Synthesis of human adenovirus early RNA species is similar in productive and abortive infections of monkey and human cells.

Northern (RNA) blot analysis has been used to show that synthesis of early mRNA species is similar in monkey cells productively or abortively infected with human adenovirus. mRNA species from all five major early regions (1A, 1B, 2, 3, 4) are identical in size and comparable in abundance whether isolated from monkey cells infected with adenovirus type 2 or with the host range mutant Ad2hr400 or coinfected with adenovirus type 2 plus simian virus 40. The mRNA species isolated from monkey cells are identical in size to those isolated from human cells. Production of virus-associated RNA is also identical in productive and abortive infections of monkey cells. Synthesis of virus-associated RNA is, however, significantly greater in HeLa cells than in CV1 cells at late times after infection regardless of which virus is used in the infection.     

Simian virus 40 cRNA is processed into functional mRNA in microinjected monkey cells.

Monkey cells, microinjected with simian virus 40 (SV40) in vitro synthesized cRNA produce full-size tumor (T)-antigen. This was verified by analyzing immunoprecipitates of microinjected cells by polyacrylamide gel electrophoresis. Early SV40 DNA contains an intron within the large T-antigen coding sequences. Therefore, cRNA copied in vitro from the early DNA strand requires removal of the intron in order to become a functional mRNA. Polyadenylation of the cRNA in vitro by Escherichia coli poly(A)-polymerase increased the biological activity of the RNA. Detection of T-antigen by gel electrophoresis required as little as 50 poly(A)-cRNA injected cells. Splicing of the microinjected cRNA appears to be a nuclear process. Cells enucleated by cytochalasin B prior to injection do not synthesize large T-antigen. However, small t-antigen, a protein with a continuous sequence, is synthesized in these cells. Finally, it is shown that the process of splicing is not required for the transport of mRNA from the nucleus into the cytoplasm. Authentic T-antigen mRNA, isolated from virus infected cells, induced T-antigen synthesis with similar efficiency after either nuclear or cytoplasmic injection.     

Translation of mRNA from Simian Virus 40-Infected Cells into Simian Virus 40 Capsid Protein by Cell-Free Extracts

Messenger RNA was isolated from simian virus 40 (SV40)-infected and mock-infected cells by chromatography on poly(U) sepharose. When added to cell-free extracts from Chinese hamster ovary cells or rabbit reticulocytes, RNA from the infected cells, but not from mock-infected cells, stimulated synthesis of the major SV40 capsid protein. Identification of this species was done by sodium dodecyl sulfate gel electrophoresis, peptide mapping, and immunoprecipitation. The in vitro synthesized capsid protein was slightly different from virion assembled capsid protein, as shown by separation upon chromatography on hydroxylapatite and by minor differences in the peptide map.     

Simian virus 40 agnoprotein facilitates normal nuclear location of the major capsid polypeptide and cell-to-cell spread of virus.

The simian virus 40 agnoprotein is a 61-amino-acid, highly basic polypeptide that is coded within the 5' leader of late 16S mRNAs. To better understand agnoprotein function and to more effectively differentiate cis-from trans-acting effects of an agnogene mutation, we constructed a mutant virus that carries a single-base-pair substitution and fails to produce agnoprotein. pm 1493 contains a T/A to A/T transversion at sequence position 335. This mutation converts the agnoprotein initiation codon from ATG to TTG, preventing synthesis of the protein. The mutant displays only a modest growth defect in CV-1P and AGMK cells and no defect in BSC-1 cells. Early-gene expression, DNA replication, synthesis of late viral products, and the kinetics of virion assembly all appear normal in pm 1493-infected CV-1P cells. Immunofluorescent studies, however, indicate that localization of the major capsid polypeptide VP1 is different in mutant- than wild-type virus-infected cells. Furthermore, the lack of agnoprotein led to inefficient release of mature virus from the infected cell. Agnogene mutants could be severely compromised in their ability to propagate in monkeys given their reduced capacity for cell-to-cell spread.     

Simian virus 40 and polyoma virus induce synthesis of heat shock proteins in permissive cells.

During the lytic infection of monkey and mouse cells with simian virus 40 and polyoma virus, respectively, the preferentially increased synthesis of two host proteins of 92,000 and 72,000 Mr was observed by 15 to 20 h after infection besides the general stimulation of most cellular proteins. The incubation of uninfected monkey and mouse cell cultures for 30 to 60 min at 43.5 degrees C induced the enhanced synthesis of at least three proteins of 92,000, 72,000 and 70,000 Mr, the last one being the major heat shock protein of mammalian cells. Two-dimensional gel electrophoresis and partial proteolytic digestion confirmed that the same 92,000- and 72,000-Mr proteins are stimulated by virus infection and thermal treatment. In simian virus 40-infected CV-1 cells, we also observed the weak stimulation of a 70,000-Mr protein comigrating in gel electrophoresis with the major heat shock protein. The 92,000-, 72,000- and 70,000-Mr proteins of monkey cells are structurally very similar to the corresponding proteins of mouse cells. In immunoprecipitations, no specific association of these proteins to simian virus 40 T antigens was noticed.     

Coupling of polyoma DNA and RNA synthesis

Polyoma virus RNA from infected mouse embryo cells was examined by gel electrophoresis and in nucleic acid hybridisation experiments. The extent of representation of the polyoma genome in RNA sequences when cytosine arabinoside is present throughout infection is 30 to 40% of that at late times in infection. When viral DNA synthesis is inhibited during the period in which it is rising to its maximum, the resulting cytoplasmic RNA resembles ‘early’ RNA both in size and by its behaviour in competition hybridisation experiments.     

Simian virus 40 gene A regulation of cellular DNA synthesis. II. In nonpermissive cells.

The stimulation of host macromolecular synthesis and induction into the cell cycle of serum-deprived G0-G1-arrested mouse embryo fibroblasts were examined after infection of resting cells with wild-type simian virus 40 or with viral mutants affecting T antigen (tsA58) or small t antigen (dl884). At various times after virus infection, cell cultures were analyzed for DNA synthesis by autoradiography and flow microfluorimetry. Whereas mock-infected cultured remained quiescent and displayed either a 2N DNA content (80%) or a 4N DNA content (15%), mouse cells infected with wild-type simian virus 40, tsA58 at 33 degrees C, or dl884 were induced into active cell cycling at approximately 18 h postinfection. Although dl884-infected mouse cells were induced to cycle initially at the same rate as wild type-infected cells, they became arrested earlier after infection and also failed to reach the saturation densities of wild-type simian virus 40-infected cells. Infection with dl884 also failed to induce loss of cytoplasmic actin cables in the majority of the infected cell population. Mouse cells infected with tsA58 and maintained at 39.5 degrees C showed a transient burst of DNA synthesis as reflected by changes in cell DNA content and an increase in the number of labeled nuclei during the first 24 h postinfection; however, after the abortive stimulation of DNA synthesis at 39.5 degrees C shift experiments demonstrated that host DNA replication was regulated by a functional A gene product. It is concluded that both products of the early region of simian virus 40 DNA play a complementary role in recruiting and maintaining simian virus 40-infected cells in the cell cycle.     

Transcription and Transport of Virus-Specific Ribonucleic Acids in African Green Monkey Kidney Cells Abortively Infected with Type 2 Adenovirus

The techniques of deoxyribonucleic acid-ribonucleic acid (DNA-RNA) hybridization and immunological precipitation were used to compare the synthesis of adenovirus-specific macromolecules in African green monkey kidney (AGMK) cells infected with adenovirus, an abortive infection, and coinfected with both adenovirus and simian virus 40 (SV40), which renders the cells permissive for adenovirus replication. When viral protein synthesis was proceeding at its maximum rate, the incorporation of (14)C-amino acids into adenovirus structural proteins was about 90 times greater in the doubly infected cells than in cells infected only with adenovirus. However, the rates of synthesis of virus-specific ribonucleic acid appeared to be comparable in the two infections at all times measured. A time-dependent increase in the rate of RNA synthesis observed late in the abortive infection was dependent upon the prior replication of viral DNA. Moreover, all virus-specific RNA species that are normally made late in a productive adenovirus infection (i.e., the true late and class II early RNA species) were also detected in the abortive infection. Adenovirus-specific RNA was detected by molecular hybridization in both the cytoplasm and nuclei of abortively infected cells. Comparable amounts of viral RNA were found in the cytoplasmic fractions of AGMK cells infected either with adenovirus or with both adenovirus and SV40. The results of hybridization-inhibition experiments clearly showed that there was a class of virus-specific RNA molecules, representing about 30% of the total, in the nucleus that was not transported to the cytoplasm. This class of RNA was also identified in similar amounts in productively infected human KB cells. The difference in the abilities of cytoplasmic and nuclear RNA to inhibit the hybridization of virus-specific RNA from whole cells was shown not to be due to a difference in the molecular size of the RNA species from the two cell fractions or to the specific loss of a cytoplasmic species during RNA extraction procedures.     

Inhibition of vimentin synthesis and disruption of intermediate filaments in simian virus 40-infected monkey kidney cells.

The organization, synthesis, and phosphorylation of vimentin were studied at various times after infection of monkey kidney cells with simian virus 40. Late after infection (between 36 and 48 h postinfection) there is a dramatic reduction in vimentin synthesis that is paralleled by a specific disruption of the intermediate filament network. At the same time there is no apparent alteration of the organization or the synthesis of the actin-containing filaments and of the microtubules. The inhibition of vimentin synthesis is also reflected by the level of vimentin mRNA activity in the infected cells, as assayed in a cell-free in vitro translation system, and vimentin mRNA concentration as revealed by RNA blot hybridization to cloned vimentin cDNA. The level of vimentin phosphorylation also decreases dramatically but at a much earlier time after infection (between 14 and 24 h postinfection), when mitosis in the infected cells is blocked. Although the decrease in vimentin synthesis in simian virus 40-infected cells is paralleled by the alterations in the organization of the intermediate filament network, the phosphorylation of vimentin correlates with the cell cycle, as it does in other systems. A possible feedback control mechanism of vimentin synthesis by alterations in the organization of the intermediate filament network is discussed.     

Immunochemical reactivity of simian sarcoma virus polypeptides isolated by preparative sodium dodecyl sulfate polyacrylamide gel electrophoresis

The polypeptides associated with a zonal centrifugation purified simian sarcoma virus propagated in lymphoblastoid NC-37 cells were isolated by preparative polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS) using a procedure designed to minimize the loss of immunochemical reactivity. The proteins p10, p15, p28, p36, p44, p75, and p86 were obtained in large yield and high degree of homogeneity. The electrophoretically purified p28 was analyzed by competition radioimmunoassay using antiserum to a pore exclusion and ion exchange purified simian sarcoma virus p28. Complete competition was observed with extracts of simian sarcoma virus infected cells. No competition was observed with uninfected or unrelated, infected cell extracts. The antigen-antibody affinity as measured by the slope of the competition curve using antiserum to p28 and 125I-labeled and electrophoretically purified p28 was the same as that for the p28 released from sonication-disrupted simian sarcoma virus. The data indicates that preparative purifications by polyacrylamide gel electrophoresis in the presence of SDS may be generally applicable for the isolation of proteins with essentially the same immunospecificities and affinity for a specific antiserum as proteins isolated by procedures that avoid the use of SDS and electrophoresis.     

Ribonucleic Acid Synthesis in Cells Infected with Herpes Simplex Virus: I. Patterns of Ribonucleic Acid Synthesis in Productively Infected Cells

HEp-2 cells were pulse-labeled at different times after infection with herpes simplex virus, and nuclear ribonucleic acid (RNA) and cytoplasmic RNA were examined. The data showed the following: (i) Analysis by acrylamide gel electrophoresis of cytoplasmic RNA of cells infected at high multiplicities [80 to 200 plaque-forming units (PFU)/cell] revealed that ribosomal RNA (rRNA) synthesis falls to less than 10% of control (uninfected cell) values by 5 hr after infection. The synthesis of 4S RNA also declined but not as rapidly, and at its lowest level it was still 20% of control values. At lower multiplicities (20 PFU), the rate of inhibition was slower than at high multiplicities. However, at all multiplicities the rates of inhibition of 18S and 28S rRNA remained identical and higher than that of 4S RNA. (ii) Analysis of nuclear RNA of cells infected at high multiplicities by sucrose density gradient centrifugation showed that the synthesis and methylation of 45S rRNA precursor continued at a reduced but significant rate (ca. 30% of control values) at times after infection when no radioactive uridine was incorporated or could be chased into 28S and 18S rRNA. This indicates that the inhibition of rRNA synthesis after herpesvirus infection is a result of two processes: a decrease in the rate of synthesis of 45S RNA and a decrease in the rate of processing of that 45S RNA that is synthesized. (iii) Hybridization of nuclear and cytoplasmic RNA of infected cells with herpesvirus DNA revealed that a significant proportion of the total viral RNA in the nucleus has a sedimentation coefficient of 50S or greater. The sedimentation coefficient of virus-specific RNA associated with cytoplasmic polyribosomes is smaller with a maximum at 16S to 20S, but there is some rapidly sedimenting RNA (> 28S) here too. (iv) Finally, there was leakage of low-molecular weight (4S) RNA from infected cells, the leakage being approximately three-fold that of uninfected cells by approximately 5 hr after infection.