor to the provirus, we inserted into a retrovirus vector a 49 bp fragment containing the junction formed by in vivo blunt-end ligation of two LTRs. Infection of chicken embryo fibroblasts with virus recovered from this vector and subsequent characterization of the proviral DNA revealed that efficient integration can occur from this introduced junction sequence. Therefore, circular DNA with two tandem LTRs is a precursor to the provirus.     

Mutations altering the moloney murine leukemia virus p12 Gag protein affect virion production and early events of the virus life cycle.

The p12 Gag protein of Moloney murine leukemia virus is a small polypeptide of unknown function, containing two proline-rich motifs. To determine its role in replication, we introduced a series of deletion and alanine-scanning substitution mutations throughout the p12 coding region of a proviral DNA, and characterized the phenotypes of the resulting mutant viruses. Complete deletion of p12 and mutations affecting the PPPY motif caused substantial reduction in the yield of virions and a modest reduction in Gag processing. Proteolytic cleavage of the R-peptide from the cytoplasmic tail of the envelope protein TM was abolished in these mutants, suggesting that the PPPY motif is crucial for the viral protease to access the TM tail. The resulting virions were non-infectious, and unable to initiate DNA synthesis in infected cells. Mutants with alterations in both the N- and C-terminal portions of p12 exhibited a distinct phenotype. The production of virions and processing of Gag, Pol and Env precursors were normal. The viruses were able to direct synthesis of linear viral DNA, but there was almost no detectable circular DNAs or LTR-LTR junction. These data suggest that p12 plays a critical role in the early events of the virus life cycle.     

Sequence requirements for integration of Moloney murine leukemia virus DNA in vitro.

Normal replication of Moloney murine leukemia virus (MoMLV) requires the integration of a DNA copy of the viral RNA genome into a chromosome of the host. In this work, we characterize the DNA sequences at the ends of the linear proviral precursor that are required for integration in the presence of MoMLV integration protein in vitro. We found that nine bases of MoMLV DNA at each end of a linear model substrate were sufficient for near-maximal levels of integration and that four bases of MoMLV DNA at each end were sufficient for low levels of correct integration. We also found that a 3'-terminal A residue was preferred for integration. We infer from the limited DNA sequence requirements for integration that factors in addition to DNA sequence direct integration protein to act at the ends of the viral DNA.     

Effect of aphidicolin on avian sarcoma virus replication.

We studied the effect of aphidicolin, an inhibitor of eucaryotic DNA polymerase alpha, on viral DNA replication and integration during the first 24 h after infection of quail embryo fibroblasts with avian sarcoma virus. In drug-treated cells, the synthesis of unintegrated linear viral DNA species was not impaired; however, the subsequent accumulation of circular viral DNA species and integrated proviral DNA was reversibly inhibited. After removal of the drug, circular viral DNA species were derived from preexisting linear viral DNA species, instead of being derived by de novo synthesis.     

Features of two hepatitis B virus (HBV) DNA integrations suggest mechanisms of HBV integration.

Two integrated hepatitis B virus (HBV) DNA molecules were cloned from two primary hepatocellular carcinomas each containing only a single integration. One integration (C3) contained a single linear segment of HBV DNA, and the other integration (C4) contained a large inverted duplication of viral DNA at the site of a chromosome translocation (O. Hino, T.B. Shows, and C.E. Rogler, Proc. Natl. Acad. Sci. USA 83:8338-8342, 1986). Sequence analysis of the virus-cell junctions of C3 placed the left virus-cell junction at nucleotide 1824, which is at the 5' end of the directly repeated DR1 sequence and is 6 base pairs from the 3' end of the long (L) negative strand. The right virus-cell junction was at nucleotide 1762 in a region of viral DNA (within the cohesive overlap) which shared 5-base-pair homology with cellular DNA. Sequence analysis of the normal cellular DNA across the integration site showed that 11 base pairs of cellular DNA were deleted at the site of integration. On the basis of this analysis, we suggest a mechanism for integration of the viral DNA molecule which involves strand invasion of the 3' end of the L negative strand of an open circular or linear HBV DNA molecule (at the DR1 sequence) and base pairing of the opposite end of the molecule with cellular DNA, accompanied by the deletion of 11 base pairs of cellular DNA during the double recombination event. Sequencing across the inverted duplication of HBV DNA in clone C4 located one side of the inversion at nucleotide 1820, which is 2 base pairs from the 3' end of the L negative strand. Both this sequence and the left virus-cell junction of C3 are within the 9-nucleotide terminally redundant region of the HBV L negative strand DNA. We suggest that the terminal redundancy is a preferred topoisomerase I nicking region because of both its base sequence and forked structure. Such nicking would lead to integration and rearrangement of HBV molecules within the terminal redundancy, as we have observed in both our clones.     

Isolation and analysis of retroviral integration targets by solo long terminal repeat inverse PCR

Upon retroviral infection, the genomic RNA is reverse transcribed to make proviral DNA, which is then integrated into the host chromosome. Although the viral elements required for successful integration have been extensively characterized, little is known about the host DNA structure constituting preferred targets for proviral integration. In order to elucidate the mechanism for the target selection, comparison of host DNA sequences at proviral integration sites may be useful. To achieve simultaneous analysis of the upstream and downstream host DNA sequences flanking each proviral integration site, a Moloney murine leukemia virus-based retroviral vector was designed so that its integrated provirus could be removed by Cre-loxP homologous recombination, leaving a solo long terminal repeat (LTR). Taking advantage of the solo LTR, inverse PCR was carried out to amplify both the upstream and downstream cellular flanking DNA. The method called solo LTR inverse PCR, or SLIP, proved useful for simultaneously cloning the upstream and downstream flanking sequences of individual proviral integration sites from the polyclonal population of cells harboring provirus at different chromosomal sites. By the SLIP method, nucleotide sequences corresponding to 38 independent proviral integration targets were determined and, interestingly, atypical virus-host DNA junction structures were found in more than 20% of the cases. Characterization of retroviral integration sites using the SLIP method may provide useful insights into the mechanism for proviral integration and its target selection.     

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.     

Fv-1 host restriction of Friend leukemia virus: analysis of unintegrated proviral DNA.

The murine gene Fv-1 predominantly controls the outcome of infection by murine ecotropic retroviruses. The inhibition of virus replication by the Fv-1 gene product has been determined to be at an early stage in virus replication. Mechanistically, its effect appears to be on the accumulation of unintegrated proviral DNA or its integration or both. We investigated the synthesis of unintegrated proviral DNA, using several clones of B-, N-, or NB-tropic Friend murine leukemia virus. Our results indicate that the accumulation of B-tropic proviral DNA in NIH cells may be inhibited at either the level of linear (form III) or covalently closed circular DNA (form I), depending upon the degree of restriction of the clone of virus used. We confirmed that there is an effect of the Fv-1 gene on the accumulation of form I DNA of either B- or N-tropic Friend murine leukemia virus. However, the decrease in infectious centers effected by the Fv-1 gene did not correlate quantitatively with the effect on form I proviral DNA produced by N-tropic Friend murine leukemia virus in nonpermissive cells. Lastly, we demonstrated in nonpermissively infected NIH cells that a rapidly migrating doublet of viral DNA is formed.     

Mapping unintegrated avian sarcoma virus DNA: termini of linear DNA bear 300 nucleotides present once or twice in two species of circular DNA.

Three major species of viral DNA have been observed in cells infected by retroviruses: a linear, double-stranded copy of a subunit of viral RNA; closed circular DNA; and proviral DNA inserted covalently into the genome of the host cell. We have studied the structures of the unintegrated forms of avian sarcoma virus (ASA) DNA using agarose gel electrophoresis in conjunction with restriction endonucleases and molecular hybridization techniques. The linear duplex DNA is approximately the same length as a subunit of viral RNA (approximately 10 kb) and it bears natural repeats of approximately 300 nucleotides at its termini. The repeats are composed of sequences derived from both the 3' and 5' termini of viral RNA in a manner suggesting that the viral DNA polymerase is transferred twice between templates. Thus the first end begins with a sequence from the 5' terminus of viral RNA and is permuted by about 100 nucleotides with respect to the 3' terminus of viral RNA; the linear DNA terminates with a sequence of about 200 nucleotides derived from the 3' end of viral RNA. We represent this structure, synthesized from right to left, as 3'5'-----3'5'. Two closed circular species of approximately monomeric size have been identified. The less abundant species contain all the sequences identified in linear DNA, including two copies in tandem of the 300 nucleotide 3'5' repeat. The major species lacks about 300 base pairs (bp) mapped to the region of the repeated sequence; thus it presumably contains only a single copy of that sequence. The strategies used to determine these structures involved the assignment of over 20 cleavage sites for restriction endonucleases on the physical maps of ASV DNA. Several strains of ASV were compared with respect to these sites, and the sites have been located in relation to deletions frequently observed in the env and src genes of ASV.     

The HIV-1 central DNA flap region contains a "flapping" third strand

Due to the discontinuous nature of HIV-1 plus-strand DNA synthesis, a 99-nt plus-strand overhang termed the "central DNA flap" is present near the center of the proviral DNA prior to integration. The flap appears to have stabilizing and/or protective effects on viral DNA, which has been hypothesized to be due to a specific conformation adopted by the three-stranded region. The 5' end of the flap sequence is very purine rich and has the potential to adopt different secondary structures (e.g., duplex, triplex or quadruplex). In the present work, circular dichroism spectroscopy and thermal unfolding techniques were used to characterize an 89-nt long DNA sequence designed to mimic the three-stranded region at the 5' end of HIV-1 proviral DNA. The effect of addition of the HIV-1 nucleocapsid protein (NC) on the nucleic acid structure was also examined. Although, guanine-rich short oligonucleotides derived from the DNA flap demonstrated CD spectra characteristic to parallel quadruplexes, this analysis reveals that the extended 89-nt construct folds into a canonical duplex with a "flapping" third strand both in the absence and presence of NC.     

Infectious Molecular Clones of Adeno-Associated Virus Isolated Directly from Human Tissues

Adeno-associated virus (AAV) replication and biology have been extensively studied using cell culture systems, but there is precious little known about AAV biology in natural hosts. As part of our ongoing interest in the in vivo biology of AAV, we previously described the existence of extrachromosomal proviral AAV genomes in human tissues. In the current work, we describe the molecular structure of infectious DNA clones derived directly from these tissues. Sequence-specific linear rolling-circle amplification was utilized to isolate clones of native circular AAV DNA. Several molecular clones containing unit-length viral genomes directed the production of infectious wild-type AAV upon DNA transfection in the presence of adenovirus help. DNA sequence analysis of the molecular clones revealed the ubiquitous presence of a double-D inverted terminal repeat (ITR) structure, which implied a mechanism by which the virus is able to maintain ITR sequence continuity and persist in the absence of host chromosome integration. These data suggest that the natural life cycle of AAV, unlike that of retroviruses, might not have genome integration as an obligatory component.     

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.