Independent expression of avian sarcoma virus in doubly infected chicken embryo fibroblasts.

Infection of a chicken cell with avian sarcoma virus requires division of the infected cell before synthesis of infectious progeny is initiated. This requirement for a cell division for the complete expression of avian sarcoma virus has been examined further with chicken embryo fibroblasts infected with two distinct viruses. Chicken cells infected with and producing a mutant of Rous sarcoma virus temperature sensitive for transformation (tsLA24PR-A) were arrested in G0 by depletion of serum factors from growth medium. These stationary cells continued to produce infectious progeny in the absence of further cell division. Superinfection of the stationary cells with the wild-type Prague strain of Rous sarcoma virus (PR-RSV-C) produced a stable double infection in these cells. Progeny of the superinfecting PR-RSV-C, however, were not detected until these cells underwent division after stimulation with fresh serum-containing medium. The addition of colchicine to these serum-stimulated cells, although not affecting production of the tsLA24PR-A, inhibited the appearance of progeny of the superinfecting PR-RSV-C. These experiments indicate that each avian sarcoma virus infection of a chicken embryo fibroblast requires division of the infected cell for production of that virus regardless of whether or not the cell is already producing a similar virus. The results suggest, therefore, that the requirement for a cell division represents a requirement for an event that controls virus expression in a "cis-acting" fashion specific for the provirus.     

Cell Cycle-Dependent Activation of Rous Sarcoma Virus-Infected Stationary Chicken Cells: Avian Leukosis Virus Group-Specific Antigens and Ribonucleic Acid

Stationary chicken embryo fibroblasts exposed to Rous sarcoma virus (RSV) remained stably infected for at least 5 days, but they did not release infectious virus or become transformed until after cell division. These infected stationary cells did not contain avian leukosis virus group-specific antigens or ribonucleic acid (RNA) hybridizable to deoxyribonucleic acid (DNA) made by the RSV endogenous RNA-directed DNA polymerase activity.     

Rate of virus-specific RNA synthesis in synchronized chicken embryo fibroblasts infected with avian leukosis virus.

The rate of avian leukosis virus (ALV)-specific RNA synthesis has been examined in bot- uninfected and ALV-infected synchronized chicken embryo fibroblasts. RNA from cells labeled for 2h with [3H]uridine was hybridized with avian myeloblastosis virus poly(dC)-DNA, and the hybridized RNA was analyzed with poly(I)-spephadex chromatography. Approximately 0.5% of the RNA synthesized in ALV-infected cells was detected as virus specific, and no more than a twofold variation in the rate of synthesis was detected at different times in the cell cycle. In synchronized uninfected chicken embryo fibroblasts, approximately 0.03% of the RNA synthesized was detected as virus specific, and no significant variation in the rate of synthesis was observed during the cell cycle. Treatment of ALV-infected chicken embryo fibroblasts with cytosine arabinoside or colchicine was used to block cells at different stages in the cell cycle. The rates of virus-specific RNA synthesis in cells so treated did not differ significantly from the rates in either stationary or unsynchronized virus-infected chicken embryo fibroblasts. These findings support the conclusion that after the initial division of an ALV-infected chicken embryo fibroblast and the initiation of virus RNA synthesis, the rate of virus-specific RNA synthesis is independent of the cell cycle.     

Replication of Reticuloendotheliosis Viruses in Cell Culture: Acute Infection

Replication of reticuloendotheliosis viruses (REV) in cultures of chicken and duck fibroblasts leads to some cell death soon after infection. This cell killing was used to develop a plaque assay for Trager duck spleen necrosis virus (TDSNV) on duck embryo fibroblasts. A normal replicative cell cycle was required for normal virus production and the development of cytopathic effects in chicken cells exposed to TDSNV. The latent period was about two days. Stationary chicken embryo fibroblasts could be infected by REV; DNA synthesis was required, but protein synthesis was not.     

Failure of defective interfering particles of Sindbis virus produced in BHK or chicken cells to affect viral replication in Aedes albopictus cells.

Whereas defective interfering particles of Sindbis virus are readily produced in BHK-21 cells or chicken embryo fibroblasts by the techniques of serial undiluted passage, similar methods failed to generate such particles in Aedes albopictus cell cultures. In addition, Sindbis virus stocks produced in BHK-21 cells or chicken embryo fibroblasts and which contained defective interfering particles, when tested in A. albopictus cells, failed (i) to interfere with the replication of standard Sindbis virus and (ii) to change the pattern of intracellular viral RNA synthesis from that produced by infection with standard Sindbis virus alone. We conclude that defective interfering particles of Sindbis virus generated in chicken or hamster cells are silent or inert in mosquito cells.     

Hybridization of Rous Sarcoma Virus Deoxyribonucleic Acid Polymerase Product and Ribonucleic Acids from Chicken and Rat Cells Infected with Rous Sarcoma Virus

Rous sarcoma virus (RSV)-specific ribonucleic acid (RNA) in virus-producing chicken cells and non-virus-producing rat cells infected with RSV was studied by hybridization with the endogenous deoxyribonucleic acid (DNA) product of the RSV virion DNA polymerase system. By hybridizing the total DNA product with excess virion RNA, the product DNA was separated into hybridized (“minus”) and nonhybridized (“plus”) DNA. The “minus” DNA was complementary to at least 20% of the RNA from RSV which remained of high molecular weight after denaturation. A maximum of approximately 65% hybridization was observed between “minus” DNA and RSV RNA or RSV-infected chicken cell RNA. A maximum of about 60% hybridization was observed between “minus” DNA and RSV-infected rat cell RNA. RSV-infected chicken cells contained RSV-specific RNA equivalent to about 6,000 virions per cell. RSV-infected rat cells contained RSV-specific RNA equivalent to approximately 400 virions per cell. Neither cell type contained detectable RNA complementary to virion RNA. The RSV-specific RNA in RSV-infected rat cells did not appear to be qualitatively different from that in RSV-infected chicken cells.     

Glycoproteins E and I of Marek's Disease Virus Serotype 1 Are Essential for Virus Growth in Cultured Cells

The role of glycoprotein E (gE) and gI of Marek's disease virus serotype 1 (MDV-1) for growth in cultured cells was investigated. MDV-1 mutants lacking either gE (20DeltagE), gI (20DeltagI), or both gE and gI (20DeltagEI) were constructed by recE/T-mediated mutagenesis of a recently established infectious bacterial artificial chromosome (BAC) clone of MDV-1 (D. Schumacher, B. K. Tischer, W. Fuchs, and N. Osterrieder, J. Virol. 74:11088-11098, 2000). Deletion of either gE or gI, which form a complex in MDV-1-infected cells, resulted in the production of virus progeny that were unable to spread from cell to cell in either chicken embryo fibroblasts or quail muscle cells. This was reflected by the absence of virus plaques and the detection of only single infected cells after transfection, even after coseeding of transfected cells with uninfected cells. In contrast, growth of rescuant viruses, in which the deleted glycoprotein genes were reinserted by homologous recombination, was indistinguishable from that of parental BAC20 virus. In addition, the 20DeltagE mutant virus was able to spread from cell to cell when cotransfected into chicken embryo fibroblasts with an expression plasmid encoding MDV-1 gE, and the 20DeltagI mutant virus exhibited cell-to-cell spread capability after cotransfection with a gI expression plasmid. The 20DeltagEI mutant virus, however, was not able to spread in the presence of either a gE or gI expression plasmid, and only single infected cells were detected by indirect immunofluorescence. The results reported here demonstrate for the first time that both gE and gI are absolutely essential for cell-to-cell spread of a member of the Alphaherpesvirinae.     

Efficient transformation by Prague A Rous sarcoma virus plasmid DNA requires the presence of cis-acting regions within the gag gene.

A region in addition to and outside the long terminal repeats (LTRs) in the gag gene of the Prague A strain of Rous sarcoma virus was found to be essential in cis for efficient cell transformation by cloned viral DNA. Transformation in chicken embryo fibroblasts, which requires infectious virus production and reinfection, was facilitated in cis by sequences between nucleotides 630 and 1659. Efficient transformation of NIH 3T3 cells in which secondary spread of virus is not necessary (as it is in chicken embryo fibroblasts) required sequences between nucleotides 630 and 1149. A src cDNA clone which also lacks this region demonstrated low transformation efficiency, indicating that the role of the cis element cannot be attributed to interference with RNA splicing. The gag gene segment required in cis for transformation, between nucleotides 630 and 1149, could substitute for the simian virus 40 enhancer in either orientation, and cells transfected with Rous sarcoma virus LTR-driven plasmids containing the gag cis element had a two- to threefold increase in steady-state viral RNA levels compared with plasmids lacking this region. Thus, additional cis-acting regulatory elements located outside the viral LTRs may modulate viral gene expression and contribute to the efficiency of cell transformation.     

Spontaneous Conversion of Nontransformed Avian Sarcoma Virus-Infected Rat Cells to the Transformed Phenotype

Normal rat kidney (NRK) fibroblasts were infected with the Schmidt-Ruppin strain (SR-D) of avian sarcoma virus (ASV) and cloned 20 h after infection without selection for the transformed phenotype. Most infected clones initially exhibited the flat, nontransformed morphology that is characteristic of uninfected NRK cells. In long-term culture, however, the majority of the SR-D NRK clones began segregating typical ASV-transformed cells. Transforming ASV could be rescued by fusion with chicken embryo fibroblasts from most of the infected clones tested. Three predominantly flat, independently infected clones were further analyzed by subcloning 8 to 10 weeks after infection. Most flat progeny subclones derived at random from two of these "parental" SR-D NRK clonal lines did not yield virus upon fusion with chicken embryo fibroblasts, although a nondefective transforming ASV was repeatedly recovered from the parental clones. This observation suggested that most, but not all, daughter cells in these SR-D NRK clones lost the ASV provirus after cloning. The progeny of the third independent parental cell clone, c17, gave rise to both flat and transformed subclones that carried ASV. In this case, ASV recovery by fusion and transfection from the progeny subclones was equally efficient regardless of the transformation phenotype of the cells. The 60,000-dalton phosphoprotein product of the ASV src gene was, however, expressed at high level only in the transformed variants. The results of a Luria-Delbruck fluctuation analysis and of Newcombe's respreading test indicated that the event leading to the spontaneous conversion to the transformed state occurred at random in dividing cultures of these flat ASV NRK cells at a rate predicted for somatic mutation.     

Latency of Human Measles Virus in Hamster Cells

A latent system employing measles virus (Schwarz strain) was developed in hamster embryo fibroblasts (HEF). Measles virus-specific antigen was detected by immunofluorescence in 30 to 50% of HEF cells, and these cells released infectious virus when co-cultivated with a susceptible monkey cell line, BSC-1 cells. No infectious virus could be detected in the cells when measures were taken to exclude passage of viable latent cells onto the indicator BSC-1 cells. Infectious center assays demonstrated that about 1 in 10 of the latently infected cells in the population could release infectious virus. Infectious virus appeared within 6 hr after co-cultivation of the HEF cells with BSC-1 cells, as compared to 24 hr required for normal replication of measles virus in the BSC-1 cells. Furthermore, labeling of progeny virus ribonucleic acid (RNA) by using tritiated uridine, and inhibition of RNA or protein synthesis by 5-azacytidine or cycloheximide suggested that neither additional RNA nor protein synthesis is required after co-cultivation of the cells to effect early virus release. It can therefore be postulated that there is a block at a late step in virus replication in the latently infected hamster cells. The most obvious site would concern maturation of infectious virions at the cell membrane.     

Replication of endogenous avian retrovirus in permissive and nonpermissive chicken embryo fibroblasts.

Clones of chicken embryo fibroblasts exogenously infected with the endogenous avian retrovirus were analyzed to examine the replication of this virus in permissive (Gr+) and nonpermissive (Gr-) cells. The results demonstrate that the endogenous virus was capable of infecting both Gr+ and Gr- cells with equal efficiency. Infected clones of Gr+ and Gr- cells differed, however, in two significant ways. At the time of their initial characterization, the Gr+ clones produced 100- to 1,000-fold more virus than the Gr- clones. Further, the amount of virus produced by Gr+ clones did not change significantly during serial passage of the cells. In contrast, continued passage of the infected Gr- clones resulted in a gradual increase in the amount of virus produced. Individual clones of infected Gr- cells produced infectious virus at rates that, initially, differed by a factor of more than 10(4). The large differences in the production of virus by these clones could not be explained by equally large differences in the number of infected cells within the clonal populations. Greater than 80% of the clonal populations examined ultimately produced virus at rates that were not significantly different from the rates observed in infected Gr+ cells. Virus produced by these infected Gr- cells exhibited the same restricted replication upon establishing a new infection in nonpermissive cells. Analysis of the appearance of free and integrated viral DNA sequences during endogenous virus infection of Gr+ and Gr- cells demonstrated that, after an initial delay in the synthesis of free viral DNA in Gr- cells, the nonpermissive cells ultimately acquired as many integrated viral DNA sequences as were found in infected Gr+ cells. These results indicate that a majority of the infectious particles of the endogenous virus are capable of establishing infection in a Gr- cell and, ultimately, of producing virus at a rate that is not significantly different from that produced by infected Gr+ cells. The virus produced from the Gr- cells is not a stable genetic variant of the original endogenous virus that is capable of unrestricted replication in nonpermissive cells. The reduced efficiency with which the endogenous virus initially replicates in nonpermissive cells and the increased length of time required for infected Gr- cells to produce maximal virus titers suggest that the endogenous virus may utilize a different mechanism of replication in Gr+ and Gr- fibroblasts.     

Comparison of Rous sarcoma virus RNA processing in chicken and mouse fibroblasts: evidence for double-spliced RNA in nonpermissive mouse cells.

Rous sarcoma virus, an avian retrovirus, transforms but does not replicate in mammalian cells. To determine to what extent differences in RNA splicing might contribute to this lack of productive infection, cloned proviral DNA derived from the Prague A strain of Rous sarcoma virus was transfected into mouse NIH 3T3 cells, and the viral RNA was compared by RNase protection with viral RNA from transfected chicken embryo fibroblasts by using a tandem antisense riboprobe spanning the three major splice sites. The levels of viral RNA in NIH 3T3 cells compared with those in chicken embryo fibroblasts were lower, but the RNA was spliced at increased efficiency. The difference in the ratio of unspliced to spliced RNA levels was not due to the increased lability of unspliced RNA in NIH 3T3 cells. Although chicken embryo fibroblasts contained equal levels of src and env mRNAs, spliced viral mRNAs in NIH 3T3 cells were almost exclusively src. In NIH 3T3 cells the env mRNA was further processed by using a cryptic 5' splice site located within the env coding sequences and the normal src 3' splice site to form a double-spliced mRNA. This mRNA was identical to the src mRNA, except that a 159-nucleotide sequence from the 5' end of the env gene was inserted at the src splice junction. Smaller amounts of single-spliced RNA were also present in which only the region between the cryptic 5' and src 3' splice sites was spliced out. The aberrant processing of the viral env mRNA in NIH 3T3 cells may in part explain the nonpermissiveness of these cells to productive Rous sarcoma virus infection.