Structural analysis of the genomes of gibbon ape and woolly monkey leukosis viruses.

Infectious retroviruses have been isolated from gibbon apes and a woolly monkey. Previous studies have shown that these isolates share some antigenic determinants and that they exhibit partial nucleic acid homology. To further define the relationships in this group of viruses, we compared the RNAs of the viruses of the woolly monkey-gibbon ape class by two-dimensional polyacrylamide gel electrophoresis of the large RNase T1-resistant oligonucleotides. The degree of sequence identity between the RNAs was determined by the similarity of the fingerprint patterns and in some cases by partial sequence analysis of individual oligonucleotides. This technique permitted us to determine the degree of sequence identity in related RNA species. These studies showed that as much as 80% of the genomes of gibbon ape leukosis virus-Halls' Island and gibbon ape leukosis virus-brain could be identical. The other viruses, simian sarcoma-associated virus, gibbon ape leukosis virus-Thailand, and gibbon ape leukosis virus-San Francisco, showed an extensive but somewhat lower degree of sequence identity (between 40 to 60% of the genomes.     

Comparative analysis of the genomes of feline leukemia viruses.

The genomes of several strains of feline leukemia virus (FeLV) were compared by two-dimensional polyacrylamide gel electrophoresis of the large RNase T1-resistant oligonucleotides of the 70S RNA. Differences between each strain of FeLV tested were detected by this method. We estimate that the degree of sequence identity between the viruses is: FeLV A (Glasgow-1) to FeLV B (Snyder-Theilen), 52%; FeLV A (Glasgow-1) to FeLV C(Sarma), 66%; FeLV B(Snyder-Theilen) to FeLV C (Sarma), 37%. The fingerprints of two independent isolates of FeLV strains of subgroup A (Glasgow-1 and Rickard) were detectably different. We conclude that the RNase T1 oligonucleotide fingerprint pattern provides a useful tool for identification of FeLV strains.     

Genomic complexities of murine leukemia and sarcoma, reticuloendotheliosis, and visna viruses.

The genetic complexities of several ribodeoxyviruses were measured by quantitative analysis of unique RNase T1-resistant oligonucleotides from 60-70S viral RNAs. Moloney murine leukemia virus was found to have an RNA complexity of 3.5 x 10(6) daltons, whereas Moloney murine sarcoma virus had a significantly smaller genome size of 2.3 x 10(6). Reticuleondotheliosis and visna virus RNAs had complexities of 3.9 x 10(6), respectively. Analysis of RNase A-resistant oligonucleotides of Rous sarcoma virus RNA gave a complexity of 3.6 x 10(6), similar to that previously obtained with RNase T1-resistant oligonucleotides. Since each of these viruses was found to have a unique sequence genomic complexity near the molecular weight of a single 30-40S viral RNA subunit, it was concluded that ribodeoxyvirus genomes are at least largely polyploid.     

T1 oligonucleotide maps of N-, B-, and B leads to NB-tropic murine leukemia viruses derived from BALB/c.

We previously described and characterized RNase T1 RNA fingerprints of an N-, a B-, and five B leads to NB-tropic murine leukemia viruses derived from BALB/c mice (Faller and Hopkins, J. Virol. 23:188-195, 1977, and J. Virol. 24:609-617, 1977). These viruses share the majority of their large RNase T1-resistant oligonucleotides, but each possesses some "unique" oligonucleotides relative to the others. We have ordered the large T1-resistant oligonucleotides of the N-, the B-, and one NB-tropic virus relative to the 3' end of their genomes to obtain oligonucleotide maps. These maps indicate that (i) the large T1 oligonucleotides shared by the N-, B-, and NB-tropic viruses probably occupy the same relative positions on their genomes; (ii) the 14 T1 oligonucleotides that differ between the N- and B-tropic viruses are derived from regions scattered along the genomes; and (iii) an oligonucleotide that is present in five NB-tropic viruses but not in their B-tropic virus progenitors lies toward the 5' end of the NB-tropic virus oligonucleotide map.     

RNase T1-resistant oligonucleotides of an N- and a B-tropic murine leukemia virus of BALB/c: evidence for recombination between these viruses.

We used two-dimensional gel electrophoresis to obtain fingerprints of 32P-labeled RNase T1-resistant oligonucleotides derived from the genomes of an N- and a B-tropic murine leukemia virus of BALB/c. These viruses share approximately 30 large T1-resistant oligonucleotides. In addition, there are eight large oligonucleotides unique to the N-tropic virus, and there are six B-trophic virus-specific oligonucleotides. Viruses, designated XLP-N, which appear by biological criteria and analysis of virion proteins to be recombinants between these N- and B-tropic viruses, possess some but not all of the N or B virus-specific oligonucleotides.     

RNase T1-resistant oligonucleotides of B-tropic murine leukemia virus from BALB/c and five of its NB-tropic derivatives.

We used two-dimensional gel electrophoresis to obtain fingerprints of RNase T1-resistant oligonucleotides of a B-tropic murine leukemia virus from BALB/c and five NB-tropic viruses independently derived from this B virus by passage through NIH Swiss mouse embryo cells in vitro. The fingerprints of the B- and NB-tropic viruses were very similar: approximately 33 of 35 large T1-resistant oligonucleotides appeared to be shared by these viruses. However, the five NB-tropic viruses possessed an apparently common alteration relative to their B virus progenitor. This change involved the acquisition of one oligonucleotide and, tentatively, the loss of one oligonucleotide. We do not know whether these changes represent an alteration responsible for the change from B- to NB-tropism. Fingerprints of B- and NB-tropic viruses were not affected when the viruses were grown in cells of different Fv-1 type.     

Biochemical analysis of murine leukemia viruses isolated from radiation-induced leukemias of strain BALB/c.

Murine leukemia viruses isolated from radiation-induced BALB/c leukemias were characterized with respect to viral proteins and RNA. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the viral structural proteins revealed that for p12, p15, p30, and gp70, three of four electrophoretic variants of each could be detected. There was no correlation found between any of these mobilities and N- or B-tropism of the viruses. Proteins of all xenotropic viral isolates were identical in their gel electrophoretic profiles. The similar phenotypes of multiple viral clones from individual leukemias and of isolates grown in different cells suggest that the polymorphism of ecotropic viruses was generated in vivo rather than during in vitro virus growth. By two-dimensional fingerprinting of RNase T1-resistant oligonucleotides from 70S viral DNA, the previously reported association of N- and B-tropism with two distinct oligonucleotides was confirmed. The presence of two other oligonucleotides was correlated with positive and negative phenotypes of the virus-coded GIX cell surface antigen. The RNAs of two B-tropic isolates with distinctive p15 and p12 phenotypes differed from the RNA of a prototype N-tropic virus by the absence of three oligonucleotides mapping in the 5' portion (gag region) of the prototype RNA. In addition, one small-plaque B-tropic virus displayed extensive changes in the RNA sequences associated with the env region of the prototype.     

Antigenic characterization of type C RNA virus isolates of gibbon apes.

Type C RNA viruses initially isolated from a lymphosarcoma of a gibbon ape and from a fibrosarcoma of a woolly monkey are very closely related immunologically. However, recent studies have shown that these viruses are distinguishable in a radioimmunoassay for the 12,000-molecular-weight polypeptide (p12) of the woolly monkey virus. In the present report, an immunoassay has been developed for the p12 polypeptide of the gibbon ape type C virus. This assay is shown to further distinguish the woolly monkey and gibbon ape viruses. In type-specific assays for the p12 polypeptides of these viruses, two new type C viruses isolated from gibbons in a second colony, characterized by high incidence of hemopoietic neoplasia, are immunologically distinguishable from the original gibbon ape virus. The p12 type-specific immunoassays described in the present report may be of importance in studying the natural history of these viruses and their relationship to tumors of primates.     

5''-terminal nucleotide sequences of the Rauscher leukemia virus and gibbon ape leukemia virus genomes exhibit a high degree of correspondence.

The 5'-terminal regions of gibbon ape leukemia virus-Hall's Island and Rauscher murine leukemia virus have been completely sequenced. The chain length for the 5'-terminal region of Rauscher murine leukemia virus is 140 nucleotides, and that for gibbon ape leukemia virus-Hall's Island is 144 nucleotides. An alignment of the sequences maximizing the number of ocrrespondences with the minimum introduction of gaps shows 81% nucleotide matches. From the complementary RNA, secondary structures of this region have been proposed. These data demonstrate the conservation of the 5'-terminal genetic sequences of these viruses and strongly reinforce the concept that viruses of murine origin and viruses of the gibbon ape leukemia virus-Simian sarcoma-associated virus group are closely related.     

Construction and properties of retrovirus packaging cells based on gibbon ape leukemia virus.

We have constructed hybrid retrovirus packaging cell lines that express the gibbon ape leukemia virus env and the Moloney murine leukemia virus gag-pol proteins. These cells were used to produce a retrovirus vector at over 10(6) CFU/ml, with a host range that included rat, hamster, bovine, cat, dog, monkey, and human cells. The gag-pol and env expression plasmids were separately transfected to reduce the potential for helper virus production, which was not observed. The NIH 3T3 mouse cells from which the packaging lines were made are not infectable by gibbon ape leukemia virus; thus, the generation and spread of possible recombinant viruses in the packaging cells is greatly reduced. These simian virus-based packaging cells extend the host range of currently available murine and avian packaging cells and should be useful for efficient gene transfer into higher mammals.     

Isolation and Characterization of Mink Cell Focus-Inducing Murine Leukemia Viruses with Xenotropic Host Range from Mouse Strain SL

A new type of mink cell focus-inducing virus was persistently isolated from the leukemic tissues of SL mice. In contrast to the dual tropic mink cell focus-inducing viruses reported to date, the new virus has the host range of the xenotropic murine leukemia virus. Analysis of RNase T(1) fingerprints of genomic RNAs suggested that the mink cell focus-inducing virus with the xenotropic host range isolated from SL mice is a recombinant virus deriving from xenotropic murine leukemia virus.     

Isolation and identification of lymphocytic and myelogenous leukemia-specific sequences in genomes of gibbon oncornaviruses

Five gibbon ape leukemia virus substrains (two from gibbons with lymphocytic leukemia and three from gibbons with myelogenous leukemia) were examined for unique genomic sequences specific for each form of leukemia. By using sequential adsorption procedures, the genome from each gibbon ape leukemia virus was fractionated into four sets of distinct nucleotide sequences. Based on their hybridization specificities toward DNAs of leukemic tissues, these sequences were designated as follows: (i) “COM,” (ii) “LYM” or “MYE,” (iii) “UNI,” and (iv) “UND.” The COM fraction represented sequences common to all of the viral genomes. The LYM fraction, which was isolated only from gibbon ape leukemia viruses associated with lymphocytic leukemia, represented genomic sequences associated with lymphocytic leukemia since the RNA hybridized at a 4- to 15-fold-higher rate to infected tissue DNA from lymphocytic leukemic gibbons than to infected tissue DNA from myelogenous leukemic gibbons. The MYE fraction, which was isolated only from gibbon ape leukemia viruses associated with myelogenous leukemia, represented genomic sequences associated with myelogenous leukemia since the RNA hybridized at a 5- to 15-fold-higher rate to infected tissue DNA from myelogenous leukemic gibbons than to infected tissue DNA from lymphocytic leukemic gibbons. The UNI fraction contained sequences unique to one virus substrain. The UND fraction contained sequences which varied depending upon the substrains involved in the adsorption procedures. These findings suggest that each gibbon ape leukemia virus examined in this study contains subgenomic sequences that are specifically identifiable only with the form of leukemia from which the virus was isolated.     

Transcription of 70S RNA by DNA polymerases from mammalian RNA viruses.

DNA polymerases purified by the same procedure from four mammalian RNA viruses, simian sarcoma virus type 1, gibbon ape lymphoma virus, Mason-Pfizer monkey virus, and Rauscher murine leukemia virus are capable of transcribing heteropolymeric regions of viral 70S RNA without any other primer. In this reconstituted system the enzymes from simian sarcoma virus type 1, Mason-Pfizer monkey virus, and Rauscher murine leukemia virus transcribe viral 70S RNA almost as efficiently as the DNA polymerase from the avian myeloblastosis virus, but gibbon ape lymphoma virus DNA polymerase is approximately three-to fivefold less efficient. Although there is a substantial difference among the sizes of these DNA polymerases (160,000 daltons for the avian myeloblastosis virus enzyme, 110,000 daltons for the Mason-Pfizer monkey virus enzyme, and 70,000 daltons for the mammalian type C viral polymerases), the ability to transcribe viral 70S RNA is a characteristic common to these enzymes.     

RNase T1-resistant oligonucleotides of Akv-1 and Akv-2 type C viruses of AKR mice.

We used two-dimensional gel electrophoresis to obtain fingerprints of RNase T1-resistant oligonucleotides derived from the genomes of Akv-1 and Akv-2 type C viruses of AKR mice. The fingerprints of these two viruses look identical. The products of pancreatic RNase digestion of corresponding oligonucleotides of the two viruses were indistinguishable. These observations are consistent with, but not proof of, the possible identity of the genomes of the Akv-1 and Akv-2 viruses and, thus, of the viral genetic material believed to comprise the Akv-1 and Akv-2 loci of AKR mice.     

The dual-function hamster receptor for amphotropic murine leukemia virus (MuLV), 10A1 MuLV, and gibbon ape leukemia virus is a phosphate symporter.

Previously, we showed that the amphotropic receptor homolog in hamster cells functions as a receptor not only for amphotropic murine leukemia viruses and 10A1 murine leukemia virus but also for gibbon ape leukemia virus (C.A. Wilson, K. B. Farrell, and M. V. Eiden, J. Virol. 68:7697-7703, 1994). Here, we demonstrate that this receptor functions as a sodium-dependent Pi transporter and that Na-Pi uptake can be specifically blocked following infection with either amphotropic murine leukemia virus, 10A1 murine leukemia virus, or gibbon ape leukemia virus.     

Purification and characterization of gibbon ape leukemia virus DNA polymerase.

An RNA directed DNA polymerase was purified over 2500 fold from gibbon ape leukemia virus by successive column chromatography on Sephadex G100, DEAE cellulose, phosphocellulose and hydroxyapatite. The purified DNA polymerase has a molecular weight of 68 000, a pH optimum of 7.5, a Mn2+ optimum of 0.8 mM, and KCl optimum of 80 mM. The purified enzyme transcribes heteropolymeric regions of viral 60-70 S RNA isolated from avian myeloblastosis virus, Rauscher murine leukemia virus and simian sarcoma virus and it is inhibited by antiserum prepared against either gibbon ape leukemia virus or simian sarcoma virus DNA polymerases.     

Evidence for the common origin of viral and cellular sequences involved in sarcomagenic transformation.

The src genes of six different strains of avian sarcoma virus (ASV) were compared with those of a series of newly isolated sarcoma viruses, termed "recovery avian sarcoma viruses" (rASV's). The rASV's were isolated recently from chicken and quail tumors induced by transformation-defective (td) deletion mutants of Schmidt-Ruppin Rous sarcoma virus. The RNase T1-resistant oligonucleotide maps were constructed for the RNA genomes of different strains of ASV and td mutants. The src-specific sequences, characterized by RNase T1-resistant oligonucleotides ranging from 9 to 19 nucleotides long, were defined as those mapping between approximately 600 and 2,800 nucleotides from the 3' polyadenylate end of individual sarcoma viral RNAs, and missing in the corresponding td viral RNAs. Our results revealed that 12 src-specific oligonucleotides were highly conserved among several strains of ASV, including the rASV's, whereas certain strains of ASV were found to contain one to three characteristic src-specific oligonucleotides. We previously presented evidence supporting the idea that most of the src-specific sequences present in rASV RNAs are derived from cellular genetic information. Our present data indicate that the src genes of rASV's are closely related to other known ASVs. We conclude that the src genes of different strains of ASV and the cellular sarc sequences are of common origin, although some divergence has occurred among different viral src genes and related cellular sequences.     

RNA synthesis of vesicular stomatitis virus. VIII. Oligonucleotides of the structural genes and mRNA.

The single-stranded RNA genome of vesicular stomatitis virus (VSV, Indiana serotype, San Juan strain) yields approx. 75 RNase T1-resistant oligonucleotides ranging in size from 10 to 50 bases. Each of the five structural genes, isolated as duplex RNA molecules hybridized to complementary mRNA, contains two or more of these large oligonucleotides. One of the oligonucleotides is identified as part of the non-coding region near the 3' end of the genome. Comparison of these results with others indicate that the RNA sequence of VSV is apparently stable in the laboratory but not in the wild. RNase T1-resistant oligonucleotides are also shown for all five VSV mRN species. Whether the mRNA for these digestions are are isolated from duplex RNA molecules or as single-stranded RNA species, the oligonucleotide patterns for each mRNA are virtually identical, indicating that each mRNA is transcribed from contiguous sequences on the genome. Comparison with published oligonucleotide patterns obtained from other isolates of VSV or from VSV deletion mutants indicate that identity and changes in their genome structure can be correlated with specific structural genes.