Characterization of K virus and its comparison with polyoma virus.

The antigenic relationship between the two murine papovaviruses, K virus and polyoma virus, was examined by serological techniques to determine whether they shared any antigenic components. No cross-reactivity was found associated with the viral (V) antigens by the indirect immunofluorescence, neutralization, or hemagglutination-inhibition tests. The tumor (T) antigens expressed in transformed cells or cells productively infected by either K or polyoma virus did not cross-react by indirect immunofluorescence. An antigenic relationship was detected, however, among the late proteins of K virus, polyoma virus, simian virus 40, and the human papovavirus BKV, when tested with either hyperimmune sera prepared against polyoma virus and simian virus 40 or sera prepared against disrupted virions. The nucleic acids of K and polyoma viruses were compared by agarose gel electrophoresis and restriction endonuclease analysis. No nucleotide sequence homology between the genomes of these two viruses was detectable by DNA-DNA hybridization techniques under stringent conditions. The genome of K virus was found to be slightly smaller than that of polyoma virus, and the cleavage patterns of the viral DNAs with six restriction endonucleases were different. These findings indicate that there is little relationship between these two murine papovaviruses.     

Further characterization of the polyoma virus Y8e from a Rauscher leukaemia virus producing mouse cell line and detection of partial sequence homology between polyoma virus Y8eDNA and hamster papovavirus DNA.

A DNA virus of the papovavirus group spontaneously appeared in RLV-infected spleen and thymus cells of mice in vitro was further characterized as polyoma virus Y8e by haemagglutination test, banding in density gradients, sedimentation coefficients of DNA and molecular hybridization of its DNA. The latter technique showed nearly complete sequence homology to polyoma virus strain SE DNA, partial sequence homology to hamster papovavirus DNA and mouse host DNA and little or no sequence homology to SV 40 DNA. The relationship between rodent papovaviruses and primate papovaviruses is discussed.     

State of the viral DNA in rat cells transformed by polyoma virus. I. Virus rescue and the presence of nonintergrated viral DNA molecules.

The interaction of polyoma virus with a continuous line of rat cells was studied. Infection of these cells with polyoma did not cause virus multiplication but induced transformation. Transformed cells did not produce infectious virus, but in all clones tested virus was rescuable upon fusion with permissive mouse cells. Transformed rat cells contained, in addition to integrated viral genomes, 20 to 50 copies of nonintegrated viral DNA equivalents per cell (average). "Free" viral DNA molecules were also found in cells transformed by the ts-a and ts-8 polyoma mutants and kept at 33 C. This was not due to a virus carrier state, since the number of nonintegrated viral DNA molecules was found to be unchanged when cells were grown in the presence of antipolyoma serum. Recloning of the transformed cell lines produced subclones, which also contained free viral DNA. Most of these molecules were supercoiled and were found in the muclei of the transformed cells. The nonintegrated viral DNA is infectious. Its specifici infectivity is, however, about 100-fold lower than that of polyoma DNA extracted from productively infected cells, suggesting that these molecules contain a large proportion of defectives.     

Late priming and variability of epitope-specific CD8+ T cell responses during a persistent virus infection

Control of persistently infecting viruses requires that antiviral CD8(+) T cells sustain their numbers and effector function. In this study, we monitored epitope-specific CD8(+) T cells during acute and persistent phases of infection by polyoma virus, a mouse pathogen that is capable of potent oncogenicity. We identified several novel polyoma-specific CD8(+) T cell epitopes in C57BL/6 mice, a mouse strain highly resistant to polyoma virus-induced tumors. Each of these epitopes is derived from the viral T proteins, nonstructural proteins produced by both productively and nonproductively (and potentially transformed) infected cells. In contrast to CD8(+) T cell responses described in other microbial infection mouse models, we found substantial variability between epitope-specific CD8(+) T cell responses in their kinetics of expansion and contraction during acute infection, maintenance during persistent infection, as well as their expression of cytokine receptors and cytokine profiles. This epitope-dependent variability also extended to differences in maturation of functional avidity from acute to persistent infection, despite a narrowing in TCR repertoire across all three specificities. Using a novel minimal myeloablation-bone marrow chimera approach, we visualized priming of epitope-specific CD8(+) T cells during persistent virus infection. Interestingly, epitope-specific CD8(+) T cells differed in CD62L-selectin expression profiles when primed in acute or persistent phases of infection, indicating that the context of priming affects CD8(+) T cell heterogeneity. In summary, persistent polyoma virus infection both quantitatively and qualitatively shapes the antiviral CD8(+) T cell response.     

Cooperation of p53 and polyoma virus middle T antigen in the transformation of primary rat embryo fibroblasts.

Cell transformation in vivo seems to be a multistep process. In in vitro studies certain combinations of two oncogenes, a cytoplasmic gene product together with a nuclear gene product, are sufficient to transform primary rodent cells. Polyoma virus large T antigen can immortalize and, in cooperation with polyoma virus middle T antigen, transform primary cells. On the other hand mutant mouse p53 can also immortalize and, in cooperation with an activated Ha-ras oncogene, transform primary cells. In the present study we analyzed whether mutant p53 can replace polyoma virus large T antigen in a cell transformation assay with polyoma virus middle T antigen. Transfection of mutant p53 alone resulted in a cell line which had retained the actin cable network, grew poorly in medium with low concentration of serum, and failed to grow in semisolid agar. Cotransfection of mutant p53 together with polyoma virus middle T led to cells which grew in medium containing low serum concentration, grew well in semisolid agar, and displayed an altered morphology with the tendency to overgrow the normal monolayer. By these criteria these cells were considered fully transformed. The rate of p53 synthesis was similar in both cell lines. However, only p53 from the transformed cell line turned out to be stable. Cells transformed by mutant p53 and polyoma virus middle T expressed nearly the same amount of the c-src-encoded pp60c-src protein as cells transformed by the same p53 and cotransfected activated Ha-ras oncogene. However, only the polyoma virus middle T/p53-transformed cells exhibited an elevated level of pp60c-src-specific tyrosine kinase activity. Thus, despite different mechanisms leading to cell transformation, mutant p53 can replace polyoma virus large T antigen and polyoma virus middle T can replace the activated Ha-ras oncogene in cell transformation.     

Recombination between endogenous and exogenous RNA tumor virus genes as analyzed by nucleic acid hybridization.

Certain chicken cells that do not spontaneously release virus particles have been shown to produce a subgroup E avian RNA tumor virus, Rous-associated virus 60 (RAV-60), after infection with viruses of other subgroups. The nucleic acids of RAV-60 were analyzed for sequence homologies with the viral nucleic acids contained in the uninfected cell and with those of RAV-2, the exogenous virus used for the preparation of this particular RAV-60 isolate. In addition, these nucleic acids were compared with those of RAV-0, an endogenous virus spontaneously released from line 100 chicken cells. RAV-60 appears to be intermediate between RAV-0 and RAV-2 in its genetic composition, based on the pattern of hybridization obtained with the nucleic acids of these viruses and on the melting profiles of the various hybrid combinations. Of the three viruses tested, RAV-0 appears to have the greatest sequence homology with the viral nucleic acids of the uninfected cell. Hybridization between RAV-60 3-H-labeled complementary DNA and either DNA or RNA from the uninfected cell indicates that RAV-60 contains some nucleic acid sequences which are not present in the cell. In addition, some RAV-60 sequences which hybridize with the cell nucleic acid contain significant amounts of mismatching, as indicated by the lower thermal stability of these hybrid duplexes. Hybrid formation between these partially homologous sequences was excluded under stringent annealing conditions. The data indicate that RAV-60 is a recombinant between exogenous and endogenous viral genes.     

Distinct transformation phenotypes induced by polyoma virus and simian virus 40 in rat fibroblasts and their control by an early viral gene function.

Several transformed cell lines established from Fisher rat cells (FR 3T3) infected with wild-type polyoma virus or simian virus 40 or early temperature-sensitive mutants (polyoma tsa and simian virus 40 tsA30) were studied for their transformation phenotypes. The distinct patterns which were obtained for polyoma and simian virus 40 transformants led to the conclusion that these two viruses express different transforming abilities in rat cells. The results obtained with temperature-sensitive mutant-derived transformants indicate that all of the transformation characteristics studied so far may be under the control of a viral function in polyoma tsa-transformed cells.     

Vitamin A inhibition of polyoma virus replication

Vitamin A (retinoic acid) inhibited polyoma virus replication in confluent mouse embryo cells. A significant, dose dependent inhibition was observed when cell monolayers were pretreated with concentrations of vitamin A (10(-8) to 10(-6) M) thought to approximate those found in vivo. This inhibitory effect could be reduced by increasing the input multiplicity of infection. Growth curves of polyoma virus in the presence and absence of vitamin A suggested that vitamin A actually inhibited, and did not simply delay, virus replication. The cell density dependence of this inhibitory effect suggested its association with the prevailing level of cellular DNA synthesis. Vitamin A caused a significant decrease in overall (viral plus cellular) DNA synthesis. Other viruses which do not require induction of host cell DNA synthesis for their replication in confluent, non-dividing cells were not inhibited by vitamin A. These results are consistent with the known inhibitory effects of vitamin A on papovavirus infection in vivo and suggest a mechanism of vitamin A action at the level of the infected cell.     

Visna virus synthesized in absence of host-cell division and DNA synthesis

Visna virus is similar to the avian and the murine oncornaviruses. Oncornavirus replication is dependent upon the provirus being integrated into the host cell's DNA but integration and subsequent oncornavirus synthesis is blocked when the host cells are prevented from synthesizing cellular DNA or dividing. The synthesis of visna virus is restricted in vivo and may be dependent upon the host cell's ability to synthesize cellular DNA or divide. Treatment of sheep choroid plexus (SCP) cells with ultraviolet light or with mitomycin C prior to infection irreversibly inhibited plexus (ScP) cells with ultraviolet light or with mitomycin C prior to infection irreversibly inhibited both cell division and cellular nucleic acid synthesis but did not inhibit visna virus synthesis. Similarly, the synthesis of visna virus in cultures of SCP cells which had been prevented from dividing by being deprived of serum and in cultures of SCP cells which were incapable of synthesizing host cell nucleic acids by being treated with miracil D or sodium hexachloroiridate was equivalent to the synthesis of visna virus in cultures of SCP cells which were allowed to both synthesize cellular nucleic acids and divide. The synthesis of visna virus in the presence of ethidium bromide further demonstrated that integration of the visna provirus into the host cell's DNA is not required for visna virus synthesis to occur.     

CD94/NKG2A expression is associated with proliferative potential of CD8 T cells during persistent polyoma virus infection

Memory CD8 T cells comprise a critical component of durable immunity because of their capacity to rapidly proliferate and exert effector activity upon Ag rechallenge. During persistent viral infection, memory CD8 T cells repetitively encounter viral Ag and must maintain a delicate balance between limiting viral replication and minimizing immunopathology. In mice infected by polyoma virus, a natural mouse pathogen that establishes long-term persistent infection, the majority of persistence-phase antiviral CD8 T cells express the inhibitory NK cell receptor CD94/NKG2A. In this study, we asked whether CD94/NKG2A expression is associated with Ag-specific recall of polyoma virus-specific CD8 T cells. During the persistent phase of infection, polyoma virus-specific CD8 T cells that express CD94/NKG2A were found to preferentially proliferate; this proliferation was dependent on cognate Ag both in vitro and in vivo. In addition, CD94/NKG2A(+) polyoma-specific CD8 T cells have a markedly enhanced capacity to produce IL-2 upon ex vivo Ag stimulation compared with CD94/NKG2A(-) polyoma-specific CD8 T cells. Importantly, CD94/NKG2A(+) anti-polyoma virus CD8 T cells appear to be essential for Ag-specific recall responses in mice persistently infected by polyoma virus. Because of its higher proliferative potential and capacity to produce IL-2, we propose that the CD94/NKG2A(+) subpopulation represents a less differentiated state than the CD94/NKG2A(-) subpopulation. Identification of proliferation-competent subpopulations of memory CD8 T cells should prove valuable in designing therapeutic vaccination strategies for persistent viral infections.     

Changes in the cell surface architecture in normal and polyoma virus transformed hamster cells after infection with influenza virus

Test of Con A induced cell agglutination, method of binding cells to Con A coated nylon fibres and modified procedure of cell-to-cell binding were used in the investigation of architectural surface changes in normal and polyoma virus transformed hamster cells infected with influenza virus. In both cell types influenza virus infection caused 1) increase in fixation resistant Con A agglutination, 2) decrease in the level of surface membrane fluidity and cell plasticity. It has postulated that influenza virus infection results in stabilization of the cell surface architecture. These changes are amplified by polyoma virus transformation. Con A acts in this system, as an indicator rather than as a modifier of architectural changes.     

Erythropoietin responses and physical characterization of erythroid progenitor cells in Rauscher virus infected BALB/c mice.

Infection of BALB/c mice with Rauscher leukemia virus (RLV) gives rise to pronounced erythrocytopoiesis manifesting in splenomegaly and is associated with progressive development of anemia. In the spleen erythroid colony forming units (CFU-E) increase exponentially up to 800-fold that of normal levels by the third week of infection. In vitro these CFU-E are dependent on erythropoietin for colony formation, their erythropoietin requirements being higher than that of CFU-E from normal mice. Numbers of CFU-E in spleen and degree of splenomegaly in anemic RLV infected mice were also shown to be modified by red blood cell transfusion, but progression of the disease was not stopped. Erythroid burst forming units (BFU-E) were also responsive to erythropoietin. However, a small proportion of cells also formed BFU-E colonies at concentrations which did not support growth of normal marrow BFU-E. When compared to normal, CFU-E found in RLV-infected spleen have similar velocity sedimentation rates. However, buoyant density separation of leukemic spleen cells indicated that CFU-E were more homogeneous (modal density 1.0695 g/cm3) than CFU-E from normal spleen. Analysis of physical properties of CFU-E and the nonhemoglobinized erythroblast-like cells, which accumulate in the spleen showed that they differed mainly in their distribution of cell diameter. Our findings show that erythroid progenitor cells in RLV infected mice are responsive to erythropoietin in vitro. Also in vivo erythropoiesis appears to be under control of erythropoietin but other factors which lead to progression of RLV disease apparently exist. Most proerythroblast-like cells, which are characteristic of this disease, apparently lack the potential to form colonies and may be more mature than CFU-E.     

Protective cellular retroviral immunity requires both CD4+ and CD8+ immune T cells.

We have found previously that postexposure chemoprophylaxis with 3'-azido-3'-deoxythymidine (also known as zidovudine or AZT) in combination with recombinant human alpha A/D interferon fully protected mice exposed to a lethal dose of Rauscher murine leukemia virus (RLV) against viremia and disease. After cessation of therapy, over 90% of these mice were able to resist rechallenge with live RLV, thus demonstrating an acquired immunity. Adoptive cell transfer of 4 x 10(7) cells from immunized mice fully protected naive recipients from viremia and splenomegaly after RLV challenge. However, when these immune T cells were fractionated into CD4+ and CD8+ subpopulations, only partial protection was found when 4 x 10(7) T cells of either subset were given. Full protection against RLV challenge was seen again when the T-cell subsets from immunized mice were recombined and transferred at the same number into naive mice. We conclude that cellular immunity alone is protective and that both CD4+ and CD8+ cell types are required for conferring full protection against live virus challenge.     

In vitro tumoricidal activity of macrophages against virus-transformed lines with temperature-dependent transformed phenotypic characteristics.

The susceptibility of targets to destruction by tumoricidal rat and mouse macrophages was studied with virus-transformed cell lines in which various elements of the transformed phenotype are only expressed at specific temperatures. BHK cells transformed by the ts3 mutant of polyoma virus, rat embryo 3Y1 cells transformed by a temperature-sensitive A cistron mutant of simian virus 40 (SV40) and the ts-H6-15 temperature-sensitive line of SV40-transformed mouse 3T3 cells were killed in vitro by macrophages at both the permissive (33 °C) or nonpermissive (39 °C) temperatures for expression of the transformed phenotype. 3T3, 3Y1 and BHK cells transformed by wild-type SV40 or polyoma virus were also destroyed by tumoricidal macrophages at both 33 and 39 °C, but untransformed 3T3, 3Y1, and BHK cells were not. Thus, transformed cells are killed by macrophages regardless of whether or not they express cell surface LETS protein or Forssman antigen, display surface changes which permit agglutination by low doses of plant lectins, express SV40 T antigen, have a low saturation density, or exhibit density-dependent inhibition of DNA synthesis.     

Cell-free synthesis of polyoma virus capsid proteins VP1 and VP2.

Polyadenylated RNA isolated from the cytoplasm of mouse 3T6 cells 28 h after infection with polyoma virus has been isolated and translated in vitro. Polyoma capsid proteins VP1 and VP2 have been identified in the cell-free product by polyacrylamide gel electrophoresis, specific immunoprecipitation, and tryptic peptide fingerprinting. Polyoma mRNA species have been isolated by preparative hybridization to purified viral DNA immobilized on cellulose nitrate filters and shown to code for both VP1 and VP2. These experiments establish conditions for the isolation of late polyoma mRNA and the cell-free synthesis of polyoma capsid proteins and indicate that the active mRNA species are at least partially virus coded.     

Application of cell fractionation techniques in the study of cells infected with polyoma virus and Newcastle disease virus

Fisher, Harold W. (University of Rhode Island, Kingston), Hidemi Matsumiya, and Masanobu Azuma. Application of cell fractionation techniques in the study of cells infected with polyoma virus and Newcastle disease virus. J. Bacteriol. 91:1645-1651. 1966.-Techniques which permitted rigorous separation of nuclei and cytoplasm were applied to the study of the formation of Newcastle disease virus (NDV) in an established line of Chinese hamster cells and of polyoma virus (PYV) in mouse embryo fibroblasts. The results obtained for hemagglutinin and plaque-forming titers during virus growth were in agreement with those obtained by others, using different techniques. These indicated that NDV matures in the cytoplasm, and PYV in the nucleus, of host cells.     

Sulfated mucopolysaccharides from normal and virus transformed rodent fibroblasts.

The sulfated mucopolysaccharide composition of normal and virus transformed Balb 3T3 and BHK21 cell lines is reported. It is shown that normal 3T3 cells contain mainly chondroitin sulfate B and heparitin sulfate. Relatively higher amounts of chondroitin sulface AC were observed in polyoma virus transformed 3T3 cells, besides an absolute increase of all the three sulfated mucopolysaccharides in the polyoma and SV 40 transformed cells. It is shown also that the three sulfated mucopolysaccharides are at least in part at the cell surface. Similar differences in sulfated mucopolysaccharide composition of normal and virus transformed BHK cell lines were also observed.     

Phenotypic transformation of the host cell enhances polyoma pseudovirion formation.

Phenotypic transformation of the host cell affected the formation of polyoma pseuodovirions. Polyoma virus infection of various transformed derivatives of mouse 3T3 cells resulted in the formation of predominantly pseudovirions, whereas infection of mouse 3T3 cells produced mainly polyoma virus. The effect that transformation of the host cell had on polyoma pseudovirus formation was further demonstrated by using phenotypic revertants isolated from some of the transformed cell lines. The revertants were characterized by their morphology, saturation densities, and colony-forming ability in methylcellulose suspension. By these criteria they were distinct from their transformed parents and similar to 3T3 cells. After infection, the revertants produced predominantly polyoma virus and few pseudovirus. Thus, for the cell lines used in this study, phenotypic transformation enhanced the formationof polyoma pseudovirions.