Polypurine tract adjacent to the U3 region of the Rous sarcoma virus genome provides a cis-acting function

Mutations Located outside the Integrase Gene Can Confer Resistance to HIV-1 Integrase Strand Transfer Inhibitors

Resistance to the integrase strand transfer inhibitors raltegravir and elvitegravir is often due to well-identified mutations in the integrase gene. However, the situation is less clear for patients who fail dolutegravir treatment. Furthermore, most in vitro experiments to select resistance to dolutegravir have resulted in few mutations of the integrase gene. We performed an in vitro dolutegravir resistance selection experiment by using a breakthrough method. First, MT4 cells were infected with human immunodeficiency virus type 1 (HIV-1) Lai. After integration into the host cell genome, cells were washed to remove unbound virus and 500 nM dolutegravir was added to the cell medium. This high concentration of the drug was maintained throughout selection. At day 80, we detected a virus highly resistant to dolutegravir, raltegravir, and elvitegravir that remained susceptible to zidovudine. Sequencing of the virus showed no mutations in the integrase gene but highlighted the emergence of five mutations, all located in the nef region, of which four were clustered in the 3' polypurine tract (PPT). Mutations selected in vitro by dolutegravir, located outside the integrase gene, can confer a high level of resistance to all integrase inhibitors. Thus, HIV-1 can use an alternative mechanism to develop resistance to integrase inhibitors by selecting mutations in the 3' PPT region. Further studies are required to determine to what extent these mutations may explain virological failure during integrase inhibitor therapy.IMPORTANCE Integrase strand transfer inhibitors (INSTIs) are increasingly used both as first-line drugs and in rescue therapy because of their low toxicity and high efficacy in both treatment-naive and treatment-experienced patients. Until now, resistance mutations selected by INSTI exposure have either been described in patients or selected in vitro and involve the integrase gene. Most mutations selected by raltegravir, elvitegravir, or dolutegravir exposure are located inside the catalytic site of the integrase gene, but mutations outside the catalytic site of the integrase gene have also been selected with dolutegravir. Following in vitro selection with dolutegravir, we report, for the first time, a virus with selected mutations outside the HIV-1 integrase gene that confer resistance to all integrase inhibitors currently used to treat patients, such as raltegravir, elvitegravir, and dolutegravir. Our observation may explain why some viruses responsible for virological failure in patients treated with dolutegravir did not show mutations in the integrase gene.

Mutations Located outside the Integrase Gene Can Confer Resistance to HIV-1 Integrase Strand Transfer Inhibitors

Resistance to the integrase strand transfer inhibitors raltegravir and elvitegravir is often due to well-identified mutations in the integrase gene. However, the situation is less clear for patients who fail dolutegravir treatment. Furthermore, most in vitro experiments to select resistance to dolutegravir have resulted in few mutations of the integrase gene. We performed an in vitro dolutegravir resistance selection experiment by using a breakthrough method. First, MT4 cells were infected with human immunodeficiency virus type 1 (HIV-1) Lai. After integration into the host cell genome, cells were washed to remove unbound virus and 500 nM dolutegravir was added to the cell medium. This high concentration of the drug was maintained throughout selection. At day 80, we detected a virus highly resistant to dolutegravir, raltegravir, and elvitegravir that remained susceptible to zidovudine. Sequencing of the virus showed no mutations in the integrase gene but highlighted the emergence of five mutations, all located in the nef region, of which four were clustered in the 3′ polypurine tract (PPT). Mutations selected in vitro by dolutegravir, located outside the integrase gene, can confer a high level of resistance to all integrase inhibitors. Thus, HIV-1 can use an alternative mechanism to develop resistance to integrase inhibitors by selecting mutations in the 3′ PPT region. Further studies are required to determine to what extent these mutations may explain virological failure during integrase inhibitor therapy.

Integrase strand transfer inhibitors (INSTIs) are increasingly used both as first-line drugs and in rescue therapy because of their low toxicity and high efficacy in both treatment-naive and treatment-experienced patients. Until now, resistance mutations selected by INSTI exposure have either been described in patients or selected in vitro and involve the integrase gene. Most mutations selected by raltegravir, elvitegravir, or dolutegravir exposure are located inside the catalytic site of the integrase gene, but mutations outside the catalytic site of the integrase gene have also been selected with dolutegravir. Following in vitro selection with dolutegravir, we report, for the first time, a virus with selected mutations outside the HIV-1 integrase gene that confer resistance to all integrase inhibitors currently used to treat patients, such as raltegravir, elvitegravir, and dolutegravir. Our observation may explain why some viruses responsible for virological failure in patients treated with dolutegravir did not show mutations in the integrase gene.

Reverse Transcriptase-Associated Ribonuclease H Activity as a Target for Antiviral Chemotherapy

The availability of highly purified recombinant enzymes and model heteropolymeric nucleic acid substrates now allows more precise evaluation of the ribonuclease H (RNase H) activity associated with human immunodeficiency virus (HIV) reverse transcriptase. In addition to degrading the RNA–DNA replicative intermediate, this C-terminal domain of around 130 residues supports highly specialized events that cannot be complemented by host-coded enzymes during retrovirus replication. RNase H activity should therefore be considered a plausible candidate for therapeutic intervention. Events during HIV replication requiring precise RNase H-mediated hydrolysis, the methodologies available to study these events, and their potential for therapeutic intervention are reviewed here.

Activation of transcription and retrotransposition of a novel retroelement, Steamer, in neoplastic hemocytes of the mollusk Mya arenaria

Bivalve mollusks of the North Atlantic, most prominently the soft shell clam Mya arenaria, are afflicted with an epidemic transmissible disease of the circulatory system closely resembling leukemia. The disease is characterized by a dramatic expansion of blast-like cells in the hemolymph with high mitotic index. Examination of hemolymph of diseased clams revealed high levels of reverse transcriptase activity, the hallmark of retroviruses and retroelements. By deep sequencing of RNAs from hemolymph, we identified transcripts of a novel retroelement, here named Steamer. The DNA of the element is marked by long terminal repeats and encodes a single large protein with similarity to mammalian retroviral Gag-Pol proteins. Steamer mRNA levels were specifically elevated in diseased hemocytes, and high expression was correlated with disease status. DNA copy number per genome was present at enormously high levels in diseased hemocytes, indicative of extensive reverse transcription and retrotransposition. Steamer activation in M. arenaria is an example of a catastrophic induction of genetic instability that may initiate or advance the course of leukemia.

Reverse transcriptase in motion: conformational dynamics of enzyme-substrate interactions

Human immunodeficiency virus type 1 reverse transcriptase (HIV-1 RT) catalyzes synthesis of integration-competent, double-stranded DNA from the single-stranded viral RNA genome, combining both polymerizing and hydrolytic functions to synthesize approximately 20,000 phosphodiester bonds. Despite a wealth of biochemical studies, the manner whereby the enzyme adopts different orientations to coordinate its DNA polymerase and ribonuclease (RNase) H activities has remained elusive. Likewise, the lower processivity of HIV-1 RT raises the issue of polymerization site targeting, should the enzyme re-engage its nucleic acid substrate several hundred nucleotides from the primer terminus. Although X-ray crystallography has clearly contributed to our understanding of RT-containing nucleoprotein complexes, it provides a static picture, revealing few details regarding motion of the enzyme on the substrate. Recent development of site-specific footprinting and the application of single molecule spectroscopy have allowed us to follow individual steps in the reverse transcription process with significantly greater precision. Progress in these areas and the implications for investigational and established inhibitors that interfere with RT motion on nucleic acid is reviewed here.

RNase H activity: structure, specificity, and function in reverse transcription

This review compares the well-studied RNase H activities of human immunodeficiency virus, type 1 (HIV-1) and Moloney murine leukemia virus (MoMLV) reverse transcriptases. The RNase H domains of HIV-1 and MoMLV are structurally very similar, with functions assigned to conserved subregions like the RNase H primer grip and the connection subdomain, as well as to distinct features like the C-helix and loop in MoMLV RNase H. Like cellular RNases H, catalysis by the retroviral enzymes appears to involve a two-metal ion mechanism. Unlike cellular RNases H, the retroviral RNases H display three different modes of cleavage: internal, DNA 3' end-directed, and RNA 5' end-directed. All three modes of cleavage appear to have roles in reverse transcription. Nucleotide sequence is an important determinant of cleavage specificity with both enzymes exhibiting a preference for specific nucleotides at discrete positions flanking an internal cleavage site as well as during tRNA primer removal and plus-strand primer generation. RNA 5' end-directed and DNA 3' end-directed cleavages show similar sequence preferences at the positions closest to a cleavage site. A model for how RNase H selects cleavage sites is presented that incorporates both sequence preferences and the concept of a defined window for allowable cleavage from a recessed end. Finally, the RNase H activity of HIV-1 is considered as a target for anti-virals as well as a participant in drug resistance.

Effect of polypurine tract (PPT) mutations on human immunodeficiency virus type 1 replication: a virus with a completely randomized PPT retains low infectivity

We introduced polypurine tract (PPT) mutations, which we had previously tested in an in vitro assay, into the viral clone NL4-3KFSdelta nef. Each mutant was tested for single-round infectivity and virion production. All of the PPT mutations had an effect on replication; however, mutation of the 5' end appeared to have less of an effect on infectivity than mutation of the 3' end of the PPT sequence. Curiously, a mutation in which the entire PPT sequence was randomized (PPTSUB) retained 12% of the infectivity of the wild type (WT) in a multinuclear activation of galactosidase indicator assay. Supernatants from these infections contained viral particles, as evidenced by the presence of p24 antigen. Two-long terminal repeat (2-LTR) circle junction analysis following PPTSUB infection revealed that the mutant could form a high percentage of normal junctions. Quantification of the 2-LTR circles using real-time PCR revealed that number of 2-LTR circles from cells infected with the PPTSUB mutant was 3.5 logs greater than 2-LTR circles from cells infected with WT virus. To determine whether the progeny virions from a PPTSUB infection could undergo further rounds of replication, we introduced the PPTSUB mutation into a replication-competent virus. Our results show that the mutant virus is able to replicate and that the infectivity of the progeny virions increases with each passage, quickly reverting to a WT PPT sequence. Together, these experiments confirm that the 3' end of the PPT is important for plus-strand priming and that a virus that completely lacks a PPT can replicate at a low level.

Nonpolar thymine isosteres in the Ty3 polypurine tract DNA template modulate processing and provide a model for its recognition by Ty3 reverse transcriptase

Despite diverging in sequence and size, the polypurine tract (PPT) primers of retroviruses and long terminal repeat-containing retrotransposons are accurately processed from (+) U3 RNA and DNA by their cognate reverse transcriptases (RTs). In this paper, we demonstrate that misalignment of the Ty3 retrotransposon RT on the human immunodeficiency virus-1 PPT induces imprecise removal of adjacent (+)-RNA and failure to release (+)-DNA from the primer. Based on these observations, we explored the structural basis of Ty3 PPT recognition by chemically synthesizing RNA/DNA hybrids whose (-)-DNA template was substituted with the non-hydrogen-bonding thymine isostere 2,4-difluoro-5-methylbenzene (F). We observed a consistent spatial correlation between the site of T --> F substitution and enhanced ribonuclease H (RNase H) activity approximately 12-13 bp downstream. In the most pronounced case, dual T --> F substitution at PPT positions -1/-2 redirects RNase H cleavage almost exclusively to the novel site. The structural features of this unusual base suggest that its insertion into the Ty3 PPT (-)-DNA template weakens the duplex, inducing a destabilization that is recognized by a structural element of Ty3 RT approximately 12-13 bp from its RNase H catalytic center. A likely candidate for this interaction is the thumb subdomain, whose minor groove binding tract most likely contacts the duplex. The spatial relationship derived from T --> F substitution also infers that Ty3 PPT processing requires recognition of sequences in its immediate 5' vicinity, thereby locating the RNase H catalytic center over the PPT-U3 junction, a notion strengthened by additional mutagenesis studies of this paper.

A nucleotide substitution in the tRNA(Lys) primer binding site dramatically increases replication of recombinant simian immunodeficiency virus containing a human immunodeficiency virus type 1 reverse transcriptase

A recombinant simian immunodeficiency virus (SIV) derived from strain 239 (SIVmac239) with reverse transcriptase (RT) sequences from human immunodeficiency virus type 1 (HIV-1) strain HXB2 was severely impaired for replication. Detectable p27(Gag) levels were not observed until day 65 and peak p27(Gag) levels were not reached until day 75 after transfection of CEMx174 cells with the recombinant DNA. Sequences from the latter time point did not contain amino acid substitutions in HIV-1 RT; however, a single nucleotide substitution (thymine to cytosine) was found at position eight of the SIV primer binding site. We engineered an RT/SHIV genome with the thymine-to-cytosine substitution, called RT/SHIV/TC, and observed dramatically faster replication kinetics than were observed with the parental RT/SHIV from which this variant was derived. RT/SHIV/TC provides an improved system for study of the impact of drug resistance mutations in HIV-1 RT in a relevant animal model.

Molecular mechanism of sequence-specific termination of lentiviral replication

The central termination sequence (CTS) terminates (+) strand DNA synthesis in certain lentiviruses. The molecular mechanism underlying this event, catalyzed by equine infectious anemia virus reverse transcriptase (EIAV RT), was evaluated by pre-steady-state kinetic techniques. Time courses in nucleotide incorporation using several DNA substrates were biphasic, consistent with release of enzyme from extended DNA being the rate-limiting step for turnover. While the burst amplitude reflecting the amount of functional RT-DNA complex was sequence-dependent, rate constants for initial product formation were not. Filter binding assays indicate the K(d) for CTS-containing substrate is only 2-fold higher than a random DNA and cannot account entirely for the large diminution in burst amplitudes. Measurements of processive DNA replication on a millisecond time scale indicate that the rate of polymerization is unaffected by the T(6)-tract within the CTS. However, termination products accumulate due to a substantial increase in the rate of nonproductive enzyme-nucleic acid complex formation after incorporation of four to five adenosines of a T(6)-tract within the CTS. During strand displacement synthesis through the CTS, products accumulate after incorporation of three to four adenosines. The rate of polymerization during strand displacement synthesis decreases 2-fold while the rate of nonproductive enzyme-nucleic acid complex formation is identical in the absence or presence of the displacement strand. These results have allowed us to develop a model for CTS-induced termination of (+) strand synthesis.

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.

Selection of optimal polypurine tract region sequences during Moloney murine leukemia virus replication

Retrovirus plus-strand synthesis is primed by a cleavage remnant of the polypurine tract (PPT) region of viral RNA. In this study, we tested replication properties for Moloney murine leukemia viruses with targeted mutations in the PPT and in conserved sequences upstream, as well as for pools of mutants with randomized sequences in these regions. The importance of maintaining some purine residues within the PPT was indicated both by examining the evolution of random PPT pools and from the replication properties of targeted mutants. Although many different PPT sequences could support efficient replication and one mutant that contained two differences in the core PPT was found to replicate as well as the wild type, some sequences in the core PPT clearly conferred advantages over others. Contributions of sequences upstream of the core PPT were examined with deletion mutants. A conserved T-stretch within the upstream sequence was examined in detail and found to be unimportant to helper functions. Evolution of virus pools containing randomized T-stretch sequences demonstrated marked preference for the wild-type sequence in six of its eight positions. These findings demonstrate that maintenance of the T-rich element is more important to viral replication than is maintenance of the core PPT.

Deletion of a short, untranslated region adjacent to the polypurine tract in Moloney murine leukemia virus leads to formation of aberrant 5' plus-strand DNA ends in vivo

Experiments were performed to determine the function of a 28-nucleotide untranslated sequence lying between the envelope gene and the polypurine tract (PPT) sequence in the Moloney murine leukemia virus (Mo-MuLV) genome. A mutant virus carrying a deletion of this sequence (Mo-MuLVDelta28) replicated more slowly than wild-type (wt) virus and reverted by recombination with endogenous sequences during growth in NIH 3T3 cells. We show that this deletion did not affect the level of viral protein expression or genomic RNA packaging. Mo-MuLVDelta28 served as a helper virus as efficiently as the wt virus; in contrast, a retroviral vector harboring this mutation exhibited reduced transduction efficiency, indicating that the mutation acts not in trans but in cis. Analysis of acutely infected cells revealed that reduced levels of viral DNA were generated by reverse transcription of the Mo-MuLVDelta28 RNA as compared to the wt RNA. Analysis of DNA circle junctions revealed that plus-strand DNA of Mo-MuLVDelta28 but not wt virus often retained the PPT and additional upstream sequences. These structures suggest that aberrant 5' ends of plus-strand DNA were generated by a failure to remove the PPT RNA primer and/or by mispriming at sites upstream of the PPT. These data demonstrate that the major role of the sequences immediately upstream of the PPT is specifying efficient and accurate plus-strand DNA synthesis.

Induction of AIDS in rhesus monkeys by a recombinant simian immunodeficiency virus expressing nef of human immunodeficiency virus type 1

A nef gene is present in all primate lentiviruses, including human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency virus of macaque monkeys (SIVmac). However, the nef genes of HIV-1 and SIVmac exhibit minimal sequence identity, and not all properties are shared by the two. Nef sequences of SIVmac239 were replaced by four independent nef alleles of HIV-1 in a context that was optimal for expression. The sources of the HIV-1 nef sequences included NL 4-3, a variant NL 4-3 gene derived from a recombinant-infected rhesus monkey, a patient nef allele, and a nef consensus sequence. Of 16 rhesus monkeys infected with these SHIVnef chimeras, 9 maintained high viral loads for prolonged periods, as observed with the parental SIVmac239, and 6 have died with AIDS 52 to 110 weeks postinfection. Persistent high loads were observed at similar frequencies with the four different SIV recombinants that expressed these independent HIV-1 nef alleles. Infection with other recombinant SHIVnef constructions resulted in sequence changes in infected monkeys that either created an open nef reading frame or optimized the HIV-1 nef translational context. The HIV-1 nef gene was uniformly retained in all SHIVnef-infected monkeys. These results demonstrate that HIV-1 nef can substitute for SIVmac nef in vivo to produce a pathogenic infection. However, the model suffers from an inability to consistently obtain persisting high viral loads in 100% of the infected animals, as is observed with the parental SIVmac239.

Effects of 3' untranslated region mutations on plus-strand priming during moloney murine leukemia virus replication

A conserved purine-rich motif located near the 3' end of retroviral genomes is involved in the initiation of plus-strand DNA synthesis. We mutated sequences both within and flanking the Moloney murine leukemia virus polypurine tract (PPT) and determined the effects of these alterations on viral DNA synthesis and replication. Our results demonstrated that both changes in highly conserved PPT positions and a mutation that left only the cleavage-proximal half of the PPT intact led to delayed replication and reduced the colony-forming titer of replication defective retroviral vectors. A mutation that altered the cleavage proximal half of the PPT and certain 3' untranslated region mutations upstream of the PPT were incompatible with or severely impaired viral replication. To distinguish defects in plus-strand priming from other replication defects and to assess the relative use of mutant and wild-type PPTs, we examined plus-strand priming from an ectopic, secondary PPT inserted in U3. The results demonstrated that the analyzed mutations within the PPT primarily affected plus-strand priming whereas mutations upstream of the PPT appeared to affect both plus-strand priming and other stages of viral replication.

Identification of a sequence element immediately upstream of the polypurine tract that is essential for replication of simian immunodeficiency virus

A short stretch of T-rich sequences immediately upstream of the polypurine tract (PPT) is highly conserved in the proviral genomes of human and simian immunodeficiency viruses (HIV and SIV). To investigate whether this 'U-box' influences SIVmac239 replication, we analyzed the properties of mutants with changes in this region of the viral genome. All mutants were either retarded in their growth (up to one month delay) or did not replicate detectably in CEMx174 cells. When U-box mutants did replicate detectably, compensatory changes were consistently observed in the viral genome. The most common compensatory change was the acquisition of thymidines immediately upstream of the PPT, but marked expansion in the length of the PPT was also observed. U-box mutants produced transiently by transfection were severely impaired in their ability to produce reverse transcripts in infectivity assays. Analysis of transiently produced mutant virus revealed no defect in RNA packaging or virus assembly. These results identify a new structural element important for an early step in the viral life cycle that includes reverse transcription.

Interaction of retroviral reverse transcriptase with template-primer duplexes during replication

Conversion of the single-stranded RNA of an invading retrovirus into double-stranded proviral DNA is catalyzed in a multi-step process by a single virus-coded enzyme, reverse transcriptase (RT). Achieving this requires a combination of DNA polymerase abd ribonuclease H (RNase H) activities, which are located at the amino and carboxy terminus of the enzyme, respectively. Moreover, proviral DNA synthesis requires that three structurally-distinct nucleic acid duplexes are accommodated by this enzyme, namely (a) A-form RNA (initiation of minus strand synthesis), non-A, non-B RNA/DNA hybrid (minus strand synthesis and initiation of plus strand synthesis) and B-form duplex DNA (plus strand synthesis). This review summarizes our current understanding of the manner in which retroviral RT interacts with this diverse array of nucleic acid duplexes, exploiting in many cases mutants unable to catalyze a specific event. These studies illustrate that seemingly 'simple' events such as tRNA-primed initiation of minus strand synthesis are considerably more complex, involving intermolecular tRNA-viral RNA interactions outside the primer binding site. Moreover, RNase H activity, generally thought to catalyze non-specific degradation of the RNA-DNA replicative intermediate, is required for highly specialized events including DNA strand transfer and polypurine selection. Finally, a unique structure near the center of HIV proviral DNA, the central termination sequence, serves to halt the replication machinery in a manner analogous to termination of transcription. As these highly specialized events are better understood at the molecular level, they may open new avenues of therapeutic intervention in the continuing effort to stem the progression of HIV infection and AIDS.

Maintenance of an unusual polypurine tract in HIV-2: stability to passage in culture

A stretch of purine residues, the polypurine tract (PPT), is found in all retroviruses and is used to initiate plus-strand DNA synthesis. While the PPT of most lentiviruses is a homogeneous sequence of purine residues, the PPT of some isolates of the human and simian immunodeficiency viruses is interrupted with a single pyrimidine residue. The ROD strain of human immunodeficiency virus type 2 (HIV-2) has such a pyrimidine-containing variant PPT. Virus generated from an infectious molecular clone, pROD10, was used to infect two CD4-positive T-cell lines, H9 and CEM. The sequence of the PPT was determined after two passages. From both cell lines, the variant PPT was retained, demonstrating that the presence of a pyrimidine in the PPT was fully functional and that there was no strong selection for an all-purine PPT.

Sequence and structural determinants required for priming of plus-strand DNA synthesis by the human immunodeficiency virus type 1 polypurine tract

At the 3' end of all retroviral genomes there is a short, highly conserved sequence known as the polypurine tract (PPT), which serves as the primer for plus-strand DNA synthesis. We have identified the determinants for in vitro priming by the human immunodeficiency virus type 1 (HIV-1) PPT. We show that when the PPT is removed and placed into different nucleotide contexts, new priming sites are produced at the precise 3' end of the PPT. In addition, we find that a hybrid consisting of a 15- or 20-nucleotide RNA primer annealed to a 35-nucleotide DNA template is competent for initiation of plus-strand synthesis with HIV-1 reverse transcriptase. Thus, no cis-acting elements appear to be required for priming activity. Changes at the 5' end of the PPT have no effect on primer function, whereas the identity of bases at the 3' end is crucial. A primer containing only the 6 G residues from the 3' end of the wild-type PPT sequence and 9 bases of random sequence at the 5' end functions like a wild-type PPT. A short hybrid having a similar helical structure but a primary sequence different from that of the PPT is cleaved imprecisely, resulting in initiation of synthesis at multiple sites; however, total primer extension is close to the wild-type level. We conclude that helical structure as well as the presence of particular bases at the 3' end of the PPT is essential for PPT function.

DNA recombination is sufficient for retroviral transduction

Oncogenic retroviruses carry coding sequences that are transduced from cellular protooncogenes. Natural transduction involves two nonhomologous recombinations and is thus extremely rare. Since transduction has never been reproduced experimentally, its mechanism has been studied in terms of two hypotheses: (i) the DNA model, which postulates two DNA recombinations, and (ii) the RNA model, which postulates a 5' DNA recombination and a 3' RNA recombination occurring during reverse transcription of viral and protooncogene RNA. Here we use two viral DNA constructs to test the prediction of the DNA model that the 3' DNA recombination is achieved by conventional integration of a retroviral DNA 3' of the chromosomal protooncogene coding region. For the DNA model to be viable, such recombinant viruses must be infectious without the purportedly essential polypurine tract (ppt) that precedes the 3' long terminal repeat (LTR) of all retroviruses. Our constructs consist of a ras coding region from Harvey sarcoma virus which is naturally linked at the 5' end to a retroviral LTR and artificially linked at the 3' end either directly (construct NdN) or by a cellular sequence (construct SU) to the 5' LTR of a retrovirus. Both constructs lack the ppt, and the LTR of NdN even lacks 30 nucleotides at the 5' end. Both constructs proved to be infectious, producing viruses at titers of 10(5) focus-forming units per ml. Sequence analysis proved that both viruses were colinear with input DNAs and that NdN virus lacked a ppt and the 5' 30 nucleotides of the LTR. The results indicate that DNA recombination is sufficient for retroviral transduction and that neither the ppt nor the complete LTR is essential for retrovirus replication. DNA recombination explains the following observations by others that cannot be reconciled with the RNA model: (i) experimental transduction is independent of the packaging efficiency of viral RNA, and (ii) experimental transduction may invert sequences with respect to others, as expected for DNA recombination during transfection.

Pausing by retroviral DNA polymerases promotes strand transfer from internal regions of RNA donor templates to homopolymeric acceptor templates

We have examined the ability of reverse transcriptases (RT) to catalyze strand transfer from internal regions of RNA templates, resulting in switching of a primer from one template to another. To study this phenomenon, we employed a system of donor and acceptor templates in which homologous strand transfer can occur from a homopolymeric sequence, positioned internally on the donor template. Our results indicate that reverse transcriptases from human immunodeficiency virus (HIV), avian myeloblastosis virus (AMV), and murine leukemia virus (MuLV) are all able to catalyze strand transfer from this sequence. Catalysis of this reaction is not dependent upon ribonuclease H (RNase H) activity, since an RNase H-deficient form of HIV-RT is able to catalyze the reaction efficiently. Additionally, N-ethylmaleimide, which inhibits RNase H but not polymerase activity, did not inhibit the template switching by either the native or RNase H-deficient forms of HIV-RT. Our data further indicate that template switching may be promoted by RT pausing at a specific site on the donor template. Conditions that increase RT pausing at this site also increase template switching. These results suggest that transient RT pausing at specific sites on the viral genome during reverse transcription may promote template switches that in turn lead to recombination.

Sequence comparison and mutational analysis of elements that may be involved in the regulation of DNA synthesis in HIV-1

The large number of sequenced clones of HIV-1 and related viruses made it possible to indicate conserved elements with potential regulatory or structural functions. Such analysis was combined with directed mutagenesis in order to investigate the importance of elements that may influence the initiation of plus-strand DNA synthesis. The main site for plus-strand initiation is a polypurine tract near the 3' end of the viral RNA (the 3' PPT). An exact copy of this PPT is located in the middle of the genome (the internal PPT). Upstream from the internal PPT there is an inverted repeat. Mutants designed to upset the internal PPT (i.e., purine to pyrimidine changes), as well as mutants designed to abolish the potential stem-loop formation (changes around the internal PPT or in the upstream inverted repeat) both resulted in viruses with a reduced ability to replicate. Upsetting the stem-loop formation was, however, less harmful than changing the polypurine nature of the PPT. Changing a conserved T on the 3' side of the PPT to a C did not affect the phenotype.

Incomplete removal of the RNA primer for minus-strand DNA synthesis by human immunodeficiency virus type 1 reverse transcriptase

A synthetic RNA oligonucleotide (15-mer) corresponding to the 3' end of the lysine tRNA primer was hybridized to single-stranded DNA containing the human immunodeficiency virus type 1 (HIV-1) primer-binding site and extended with a DNA polymerase. The resulting structures were used to study primer removal by the RNase H activity of HIV-1 reverse transcriptase. The initial cleavage event removes the RNA primer as a 14-mer and leaves a single ribonucleotide A residue bound to the 5' end of the DNA strand. This result explains the observation by several groups that HIV-1 circle junctions contain 4 bp that are not present in the integrated provirus instead of the predicted 3 bp. Subsequent cleavage events occur at other sites internal to the RNA molecule, and the ribonucleotide A residue on the end of the DNA strand is ultimately removed. Therefore, the biologically relevant cleavage that produces the 14-mer reflects the kinetics of the reaction as well as a specificity for nucleic acid sequence. When the RNA oligonucleotide alone was hybridized to the primer-binding site and tested as a substrate for HIV-1 RNase H, the cleavage pattern near the 3' end of the RNA was altered.

Plus-strand origin for human immunodeficiency virus type 1: implications for integration

The start site for human immunodeficiency virus type 1 plus strands within the polypurine tract was mapped by an in vitro analysis to the sequence 5'-ACTG....From this result, it can be inferred that integration of human immunodeficiency virus type 1 must be accompanied by the loss of two base pairs from the polypurine tract-primed long terminal repeat end.

Specificities involved in the initiation of retroviral plus-strand DNA

Reverse transcription of the retroviral RNA genome begins with tRNA-primed synthesis of a minus-strand DNA, which subsequently acts as the template for the synthesis of plus-strand DNA. This plus-strand DNA is initiated at a unique location and makes use of a purine-rich RNA oligonucleotide derived by RNase H action on the viral RNA. To determine the variables that are relevant to successful specific initiation of plus-strand DNA synthesis, we have used nucleic acid sequences from the genome of Rous sarcoma virus along with three different sources of RNase H: avian myeloblastosis virus DNA polymerase, murine leukemia virus DNA polymerase, and the RNase H of Escherichia coli. Our findings include evidence that specificity is controlled not only by the nucleic acid sequences but also by the RNase H. For example, while the avian reverse transcriptase efficiently and specifically initiates on the sequences of the avian retrovirus, the murine reverse transcriptase initiates specifically but at a location 4 bases upstream of the correct site.

Ribonucleases H of retroviral and cellular origin

Ribonucleases H (RNases H) are enzymes which catalyse the hydrolysis of the RNA-strand of an RNA-DNA hybrid. Retroviral reverse transcriptases possess RNase H activity in addition to their RNA- as well as DNA-dependent DNA-polymerizing activity. These enzymes transcribe the viral single stranded RNA-genome into double stranded DNA, which then can be handled by the host cell like one of its own genes. Various, sometimes highly repeated, sequences related to retroviruses and like these encompassing two separate domains, one of which potentially codes for a DNA polymerizing, the other for an RNase H activity, are found in genomes of uninfected cells. In addition proteins coded for by cellular genes (e.g. from E. coli and from yeast) are known, which exhibit RNase H activity, the biological function of which is not fully understood. In the light of these facts the question of whether retroviral RNases H could be promising targets for antiviral drugs is discussed.

Magnesium transport in Salmonella typhimurium: expression of cloned genes for three distinct Mg2+ transport systems

In Salmonella typhimurium, the corA, mgtA, and mgtB loci are involved in active transport of Mg2+ (S. P. Hmiel, M. D. Snavely, C. G. Miller, and M. E. Maguire, J. Bacteriol. 168:1444-1450, 1988; S. P. Hmiel, M. D. Snavely, J. B. Florer, M. E. Maguire, and C. G. Miller, J. Bacteriol. 171:4742-4751, 1989). In this study, the gene products coded for by the corA, mgtA, and mgtB genes were identified by using plasmid expression in Escherichia coli maxicells. Complementation was assessed by introducing plasmids into a Mg2+-dependent corA mgtA mgtB strain and determining the ability of the plasmid to restore growth on medium without a Mg2+ supplement. Complementing plasmids containing corA expressed a 42-kilodalton (kDa) protein. This protein was not expressed by plasmids containing insertions or deletions that eliminated complementation. A plasmid containing mgtA expressed 37- and 91-kDa gene products. Data obtained with subclones and insertions in this plasmid indicated that plasmids expressing only the 91-kDa polypeptide complemented; plasmids that did not express this protein did not complement regardless of whether they expressed the 37-kDa protein. Plasmids carrying mgtB expressed a single protein of 102 kDa whose presence or absence correlated with the ability of the plasmid to complement the Mg2+-dependent triple mutant. Fractionation of labeled maxicells demonstrated that the 42-kDa corA, the 91-kDa mgtA, and the 102-kDa mgtB gene products are all tightly associated with the membrane, a location consistent with involvement in a transport process. These data provide further support the for existence of three distinct systems for Mg2+ transport in S. typhimurium.

Avian retroviral vectors derived from avian defective leukemia virus: role of the translational context of the inserted gene on efficiency of the vectors

We have constructed retroviral vectors derived from the genome of avian erythroblastosis virus ES4 (AEV ES4). The neo selectable gene was substituted for the original v-erbA or v-erbB oncogenes of AEV, either in the same or in a different reading frames. Recombinant retrovirus were rescued and used to infect chicken embryo fibroblasts or quail QT6 cells. When the neo gene was inserted in the same reading frame as the original oncogene, we obtained (1) a high level of expression of the neo gene, (2) a balanced ration of both genomic and subgenomic RNAs, and (3) high titer recombinant viruses. Conversely, when the neo gene was inserted in a reading frame different from that of the original oncogene, we observed (1) a very low level of expression of the neo protein, (2) a predominance of the viral transcript used as translational template for the neo protein synthesis, and (3) low titer recombinant viruses. One of the vectors was used to transfer a human delta-globin gene into avian cells in culture without detectable rearrangement of this gene, but exhibited a deletion within the conserved noncoding region located between the two original oncogenes. Our data provide information for further construction of double expression vectors. Furthermore, three of the vectors would provide helpful tools to identify genetic elements of the virus genome involved in splicing regulation.

The LTR, v-src, LTR provirus generated in the mammalian genome by src mRNA reverse transcription and integration

Different types of altered proviruses of Rous sarcoma virus (RSV) have been detected in mammalian tumor cell lines. We cloned and sequenced one of these altered proviruses with the structure LTR, v-src, LTR. The presence of an intact viral splice junction, as well as duplications of the chromosomal sequence GCGGGG flanking the two 2-base-pair-deleted LTRs, demonstrated reverse transcription and normal retroviral integration of src mRNA in mammalian cells. In addition, a 1-nucleotide deletion 2 bases upstream from the AAUAAA polyadenylation signal is suspected to be responsible for the absence of a poly(A) track in the src mRNA present in virions of rescued viruses.

Development of avian sarcoma and leukosis virus-based vector-packaging cell lines

We have constructed an avian leukosis virus derivative with a 5' deletion extending from within the tRNA primer binding site to a SacI site in the leader region. Our aim was to remove cis-acting replicative and/or encapsidation sequences and to use this derivative, RAV-1 psi-, to develop vector-packaging cell lines. We show that RAV-1 psi- can be stably expressed in the quail cell line QT6 and chicken embryo fibroblasts and that it is completely replication deficient in both cell types. Moreover, we have demonstrated that QT6-derived lines expressing RAV-1 psi- can efficiently package four structurally different replication-defective v-src expression vectors into infectious virus, with very low or undetectable helper virus release. These RAV-1 psi--expressing cell lines comprise the first prototype avian sarcoma and leukosis virus-based vector-packaging system. The construction of our vectors has also shown us that a sequence present within gag, thought to facilitate virus packaging, is not necessary for efficient vector expression and high virus production. We show that quantitation and characterization of replication-defective viruses can be achieved with a sensitive immunocytochemical procedure, presenting an alternative to internal selectable vector markers.

The role of Moloney murine leukemia virus RNase H activity in the formation of plus-strand primers

On the basis of earlier studies with both detergent-disrupted virions (the endogenous reaction) and an in vitro reconstructed reaction, the RNase H activity associated with Moloney murine leukemia virus reverse transcriptase has been implicated in the generation of plus-strand RNA primers during reverse transcription. Here we used an oligonucleotide extension assay to show that the RNA primers remaining bound to the plus DNA strands initiated at the normal origin in the in vitro reaction are heterogeneous in length. This result indicates that, although a precise cleavage generates the 3' end of the priming RNA, RNase H exhibits less specificity at other break sites. During the endogenous reaction, a kinetic analysis of the synthesis of plus strands corresponding to different regions of the genome suggested that additional sites for the initiation of plus-strand DNA existed upstream of the normal origin. Direct analysis of fragments produced in the endogenous reaction, as well as in the in vitro reaction, confirmed the existence of upstream plus-strand initiation sites. Several of these sites were mapped to the nucleotide level by the oligonucleotide extension method. A comparison of the nucleotide sequences surrounding the upstream initiation sites with the sequence at the normal plus-strand origin revealed common features, which suggests a mechanism for plus-strand priming based on sequence recognition by the RNase H/reverse transcriptase protein. Although primer removal by RNase H is highly efficient for DNA fragments initiated at the normal origin, the RNA primers were inefficiently removed from the fragments initiated at the upstream sites. This result suggests that primer removal, like primer generation, involves sequence recognition by the enzyme.

Complete nucleotide sequence of a milk-transmitted mouse mammary tumor virus: two frameshift suppression events are required for translation of gag and pol

We sequenced two recombinant DNA clones constituting a single provirus of the milk-transmitted mouse mammary tumor virus characteristic of BR6 mice. The complete provirus is 9,901 base pairs long, flanked by 6 base-pair duplications of cellular DNA at the site of integration. Five extensive blocks of open reading frame corresponding to the gag gene, the presumed protease, the pol and env genes, and the open reading frame orf within the long terminal repeat of the provirus were readily discernible. Translation of gag, protease, and pol involved three different translational reading frames to produce the three overlapping polyprotein precursors Pr77, Pr110, and Pr160 found in virus-infected cells. Synthesis of the reverse transcriptase and endonuclease therefore required two separate frameshifts to suppress the termination codons at the ends of the Pr77 and Pr110 domains. Direct evidence is presented for translational readthrough of both stop codons in an in vitro protein synthesis system.

Evidence of sequences resembling avian retrovirus long terminal repeats flanking the trout protamine gene

Additional TATA boxes are present in the flanking regions of trout protamine genes. Their activity as promoters was assayed using an in vitro transcription system. These additional TATA boxes, together with polyadenylation signals that include the consensus AATAAA and CACTG sequences very close to the promoters, suggest that these sequences may be closely related to retroviral long terminal repeat (LTR) sequences. Other features of retroviral LTRs that are also present are short inverted repeats. The LTR-like sequences flanking the trout protamine gene show significant homology to the avian sarcoma virus LTR over a 40-bp region. The trout protamine gene falls into the relatively rare intronless class of eukaryotic genes. This suggests that the gene could have been derived from a processed gene introduced into the genome by reverse transcription of a mature mRNA. The protamine-mRNA-coding region is flanked by AACA... TGTT sequences, which might represent vestigial traces of past recombination events and whose presence supports the notion that the protamine gene sequence was of foreign origin. Recent attempts in this laboratory to transfer the protamine gene into mouse cells have resulted in a high frequency of deletions similar to those observed with constructs in which a retrovirus was used as a vector to transfect foreign DNA with promoters. The distribution of protamine genes in the animal kingdom is very sporadic, which suggests that protamine genes appeared relatively late in evolution. The nonuniform occurrence of the gene among lower vertebrates may have been the result of its horizontal transmission only to certain species, possibly by infection with retroviruses that acquired it from a different species.

Evolutionary variants of Rous sarcoma virus: large deletion mutants do not result from homologous recombination

Large deletion (LD) mutants of Prague strain Rous sarcoma virus, subgroup B (PrB), derived by serial undiluted passage through chicken (C/E) cells, were isolated and characterized. Individual LD viruses were initially isolated by cloning in soft agar of infected, chemically transformed quail (QT6) cells. Two regions of the PrB genome were deleted in the formation of the LD virus. This resulted in the junction of gag sequences in p12 to env sequences in gp37, and in the loss of the src gene. DNA restriction analysis of biologically active lambda Charon 27-LD recombinant clones indicated that individual LD viruses contained similar but not identical deletion endpoints. Two LD isolates, LD25 and LD85, were further subcloned into pBR322, and the deletion junctions were examined by DNA sequencing. Although the gag-env deletion endpoints were identical in the two subclones, heterogeneity was observed across the src deletion in that both mutants analyzed had the same 5' endpoint but slightly different 3' endpoints. In all cases, only a single homologous base (always an A residue) was found at the deletion endpoint. S1 nuclease analysis of the RNA from a number of QT6-LD clones gave similar results, indicating that the LD population was composed of viruses with similar but not identical deletion endpoints. Such viruses may have been generated from errors during reverse transcription of the virion RNA with subsequent selection assuring their dominance in the population.

Amphotropic retrovirus vector system for human cell gene transfer

Retroviral vectors have been constructed for gene transfer in mammalian and avian cells, however most retroviral vector systems are complicated by the spread of a replication-competent helper virus. This problem has been circumvented by segregating the viral genome into cis- and trans-acting components. By establishing helper cell lines that produce the trans-acting viral gene products, one can propagate the cis-acting component in them and harvest defective viral particles that contain only the cis-acting component. The cis-acting component can provide a useful vehicle for the highly efficient transfer of genes into target cells. The defective vector systems described to date, however, are restricted in host range to murine, avian, rat, and dog cells. We describe a helper-free vector system based entirely on an amphotropic murine virus with a wide mammalian host range, including the ability to carry out efficient gene transfer into human cells. We also describe a double mutation constructed in the trans-acting genome which reduces the frequency of replication-competent recombinant viruses to undetectable levels.

Specificity of initiation of plus-strand DNA by Rous sarcoma virus

We previously reported that in the endogenous reaction of Rous sarcoma virus disrupted by melittin, plus-strand DNA initiates on a small oligonucleotide primer and that this initiation can be reconstructed in vitro in reactions containing purified minus-strand DNA as template, viral RNA as a source of primer, and reverse transcriptase (Smith et al., J. Virol. 49:200-204, 1984). Further studies on the specificity of initiation in the endogenous reaction have shown the following. (i) The primer was 12 nucleotides in length. Its sequence began with a 5' pyrimidine, followed by 11 purines, ending with rGrA-3'. This sequence was in agreement with the known plus-strand RNA sequence immediately upstream from the initiation site. Thus, the primer began one nucleotide 5' to the so-called polypurine tract that has been found on all retrovirus genomes. (ii) The transition point between RNA primer and DNA product was precisely located. It was before the end of the polypurine tract. Thus the polypurine tract, although essential for virus replication and probably a flag for the priming event, did not define the limits of the RNA primer. After primer removal, the DNA had a 5' phosphate, consistent with generation by the viral RNase H activity. The priming specificity in reconstructed reactions was also examined further, with the following observations. (i) When the source of RNA primer was prehybridized to the template viral DNA, the generation, utilization, and subsequent removal of primer were essentially the same as those observed in the endogenous reaction. In the absence of deliberate prehybridization, some specificity was lost. There were than additional locations for the 5' end of the primer as well as the transition point between RNA primer and DNA. (ii) Purine-rich oligoribonucleotides created by RNase A digestion of viral RNA could prime strong-stop plus DNA, but again with the loss of specificity relative to that in the endogenous reaction. (iii) The 5' end of the minus-strand DNA template was not required for initiation of strong-stop plus DNA. Therefore, the specificity of initiation did not depend upon an intramolecular interaction requiring the two inverted repeat sequences that flank the long terminal repeat.

Amphotropic retrovirus vector system for human cell gene transfer

Retroviral vectors have been constructed for gene transfer in mammalian and avian cells, however most retroviral vector systems are complicated by the spread of a replication-competent helper virus. This problem has been circumvented by segregating the viral genome into cis- and trans-acting components. By establishing helper cell lines that produce the trans-acting viral gene products, one can propagate the cis-acting component in them and harvest defective viral particles that contain only the cis-acting component. The cis-acting component can provide a useful vehicle for the highly efficient transfer of genes into target cells. The defective vector systems described to date, however, are restricted in host range to murine, avian, rat, and dog cells. We describe a helper-free vector system based entirely on an amphotropic murine virus with a wide mammalian host range, including the ability to carry out efficient gene transfer into human cells. We also describe a double mutation constructed in the trans-acting genome which reduces the frequency of replication-competent recombinant viruses to undetectable levels.

Mutagenesis of the region between env and src of the SR-A strain of Rous sarcoma virus for the purpose of constructing helper-independent vectors

The major goal of these experiments is to derive stable, helper independent, retroviral vectors using the SR-A strain of Rous sarcoma virus. Because src is flanked by direct repeats of 110 bases, both src, and sequences that replace src in vector constructions, are lost at high frequency. We have sought to eliminate this homology in order to stabilize the vectors. One copy of the direct repeat must be retained for the virus to replicate properly. Because the downstream direct repeat is linked to the polypurine tract the entire downstream direct repeat cannot easily be eliminated. We therefore sought to eliminate the upstream direct repeat. Using linkers a series of defined deletions and duplications has been created within the region between env and src. The region is relatively large, 379 bases, and has a complex history (it is derived from three different nucleic acid segments each with a distinct and separate origin). We show here that this region provides no functions essential for growth and, for src expression, provides only a functional splice acceptor. We were able to successfully replace the splice acceptor found in the wild type virus with an unrelated splice acceptor partially derived from a synthetic DNA segment. The final product is a replication competent virus that expresses src, and that lacks the entire upstream repeat. Since src is flanked by ClaI sites in these constructions, src can easily be replaced by other genes. Substituting the Tn5 neo gene for src in this construction yields a virus that expresses the neo gene nonselectively.

RNA-primed initiation of Moloney murine leukemia virus plus strands by reverse transcriptase in vitro

A 190-base-pair DNA-RNA hybrid containing the Moloney murine leukemia virus origin of plus-strand DNA synthesis was constructed and used as a source of template-primer for the reverse transcriptase in vitro. Synthesis was shown to initiate precisely at the known plus-strand origin. The observation that some of the origin fragments retained ribonucleotide residues on their 5' ends suggests that the primer for chain initiation is an RNA molecule left behind by RNase H during the degradation of the RNA moiety of the DNA-RNA hybrid. If the RNase H is responsible for creating the correct primer terminus, then it must possess a specific endonucleolytic activity capable of recognizing the sequence in the RNA where plus strands are initiated. The 16-base RNase A-resistant fragment which spans the plus-strand origin can also serve as a source of the specific plus-strand primer RNA. Evidence is presented that some of the plus-strand origin fragments synthesized in the endogenous reaction contain 5' ribonucleotides, suggesting that specific RNA primers for plus-strand initiation may be generated during reverse transcription in vivo as well.

Construction of a helper cell line for avian reticuloendotheliosis virus cloning vectors

We wished to construct cell lines that supply the gene products of gag, pol, and env for the growth of replication-defective reticuloendotheliosis retrovirus vectors without production of the helper virus. To do this, first we located by S1 mapping the donor and acceptor splice sites of reticuloendotheliosis virus strain A. The donor splice site is ca. 850 base pairs from the 5' end of proviral DNA. It is close to or overlaps the encapsidation sequences for viral RNA. The splice acceptor site is ca. 5.6 kilobase pairs from the 5' end of proviral DNA. Therefore, the encapsidation sequences and the donor splice site were removed from viral DNA to give expression of the gag and pol genes without virus production. The promoter in the long terminal repeat was fused to a site near the first ATG codon of the env gene, thereby deleting the encapsidation sequences and the gag and pol genes to give expression of the env gene without virus production. The permissive canine cell line D17 was transfected with the two modified viral DNAs. Two cell clones that contain both modified viral DNAs support the production of replication-defective spleen necrosis virus-thymidine kinase recombinant retrovirus vectors without the production of helper virus. To prevent recombination, the vector contains deletions that overlap with deletions in the integrated helper virus DNAs. This helper cell-vector system will be useful to derive infectious recombinant virus stocks of high titer (over 10(5) thymidine kinase transforming units per ml) which are able to infect avian, rat, and dog cells without the aid of helper virus.

Nucleotide sequence analysis of the long terminal repeat of integrated bovine leukemia provirus DNA and of adjacent viral and host sequences

The nucleotide sequence of the 3' long terminal repeat and adjacent viral and host sequences was determined for a bovine leukemia provirus cloned from a bovine tumor. The long terminal repeat was found to comprise 535 nucleotides and to harbor at both ends an imperfect inverted repeat of 7 bases. Promoter-like sequences (Hogness box and CAT box), an mRNA capping site, and a core enhancer-related sequence were tentatively located. No kinship was detected between this bovine leukemia proviral fragment and other retroviral long terminal repeats, including that of human T-cell leukemia virus.

Construction of a helper cell line for avian reticuloendotheliosis virus cloning vectors

We wished to construct cell lines that supply the gene products of gag, pol, and env for the growth of replication-defective reticuloendotheliosis retrovirus vectors without production of the helper virus. To do this, first we located by S1 mapping the donor and acceptor splice sites of reticuloendotheliosis virus strain A. The donor splice site is ca. 850 base pairs from the 5' end of proviral DNA. It is close to or overlaps the encapsidation sequences for viral RNA. The splice acceptor site is ca. 5.6 kilobase pairs from the 5' end of proviral DNA. Therefore, the encapsidation sequences and the donor splice site were removed from viral DNA to give expression of the gag and pol genes without virus production. The promoter in the long terminal repeat was fused to a site near the first ATG codon of the env gene, thereby deleting the encapsidation sequences and the gag and pol genes to give expression of the env gene without virus production. The permissive canine cell line D17 was transfected with the two modified viral DNAs. Two cell clones that contain both modified viral DNAs support the production of replication-defective spleen necrosis virus-thymidine kinase recombinant retrovirus vectors without the production of helper virus. To prevent recombination, the vector contains deletions that overlap with deletions in the integrated helper virus DNAs. This helper cell-vector system will be useful to derive infectious recombinant virus stocks of high titer (over 10(5) thymidine kinase transforming units per ml) which are able to infect avian, rat, and dog cells without the aid of helper virus.

cis-Acting RNA packaging locus in the 115-nucleotide direct repeat of Rous sarcoma virus

The v-src gene of Schmidt-Ruppin strain A of Rous sarcoma virus is flanked by a 115-nucleotide direct repeat. Mutants that lack either the upstream or downstream copy replicate normally. However, mutants that lack both copies do not replicate. Cloned viral DNA lacking both copies of the 115-nucleotide sequence is capable of directing the transcription of viral RNA posttransfection. This viral RNA is polyadenylated, spliced, exported from the nucleus, and translated into protein normally. However, virions isolated from the culture medium 48 h posttransfection lack viral RNA. When mutant DNA is contransfected with wild-type DNA, the virions produced 48 h later contain wild-type RNA but not mutant RNA, even though both RNAs are present in the cytoplasm. We propose that the 115-nucleotide element of Rous sarcoma-avian leukosis virus encodes a cis-acting sequence that is necessary for the proper incorporation of viral RNA into virions.

The terminal nucleotides of retrovirus DNA are required for integration but not virus production

Deletion of specific nucleotides at either end of the long terminal repeat of the avian retrovirus, spleen necrosis virus, results in replication-competent but integration-defective virus. This result supports two conclusions: (1) the 5-base pair terminal inverted repeats and three to seven adjacent nucleotides are required for integration; (2) integration of retrovirus DNA is not required for retrovirus gene expression.

Mutants of Dictyostelium discoideum blocked in expression of all members of the developmentally regulated discoidin multigene family

Mutant strains of D. discoideum are described that can complete morphogenesis and cytodifferentiation but which express vastly reduced levels of the galactose-binding lectins discoidin I and II (less than 1% and 1%-2% respectively) compared to the wild-type control. Mutant cells proceeding through development lack lectin activity, lectin protein, and specific lectin mRNA. In contrast, the genes encoding these proteins are present in their wild-type configurations in the genome. Since these proteins are encoded by four to five discrete genes, the mutations in these strains are most likely in genes involved in the regulation of the expression of members of this multigene family. The results also indicate that the discoidin lectins may not be required for fruiting body construction in this organism. Finally, coupled with the recent ability to transform D. discoideum, these mutants open the way to identification and isolation of regulatory genes and their products.

Nucleotide sequence of the envelope gene of Gardner-Arnstein feline leukemia virus B reveals unique sequence homologies with a murine mink cell focus-forming virus

The nucleotide sequence of the envelope gene and the adjacent 3' long terminal repeat (LTR) of Gardner-Arnstein feline leukemia virus of subgroup B (GA-FeLV-B) has been determined. Comparison of the derived amino acid sequence of the gp70-p15E polyprotein to those of several previously reported murine retroviruses revealed striking homologies between GA-FeLV-B gp70 and the gp70 of a Moloney virus-derived mink cell focus-forming virus. These homologies were located within the substituted (presumably xenotropic) portion of the mink cell focus-forming virus envelope gene and comprised amino acid sequences not present in three ecotropic virus gp70s. In addition, areas of insertions and deletions, in general, were the same between GA-FeLV-B and Moloney mink cell focus-forming virus, although the sizes of the insertions and deletions differed. Homologies between GA-FeLV-B and mink cell focus-forming virus gp70s is functionally significant in that they both possess expanded host ranges, a property dictated by gp70. The amino acid sequence of FeLV-B contains 12 Asn-X-Ser/Thr sequences, indicating 12 possible sites of N-linked glycosylation as compared with 7 or 8 for its murine counterparts. Comparison of the 3' LTR of GA-FeLV-B to AKR and Moloney virus LTRs revealed extensive conservation in several regions including the "CCAAT" and Goldberg-Hogness (TATA) boxes thought to be involved in promotion of transcription and in the repeat region of the LTR. The inverted repeats that flanked the LTR of GA-FeLV-B were identical to the murine inverted repeats, but were one base longer than the latter. The region of U3 corresponding to the approximately 75-nucleotide "enhancer sequence" is present in GA-FeLV-B, but contains deletions relative to AKR and Moloney virus and is not repeated. An interesting pallindrome in the repeat region immediately 3' to the U3 region was noted in all the LTRs, but was particularly pronounced in GA-FeLV-B. Possible roles for this structure are discussed.