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

Effects of reticuloendotheliosis virus infection on cytokine production in SPF chickens

Infection with reticuloendotheliosis virus (REV), a gammaretrovirus in the Retroviridae family, can result in immunosuppression and subsequent increased susceptibility to secondary infections. The effects of REV infection on expression of mRNA for cytokine genes in chickens have not been completely elucidated. In this study, using multiplex branched DNA (bDNA) technology, we identified molecular mediators that participated in the regulation of the immune response during REV infection in chickens. Cytokine and chemokine mRNA expression levels were evaluated in the peripheral blood mononuclear cells (PBMCs). Expression levels of interleukin (IL)-4, IL-10, IL-13 and tumor necrosis factor (TNF)-α were significantly up-regulated while interferon (IFN)-α, IFN-β, IFN-γ, IL-1β, IL-2, IL-3, IL-15, IL-17F, IL-18 and colony-stimulating factor (CSF)-1 were markedly decreased in PBMCs at all stages of infection. Compared with controls, REV infected chickens showed greater expression levels of IL-8 in PBMCs 21 and 28 days post infection. In addition, REV regulates host immunity as a suppressor of T cell proliferative responses. The results in this study will help us to understand the host immune response to virus pathogens.

Infectious molecular clones with the nonhomologous dimer initiation sequences found in different subtypes of human immunodeficiency virus type 1 can recombine and initiate a spreading infection in vitro

Recombinant forms of human immunodeficiency virus type 1 (HIV-1) have been shown to be of major importance in the global AIDS pandemic. Viral RNA dimer formation mediated by the dimerization initiation sequence (DIS) is believed to be essential for viral genomic RNA packaging and therefore for RNA recombination. Here, we demonstrate that HIV-1 recombination and replication are not restricted by variant DIS loop sequences. Three DIS loop forms found among HIV-1 isolates, DIS (CG), DIS (TA), and DIS (TG), when introduced into deletion mutants of HIV-1 recombined efficiently, and the progeny virions replicated with comparable kinetics. A fourth DIS loop form, containing an artificial AAAAAA sequence disrupting the putative DIS loop-loop interactions [DIS (A6)], supported efficient recombination with DIS loop variants; however, DIS (A6) progeny virions exhibited a modest replication disadvantage in mixed cultures. Our studies indicate that the nonhomologous DIS sequences found in different HIV-1 subtypes are not a primary obstacle to intersubtype recombination.

Alteration of location of dimer linkage sequence in retroviral RNA: little effect on replication or homologous recombination

Retrovirus particles contain a dimer of retroviral genomic RNA. A defined region of the retrovirus genome has previously been shown to be important for both dimerization and encapsidation. To study the importance of the position of this encapsidation and dimerization signal for retroviral replication and homologous recombination, we used a previously described spleen necrosis virus-based helper cell system. This system allows retroviral vectors with multiple genetic markers to be studied after a single cycle of retroviral replication. The sequence responsible for dimerization, the encapsidation/dimer linkage sequence (E/DLS), was moved from its normal location near the 5' end of the retroviral genome to a location near the 3' end of the genome. We characterized four pairs of retroviral vectors: (i) with both E/DLSs at the 5' ends of the genomes, (ii) with both E/DLSs at the 3' ends of the genomes, and (iii) two with one E/DLS at the 5' end of the genome and one at the 3' end of the genome. We found that moving the E/DLS to the 3' end of the genome resulted in at most an approximately factor of 5 reduction in virus titer in a single cycle of retroviral replication. Furthermore, we found no changes that were attributable to the alteration of the position of the E/DLS in the minus-strand DNA primer transfers or the plus-strand DNA primer transfers, the rate of homologous recombination, or the number of internal template switches in recombinant proviruses. These results indicate that any alignment or conformation necessary for retroviral replication or recombination is not the result of the position of the E/DLS.

Genetic consequences of packaging two RNA genomes in one retroviral particle: pseudodiploidy and high rate of genetic recombination

Retroviruses contain two complete viral genomic RNAs in each virion. A system to study in a single round of replication the products of virions with two different genomic RNAs was established. A spleen necrosis virus-based splicing vector containing both the neomycin-resistance gene (neo) and the hygromycin B phosphotransferase gene (hygro) was used. Two frameshift mutants were derived from this vector such that the neo and the hygro genes were inactivated in separate vectors. Thus, each vector confers resistance to only one selection. The vectors with frameshift mutations were separately propagated and were pooled to infect DSDh helper cells. Doubly resistant cell clones were isolated, and viruses produced from these clones were used to infect D17 cells. This protocol allowed virions containing two different genomic RNAs (heterozygotes) to complete one round of retroviral replication. The molecular nature of progeny that conferred resistance to single or double selection and their ratio were determined. Our data demonstrate that each infectious heterozygous virion produces only one provirus. The rate of retroviral recombination is approximately 2% per kilobase per replication cycle. Recombinant proviruses are progeny of heterozygous virions.

Applications of Oligonucleotide Fingerprinting to the Identification of Viruses

This chapter focuses on applications of oligonucleotide fingerprinting to the identification of viruses. Fingerprinting is a technique by which oligonucleotides, produced by cleavage of RNA molecules with specific ribonucleases, are separated in two dimensions. It is a definitive method of identifying RNA viruses according to their genotypes. It is not subject to the problems of antigenic drift or antigenic convergence that complicate serological identification. Furthermore, it provides a semiquantitative means of following the evolution of viral genomes in nature. Because all regions of the genome are represented by the large diagnostic oligonucleotides, a survey of the total genomic changes can be monitored. Fingerprinting has two limitations as a diagnostic tool. First, although highly definitive, fingerprinting is not as rapid or inexpensive as serological techniques and cannot be as easily scaled up for routine identification of a large number of samples. Second, the evolutionary range of fingerprinting is short and relationships may not be evident for isolates of rapidly evolving viruses obtained over long intervals. However, these limitations are not large, compared to the full benefits offered to the virologist by the fingerprinting method.

Identification of proteins encoded by the Gazdar murine sarcoma virus genome by in vitro translation and comparison with Moloney murine sarcoma virus 124

The gene products of Gazdar murine sarcoma virus (Gz-MuSV) were identified by in vitro translation of Gz-MuSV virion RNA. An overlapping set of proteins with approximate molecular weights of 37,000 (37K), 33K, 24K, and 18K were synthesized from the transforming gene of Gz-MuSV, v-mosGz. In addition, Gz-MuSV-specific RNA directed the in vitro synthesis of a 62K gag gene protein and a 37.5K env gene-related product. The Gz-MuSV-specific in vitro translation products were compared with the in vitro translation products of M-MuSV 124, an independent isolate with a similar v-mos gene. This analysis showed that the 62K Gz-MuSV gag gene protein and the 37K, 33K, 24K, and 18K v-mosGz proteins were almost identical to the M-MuSV 124 62K (gag) and 37K, 33K, 24K, and 18K (v-mosMo) proteins that we previously identified and characterized. The 37.5K env gene product from Gz-MuSV does not have a correlate in the M-MuSV 124 translation products. These results were analyzed in the context of expectations based on similarities and differences in genetic organization of these two viral genomes.

Precursor polypeptides to structural proteins of visna virus

Visna virus is a retrovirus which replicates in fibroblast-like cells of the sheep choroid plexus through a lytic cycle. Visna virions contain three major low-molecular-weight proteins (p30, p16, and p14) which, together with the genomic RNA and several molecules of reverse transcriptase, constitute the core structure of the virions. The core is surrounded by an envelope containing a major glycoprotein (gp135). By analogy with the oncoviruses, these three groups of structural proteins (i.e., the internal proteins, the envelope glycoprotein, and the reverse transcriptase) are probably encoded by the gag, env, and pol genes, respectively. To elucidate the genetic organization of the visna virus genome and its expression, we studied the synthesis of viral proteins in infected sheep choroid plexus cells. Intracellular viral proteins were detected by immunoprecipitation of pulse-labeled cell extracts with monospecific sera raised against p30, p16, and gp135 and resolution of the proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Immunoprecipitation with anti-p30 and anti-p16 sera allowed the characterization of the 55,000-dalton polypeptide precursor to internal virion proteins p30, p16, and p14 (Pr55(gag)). Tryptic peptide mapping confirmed the precursor-product relationship between Pr55(gag) and the three internal proteins. In addition, a gag-related polypeptide of 150,000 daltons was also detected. This polypeptide, which was less abundant than Pr55(gag), is a likely precursor to the viral reverse transcriptase (Pr150(gag-pol)). Pr55(gag) and Pr150(gag-pol) are not glycosylated. The precursor related to major envelope protein gp135 is a glycosylated polypeptide with an average molecular weight of 150,000 (gPr150(env)). Pulse-chase experiments indicated that gPr150(env) matures into glycoprotein gp135 intracellularly; however, gp135 was never preponderant in cell extracts. The non-glycosylated from of gPr150(env), which accumulated in the presence of 2-deoxy-d-glucose, appeared as a polypeptide of about 100,000 daltons. These results indicated that visna virus codes for the largest non-glycosylated env-related precursor among all of the retroviruses and therefore probably contains the largest env gene.

Genomic changes associated with antigenic variation of visna virus durig persistent infection

Visna virus undergoes antigenic change during persistent infection of sheep. Antigenic variants of visna virus were compared by using the genomic RNA and analyzing the large RNase T1-resistant oligonucleotides. Mutants isolated from a persistently infected sheep contained a small number of changes in their oligonucleotide patterns when compared with parental virus. To determine whether the changes in the nucleotide structure were clustered in one region of the genome, we determined the order of the oligonucleotides of the parental and mutant RNAs along the genome with respect to the 3' polyadenylylated end. All but one difference between the parental strain and the antigenic mutant used for mapping were located within 2 kilobases from the 3' terminus. Nucleotide sequence analyses showed that several of the oligonucleotides that differed in the parental and mutant RNAs could be accounted for by single base changes.

Comparative study of different isolates of murine sarcoma virus

The RNA genomes of a variety of murine sarcoma viruses (MSV) were compared by heteroduplex analysis. These viruses included the Moloney-derived isolates 124-MSV, m1-MSV, m3-MSV, HT1-MSV, and NP-MSV and also two independent isolates, Gazdar MSV and 1712-MSV. All of these viral genomes exhibited the acquired cellular sequences previously identified in 3124-MSV and thought to be responsible for transformation and sarcomagenesis. The location of the acquired cellular sequences within the envelope gene was variable in different MSV isolates, suggesting that the cellular sequences can be expressed in different positions relative to murine leukemia virus-derived information present in MSV. Deletions in the gag coding region of the different MSVs were consistent with their known gag-related gene products. Based on several features of the hetero-duplex analysis and the known genealogical relationships of the different MSVs, various possible mechanisms for the formation of MSV are considered.

Spleen focus-forming Friend virus: identification of genomic RNA and its relationship to helper virus RNA

The genome of the defective, murine spleen focus-forming Friend virus (SFFV) was identified as a 50S RNA complex consisting of 32S RNA monomers. Electrophoretic mobility and the molecular weights of unique RNase T1-resistant oligonucleotides (T1-oligonucleotides) indicated that the 32S RNA had a complexity of about 7.4 kilobases. Hybridization with DNA complementary to Friend murine leukemia virus (Fr-MLV) has distinguished two sets of nucleotide sequences in 32S SFFV RNA, 74% which were Fr-MLV related and 26% which were SFFV specific. By the same method, SFFV RNA was 48% related to Moloney MLV. We have resolved 23 large T1-oligonucleotides of SFFV RNA and 43 of Fr-MLV RNA. On the basis of the relationship between SFFV and Fr-MLV RNAs, the 23 SFFV oligonucleotides fell into four classes: (i) seven which had homologous equivalents in Fr-MLV RNA; (ii) six more which could be isolated from SFFV RNA-Fr-MLV cDNA hybrids treated with RNases A and T1; (iii) eight more which were isolated from hybrids treated with RNases A and T1; and (iv) two which did not have Fr-MLV-related counterparts. Surprisingly, the two class iv oligonucleotides had homologous counterparts in the RNA of six amphotropic MLV's including mink cell focus-forming and HIX-MLVs analyzed previously. The map locations of the 23 SFFV T1-oligonucleotides relative to the 3' polyadenylic acid coordinate of SFFV RNA were deduced from the size of the smallest polyadenylic acid-tagged RNA fragment from which a given oligonucleotide was isolated. The resulting oligonucleotide map could be divided roughly into three segments: two terminal segments which are mosaics of oligonucleotides of classes i, ii, and iii and an internal segment between 2 and 2.5 kilobases from the 3' end containing the two oligonucleotides shared with amphotropic MLVs. Since SFFV RNA consists predominantly of sequence elements related to ecotropic and amphotropic helper-independent MLVs, it would appear that the transforming gene of SFFV is not a major specific sequence unrelated to genes of helper viruses, as is the case with Rous sarcoma and probably withe other defective sarcoma and acute leukemia viruses.

Optimal conditions for synthesis of long complementary DNA product with Moloney murine leukemia virus

Studies are described on the interrelationships between divalent metals, dNTP's and PPi in determining the properties of complementary DNA (cDNA) product from the in vitro reverse transcriptase reaction with detergent-treated Moloney murine leukemia virus. In spite of the several-fold greater amount of cDNA product with Mn2+ than with Mg2+, net yield of high-molecular-weight cDNA was much greater with Mg2+ thant with Mn2+. This held true, as well, for the reactions containing excess dNTP or dNTP plus PPi, both of which (as has been reported for Mg2+) promote synthesis of high-molecular-weight cDNA product. Hif total dNTP concentration remained important for maximum high-molecular-weight product with Mg2+ and was not replaced by simply providing dNTP in excess over Mg2+. Under the conditions tested here, addition of PPi did not further increase cDNA product size with Mg2+ when compared with dNTP in excess over Mg2+. Extent of degradation of the RNA template during the incubations was correlated with the size of cDNA product.

Lymphomas resembling lymphoid leukosis in chickens inoculated with reticuloendotheliosis virus

Chickens inoculated as embyros or at hatching with the chick syncytial strain of reticuloendotheliosis virus developed a high incidence of lymphoid neoplasms between the 17th and 43rd weeks of age, involving principally the liver and bursa of Fabricius. On the basis of organ distribution, latent period, pathology and surface IgM production, the lymphomas closely resembled those of lymphoid leukosis. One inoculated chicken developed a myxosarcoma. No tumors were observed in uninoculated controls. The tumor-bearing chickens were free of infection with Marek's disease virus and exogenous avian leukosis virus (ALV) of subgroups A, B, C or D. However, the chickens were known to express endogenous ALV genes to varying degrees.

Precipitation of visna viral proteins by immune sera of rabbits and sheep

Eighteen polypeptides equivalent to 1.2 x 10(6) daltons of visna virus were specifically precipitated by immune sera from rabbits and sheep. The hyperimmunized rabbit antisera contained high concentrations of antibodies against p25 and p14, whereas the sera from sheep actively infected with visna virus showed a large quantity of anti-gp115 antibody. The results indicate that almost all the polypeptides reported previously (F. H. Lin, J. Virol. 25:207--214, 1978) are virus-specific components of visna. The presence of anti-gp115 antibody in sera of infected sheep may offer a simple and sensitive diagnostic procedure for visna.

Absence of circularly permuted and largely redundant sequences in the genome of visna virus

A previous study of the infectivity of visna virus proviral DNA suggested that the genetic information of the virus is distributed over at least two of the RNA subunits. Because the genetic complexity of visna virus corresponds to the size of one subunit, this result may imply that sequence redundancies exist within each subunit. In the present article we have examined this question by constructing a map of the large RNase T1-resistant oligonucleotides of the viral genome. Our principal results are as follows: (i) all 36S RNA subunits have the same genetic content regardless of their polyadenylic acid [poly(A)] content; (ii) the poly(A) tract is present at the 3' end of the molecule; and (iii) the recoveries of 19 large RNase T1-resistant oligonucleotides from poly(A)-tagged RNA fragments of various sizes demonstrate that the oligonucleotides are organized in the same linear order within all subunits. Our results, therefore, exclude the existence of large sequence redundancies in the genome of visna virus.

Viral gene expression in murine sarcoma virus(murine leukemia virus)-infected cells

NIH 3T3 cells infected with Moloney murine sarcoma virus (murine leukemia virus) produce virions which contain about 99% murine sarcoma virus RNA and 1% murine leukemia virus RNA. This report describes experiments which measured intracellular concentrations of proviral DNA and RNA transcripts for each of the viruses. We found that three to four copies of proviral DNA from each virus were integrated into the cellular DNA. Measurements of RNA specific for each of the genomes by hybridization to specific cDNA reagents revealed a 10- to 15-fold difference in concentration in both nuclear and polysomal RNA fractions, with murine sarcoma virus RNA predominating in both cases. Unless there are major differences in stability between the two viral RNAs, our results suggest that transcriptional control is responsible for much of the difference in final levels of virus synthesis.

Abrogation of Fv-1b restriction with murine leukemia viruses inactivated by heat or by gamma irradiation

Fv-1b restriction in BALB/3T3 cells is temporarily abrogated following infection with N-tropic murine leukemia virus. The mechanism of this phenomenon was investigated by comparing the inactivation rates for viral infectivity and for the ability of the same virus to abrogate Fv-1 restriction. Inactivation of the abrogating ability of N-tropic murine leukemia virus following graduated doses of gamma radiation proceeded at half the rate of that for viral infectivity. This result indicates that viral RNA must function in abrogating Fv-1b restriction but that only a portion of the viral genome is required. The inactivation kinetics of N-tropic murine leukemia virus were also determined following incubation of virus at 43 degrees C. Abrogating ability of N-tropic murine leukemia virus was found to be about six times as stable under these conditions as was viral infectivity. Interestingly, virion-associated reverse transcriptase activity was inactivated at the same rate as was viral infectivity, indicating that this enzyme may not need to function during abrogation. Virus heated at 43 degrees C was used to study the kinetics of the abrogation phenomenon itself. Abrogation was shown to be transient, requiring 6 to 9 h after virus infection to become maximally effective and beginning to disappear after about 18 h. The data reported here confirm the idea that abrogation of Fv-1 restriction can be separated experimentally from virus replication, and they raise the possibility that a separate biochemical pathway exists for incoming viral RNA in Fv-1 restrictive cells.

Mapping host range-specific oligonucleotides within genomes of the ecotropic and mink cell focus-inducing strains of Moloney murine leukemia virus

The site of recombination of a mink cell focus-inducing strain (Mo-MuLV83) derived from an ecotropic Moloney murine leukemia virus (Mo-MuLV) was mapped by fingerprint analysis of the large RNase T1-resistant oligonucleotides, employing a two-dimensional gel electrophoresis method. Mo-MuLV83, in contrast to the ecotropic Mo-MuLV, demonstrated a broadened host range, i.e., growth not only on mouse cells but also on mink cells, and recombination involved the env gene function. The genomic RNA of these two viruses shared 42 out of a total of 51 to 53 large T1 oligonucleotides (81%) and possessed a similar subunit size of 36S. Most of these T1 oligonucleotides were mapped in their relative order to the 3' polyadenylic acid end of the viral RNA molecules. There were 10 common oligonucleotides immediately next to the 3' termini. A cluster of 7 (in Mo-MuLV83) or 10 (in Mo-MuLV) unique T1 oligonucleotides were mapped next to the common sequences at the 3' end, and they all appeared concomitantly in a polyadenylic acid-containing RNA fraction with a sedimentation coefficient slightly larger than 18S. Therefore, the env gene of Mo-MuLV was situated at a location approximately 2,000 to 4,000 nucleotides from the 3' end of the genomic RNA, and the gene order of Mo-MuLV appeared to be similar to that of the more rigorously determined avian oncornaviruses. cDNA(SFFV) specific for the xenotropic sequences in the spleen focus-forming virus RNA hybridized to the cluster of unique oligonucleotides of Mo-MuLV83 RNA. This suggests that the loci of recombination involve the homologous env gene region of a xenotropic virus.

Structure of the genome of Moloney murine leukemia virus: a terminally redundant sequence

The genome of the Moloney strain of murine leukemia virus (Mo-MuLV) has been analyzed by digestion with ribonuclease T1 and separation of the digestion products by two-dimensional gel electrophoresis. Thirty large oligonucleotides isolated from such a fingerprint have been characterized. One of these oligonucleotides (number 21) was found to be present in twice the molar yield of the rest. The 30 oligonucleotides were mapped on the genome by determining their yields in various size classes of 3' terminal fragments of Mo-MuLV RNA. The physical map obtained in this way suggested that oligonucletoide 21 was present very near the 3' end of the geome as well as in another location near or at the 5' end. The genome structure suggested by these results was confirmed by analyzing oligonucleotides in Mo-Mulv RNA complementary to strong stop DNA, which is shown to be a copy of the 5' terminal 134 nucleotides of the MoMuLV genome. Some of the oligonucleotides in the RNA protected from RNAase digestion by hybridization to this DNA, including oligonucleotide 21, were present near both the 3' and 5' ends. Comparison of these with the nucleotide sequence of strong stop DNA shows that there is a terminal redundancy of 49-60 nucleotides in the Mo-MuLV genome RNA.

Polyacrylamide gel electrophoresis of visna virus polypeptides isolated by agarose gel chromatography

The proteins of visna are separated into nine major peaks by agarose gel chromatography in 6 M guanidine hydrochloride (GuHCl). The polypeptides in eack peak were isolated by acid precipitation and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). The patterns of SDS-PAGE show that the excluded material from the GuHCl column contains an aggregate of 10 non-glycosylated polypeptides. It is shown that this aggregate represents virus substructures that are not completely solubilized by GuHCl. Two glycoproteins, gp175 and gp115, were isolated from the column eluate. The major glycoprotein gp115 was coeluted with P90, P68, and P61 in GuHCl 4. Each of the four major peaks (GuHCl 5 to 8) contains more than one nonglycosylated polypeptide. However, a small polypeptide, P12, can be isolated in a homogeneous form in the last peak, GuHCl 9. Analysis of the virus proteins (100 microgram) by SDS-PAGE shows that 20 radioactive bands can be recognized. During fractionation of the protein on agarose gel columns followed by analysis with SDS-PAGE, a number of minor polypeptides that were not detected before became clearly recognizable. Thus, the combined use of column chromatography and SDS-PAGE shows that visna virus is composed of 25 proteins.

Structure of 50 to 70S RNA from Moloney sarcoma viruses

The 50 to 70S RNAs of two clonal isolates of defective Moloney sarcoma-leukemia helper virus complex were analyzed by gel electrophoresis and electron microscopy. The RNAs extracted from both clone 3 and clone 124-5R of Moloney sarcoma-leukemia virus complex contained some large monomer subunits ca. 10,000 nucleotides in length (10 kilobases), which are believed to be the Moloney leukemia virus subunits. Both RNAs had an excess of a smaller, sarcoma-specific subunit, 5 kilobases (clone 3) or 6 kilobases (clone 124-5R) in length. Electron microscopy of intact 50 to 70S dimer RNA molecules showed for both clones many dimers of two small subunits, some dimers of two large subunits, but few if any heterodimers with one large and one small subunit. This result was unexpected because the sequences near the 5'end of the RNA subunits, which are believed to be involved in the dimer linkage, are probably homologous between the large and small subunits. We also observed that some small-small dimers migrated anomalously slowly on nondenaturing gels. The nature of this slow-migrating complex is unkown; it could be a higher aggregate of the small-small dimer with additional small or large subunits, or it could be an extended conformation of the small-small dimer.

Physical map of the Kirsten sarcoma virus genome as determined by fingerprinting RNase T1-resistant oligonucleotides

From analysis of the large RNase T1-resistant oligonucleotides of Kirsten sarcoma virus (Ki-SV), a physical map of the virus genome was deduced. Kirsten murine leukemia virus (Ki-MuLV) sequences were detected in T1 oligonucleotides closest to the 3' end of the viral RNA and extended approximately 1,000 nucleotides into the genome. The rat genetic sequences started at this point and extended all the way to the very 5' end of the RNA molecules, where a small stretch of Ki-MuLV sequence was detected. By comparison of the fingerprints of Ki-SV RNA and the RNA of the endogenous rat src genetic sequences, it was found that more than 50% of the T1 oligonucleotides were similar between Ki-SV and the endogenous rat src RNA, suggesting an identical primary nucleotide sequence in over 50% of the viral genomes. The results indicate that Ki-SV arose by recombination between the 5' and 3' ends of Ki-MuLV and a large portion of the homologous sequences of the endogenous rat src RNA.

Characterization of RNA from equine infectious anemia virus

The genome of equine infectious anemia virus, a nononcogenic retrovirus, has been characterized by velocity sedimentation, electrophoresis in polyacrylamide gels, buoyant density in CS2SO4, and susceptibility to nuclease digestion. The nucleic acid of purified virus was resolved by sedimentation analysis into a fast-sedimenting genome component, which comprises about two-thirds of the virion RNA, and a slow-sedimenting RNA, which is probably comprised of host-derived tRNA and a trace amount of 5S RNA. The fast-sedimenting RNA had a sedimentation coefficient of 62S and a molecular weight of 5.4 X 10(6) to 5.6 X 10(6), as determined by sedimentation velocity and electrophoretic mobility. Upon heat denaturation, [3H]uridine-labeled 62S RNA dissociated into material comprised of 90 to 95% single-stranded species, sedimenting predominantly at 34S, with a molecular weight of 2.7 X 10(6) to 2.9 X 10(6) and 5 to 10% 4S RNA. The 62S RNA was predominantly single-stranded but contained double-stranded regions, as indicated by partial resistance to RNase IA and SI nuclease and by a lower buoyant density in CS2SO4 than that of the single-stranded 34S RNA derived by heat denaturation. These data indicated that the viral genome consisted of two 34S subunits of single-stranded RNA held in a high-molecular-weight complex with 4S RNA by a mechanism involving a small degree of base pairing. Thus, the structure of equine infectious anemia virus RNA is similar to that of other retroviruses.

Genetic studies of the ploidy of Moloney murine leukemia virus

An assay for Moloney murine leukemia virus was developed that made use of the production of morphologically altered foci in nonproducer mouse cells (15F) carrying murine sarcoma virus. Wild-type (wt) virus gave a ratio of titers at 39 degrees C/34degrees C = 1.05 +/- 0.45 (standard deviation;n = 20). A spontaneous, thermosensitive (ts) mutant of Moloney murine leukemia virus, ts3, defective in a late viral function, gave 39 degrees C/34degrees C = 0. A murine cell line (TB) was mixedly infected with ts3 and wt (multiplicities of infection, 7.8:4.3), cloned after infection, and shown to be infected by both viruses. At 34 degrees C it produced wt, ts, and particles of mixed parentage. The heterozygotes (hz) had ratios of assays 39 degrees C/34 degrees C = 0.06 to 0.84 (mean, 0.36). To eliminate possible interference by multiploid particles with determination of the proportions of the three types of particles, the virus produced by the mixedly infected, cloned cell line at 34 degrees C was distributed by velocity sedimentation in a sucrose gradient, and virus was picked from the lightest part of the gradient. The proportions of ts, wt, and hz were 0.27, 0.26, and 0.47. Those particles identified as hz segreated ts, wt, and hz in the proportions 0.24, 0.27, and 0.49, respectively. These values were not significantly different from those predicted from a diploid model of the genome.

A heteroduplex study of the sequence relationships between the RNAs of M-MSV and M-MLV

The regions of sequence homology between the RNA genomes of a murine sarcoma virus (clone 124 Moloney-MSV) and its parental helper virus (clone 3 Moloney-murine leukemia virus (M-MLV)) have been mapped. Long complementary DNA transcripts of the M-MLV RNA were hybridized to M-MSV RNA, and the structures of the hybrids were observed in the electron microscope. Beginning at the 5' end, the two RNAs are homologous for a region of length 2.25 kb (kilobases). In the next region, of length approximately 4.2 kb on the MLV genome, there are several homology segments between MLV and MSV, but there are also several short sequences present on MLV and deleted in MSV. There is then a major substitution loop; with a sequence (beta L) of length 2.9 kb present on MLV and missing on MSV, and a sequence (beta S) of length 1.5 kb present on MSV and missing on MLV. At the 3' end, there is a homology sequence of length 0.8 kb. On the basis of these results, other data on genes expressed in M-MSV-transformed cells, and by analogy with the avian gene map, we suggest that the gag genes (internal structural proteins) lie in the 2.25 kb region of homology near the 5' ends of M-MSV and M-MLV RNAs, and that the beta S segment contains a sarcoma (src) gene. Some of the heteroduplexes and some of the MLV cDNA/MLV RNA homoduplexes are circular, thus showing that cDNA transcription is initiated at an internal position in the RNA, proceeds to the 5' end, and them "jumps" to the 3' end.

Complexity and polyadenylic acid content of visna virus 60-70S RNA

The genomic complexity of visna virus was measured by quantitative analysis of 18 RNase T1-resistant oligonucleotides from 60-70S RNA. T1-resistant oligonucleotides were separated by two-dimensional polyacrylamide gel electrophoresis. Visna virus had a genomic complexity of 3.6 X 10(6) daltons, very close to the size of a single 30-40S RNA subunit. It was therefore concluded that the visna virus genome is largely polyploid. Visna virus 60-70S RNA polyadenylic acid segment was purified by T1 RNase digestion followed by oligodeoxythymidylic acid-cellulose column chromatography. It contained over 99% AMP and had a size of about 200 nucleotides. The binding capacities on oligodeoxythymidylic acid-cellulose of native 60-70S RNA and purified 30-40S RNA subunits were examined. It was concluded that two out of three intact subunits contain a polyadenylic acid segment.

Formation and structure of infectious DNA of spleen necrosis virus

The kinetics of formation and the structure of infectious DNA of spleen necrosis virus were determined. Nonintegrated infectious viral DNA first appeared 18 to 24 h after infection of dividing cells and persisted for more than 14 days. The nonintegrated infectious viral DNA was in the form of either a double-stranded linear DNA with a molecular weight of 6 X 10(6), detected in both the cytoplasm and nucleus, or a closed circular DNA of the same molecular weight, detected primarily in the nucleus. Integrated infectious viral DNA appeared soon after the nonintegrated infectious viral DNA and was the predominant form of infectious viral DNA late after infection. Integration of the spleen necrosis virus DNA into the chicken cell genome was demonstrated by three independent criteria. Nucleic acid hybridization indicated that the linear infectious viral DNA had a 5- to 10-fold higher specific infectivity than either the closed circular or integrated infectious viral DNA. Infectious viral DNA did not appear in infected stationary cells, indicating some cellular influence on the formation of infectious viral DNA.

The 30S Moloney sarcoma virus RNA contains leukemia virus nucleotide sequences

The 50S-70S RNA of a Moloney sarcoma-leukemia virus [Mo-MSV(MLV)] complex produced by a particular mouse cell line was shown by gel electrophoresis to contain a major (97%) 30S sarcoma-specific subunit species and a minor (3%) 38S leukemia virus-specific subunit. On the basis of its sedimentation coefficient and known complexity, the 30S Mo-MSV RNA was estimated to be a unique RNA molecule of about 6000 nucleotides. Hybridization experiments using viral RNA and DNA complementary to viral RNA (cDNA) made by viral DNA polymerase indicated that the 30S Mo-MSV RNA shared 70% of its sequences with Mo-MLV, 30% with another MLV derived from Mo-MLV, and 30% with Kirsten sarcoma-xenotropic leukemia virus. The 30S Mo-MSV RNA sequences shared with these viruses were not additive. The Tm of a Mo-MSV RNA-MLV cDNA hybrid was 83 degrees C, indicating that large contiguous nucleotide sequences were shared between the two nucleic acids. Mo-MSV RNA and Mo-MLV RNA shared possibly seven of 20-30 RNAase T1-resistant oligonucleotides, while Mo-MSV RNA contained three, and Mo-MLV RNA contained at least five specific oligonucleotides. We conclude that the 30S Mo-MSV RNA molecule consists of approximately 70% (about 4200 nucleotides) Mo-MLV-specific sequences and of 30% (1800 nucleotides) Mo-MSV-specific sequences covalently linked. Our results favor the hypothesis that 30S Mo-MSV RNA was generated by recombination between Mo-MLV and other genetic elements. We discuss whether all or only the MSV-specific sequences of the 30S Mo-MSV RNA function as sarcoma genes. Mo-MLV cDNA was hybridized about 45% by unfractionated Mo-MSV (MLV) RNA at RNA/DNA ratios of up to 10, about 50% by electrophoretically purified 30S Mo-MSV RNA at RNA/DNA ratios up to 500, but close to 100% by unfractionated Mo-MSV(MLV) RNA at RNA/DNA ratios over 900. This indicated that unfractionated RNA of our Mo-MSV(MLV) contained a complete complement of Mo-MLV, albeit at a low ratio.

5'-terminus of Moloney murine leukemia virus 35s RNA is m7G5' ppp5' GmpCp

The 5'-terminal sequence m(7)G(5') ppp(5') GmpCp was isolated from Moloney murine leukemia virus 35S RNA after digestion of (32)P-labeled RNA with RNases T1, T2, and A followed by pH 3.5 ionophoresis on DEAE paper.