Visna virus DNA: discovery of a novel gapped structure

Investigation of Topoisomerase Inhibitors for Activity against Human Immunodeficiency Virus: Inhibition by Coumermycin A1

Representative DNA gyrase inhibitors, eukaryotic topoisomerase I and II inhibitors and DNA cleaving or binding compounds were screened for their activity against human immunodeficiency virus (HIV) replication in MT-2 cells, with the HIV supercoiled DNA form as the proposed target. Of 17 compounds, only the DNA gyrase inhibitor coumermycin A1 was active. This inhibition was observed for two HIV isolates in both MT-2 cells and peripheral blood leucocytes, and could not be attributed to cytotoxicity. Coumermycin A1 did not inhibit HIV reverse transcriptase activity in an in vitro assay at concentrations that inhibited HIV replication in infected cells; its precise mechanism of action remains to be elucidated.

The importance of becoming double-stranded: Innate immunity and the kinetic model of HIV-1 central plus strand synthesis

Central initiation of plus strand synthesis is a conserved feature of lentiviruses and certain other retroelements. This complication of the standard reverse transcription mechanism produces a transient "central DNA flap" in the viral cDNA, which has been proposed to mediate its subsequent nuclear import. This model has assumed that the important feature is the flapped DNA structure itself rather than the process that produces it. Recently, an alternative kinetic model was proposed. It posits that central plus strand synthesis functions to accelerate conversion to the double-stranded state, thereby helping HIV-1 to evade single-strand DNA-targeting antiviral restrictions such as APOBEC3 proteins, and perhaps to avoid innate immune sensor mechanisms. The model is consistent with evidence that lentiviruses must often synthesize their cDNAs when dNTP concentrations are limiting and with data linking reverse transcription and uncoating. There may be additional kinetic advantages for the artificial genomes of lentiviral gene therapy vectors.

Residual HIV-1 DNA Flap-independent nuclear import of cPPT/CTS double mutant viruses does not support spreading infection

BACKGROUND

The human immunodeficiency virus type 1 (HIV-1) central DNA Flap is generated during reverse transcription as a result of (+) strand initiation at the central polypurine tract (cPPT) and termination after a ca. 100 bp strand displacement at the central termination sequence (CTS). The central DNA Flap is a determinant of HIV-1 nuclear import, however, neither cPPT nor CTS mutations entirely abolish nuclear import and infection. Therefore, to determine whether or not the DNA Flap is essential for HIV-1 nuclear import, we generated double mutant (DM) viruses, combining cPPT and CTS mutations to abolish DNA Flap formation.

RESULTS

The combination of cPPT and CTS mutations reduced the proportion of viruses forming the central DNA Flap at the end of reverse transcription and further decreased virus infectivity in one-cycle titration assays. The most affected DM viruses were unable to establish a spreading infection in the highly permissive MT4 cell line, nor in human primary peripheral blood mononuclear cells (PBMCs), indicating that the DNA Flap is required for virus replication. Surprisingly, we found that DM viruses still maintained residual nuclear import levels, amounting to 5-15% of wild-type virus, as assessed by viral DNA circle quantification. Alu-PCR quantification of integrated viral genome also indicated 5-10% residual integration levels compared to wild-type virus.

CONCLUSION

This work establishes that the central DNA Flap is required for HIV-1 spreading infection but points to a residual DNA Flap independent nuclear import, whose functional significance remains unclear since it is not sufficient to support viral replication.

The inside out of lentiviral vectors

Lentiviruses induce a wide variety of pathologies in different animal species. A common feature of the replicative cycle of these viruses is their ability to target non-dividing cells, a property that constitutes an extremely attractive asset in gene therapy. In this review, we shall describe the main basic aspects of the virology of lentiviruses that were exploited to obtain efficient gene transfer vectors. In addition, we shall discuss some of the hurdles that oppose the efficient genetic modification mediated by lentiviral vectors and the strategies that are being developed to circumvent them.

The HIV-1 central polypurine tract functions as a second line of defense against APOBEC3G/F

HIV-1 and certain other retroviruses initiate plus-strand synthesis in the center of the genome as well as at the standard retroviral 3' polypurine tract. This peculiarity of reverse transcription results in a central DNA "flap" structure that has been of controversial functional significance. We mutated both HIV-1 flap-generating elements, the central polypurine tract (cPPT) and the central termination sequence (CTS). To avoid an ambiguity of previous studies, we did so without affecting integrase coding. DNA flap formation was disrupted but single-cycle infection was unaffected in all target cells tested, regardless of cell cycle status. Spreading HIV-1 infection was also normal in most T cell lines, and flap mutant viruses replicated equivalently to the wild type in nondividing cells, including macrophages. However, spreading infection of flap mutant HIV-1 was impaired in non-vif-permissive cells (HuT78, H9, and primary human peripheral blood mononuclear cells [PBMCs]), suggesting APOBEC3G (A3G) restriction. Single-cycle infections confirmed that vif-intact flap mutant HIV-1 is restricted by producer cell A3G/F. Combining the Δvif and cPPT-CTS mutations increased A3G restriction synergistically. Moreover, RNA interference knockdown of A3G in HuT78 cells released the block to flap mutant HIV-1 replication. Flap mutant HIV-1 also accrued markedly increased A3G-mediated G→A hypermutation compared to that of wild-type HIV-1 (a full log(10) in the 0.36 kb downstream of the mutant cPPT). We suggest that the triple-stranded DNA structure, the flap, is not the consequential outcome. The salient functional feature is central plus-strand initiation, which functions as a second line of defense against single-stranded DNA editing by A3 proteins that survive producer cell degradation by Vif.

Lentiviral nuclear import: a complex interplay between virus and host

Although the capacity to infect non-dividing cells is a hallmark of lentiviruses, nuclear import is still barely understood. More than 100 research papers have been dedicated to this topic during the last 15 years, yet, more questions have been raised than answers. The signal-facilitating translocation of the viral preintegration complex (PIC) through the nuclear pore complex (NPC) remains unknown. It is clear, however, that nuclear import is the result of a complex interplay between viral and cellular components. In this review, we discuss the current knowledge on nuclear import. We focus on the controversies and pitfalls and discuss the interplay between virus and host.

The central DNA flap of the human immunodeficiency virus type 1 is important for viral replication

Reverse transcription of the human immunodeficiency virus type 1 is characterized by the formation of a DNA flap at the center of the viral cDNA in between the central polypurine tract (cPPT) and the central termination sequence (CTS). The importance of the DNA flap for HIV-1 replication has been questioned, whereas its importance for lentiviral vector performance is well accepted. To investigate this controversy, we re-evaluated the importance of the DNA flap for HIV-1 replication. A flap negative HIV-1 virus showed a 10- to 100-fold replication defect in comparison with a WT strain. Further characterization of the DNA flap in the context of lentiviral vectors showed that mutations in the DNA-flap sequence did not affect the transduction efficiency. Finally, introduction of a second cPPT/CTS sequence resulted in the presence of two DNA flaps but no higher transduction efficiency.

Incorporation of uracil into minus strand DNA affects the specificity of plus strand synthesis initiation during lentiviral reverse transcription

Many retroviruses either encode dUTP pyrophosphatase (dUTPase) or package host-derived uracil DNA glycosylase as a means to limit the accumulation of uracil in DNA strands, suggesting that uracil is detrimental to one or more steps in the viral life cycle. In the present study, the effects of DNA uracilation on (-) strand DNA synthesis, RNase H activity, and (+) strand DNA synthesis were investigated in a cell-free system. This system uses the activities of purified human immunodeficiency virus type 1 (HIV-1) reverse transcriptase to convert single-stranded RNA to double-stranded DNA in a single reaction mixture. Substitution of dUTP for dTTP had no effect on (-) strand synthesis but significantly decreased yields of (+) strand DNA. Mapping of nascent (+) strand 5' ends revealed that this was due to decreased initiation from polypurine tracts with a concomitant increase in initiation at non-polypurine tract sites. Aberrant initiation correlated with a change in RNase H cleavage specificity when assayed on preformed RNA-DNA duplexes containing uracilated DNA, suggesting that appropriate "selection" of the (+) strand primer is affected. Collectively, these data suggest that accumulation of uracil in retroviral DNA may disrupt the viral life cycle by altering the specificity of (+) strand DNA synthesis initiation during reverse transcription.

Identification of a central DNA flap in feline immunodeficiency virus

A duplication of the polypurine tract (PPT) at the center of the human immunodeficiency virus type 1 (HIV-1) genome (the cPPT) has been shown to prime a separate plus-strand initiation and to result in a plus-strand displacement (DNA flap) that plays a role in nuclear import of the viral preintegration complex. Feline immunodeficiency virus (FIV) is a lentivirus that infects nondividing cells, causes progressive CD4(+) T-cell depletion, and has been used as a substrate for lentiviral vectors. However, the PPT sequence is not duplicated elsewhere in the FIV genome and a central plus-strand initiation or strand displacement has not been identified. Using Southern blotting of S1 nuclease-digested FIV preintegration complexes isolated from infected cells, we detected a single-strand discontinuity at the approximate center of the reverse-transcribed genome. Primer extension analyses assigned the gap to the plus strand, and mapped the 5' terminus of the downstream (D+) segment to a guanine residue in a purine-rich tract in pol (AAAAGAAGAGGTAGGA). RACE experiments then mapped the 3' terminus of the upstream plus (U+)-strand segment to a T nucleotide located 88 nucleotides downstream of the D+ strand 5' terminus, thereby identifying the extent of D+ strand displacement and the central termination sequence of this virus. Unlike HIV, the FIV cPPT is significantly divergent in sequence from its 3' counterpart (AAAAAAGAAAAAAGGGTGG) and contains one and in some cases two pyrimidines. An invariant thymidine located -2 to the D+ strand origin is neither required nor optimal for codon usage at this position. Although the mapped cPPTs of FIV and HIV-1 act in cis, they encode homologous amino acids in integrase.

HIV-1 genome nuclear import is mediated by a central DNA flap

HIV-1 and other lentiviruses have the unique property among retroviruses to replicate in nondividing cells. This property relies on the use of a nuclear import pathway enabling the viral DNA to cross the nuclear membrane of the host cell. In HIV-1 reverse transcription, a central strand displacement event consecutive to central initiation and termination of plus strand synthesis creates a plus strand overlap: the central DNA flap. We show here that the central DNA flap acts as a cis-determinant of HIV-1 DNA nuclear import. Wild-type viral linear DNA is almost entirely imported into the nucleus where it integrates or circularizes. In contrast, mutant viral DNA, which lacks the DNA flap, accumulates in infected cells as unintegrated linear DNA, at the vicinity of the nuclear membrane. Consistently, HIV-1 vectors devoid of DNA flap exhibit a strong defect of nuclear import, which can be corrected to wild-type levels by reinsertion of the DNA flap sequence.

Analysis of polypurine tract-associated DNA plus-strand priming in vivo utilizing a plant pararetroviral vector carrying redundant ectopic priming elements

Initiation of DNA plus-strand synthesis in most reverse-transcribing elements requires primer generation by reverse transcriptase-associated RNase H at one or more template polypurine tracts (PPTs). We have exploited infectious clones of the plant pararetrovirus cauliflower mosaic virus carrying redundant ectopic plus-strand priming elements to study priming in vivo. Ectopic priming generated an additional discontinuity in progeny virion DNA during infection of plants. We found that altering the length of the 13-base pair PPT by +/-25% significantly reduced priming efficiency. A short pyrimidine tract 5' to the PPT, highly conserved among diverse reverse-transcribing elements, was shown to play an important role in PPT recognition in vivo. The predominant DNA plus-strand 5' end remained 3 nucleotides from the PPT 3' end in mutant primers that were longer or shorter than the wild-type primer. Use of an ectopic redundant primer to study replication-dependent priming was validated by demonstrating that it could rescue infectivity following destruction of the wild-type priming elements. We propose a model for plant pararetroviral plus-strand priming in which pyrimidines enhance PPT recognition during polymerase-dependent RNase H cleavages, and suggest that fidelity of primer maturation during polymerase-independent cleavages involves PPT length measurement and 3' end recognition by RNase H.

Discontinuous plus-strand DNA synthesis in human immunodeficiency virus type 1-infected cells and in a partially reconstituted cell-free system

Human immunodeficiency virus type 1 (HIV-1) replication requires conversion of viral RNA to double-stranded DNA. To better understand the molecular mechanisms of this process, we examined viral DNA synthesis in a simple cell-free system that uses the activities of HIV-1 reverse transcriptase to convert regions of single-stranded HIV-1 RNA to double-stranded DNA in a single incubation. This system recapitulated several of the required intermediate steps of viral DNA synthesis: RNA-templated minus-strand polymerization, preferential plus-strand initiation at the central and 3' HIV-1 polypurine tracts, and DNA-templated plus-strand polymerization. Secondary sites of plus-strand initiation were also observed at low frequency both in the cell-free system and in cultured virus. Direct comparison of viral and cell-free products revealed differences in the precision and selectivity of plus-strand initiation, suggesting that the cell-free system lacks one or more essential replication components. These studies provide clues about mechanisms of plus-strand initiation and serve as a starting point for the development of more complex multicomponent cell-free systems.

Efficient initiation and strand transfer of polypurine tract-primed plus-strand DNA prevent strand transfer of internally initiated plus-strand DNA

A critical step in retroviral reverse transcription is the initiation of plus-strand DNA synthesis at the polypurine tract (PPT) and strand transfer of the PPT-primed strong-stop DNA to the 5' end of the viral DNA. An attachment site (att) immediately 3' to the PPT is essential for proper integration of proviral DNA into the host chromosome. Plus-strand DNA synthesis is discontinuous in many retroviruses, indicating that sequences upstream of the PPT are also used to initiate plus-strand DNA synthesis (internally initiated DNA). Strand transfer of internally initiated DNA would result in "dead" viral DNA that lacks the att site needed for integration. Strand transfer of the internally initiated DNA could occur if DNA synthesis failed to initiate at the PPT or if the PPT-primed DNA was displaced before strand transfer. We sought to determine the efficiency of DNA synthesis initiating at the PPT and the proportions of PPT-primed DNA and internally initiated DNAs that are utilized for strand transfer. We constructed spleen necrosis virus-based retroviral vectors containing an internal PPT and an att site 5' of the normal PPT and att site. After one replication cycle of the retroviral vectors, the structures of the resulting proviruses were determined by Southern blotting. The analysis suggested that the PPT is an efficient and rapid initiator of plus-strand DNA synthesis and that internally initiated DNAs are rarely utilized for strand transfer. We hypothesize that efficient synthesis and strand transfer of PPT-primed DNA evolved to prevent lethal strand transfers of internally initiated DNAs.

Role of RNA primers in initiation of minus-strand and plus-strand DNA synthesis of the yeast retrotransposon Ty1

The Ty1 retrotransposon of the yeast Saccharomyces cerevisiae is a long terminal repeat mobile genetic element that transposes through an RNA intermediate. Initiation of minus-strand and plus-strand DNA synthesis are two critical steps during reverse transcription of the retrotransposon genome. Initiation of minus-strand DNA synthesis of the Ty1 element is primed by the cytoplasmic initiator methionine tRNA base paired to the primer binding site near the 5' end of the genomic RNA. A structural probing study of the primer tRNA-Ty1 RNA binary complex reveals that besides interactions between the primer binding site and the last 10 nucleotides at the 3' end of the primer tRNA, three short regions of Ty1 RNA named box 0, box 1 and box 2.1 interact with the T and D stems and loops of the primer tRNA. Some in vivo results underline the functional importance of the nucleotide sequence of the boxes and suggest that extended interactions between genomic Ty1 RNA and the primer tRNA play a role in the reverse transcription pathway. Plus-strand DNA synthesis is initiated from an RNase H resistant oligoribonucleotide spanning a purine-rich sequence, the polypurine tract (PPT). Two sites of initiation located at the 5' boundary of the 3' long terminal repeat (PPT1) and near the middle of the TyB (pol) gene in the integrase coding sequence (PPT2) have been identified in the genome of Ty1. The two PPTs have an identical sequence, TGGGTGGTA. Mutations replacing purines by pyrimidines in this sequence significantly diminish or abolish initiation of plus-strand DNA synthesis. Ty1 elements bearing a mutated PPT2 sequence are not defective for transposition whereas mutations in PPT1 abolish transposition.

Human immunodeficiency virus type 1 preintegration complexes containing discontinuous plus strands are competent to integrate in vitro

Despite intensive study, the mechanism by which many retroviruses complete reverse transcription has remained unclear. Most retroviruses and all lentiviruses fail to synthesize a full-length second strand of the viral cDNA (plus strand) efficiently in infected cells. For human immunodeficiency virus type 1, we find in synchronous infection experiments that full-length plus strands are rare (< 1% of products) at times when integration is likely taking place. Subviral nucleoprotein complexes containing such discontinuous cDNA can be extracted from infected cells and used to generate integration products in vitro. Analysis of such integration products using two-dimensional gel electrophoresis revealed that the discontinuous viral DNA was efficiently integrated into an added target DNA. These data support a model in which the discontinuities in the plus strand need not be sealed until after integration, potentially by the enzymes that are already thought to repair DNA gaps at the junctions between host and viral DNA.

Strand displacement synthesis capability of Moloney murine leukemia virus reverse transcriptase

The accepted model of retroviral reverse transcription includes a circular DNA intermediate which requires strand displacement synthesis for linearization and creation of an integration-competent, long terminal repeat-flanked DNA product. We have used an in vitro model of this last step of reverse transcription to examine the role of the viral enzyme, reverse transcriptase (RT), in displacement synthesis. We show that Moloney murine leukemia virus RT possesses an activity which allows for displacement synthesis through a minimum of 1,334 bp of duplex DNA--an extent much greater than that required during in vivo reverse transcription and over 25-fold greater than has been previously demonstrated for a viral RT. RT does not function as a helicase in the classical sense but appears to closely couple duplex DNA melting with synthesis-driven translocation of the enzyme. In the absence of synthesis, the unwound region created by a primer-positioned RT appears to be no greater than 2 bp and does not advance along the template. Additionally, RT does not utilize ATP or any deoxynucleoside triphosphate not directly encoded by the template strand to catalyze processive duplex unwinding at a nick; nor does binding of the enzyme unwind duplex DNA in the absence of a 3' terminus. The approximate maximum chain elongation rate during strand displacement synthesis by Moloney murine leukemia virus RT falls between 0.73 and 1.5 nucleotides per s at 37 degrees C. The RNase H activity of RT does not appear to play a role in displacement synthesis; however, a 181-amino-acid C-terminal truncation of RT displays a dramatically reduced ability to catalyze synthesis through duplex DNA.

In vitro activities of purified visna virus integrase

Although integration generally is considered a critical step in the retrovirus life cycle, it has been reported that visna virus, which causes degenerative neurologic disease in sheep, can productively infect sheep choroid plexus cells without detectable integration. To ascertain whether the integrase (IN) of visna virus is an inherently defective enzyme and to create tools for further study of integration of the phylogenetically related human immunodeficiency virus type 1 (HIV-1), we purified visna virus IN by using a bacterial expression system and applied various in vitro oligonucleotide-based assays to studying this protein. We found that visna virus IN demonstrates the full repertoire of in vitro functions characteristic of retroviral integrases. In particular, visna virus IN exhibits site-specific endonuclease activity following the invariant CA found two nucleotides from the 3' ends of viral DNA (processing activity), joins processed oligonucleotides to various sites on other oligonucleotides (strand transfer or integration activity), and reverses the integration reaction by resolving a complex that mimics one end of viral DNA integrated into host DNA (disintegration activity). In addition, although it has been reported that purified HIV-1 IN cannot specifically nick visna virus DNA ends, purified visna virus IN does specifically process and integrate HIV-1 DNA ends.

Transcriptional mapping of the 3' end of the bovine syncytial virus genome

The bovine syncytial virus, a member of the retroviral subfamily Spumavirinae, causes a persistent, asymptomatic infection in cattle. Nucleotide sequence analysis of the viral genome revealed two overlapping reading frames in the 3' region, traditionally occupied by accessory-function genes in other complex retroviruses. In order to analyze the transcripts from the accessory-gene region, we designed oligonucleotide primers complementary to sequences within the 5' and 3' long terminal repeats (LTRs) for use with the PCR. Southern blot analysis of amplification products revealed eight major cDNA bands. Eleven distinct cDNA clones were subsequently isolated and characterized. The initial splice donor in each clone is located 49 bp downstream from the mRNA cap site in the 5' LTR. The primary splice acceptor site was located 17 bp upstream from the proximal 3' open reading frame known as BF-ORF1. A second major splice acceptor was localized to a region upstream of the second open reading frame, BF-ORF2. Clones were identified which spliced directly to each of these sites. Additional splice donor and acceptor sites within BF-ORF1 and BF-ORF2 and the 3' LTR were variously used to generate a complex array of multiply spliced transcripts. Each of these transcripts remained in frame and coded for a potential protein product.

The biology of maedi-visna virus--an overview

This review aims to summarize the current understanding of the biology of maedi-visna virus (MVV), the prototype virus of the family lentivirinae. The paper provides a short overview of the historical background to the discovery of MVV. Detailed descriptions of the structure and organization of the MVV genome and of the virion encoded polypeptides are given and the MVV life cycle in vitro and in vivo are compared and contrasted and the tropism of the virus discussed. The clinical consequences of infection are considered and the mode of transmission, immune response to the virus and possible mechanisms of pathogenesis are discussed.

Vif is crucial for human immunodeficiency virus type 1 proviral DNA synthesis in infected cells

The human immunodeficiency virus type 1 (HIV-1) vif gene encodes a 23-kDa protein of unknown function, also produced by most other known lentiviruses. Vif was found to be essential for the spread of HIV-1 in peripheral blood lymphocytes and in primary macrophages, as well as in some but not all established T-cell lines. Vif was required at the stage of viral particle formation, for cell-to-cell as well as for cell-free transmission of HIV-1. Accordingly, vif-defective viruses could be complemented by the expression of vif in the producer but not in the target cell. vif-defective virions contained wild-type amounts of Gag and Env proteins, reverse transcriptase, integrase, genomic RNA, and partial reverse transcripts. Most importantly, they could enter cells normally, and the vif defect could not be rescued through the use of HIV(MLV [murine leukemia virus]) pseudotypes. Instead, vif-mutant viruses were severely impaired in their ability to complete the synthesis of proviral DNA, once internalized in the target cell. These results suggest that Vif plays a role which is novel for a retroviral protein, in allowing the processing and/or the transport of the internalized HIV core.

Mutations in the central polypurine tract of HIV-1 result in delayed replication

The reverse transcription of HIV-1 generates a linear genomic DNA with a single-stranded gap. The gap is believed to be the result of plus-strand priming from a second, centrally located, polypurine tract (PPT). A mutant containing four amino-acid-neutral purine-to-pyrimidine changes within the central PPT did not replicate as fast as wild-type virus. Another mutant with the entire 15-bp PPT deleted was replication-deficient. The results indicate that plus-strand priming at the central PPT is important for viral replication, possibly by ensuring efficient DNA synthesis.

A second origin of DNA plus-strand synthesis is required for optimal human immunodeficiency virus replication

We recently reported that human immunodeficiency virus type 1 (HIV-1) unintegrated linear DNA displays a discontinuity in its plus strand, precisely defined by a second copy of the polypurine tract (PPT) located near the middle of the genome (P. Charneau and F. Clavel, J. Virol. 65:2415-2421, 1991). This central PPT appears to determine a second initiation site for retrovirus DNA plus-strand synthesis. We show here that mutations replacing purines by pyrimidines in the HIV-1 central PPT, which do not modify the overlapping amino acid sequence, are able to significantly slow down viral growth as they reduce plus-strand origin at the center of the genome. One of these mutations, introducing four pyrimidines, results in a 2-week delay in viral growth in CEM cells and abolishes plus-strand origin at the central PPT. The introduction in this mutant of a wild-type copy of the PPT at a different site creates a new plus-strand origin at that site. This new origin also determines the end of the upstream plus-strand segment, probably as a consequence of limited strand displacement-synthesis. Our findings further demonstrate the role of PPTs as initiation sites for the synthesis of the retroviral DNA plus strand and demonstrate the importance of a second such origin for efficient HIV replication in vitro.

Molecular characterization of a unique retrovirus associated with a fish tumor

The walleye dermal sarcoma is a mesenchymal tumor which seasonally affects up to 27% of adult walleye fish (Stizostedion vitreum). It arises multicentrically in the dermis, in which its development remains restricted. We report the molecular cloning of a type C retrovirus from this tumor. The genome of this virus (13.2 kb) is larger than that of all retroviruses and in that respect is approximated only by the recently characterized spumaviruses. In tumors, the predominantly unintegrated linear viral DNA has a single-stranded gap region which is similar to the structure found in some lentiviruses and all spumaviruses. The presence of at least four viral transcripts suggests that this virus has the capacity to encode accessory functions and is reminiscent of the transcriptional complexity of lentiviruses and spumaviruses.

Structure and transcriptional status of bovine syncytial virus in cytopathic infections

The genomic structure of bovine syncytial virus (BSV), a virus commonly infecting cattle, was examined in order to gain insights into the nature of viral DNA (vDNA) intermediates and the transcriptional status of the virus in cytopathic infections. In dog Cf2Th cells, the DNA intermediate of BSV was found to exist predominantly as linear unintegrated vDNA (uvD) molecules. The uvD molecules were cloned directly from total cellular DNA by addition of EcoRI linkers and subsequent ligation into the phage lambda EMBL4 vector. Of the eleven clones characterized, seven were full length as judged by restriction fragment analysis. The remaining four clones showed varying degrees of heterogeneity in the form of internal deletions or terminal truncations. Heat denaturation and S1 nuclease analyses were used to show that vDNA isolated from Cf2Th cells contains a single-stranded (ss) gap structure located in the central region of the genome. In addition, a double-stranded (ds) 1.3-kb fragment is observed in this vDNA population. Northern-blot analysis revealed the presence of virus-specific transcripts of 11.0, 6.4, 2.8, and 2.4 kb. This suggests that BSV is similar in complexity to the lentiviruses in terms of linear intermediates containing ss gap structures, and the presence of several RNA transcripts which may direct complex regulatory functions.

A single-stranded gap in human immunodeficiency virus unintegrated linear DNA defined by a central copy of the polypurine tract

The structure of unintegrated human immunodeficiency virus type 1 (HIV-1) DNA from acutely infected human lymphoid cells was analyzed by nuclease S1 cleavage. We observed a unique, discrete single-stranded gap in unintegrated linear DNA molecules, located near the center of the genome. Oligonucleotide primer extension experiments determined that the downstream limit of this gap coincides with the last nucleotide of a central copy of the polypurine tract found in all sequenced lentivirus genomes. Other retroviruses have only one copy of the polypurine tract at the 5' boundary of the 3' long terminal repeat, which has been shown to determine initiation of retroviral DNA plus-strand synthesis. We conclude from our observations that the central repeat of the polypurine tract can create an additional site for plus-strand synthesis initiation in lentiviruses. The central single-stranded gap was not found in circular DNA molecules, the vast majority of them carrying only one long terminal repeat. This finding suggests that the generation of such circular molecules is associated with early DNA ligation events.

Equine infectious anemia virus and human immunodeficiency virus DNA synthesis in vitro: characterization of the endogenous reverse transcriptase reaction

The endogenous reverse transcriptase reaction of equine infectious anemia virus (EIAV) has been studied, and conditions allowing synthesis of full-length minus-strand DNA have been determined. In contrast to results reported for other retroviruses, synthesis of EIAV full-length minus-strand DNA was not impaired by high concentrations of Nonidet P-40, a nonionic detergent used to make the virion envelope permeable. All components of the reaction were titrated for maximum synthesis of complete minus strands, and a time course under the standardized conditions was determined. Minor subgenomic bands were observed in some cases, and both the size and proportion varied with reaction conditions. Conditions established for full-length EIAV DNA synthesis also allowed full-genome-length human immunodeficiency virus type 1 DNA synthesis. The human immunodeficiency virus type 1 DNA product contained a greater proportion of reverse transcripts that were shorter than the complete virus genome. Also in contrast to EIAV, the endogenous synthesis of high-molecular-weight human immunodeficiency virus type 1 DNA was drastically reduced at Nonidet P-40 concentrations above 0.02%. These results indicated that a detergent-stable core is not a property shared by all lentiviruses. The EIAV virion synthetic machinery is unusually stable and provides a convenient system for further in vitro study of reverse transcription.

The plus strand is discontinuous in a subpopulation of unintegrated HIV-1 DNA

During reverse transcription the synthesis of plus strand viral DNA is initiated from an RNA polypurine primer immediately upstream of the U 3 region. The polypurine tract (PPT) sequence at this site is in HIV-1 also present in the middle of the genome. Here we demonstrate that a subpopulation of linear unintegrated HIV-1 DNA has a discontinuity in the plus strand within less than 50 bp from this central PPT, consistent with its utilization as a plus strand initiation site.

Structural analysis of proviral DNA in simian foamy virus (LK-3)-infected cells

Proviral DNA of the T-cell lymphotropic simian foamy virus strain LK-3 was characterized. In infected cells, multiple copies of unintegrated linear duplex viral DNA of about 13 kbp length are present. Nuclease S1 treatment of the DNA generated two fragments of 6.5 and 6.0 kbp length that were cloned in phage and plasmid vectors. The proviral DNA contains a single-stranded gap of 109 nucleotides. A DNA fragment spanning the gap was cloned after completing the double strand by DNA synthesis in vitro. At the 3' end, the gap contains a polypurine tract (PPT) similar to the putative initiation site of retroviral plus strand DNA synthesis, suggesting discontinuous DNA synthesis. Further analysis of the genome architecture revealed LTRs of 1.7 kbp length. An additional 1.7 kbp DNA fragment was detected after nuclease S1 digestion of proviral DNA and probably represents trimmed intermediates of "strong-stop" DNA.

Evidence for a gapped linear duplex DNA intermediate in the replicative cycle of human and simian spumaviruses

Two forms of linear DNAs have been found in simian (SFV1) and human (HSRV) spumaviruses: a linear duplex unsensitive to nuclease S1 and a sensitive structure with a single-stranded gap. Two nuclease S1 sensitive sites, mapping at the same position for both viruses, have been identified in the gapped structure. Using different molecular subgenomic clones of HSRV as probes in Southern blot analysis, one S1 site was localized in the 3'LTR and the other near the middle of the molecule at about 6.5 kbp from the 5' end of the viral genome. The latter site was shown to correspond to a single stranded region within the linear duplex DNA. Nucleotide sequence analysis revealed that the polypurine tract (PPT) usually found at the 5' boundary of the 3'LTR of retroviruses, is duplicated in HSRV at the 3' end of the pol gene, near the gap. This suggests that the synthesis of plus strand DNA is discontinuous, generating the gap.

Characteristics of a novel lentivirus derived from South African sheep with pulmonary adenocarcinoma (jaagsiekte)

A novel lentivirus was isolated from South African sheep with experimentally transmitted lung adenocarcinoma. Similar to visna virus and caprine arthritis encephalitis virus, this new strain induced cytopathic effects on ovine plexus choroid cultures. In contrast to a recent Israeli isolate from sheep with adenocarcinoma, the South African lentivirus could not transform fibroblast cultures. The antigenic relatedness between the new isolate and visna virus was assessed by immunoprecipitation of radiolabeled viral proteins, using monospecific antisera against visna virus proteins. The results indicate that the new virus contains four major structural proteins of sizes similar to those of visna virus (i.e., gp135, p30, p16, and p14) and have some common antigenic determinants (about 90% in the major core antigen p30). However, the nucleotidic sequences of the novel lentivirus were found to be only 16.5 to 27.4% homologous to visna virus and 8.3 to 15% homologous to caprine arthritis encephalitis virus, by means of liquid hybridization under stringent conditions. The genetic divergence indicated by this last result was confirmed by the dissimilar restriction endonuclease cleavage map of the new virus in comparison to those of visna virus and three caprine arthritis encephalitis virus strains. The demonstration of a third type of ovine lentivirus supports the concept of an important genetic variation among the lentiviruses infecting one animal species.

Pathogenesis of lentivirus infections

Following infection of animals or humans, lentiviruses play a prolonged game of hide and seek with the host's immune system which results in a slowly developing multi-system disease. Emerging knowledge of the disease processes is of some relevance to acquired immune deficiency syndrome (AIDS), which is caused by a virus possessing many of the characteristics of a lentivirus.

Molecular cloning of integrated caprine arthritis-encephalitis virus

A full-length DNA clone of the exogenous retrovirus, caprine arthritis-encephalitis virus (CAEV), was isolated from high molecular weight DNA of CAEV-infected Himalayan tahr ovary cells. Although other restriction maps of CAEV have been published, this is the first time that the proviral DNA has been cloned. The restriction enzyme map of the clone was determined and found to be identical to that of unintegrated linear CAEV DNA except for the presence of cellular flanking sequences. These findings establish that lentiviruses are able to integrate within the infected host cellular genome. The cloned CAEV genome was shown to contain terminal repeats of approximately 450 base pairs in length, and its restriction enzyme map was oriented with respect to the direction of viral RNA transcription. When the cloned CAEV DNA was used as a molecular probe, it failed to detect related proviral sequences in the genomes of a variety of vertebrate species, including the goat, sheep, horse, mouse, and man. When CAEV DNA was hybridized under relaxed conditions to a variety of cloned DNAs, representing different oncoviral genera, homology to mouse mammary tumor virus (MMTV) was observed, while no homology to avian type C or mammalian type A, C, and D retroviruses was detected. This homology was localized to a region in MMTV corresponding to the 3' end of the gag gene and the 5' end of the pol gene.

Synthesis in cell culture of the gapped linear duplex DNA of the slow virus visna

Visna virus is a nontransforming retrovirus that causes slow infections in animals and a rapidly progressive-lytic infection in cell culture. The results of an analysis of the synthesis of viral DNA in cell culture are reported. Region- and strand-specific probes cloned in M13 have been used to define the dynamics of DNA synthesis and the major nucleic acid species formed. It is shown that (i) within the first hours of infection, a full-length copy of the viral RNA genome is synthesized by reverse transcription, (ii) early in infection a major species of DNA is formed that extends from a site near the center of the molecule to the 3' end, (iii) somewhat later a second major species of plus-strand DNA is generated that extends from the 5' end to the middle of the genome. As a consequence, most viral DNA molecules consist of a full-length minus strand, and two plus strands separated by a gap or nick in the center of the molecule (J. D. Harris, J. V. Scott, B. Traynor, M. Brahic, L. Stowring, P. Ventura, A. T. Haase, and R. Peluso (1981). Virology 113, 573-583). The implications of this viral DNA structure for one unusual aspect of the lentivirus life cycle, the production of viral RNA, and virions from extrachromosomal DNA are discussed (J. D. Harris, H. Blum, J. Scott, B. Traynor, P. Ventura, and A. T. Haase (1984). Proc. Natl. Acad. Sci. USA 81, 7212-7215).

Nucleotide sequence of the AIDS virus, LAV

The complete 9193-nucleotide sequence of the probable causative agent of AIDS, lymphadenopathy-associated virus (LAV), has been determined. The deduced genetic structure is unique: it shows, in addition to the retroviral gag, pol, and env genes, two novel open reading frames we call Q and F. Remarkably, Q is located between pol and env and F is half-encoded by the U3 element of the LTR. These data place LAV apart from the previously characterized family of human T cell leukemia/lymphoma viruses.

Molecular cloning of lymphadenopathy-associated virus

Lymphadenopathy-associated virus (LAV) is a human retrovirus first isolated from a homosexual patient with lymphadenopathy syndrome, frequently a prodrome or a benign form of acquired immune deficiency syndrome (AIDS). Other LAV isolates have subsequently been recovered from patients with AIDS or pre-AIDS and all available data are consistent with the virus being the causative agent of AIDS. The virus is propagated on activated T lymphocytes and has a tropism for the T-cell subset OKT4 (ref. 6), in which it induces a cytopathic effect. The major core protein of LAV is antigenically unrelated to other known retroviral antigens. LAV-like viruses have more recently been independently isolated from patients with AIDS and pre-AIDS. These viruses, called human T-cell leukaemia/lymphoma virus type III (HTLV-III) and AIDS-associated retrovirus (ARV), seem to have many characteristics in common with LAV and probably represent independent isolates of the LAV prototype. We have sought to characterize LAV by the molecular cloning of its genome. A cloned LAV complementary DNA was used to screen a library of recombinant phages constructed from the genomic DNA of LAV-infected T lymphocytes. Two families of clones were characterized which differ in a restriction site. The viral genome is longer than any other human retroviral genome (9.1-9.2 kilobases).

Slow virus visna: reproduction in vitro of virus from extrachromosomal DNA

Under permissive conditions of growth in tissue culture, the retrovirus visna multiples over the course of a few days to high titer and kills the host cell. We show that in this lytic life cycle, viral DNA is tightly associated with, but not covalently linked to, chromosomal DNA. This finding provides explanations for a number of the unusual properties of the lentivirus subfamily of retroviruses, and suggests potential mechanisms for the block in virus gene expression in vivo responsible for the slow infection in nature.

Highly lytic and persistent lentiviruses naturally present in sheep with progressive pneumonia are genetically distinct

Ovine and caprine lentiviruses share the capacity to induce slowly progressive and inflammatory diseases of the central nervous system (leukoencephalitis or visna), lungs (progressive pneumonia or maedi), and joints (arthritis) in their natural hosts. Studies on their replication indicated that ovine lentiviruses and caprine arthritis-encephalitis virus (CAEV) recently isolated in the United States establish persistent infection in ovine and caprine fibroblasts, whereas older prototype ovine lentiviruses such as Icelandic visna virus or American progressive pneumonia virus irreversibly lyse fibroblast cultures. Since all of the recent isolates were found to be persistent, Narayan et al. (J. Gen. Virol. 59:345-356, 1982) concluded that the highly lytic viruses were only tissue-culture-adapted strains. In the present report, we isolated new ovine lentiviruses from French sheep with naturally occurring progressive pneumonia which are either highly lytic (five isolates), as are the Icelandic strains of visna virus, or persistent (one isolate), as are CAEV or American persistent ovine lentiviruses. Protein and nucleic acid content analyses of these new highly lytic (type I) and persistent (type II) isolates indicated that type I and type II ovine lentiviruses were genetically distinct, type I and type II viruses being closely related to the Icelandic strains of visna virus and to CAEV, respectively. We conclude that (i) highly lytic ovine lentiviruses, such as the Icelandic prototype strains of visna virus and persistent lentiviruses more related to CAEV, are naturally present in the ovine species, and (ii) irreversible cell lysis induced by highly lytic viruses does not result from a tissue culture adaptation of field isolates that were originally persistent but is instead the consequence of a genetic content distinct from that of persistent viruses.

A physical map of caprine arthritis-encephalitis provirus

Terminally redundant linear proviral DNA of approximately 9.5 kb was the major unintegrated species recovered in the Hirt supernatant fraction of caprine synovial membrane cells infected with strain 75-G63 caprine arthritis-encephalitis virus. A physical map based on the cleavage sites of 13 restriction endonucleases was deduced for this proviral DNA.

Discontinuities in the DNA synthesized by an avian retrovirus

The unintegrated linear DNA synthesized in cells infected by Rous sarcoma virus is a predominantly double-stranded structure in which most of the minus-strand DNA, complementary to the viral RNA genome, is genome sized, whereas the plus-strand DNA is present as subgenomic fragments. We previously reported the application of benzoylated naphthoylated DEAE-cellulose chromatography to demonstrate that of the linear viral DNA species synthesized in quail embryo fibroblasts infected with Rous sarcoma virus greater than 99.5% contain single-stranded regions and these regions are predominantly composed of plus-strand DNA sequences (T. W. Hsu and J. M. Taylor, J. Virol. 44:47-53, 1982). We now present the following additional findings. (i) There were on the average 3.5 single-stranded regions per linear viral DNA, and these single-stranded regions could occur at many locations. (ii) With a probe to the long terminal repeat, we detected, in addition to a heterogeneous size distribution of subgenomic plus-strand DNA species, at least three prominent discrete size classes. Each of these discrete species had its own specific initiation site, but all had the same termination site. Such species were analogous to those reported by Kung et al. (J. Virol. 37: 127-138, 1981). (iii) These discrete size classes of plus-strand DNA were present not only on the major size class of linear DNA but also on a heterogeneous of slower-sedimenting species, which we have called immature linears. Our interpretation is that we have thus detected several additional sites for the initiation of plus-strand DNA. (iv) The 340-base plus-strand strong-stop DNA was only found associated with the immature linears. (v) From a size and hybridization comparison of these discrete size classes of plus-strand DNA with minus-strand DNA species, as synthesized in the endogenous reaction of melittin-disrupted virions, it was found that the putative additional initiation sites for plus-strand DNA synthesis corresponded to many of the pause sites in the synthesis of minus-strand DNA.

Molecular cloning of unintegrated visna viral DNA and characterization of frequent deletions in the 3' terminus

Visna viral DNA, like other retroviral DNA, exists in two circular forms in infected cells. The larger probably contains two copies of the LTR, the smaller, one copy. Recombinant DNA techniques were used to clone unintegrated circular visna viral DNA in the lambda WES . lambda B vector. Circular visna viral DNA was digested with the restriction enzyme SstI, which yields a 9.2-kb viral DNA fragment containing 90% of the viral genome colinear with the restriction map of linear viral DNA. This fragment extends from a site about 900 bp from the left (5') end of the viral DNA molecule, through the 3' region, including U3 and R sequences at its right (3') end. The recombinant clones isolated contain visna viral DNA inserts which range in size from 3.1 kb to 9.2 kb. All the clones contain the 5' region intact, but most had sustained deletions of varying lengths in the 3' terminal region of the cloned fragment.

Intracellular ribonucleoprotein complexes of visna virus are infectious

Sheep choroid plexus cells infected with visna virus produce intracytoplasmic viral ribonucleoprotein complexes with sedimentation values of 120S to 200S and buoyant densities of 1.29 to 1.32 g/cm3. These ribonucleoprotein complexes display an endogenous RNA-directed DNA polymerase activity and contain all of the species of RNA associated with polysomes. An analysis of the polypeptides present in the ribonucleoproteins allowed us to identify the mature internal virion core proteins and their precursor, Pr55gag, as well as the glycosylated envelope precursor gPr150env and small amounts of mature glycoprotein gp135. Ultracentrifugation-purified ribonucleoproteins could infect sheep choroid plexus cells and led to a normal lytic cycle with virus production. Our results suggest that visna virus can propagate by means of intracellular infectious particles.