Genome organization of RNA tumor viruses. I. In vitro synthesis of full-genome-length single-stranded and double-stranded viral DNA transcripts

Oligo(dT) primer generates a high frequency of truncated cDNAs through internal poly(A) priming during reverse transcription

We have analyzed a systematic flaw in the current system of gene identification: the oligo(dT) primer widely used for cDNA synthesis generates a high frequency of truncated cDNAs through internal poly(A) priming. Such truncated cDNAs may contribute to 12% of the expressed sequence tags in the current dbEST database. By using a synthetic transcript and real mRNA templates as models, we characterized the patterns of internal poly(A) priming by oligo(dT) primer. We further demonstrated that the internal poly(A) priming can be effectively diminished by replacing the oligo(dT) primer with a set of anchored oligo(dT) primers for reverse transcription. Our study indicates that cDNAs designed for genomewide gene identification should be synthesized by use of the anchored oligo(dT) primers, rather than the oligo(dT) primers, to diminish the generation of truncated cDNAs caused by internal poly(A) priming.

Synthesis of full-length viral DNA in CD4-positive membrane vesicles exposed to HIV-1. A model for studies of early stages of the hiv-1 life cycle

CD4-positive membrane vesicles (MV) were isolated under isotonic conditions from human T lymphoblastoid cells MT-2 and CEM and tested for their ability to support reverse transcription of viral RNA upon exposure to human immunodeficiency virus, type 1 (HIV-1). MV contained cytoplasms as confirmed by the presence of mitochondrial DNA but were devoid of chromosomal DNA. Virus binding and vesicle lysis assays revealed that 4-19% (depending upon virus dose) of MV-bound HIV-1 entered the vesicles. HIV-1 internalized in MV was able to initiate and complete viral DNA synthesis as determined by the detection of products of reverse transcription using polymerase chain reaction amplification of viral DNA using regions present in early (strong stop) transcripts and full-length double-stranded molecules. Viral DNA was undetectable in MV exposed to HIV-1 at 0 degrees C, in MV exposed to UV-inactivated virus at 37 degrees C, or after exposure to intact virus at 37 degrees C in the presence of reverse transcriptase inhibitors 2',3'-dideoxycytidine and a tetrahydroimidazo[4,5,1-jk](1,4)-benzodiazepin-2-(1H)-thione derivative, indicating that viral DNA detected in HIV-1-exposed MV was synthesized de novo. Kinetic studies revealed that HIV-1 DNA synthesis in MV was very rapid; full-length viral DNA was detected within 15 min of exposure at 37 degrees C, and the DNA levels increased 90-fold after 1 h and declined thereafter. Strong stop viral DNA was 10-fold more abundant than full-length DNA after 1 h at 37 degrees C, indicating that 10% of input viral genomes are fully transcribed in MV within this time frame. This system preserves the critical features of intact CD4-bearing cells to permit studies of HIV-1 entry, uncoating, and reverse transcription of viral RNA.

Development of a human immunodeficiency virus-1 in vitro DNA synthesis system to study reverse transcriptase inhibitors

A Human immunodeficiency virus type-1 endogenous reverse transcriptase reaction was developed as an in vitro assay to study the inhibition of reverse transcription by antiviral compounds. Conditions were established for producing genomic length (-) strand DNA in high yields and measuring the inhibition of this transcript as the assay endpoint. In addition to genomic length (-) strand DNA, a novel segmented (-) strand product composed of a 6.0 kb reverse transcript of the 5' 2/3 of the viral RNA genome and a 3.5 kb reverse transcript of the 3' 1/3 was observed. The most prominent (+) strand product was the size expected for plus-strong stop DNA. Additional minor (+) strand species were also observed. The triphosphate form of the nucleoside analog inhibitor 3'-azido-3'-deoxythymidine (RETROVIR, Zidovudine, AZT) and BI-RG-587 (nevirapine), a non nucleoside inhibitor, were used to demonstrate the utility of the endogenous system for the analysis of reverse transcriptase inhibitors. In a standard reaction, synthesis of genomic length DNA was 50% inhibited by 0.1 microM AZTTP and 0.1 microM nevirapine.

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.

Characterization of exogenous proviral sequences in hamster tumor cell lines transformed by Rous sarcoma virus rescued from XC cells

Alterations in viral structural genes have been studied in five cell lines derived from Syrian hamster tumors which had been induced by the virus rescued from XC cells by transfection. Two cell lines, H-18 and H-20, have all the viral structural genes expressed, but a new EcoRI recognition site appeared in the region of the pol gene sequence. Provirus present in H-12 lacks the 3' part of the gag gene sequences as well as the pol gene, therefore, it gives rise to an anomalous 1.8 Md EcoRI fragment. This line also does not synthesize viral RNA of genomic size, and none of the subgenomic RNAs found hybridized with the DNApol probe. The H-19 cell line harbors only the src gene and LTR sequences, the U3 part of which seems incomplete or different from that of PR-RSV. The cryptic proviral structure in H-19 is transcribed into src mRNA. The degree of transcription of the src gene is about 25 viral RNA equivalents per cell. The H-9 cells harbor the complete provirus and, in addition, proviral structures having the deletion in gag-pol genes. The possible ways of development of provirus alterations and the role of cryptic proviral sequences in oncogenesis are discussed.

Subgenomic mRNA in OK10 defective leukemia virus-transformed cells

OK10, a defective leukemia virus, is produced as a defective particle by so-called nonproducer transformed quail fibroblasts. OK10 defective viral particles contain an 8-kilobases (kb)-long genomic RNA, lack any detectable reverse transcriptase activity, and are not infectious. We studied the genetic content of OK10 RNA extracted from both virions and infected cells. As shown by RNA-cDNA hybridizations in stringent conditions, about 77% (6.4 kb) of the OK10 8.0kb RNA was related to avian leukosis viruses in the three structural genes gag, pol, and env, as well as in the c region. The remainder of the OK10 genome-encoding capacity (</=1.6 kb) was homologous to the MC29-specific transforming sequence myc(m) and therefore has been named myc(o). EcoRI restriction analysis of the OK10 integrated proviral DNA with different probes indicated the presence of only one provirus in the OK10 QB5 clone, which agreed with the gene order: 5'-gag-Deltapol-myc(o)-Deltaenv-c- 3'. Heteroduplex molecules formed between the viral OK10 8.0-kb RNA and the 6.8-kb SacI DNA fragment of the Prague A strain of Rous sarcoma virus confirmed that structure and indicated that the myc(o) sequence formed a continuous RNA stretch of 1.4 to 1.6 kb long between Deltapol and Deltaenv. We also examined the myc(o)-containing mRNA's transcribed in OK10-transformed cells. OK10-transformed quail fibroblasts (OK10 QB5) transcribed two mRNA species of 8.0 and 3.6 kb containing the myc(o) sequence. The genetic content of the 3.6-kb species made it a possible maturation product of the genome size 8-kb species by splicing out the gag and pol sequences. In OK10-transformed bone marrow cells (OK10 BM), a stable bone marrow-derived cell line producing OK10, the myc(o) sequence was found in four RNA species of 11.0, 8.0, 7.0, and 3.6 kb. Again, the genetic content of these mRNA's indicated that (i) the 3.6-kb species could be spliced out of the 8.0-kb-genome size mRNA and (ii) the 11.0-kb-long mRNA could represent a read-through of the OK10 provirus, the corresponding maturation product being, then, a 7.0-kb mRNA. The 7.0- and 3.6- kb mRNA's both contained the myc(o) sequence, but no sequences related to the gag or pol gene. In conclusion, whereas the myc sequences have been generally thought to be expressed through a gag-onc fusion protein, as for MC29 and CMII viruses, our experiments indicate that they could also be expressed as a non-gag-related product made from a subgenomic mRNA in the OK10-transformed cells.

M-MuLV-induced leukemogenesis: integration and structure of recombinant proviruses in tumors

M-MuLV-specific DNA probes were used to establish the state of integration and amplification of recombinant proviral sequences in Moloney virus-induced tumors of Balb/Mo, Balb/c and 129 mice. The somatically acquired viral sequences contain both authentic M-MuLV genomes and recombinants of M-MuLV with endogenous viral sequences. All reintegrated genomes carry long terminal repeat (LTR) sequences at both termini of their genome. In the preleukemic stage a large population of cells exhibiting a random distribution of reintegrated M-MuLV genomes are seen, but during outgrowth of the tumor, selection of cells occurs leaving one or a few clonal descendants in the outgrown tumor. In this latter stage recombinant genomes can be detected. Although these recombinants constitute a heterogeneous group of proviruses, characteristic molecular markers are conserved among many individual proviral recombinants, lending credence to the notion that a certain recombinant structure is a prerequisite for the onset of neoplasia. The structure of these recombinants shows close structural similarities to the previously described mink cell focus-inducing (MCF)-type viruses.

Characterization of the oncogene (erb) of avian erythroblastosis virus and its cellular progenitor

Avian erythroblastosis virus (AEV) induces primarily erythroblastosis when injected intravenously into susceptible chickens. In vitro, the hematopoietic target cells for transformation are the erythroblasts. Occasional sarcomas are also induced by intramuscular injection, and chicken or quail fibroblasts can be transformed in vitro. The transforming capacity of AEV was shown to be associated with the presence of a unique nucleotide sequence denoted erb in its genomic RNA. Using a simplified procedure, we prepared radioactive complementary DNA (cDNAaev) representative of the erb sequence at a high yield. Using a cDNAaev excess liquid hybridization technique adapted to defective retroviruses, we determined the complexity of the erb sequence to be 3,700 +/- 370 nucleotides. AEV-transformed erythroblasts, as well as fibroblasts, contained two polyadenylated viral mRNA species of 30 and 23S in similar high abundance (50 to 500 copies per cell). Both species were efficiently packaged into the virions. AEV-transformed erythroblasts contained additional high-molecular-weight mRNA species hybridizing with cDNAaev and cDNA5' but not with cDNA made to the helper leukosis virus used (cDNArep). The nature and the role, if any, of these bands remain unclear. The erb sequence had its counterpart in normal cellular DNA of all higher vertebrate species tested, including humans and fish (1 to 2 copies per haploid genome in the nonrepetitive fraction of the DNA). These cellular sequences (c-erb) were transcribed at low levels (1 to 2 RNA copies per cell) in chicken and quail fibroblasts, in which the two alleged domains of AEV-specific sequences corresponding to the 75,000- and 40,000-molecular-weight proteins seemed to be conserved phylogenetically and transcribed at similar low rates.

Independent recombination between avian leukosis virus terminal sequences and host DNA in virus-induced proliferative disease

A cDNA transcript of Rous sarcoma virus, which contained the long terminal repeat (LTR) and some additional 3'-terminal sequences, was inserted into the plasmid pBR322. This recombinant plasmid, p53, was then used as a hybridization probe to detect viral terminal sequences in DNA from a number of tissues of birds with a variety of avian leukosis virus (ALV)-induced proliferative diseases. Using restriction endonuclease digestion and blot hybridization analysis, we detected, in addition to standard ALV genomes, viral terminal sequences linked to host DNA and not to viral genes. In DNA from bursal lymphomas and nephroblastomas, we observed small numbers of integration sites occupied by sequences in p53 and lacking most or all of the remainder of the viral genome. In DNA from osteopetrosis, we observed apparently multiple copies of molecules containing host DNA linked to viral LTR sequences. Some of these structures were contained in discrete, probably unintegrated, DNA molecules. We concluded that viral LTR sequences can be inserted as independent elements during recombination with host DNA in some forms of interaction between exogenous retroviruses and host cells. Because the LTRs have been implicated in integration and transcription of viral genes, the possibility that translocation or activation, or both, of host genes may occur as a consequence of viral infection is reinforced by these observations.

Viral DNA synthesized in vitro by avian retrovirus particles permeabilized with melittin. I. Kinetics of synthesis and size of minus- and plus-strand transcripts

We have examined the kinetics of synthesis of minus [(-)]- and plus [(+)]-strand viral DNA in melittin-permeabilized avian retrovirus particles. The reaction was biphasic. There was a very rapid initial rate, followed, after approximately 1 h, by a lower rate. Many discrete bands of subgenomic-length (-) strands were produced after 10 and 20 min of synthesis; genome-length (7.7-kilobase [kb]) (-) strands were detected within 30 min. Extension to an 8.0-kb (-)-strand species was evident by 60 min. This extension was inhibited by actinomycin D. Synthesis of (+) strands (which is also inhibited by actinomycin D) began early, before any (-) strands were completed, and continued for more than 4 h beyond the time when synthesis of full-length DNA had terminated. Two distinct species of (+)-strand DNA, 0.27 and 0.35 kb, could be observed at the earliest times. Their presence was quickly obscured by subsequent formation of (+)-strand molecules of molecular length between 0.2 and 2.0 kb.

Synthesis of plus strands of retroviral DNA in cells infected with avian sarcoma virus and mouse mammary tumor virus

The vast majority of plus strands synthesized in quail cells acutely infected with avian sarcoma virus were subgenomic in size, generally less than 3 kilobases (kb). A series of discrete species could be identified after agarose gel electrophoresis by annealing with various complementary DNAs, indicating specificity in the initiation and termination of plus strands. The first plus strand to appear (within 2 h postinfection) was similar in length to the long redundancy at the ends of linear DNA (0.35 kb), and it annealed with complementary DNAs specific for the 3' and 5' termini of viral RNA (Varmus et al., J. Mol. Biol. 120:50-82, 1978). Several subgenomic plus-strand fragments (0.94, 1.38, 2.3, and 3.4 kb) annealed with these reagents. At least the 0.94- and 1.38-kb strands were located at the same end of linear DNA as the 0.35-kb strand, indicating that multiple specific sites for initiation were employed to generate strands which overlapped on the structural map. We were unable to detect RNA liked to plus strands isolated as early as 2.5 h postinfection; thus, the primers must be short (fewer than 50 to 100 nucleotides), rapidly removed, or not composed of RNA. To determine whether multiple priming events are a general property of retroviral DNA synthesis in vivo, we also examined plus strands of mouse mammary tumor virus DNA in chronically infected rat cells after induction of RNA and subsequent DNA synthesis with dexamethasone. In this case, multiple, discrete subgenomic DNA plus strands were not found when the same methods applied to avian sarcoma virus DNA were used; instead, the plus strands present in the linear DNA of mouse mammary tumor virus fell mainly into two classes: (i) strands of ca. 1.3 kb which appeared early in synthesis and were similar in size and genetic content to the terminally repeated sequence in linear DNA; and (ii) plus strands of the same length as linear DNA. A heterogeneous population of other strands diminished with time, was not found in completed molecules, and was probably composed of strands undergoing elongation. These two retroviruses thus appear to differ with respect to both the number of priming sites used for the synthesis of plus strands and the abundance of full-length plus strands. On the other hand the major subgenomic plus strand of mouse mammary tumor virus DNA (1.3 kb) is probably the functional homolog of a major subgenomic plus strand of avian sarcoma virus DNA (0.35 kb). The significance of this plus strand species is discussed in the context of current models which hold that it is used as a template for the completion of the minus strand, thereby generating the long terminal redundancy.

Structure of Moloney murine leukemia viral DNA: nucleotide sequence of the 5' long terminal repeat and adjacent cellular sequences

Some unintegrated and all integrated forms of murine leukemia viral DNA contain long terminal repeats (LTRs). The entire nucleotide sequence of the LTR and adjacent cellular sequences at the 5' end of a cloned integrated proviral DNA obtained from BALB/Mo mouse has been determined. It was compared to the nucleotide sequence of the LTR at the 3' end. The results indicate: (i) a direct 517-nucleotide repeat at the 5' and 3' termini; (ii) 145 nucleotides out of 517 nucleotides represent sequences between the 5'-CAP nucleotide and 3' end of the primer tRNA (strong-stop DNA); (iii) an 11-nucleotide inverted repeat is present at the ends of the 5'-LTR and a total of 17 out of 21 nucleotides at the termini are inverted repeats; (iv) sequences CAATAAAAG (at positions -24 to -31) and CAATAAAC (at positions +46 to +53) resembling the hypothetical DNA-dependent RNA polymerase II promoter site can be identified in the 5'-LTR; (v) the sequence GAAA appears to be repeated on both sides of the junction of viral and cellular sequences; and (vi) in analogy with the bacterial transposons, the presence of an inverted repeat sequence at the termini of 5'-LTR suggests that M-MLV also has the integration properties of a transposon.

Nucleotide sequence of Moloney leukemia virus: 3' end reveals details of replications, analogy to bacterial transposons, and an unexpected gene

We have determined the sequence of a cloned DNA fragment 1108 base pairs long which corresponds to the 3' end of the Moloney murine leukemia provirus. The clone was obtained as the primary product of reverse transcription and begins with the Moloney "strong stop" sequence, then extends towards the 5' end of the provirus. Our sequence: (i) proves that reverse transcriptase switches templates during minus strand synthesis; (ii) defines the limits of the 515-base-pair repeats which occupy both ends of the integrated provirus; (iii) shows that the structure of the proviral repeats has strong analogy to bacterial insertion sequences, indicating that the Moloney provirus is a transposon; (iv) identifies the putative promotor for genomic transcription within these repeats; (v) shows that the presumed origin of second strand synthesis, which lies just outside the 3' repeat, has tertiary structure analogous to single-stranded bacteriophage origins of replication; (vi) solves the amino acid sequence of most of pI5E, the carboxy-terminal product of the env gene; (vii) allows detailed mapping of the mink cell focus-forming virus substitution locus in a central location within the gp70 region of the env gene; and (viii) identifies a long open translation frame to the right of the env gene (R gene) which could be involved in leukemogenesis.

Molecular cloning of Snyder-Theilen feline leukemia and sarcoma viruses: comparative studies of feline sarcoma virus with its natural helper virus and with Moloney murine sarcoma virus

Extrachromosomal DNA obtained from mink cells acutely infected with the Snyder-Theilen (ST) strain of feline sarcoma virus (feline leukemia virus) [FeSV(FeLV)] was fractionated electrophoretically, and samples enriched for FeLV and FeSV linear intermediates were digested with EcoRI and cloned in lambda phage. Hybrid phages were isolated containing either FeSV or FeLV DNA "inserts" and were characterized by restriction enzyme analysis, R-looping with purified 26 to 32S viral RNA, and heteroduplex formation. The recombinant phages (designated lambda FeSV and lambda FeLV) contain all of the genetic information represented in FeSV and FeLV RNA genomes but lack one extended terminally redundant sequence of 750 bases which appears once at each end of parental linear DNA intermediates. Restriction enzyme and heteroduplex analyses confirmed that sequences unique to FeSV (src sequences) are located at the center of the FeSV genome and are approximately 1.5 kilobase pairs in length. With respect to the 5'-3' orientation of genes in viral RNA, the order of genes in the FeSV genome is 5'-gag-src-env-c region-3'; only 0.9 kilobase pairs of gag and 0.6 kilobase pairs of env-derived FeLV sequences are represented in ST FeSV. Heteroduplex analyses between lambda FeSV or lambda FeLV DNA and Moloney murine sarcoma virus DNA (strain m1) were performed under conditions of reduced stringency to demonstrate limited regions of base pair homology. Two such regions were identified: the first occurs at the extreme 5' end of the leukemia and both sarcoma viral genomes, whereas the second corresponds to a 5' segment of leukemia virus "env" sequences conserved in both sarcoma viruses. The latter sequences are localized at the 3' end of FeSV src and at the 5' end of murine sarcoma virus src and could possibly correspond to regions of helper virus genomes that are required for retroviral transforming functions.

Two species of full-length cDNA are synthesized in high yield by melittin-treated avian retrovirus particles

A method of activating endogenous cDNA synthesis in avian retroviruses that results in the formation of two species of full-length cDNA in high yield is described. Tests of biological activity show infectivity of at least the same order of magnitude as for full-length cDNA made by other procedures. Melittin, the major component of bee venom, is used as an alternative to nonionic detergents to make the viral envelope permeable and thus activate the endogenous RNA-dependent DNA polymerase. This compound is a toxic peptide known to interact with phospholipid membranes. It appears to be less disruptive to the viral structure than detergents, resulting in a more efficient transcription of the viral genome. Preliminary tests indicate that this method will also prove useful for studying enzymatic activities associated with other enveloped viruses.

Genome organization of retroviruses. V. In vitro-synthesized Moloney murine leukemia viral DNA has long terminal redundancy

Purified virions of Moloney murine leukemia virus can synthesize genome-length double-stranded DNA in vitro. Two predominant species of long DNA transcripts, with average sizes of 9.1 and 8.5 kilobases (kb) can be identified. Both species of DNA contain the negative (complementary to viral RNA) and positive (same polarity as viral RNA) strands. However, only the negative strand of the 8.5-kb species can be identified if the synthesis of DNA is carried out in the presence of the drug actinomycin D. The 9.1-kb species appears to be slightly larger than the genomic RNA. If the linear double-stranded 9.1-kb species is treated with Escherichia coli exonuclease III and allowed to anneal, circular DNA molecules can be observed. Furthermore, polyadenylate-containing short genomic RNA fragments (0.5 to 1.0 kb) can anneal to both the 5' and the 3' termini of 9.1-kb complementary DNA. The polyadenylate moiety of the RNA fragments can be identified by tagging it with circular polyoma DNA containing polydeoxybromouridylic acid tails. Thus, the 9.1-kb complementary DNA transcript with two circular polyoma DNA molecules at its termini can be observed. However, when similar annealings are performed with 8.5-kb complementary DNA species, only one end of the resulting molecule has circular polyoma DNA. We conclude that the 9.1-kb complementary DNA species has a large terminal redundancy. The sequences involved in terminal redundancy appear to be derived from the 3' end of the genomic RNA.

Restriction endonuclease mapping of unintegrated proviral DNA of Snyder-Theilen feline sarcoma virus: localization of sarcoma-specific sequences

Extrachromosomal DNA purified from mink cells acutely infected with the Snyder-Theilen strain of feline sarcoma virus (FeSV) was digested with restriction endonucleases, and the DNA fragments were electrophoretically separated, transferred to a solid substrate, and hybridized with radiolabeled DNA transcripts complementary to different portions of the FeSV RNA genome. Major DNA species 8.4 and 5.0 kilobase pairs (kbp) long represent the linear, unintegrated proviruses of Snyder-Theilen feline leukemia virus and FeSV, respectively. Transfection experiments performed with electroeluted DNAs showed that the 8.4-kbp form led to the production of replicating nontransforming virus in mink and cat cells; in contrast, the 5.0-kbp DNA produced helper virus-independent foci of transformation in mouse NIH/3T3 cells and helper virus-dependent foci in mink cells at an efficiency comparable to that obtained with unfractionated extrachromosomal DNA. Sites of restriction endonuclease cleavage for six enzymes were oriented with respect to one another within the FeSV provirus. EcoRI recognized cleavage sites at 0.3 to 0.4 kbp from each terminus of FeSV DNA, reducing the 5.0-kbp DNA to molecules 4.3 kbp long; this enzyme excised a large internal proviral DNA fragment of corresponding size from the DNA of FeSV-transformed mink nonproducer cells. By using DNA transcripts complementary to different portions of the FeSV genome, sarcoma-specific sequences (the FeSV src gene) were positioned within 2.1 and 3.4 kbp from the 5' end of the proviral DNA with respect to the viral RNA genome. The src gene is flanked at both ends by sequences shared in common with feline leukemia virus. The localization of src sequences to this region suggests that a portion of an FeSV polyprotein which contains feline oncornavirus-associated cell membrane antigen (FOCMA-S) is the major product of this gene.

Genome organization of retroviruses. VI. Heteroduplex analysis of ecotropic and xenotropic sequences of moloney mink cell focus-inducing viral RNA obtained from either a cloned isolate or a thymoma cell line

The genome of a recombinant murine leukemia virus capable of inducing focal areas of morphological alteration in mink lung fibroblasts was studied by heteroduplex analysis. The dual-tropic recombinant virus was isolated from a thymoma cell line (Th16.3) and is referred to as BALB/Moloney mink cell focus-inducing virus (BALB/Mo-MCF virus). The nucleic acid sequences of RNA from virions obtained from either a thymoma cell line (Th16.3) or a clonal isolate (BALB/Mo-MCF81) were compared with the genomes of ecotropic and xenotropic viruses. The following inferences were drawn (i) A single nonhomologous region (substitution loop alpha) of about 0.7 kilobase was observed in a heteroduplex formed between Moloney murine leukemia virus complementary DNA (cDNA) and BALB/MoMCF81 RNA. This nonhomology region was mapped between 1.71 and 2.40 kilobases from the 3' end of the genome. (ii) The predominant class of heteroduplexes formed between virion RNA obtained from the thymoma cell line (Th16.3) and Moloney murine leukemia virus cDNA showed a substitution loop similar to that observed with the RNA obtained from a cloned isolate, BALB/Mo-MCF81. However, there were other molecules with additional regions of nonhomology. (iii) Heteroduplexes formed between NZB xenotropic RNA and ecotropic Moloney murine leukemia virus cDNA exhibited four major nonhomology regions extending 0.75 to 1.46, 2.0 to 2.8, 3.6 to 4.3, and 7.4 to 7.9 kilobases from the 3' end of the genome. (iv) The MCF-specific substitution loop alpha (1.71 to 2.40 kilobases) appeared as a duplex region when NZB xenotropic RNA was hybridized to cDNA transcripts synthesized by virions obtained from thymoma cell line Th16.3. The position of the other substitution loops observed in a heteroduplex formed between NZB xenotropic RNA and Moloney murine leukemia virus cDNA was not affected. (v) Heteroduplexes formed between xenotropic BALB virus 2 cDNA and NZB xenotropic RNA demonstrated a large degree of nucleic acid sequence homology. Of the 29 heteroduplexes examined, 24 appeared to be homoduplexes, and in the remaining 5 heteroduplexes only one region of nonhomology located between 3.2 and 3.8 kilobases from the 3' end of the genome could be identified. Hybridization of BALB virus 2 xenotropic RNA to NZB xenotropic cDNA followed by digestion with single-strand-specific nuclease S1 showed an 80% sequence homology.

Circular forms of DNA synthesized by Rous sarcoma virus in vitro

Electron microscopic analysis of the DNA product synthesized by detergent-disrupted preparations of Rous sarcoma virus in vitro revealed the presence of several interesting molecular forms including covalently closed circular DNA. The identification of such circular DNA indicates that virions of retroviruses contain all the components necessary to facilitate the complete synthesis of mature forms of viral DNA and therefore provide a useful system to delineate the molecular mechanisms involved in their synthesis.

Moloney murine sarcoma virions synthesize full-genome-length double-stranded DNA in vitro

Moloney murine sarcoma virus (MSV) virions incubated under optimal conditions were shown to support extensive synthesis of double-stranded DNA. The major product, a 5950-base-pair (6-kilobase-pair DNA) double-stranded DNA, was characterized by cleavage with restriction endonucleases and shown to contain a 600-nucleotide-long direct repeat at both ends of the MSV genome. Linear DNA molecules made in vivo shortly after infection were compared to the linear double-stranded DNA synthesized in vitro. The restriction maps of both viral DNA products were indistinguishable. The 600-base-pair repeat results in a progeny DNA molecule that is longer than the parental MSV genomic RNA. The generation of this repeat must involve a mechanism that allows the viral reverse transcriptase (RNA-dependent DNA nucleotidyltransferase) to copy 5'- and 3'-terminal genomic (+) strand sequences twice.

Synthesis of long complementary DNA in the endogenous reaction by equine infectious anemia virus

In the endogenous reverse transcriptase reaction, equine infectious anemia virus is able to synthesize complementary DNA (cDNA) of 8,000 nucleotides in high yield. After 2 h in 50 muM dNTP, about 2.8 mug of cDNA per mg of protein is produced, almost 30% of which is long cDNA. The system thus compares favorably with the other two well-characterized endogenous reaction systems, Moloney murine leukemia virus and avian sarcoma virus. Elongation rates of 100 to 150 nucleotides per min have been observed; these rates are comparable to those seen with purified avian myeloblastosis virus reverse transcriptase and significantly higher than those observed in vivo. In the absence of actinomycin D, equine infectious anemia virus does not require high dNTP levels for either optimal incorporation or long cDNA synthesis. The amount of long cDNA synthesized is maximal at 2 h in 50 muM dNTP; neither longer time nor higher dNTP levels (through 1.8 mM) increased this yield. Half-maximum yield in 2 h was achieved at about 15 muM dNTP, which is very similar to the published K(M)'s for isolated avian and murine reverse transcriptases. Total incorporation, on the other hand, continues to rise slowly through 1 mM dNTP; the half-maximum was 30 to 50 muM dNTP. In the presence of 100 mug of actinomycin D per ml, however, higher dNTP levels are required for long cDNA synthesis. We conclude that equine infectious anemia virus is exceptionally well-suited to studies of the physical organization of the retrovirus genome and to investigations of the mechanism of synthesis of the double-standard cDNA endogenous reaction product.

In vitro synthesis of infectious transforming DNA by the avian sarcoma virus reverse transcriptase

Infectious DNA molecules, capable of transforming chicken embryo fibroblasts, can be synthesized by the Rous sarcoma virus-associated reverse transcriptase in vitro. The optimal enzymatic conditions employed for infectious DNA synthesis also facilitate maximum synthesis of genome length DNA. Analysis of the DNA product synthesized by detergent-disrupted Rous sarcoma virus under these conditions indicates that DNA complementary to viral RNA (minus-strand DNA) is genome length in size, whereas DNA complementary to genome length minus-strand DNA (plus-strand DNA) appears as subgenomic-length molecules ranging between 300 and 3,500 nucleotides in length. These features of the DNA product synthesized by the Rous sarcoma virus reverse transcriptase in vitro are similar to those identified in the cytoplasm of cells shortly after infection and lend credence to studies of the mechanism of reverse transcription in vitro and their significance to proviral DNA synthesis in vivo.

Heteroduplex analysis of the sequence relations between the RNAs of mink cell focus-inducing and murine leukemia viruses

The sequence relationships betwen AKR ecotropic virus and an AKR-derived "mink cell focus-inducing" (MCF) isolate (AKR MCF 247), between Moloney murine leukemia virus (M-MLV) and an M-MLV MCF isolate (M-MLV83), and between AKR and M-MLV were studied by electron microscopic heteroduplex analysis. The MCF-specific sequences were found to map from 1.95 kilobases (kb) to 2.75 kb (+/- 0.15 kb) from the 3' end of the RNAs for both MCF isolates. The major sequence nonhomology regions between AKR and M-MLV lie between 0.9 and 3.5 kb from the 3' end. However, the AKR and M-MLV sequences immediately adjacent to the 1.95- and 2.75-kb junctions with MCF-specific sequences are relatively similar in AKR and M-MLV. Our results suggest that the env gene of MLVs maps from 1 kb to 3 kb from the 3' end of the genomic RNA and that the carboxyl end of the glycoprotein of each MCF strain is similar (or identical) to that of its ecotropic parent.

Genome organization of RNA tumor viruses II. Physical maps of in vitro-synthesized Moloney murine leukemia virus double-stranded DNA by restriction endonucleases

Physical maps of the genome of Moloney murine leukemia virus (M-MLV) DNA were constructed by using bacterial restriction endonucleases. The in vitro-synthesized M-MLV double-stranded DNA was used as the source of the viral DNA. Restriction endonucleases Sal I and Hind III cleave viral DNA at only one site and, thus, generate two DNA fragments. The two DNA fragments generated by Sal I are Sal IA (molecular weight, 3.5 x 10(6)) and Sal IB (molecular weight, 2.4 x 10(6)) and by Hind III are Hind IIIA (molecular weight, 3.6 x 10(6) and Hind IIIB (molecular weight, 2.3 x 10(6)). Restriction endonuclease Bam I generates four fragments of molecular weights of 2.1 x 10(6) (Bam IA), 2 X 10(6) (Bam IB), 1.25 X 10(6) (Bam IC), and 0.24 x 10(6) (Bam ID), whereas restriction endonuclease Hpa I cleaves the M-MLV double-stranded DNA twice to give three fragments of molecular weights of 4.4 x 10(6) (Hpa IA), 0.84 X 10(6) (Hpa IB), and 0.74 x 10(6) (Hpa IC). Digestion of M-MLV double-stranded DNA with restriction endonuclease Sma I produces four fragments of molecular weights of 3.9 x 10(6) (Sma IA), 1.3 X 10(6) (Sma IB), 0.28 X 10(6) (Sma IC), and 0.21 x 10(6) (Sma ID). A mixture of restriction endonucleases Bgl I and Bgl II (Bgl I + II) cleaves the viral DNA at four sites generating five fragments of approximate molecular weights of 2 x 10(6) (Bgl + IIA), 1.75 X 10(6) (Bgl I + IIB), 1.25 X 10(6) (Bgl I + IIC), 0.40 X 10(6) (Bgl I + IID), and 0.31 x 10(6) (Bgl I + IIE). The order of the fragments in relation to the 5' end and 3' end of the genome was determined either by using fractional-length M-MLV double-stranded DNA for digestion by restriction endonucleases or by redigestion of Sal IA, Sal IB, Hind IIIA, and Hind IIIB fragments with other restriction endonucleases. In addition, a number of other restriction endonucleases that cleave in vitro-synthesized M-MLV double-stranded DNA have also been listed.