The synthesis and turnover of virus-specific polyadenylated RNA in polyoma-infected cells.

Mouse embryo cells infected with the 3049 strain of polyoma virus contain several fold more virus-specific, polyadenylated RNA beginning between 4 and 8 hours after the onset of viral DNA synthesis than do cells infected with wild-type virus (lpS). Following infection with either virus strain, there is an identical small but significant enhancement of the level of total polyadenylated RNA measured by binding of ¹²⁵I-labeled RNA to poly(dT)cellulose. The polyadenylation of “early” virus-specific RNA is inhibited 85–90% by cordycepin resulting in an “early” RNA preparation which competes fully with polyadenylated “early” virus-specific RNA in the ternary complex assay. Utilizing the nonpolyadenylated “early” RNA, competition hybridization demonstrated that approximately 78% of the enlarged pool of “late” 3049 polyadenylated RNA and 72% of the “late” lpS pool consisted of sequences unique to the “late” period. No significant difference in the rate of decay of 3049 and lpS-specific, “late” polyadenylated RNA following actinomycin D block was found. Infection by either strain of polyoma virus did not alter the rate of decay of total polyadenylated RNA.     

Mechanism of Viral Carcinogenesis by Deoxyribonucleic Acid Mammalian Viruses IV. Related Virus-specific Ribonucleic Acids in Tumor Cells Induced by “Highly” Oncogenic Adenovirus Types 12, 18, and 31

Formation of hybrids between viral deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) was used to detect virus-specific RNA in the nuclei and polyribosomes of transformed and tumor cells induced by "highly" oncogenic human adenovirus (Ad) types 12, 18, and 31. The presence of virus-specific RNA in the cell nucleus, and the inhibitory effect of actinomycin D on its synthesis, suggest that adenovirus-specific RNA is transcribed from a DNA template in the nucleus. Ad 12, 18, and 31 virus-specific RNA did not hybridize significantly with the DNA of the "weakly" oncogenic adenovirus group (Ad 3, 7, 11, 14, 16, and 21) or with that of nononcogenic Ad 2 and 4. Labeled RNA from Ad 12, 18, and 31 tumor cells hybridized with heterologous Ad 12, 18, and 31 DNA 30 to 60% as efficiently as with homologous DNA. Thus, common viral genes are transcribed in tumor cells induced by Ad 12, 18, and 31.     

Requirement of cell nucleus for Sindbis virus replication in cultured Aedes albopictus cells.

The ability of Sindbis virus to grow in enucleated BHK-21 (vertebrate) and Aedes albopictus (invertebrate) cells was tested to determine the dependence of this virus upon nuclear function in these two phylogenetically unrelated hosts. Although both cell types could be demonstrated to produce viable cytoplasts (enucleated cells) which produced virus-specific antigen subsequent to infection. BHK cytoplasts produced a significant number of progeny virions, whereas mosquito cytoplasts did not. The production of vesicular stomatitis virus in mosquito cells was not significantly reduced by enucleation. That such a host function was not essential for vesicular stomatitis virus growth in insect cells is supported by the observation that the production of this virus by mosquito cells is not actinomycin D sensitive. This result agrees with a previously published report in which it was shown that Sindbis virus maturation in invertebrate cells is inhibited by actinomycin D, indicating a possible requirement for host cell nuclear function (Scheefers-Borchel et al., Virology, 110:292-301, 1981).     

Flock House Virus RNA Replicates on Outer Mitochondrial Membranes in Drosophila Cells

The identification and characterization of host cell membranes essential for positive-strand RNA virus replication should provide insight into the mechanisms of viral replication and potentially identify novel targets for broadly effective antiviral agents. The alphanodavirus flock house virus (FHV) is a positive-strand RNA virus with one of the smallest known genomes among animal RNA viruses, and it can replicate in insect, plant, mammalian, and yeast cells. To investigate the localization of FHV RNA replication, we generated polyclonal antisera against protein A, the FHV RNA-dependent RNA polymerase, which is the sole viral protein required for FHV RNA replication. We detected protein A within 4 h after infection of Drosophila DL-1 cells and, by differential and isopycnic gradient centrifugation, found that protein A was tightly membrane associated, similar to integral membrane replicase proteins from other positive-strand RNA viruses. Confocal immunofluorescence microscopy and virus-specific, actinomycin D-resistant bromo-UTP incorporation identified mitochondria as the intracellular site of protein A localization and viral RNA synthesis. Selective membrane permeabilization and immunoelectron microscopy further localized protein A to outer mitochondrial membranes. Electron microscopy revealed 40- to 60-nm membrane-bound spherical structures in the mitochondrial intermembrane space of FHV-infected cells, similar in ultrastructural appearance to tombusvirus- and togavirus-induced membrane structures. We concluded that FHV RNA replication occurs on outer mitochondrial membranes and shares fundamental biochemical and ultrastructural features with RNA replication of positive-strand RNA viruses from other families.     

Role of RNA synthesis in DNA replication of synchronized populations of cultured mammalian cells

Using the harvesting method of synchronizing L cells, the relationship of RNA synthesis of DNA replication was studied by the use of selective inhibitors of RNA synthesis such as actinomycin D and chromomycin succinate. The synthesis of the early replicating DNA fraction is a process sensitive to the inhibition of RNA synthesis during the G1 period. The synthesis of early replicating DNA was inhibited by chromomycin succinate without affecting the initation of DNA synthesis. However, actinomycin D inhibited the synthesis of early replicating DNA and prevented the initiation of DNA synthesis in 50% of the synchronized cells. However, it was found that the continued synthesis of RNA during the S period is not essential for the synthesis of late replicating DNA. In addition to this specific response of DNA synthesis to the inhibitors of RNA synthesis, another function of early and late replicating DNA was determined relative to the cell viability. Cells synthesizing early replicating DNA were killed more efficiently by chromomycin than at other stages of the cell cycle. This indicates that the early replicating DNA unit plays a more important role in cell reproduction than the late replicating DNA unit.     

Synthesis of reovirus ribonucleic acid in L cells

Kudo, Hajime (The Wistar Institute of Anatomy and Biology, Philadelphia, Pa.), and A. F. Graham. Synthesis of reovirus ribonucleic acid in L cells. J. Bacteriol. 90:936-945. 1965.-There is no inhibition of protein or deoxyribonucleic acid (DNA) synthesis in L cells infected with reovirus until the time that new virus starts to form about 8 hr after infection. At this time, both protein synthesis and DNA synthesis commence to be inhibited. Neither the synthesis of ribosomal ribonucleic acid (RNA) nor that of the rapidly labeled RNA of the cell nucleus is inhibited before 10 hr after infection. Actinomycin at a concentration of 0.5 mug/ml does not inhibit the formation of reovirus, although higher concentrations of the antibiotic do so. Pulse-labeling experiments with uridine-C(14) carried out in the presence of 0.5 mug/ml of actinomycin show that, at 6 to 8 hr after infection, two species of virus-specific RNA begin to form and increase in quantity as time goes on. One species is sensitive to ribonuclease action and the other is very resistant. The latter RNA is probably double-stranded viral progeny RNA, and it constitutes approximately 40% of the RNA formed up to 16 hr after infection. The function of the ribonuclease-sensitive RNA is not yet known. Synthesis of both species of RNA is inhibited by 5 mug/ml of actinomycin added at early times after infection. Added 6 to 8 hr after infection, when virus-specific RNA has already commenced to form, 5 mug/ml of actinomycin no longer inhibit the formation of either species of RNA.     

Newcastle Disease Virus Infection of L Cells

Newcastle disease virus (NDV) California strain reportedly grows poorly in L cells but replicates very well in chicken embryo cells. NDV-infected L cell cultures show a characteristic virus growth curve with respect to uridine incorporation, but plaque assays of the virus produced 24 h postinfection (PI) show no infectious particles when assayed on L cell monolayers and only a very low titer on chick cell monolayers. Plasma membranes isolated and purified from infected L cells 8 h PI contain all of the major virion proteins. In addition, NDV-infected L cells show a 50% loss of H-2 antigenic activity, a phenomenon previously observed in cells productively infected with vesicular stomatitis virus. These results suggest that at least part of the normal process of NDV maturation occurs in NDV-infected L cells. Sodium dodecyl sulfate-polyacrylamide gel patterns of supernatant virus purified from cells radiolabeled with amino acids from 3 to 24 h PI in the presence of actinomycin D show that all the major NDV structural proteins are present. Electron micrographs of NDV-infected L cells show extensive virus maturation at cell membranes. It can be concluded that infection of L cells with NDV results in a normal production of virus-specific RNA, synthesis of all the major structural proteins, association of the viral envelope proteins with the L cell plasma membrane, and the loss of cell surface H-2 antigenic activity. However, most of the virus particles produced are noninfectious.     

Phospholipid Synthesis in Sindbis Virus-Infected Cells

We investigated the metabolic requirements for the decrease in phospholipid synthesis previously observed by Pfefferkorn and Hunter in primary cultures of chick embryo fibroblasts infected with Sindbis virus. The incorporation of (32)PO(4) into all classes of phospholipids was found to decline at the same rate and to the same extent; thus, incorporation of (14)C-choline into acid-precipitable form provided a convenient measure of phospholipid synthesis that was used in subsequent experiments. Experiments with temperature-sensitive mutants suggested that some viral ribonucleic acid (RNA) synthesis was essential for the inhibition of choline incorporation, but that functional viral structural proteins were not required. The reduction in phospholipid synthesis was probably a secondary effect of infection resulting from viral inhibition of the cellular RNA and protein synthesis. All three inhibitory effects required about the same amount of viral RNA synthesis; the inhibition of host RNA and protein synthesis began sooner than the decline in phospholipid synthesis; and both actinomycin D and cycloheximide inhibited (14)C-choline incorporation in uninfected cells. In contrast, incorporation of (14)C-choline into BHK-21 cells was not decreased by 10 hr of exposure to actinomycin D and declined only slowly after cycloheximide treatment. Growth of Sindbis virus in BHK cells did not cause the marked stimulation of phospholipid synthesis seen in picornavirus infections of other mammalian cells; however, inhibition was seen only late in infection.     

Black beetle virus: messenger for protein B is a subgenomic viral RNA

Black beetle virus induces the synthesis of three new proteins, protein A (molecular weight, 104,000), protein α (molecular weight, 47,000), and protein B (molecular weight, 10,000), in infected Drosophila cells. Two of these proteins, A and α, are known to be encoded by black beetle virus RNAs 1 and 2, respectively, extracted from virions. We found that RNA extracted from infected cells directed the synthesis of all three proteins when it was added to a cell-free protein-synthesizing system. When polysomal RNA was fractionated on a sucrose density gradient, the messengers for proteins A and α cosedimented with viral RNAs 1 (22S) and 2 (15S), respectively. However, the messenger for protein B was a 9S RNA (RNA 3) not found in purified virions. Like the synthesis of viral RNAs 1 and 2, intracellular synthesis of RNA 3 was not affected by the drug actinomycin D at concentrations which blocked synthesis of host cell RNA. This indicated that RNA 3 is a virus-specific subgenomic RNA and, therefore, that protein B is a virus-encoded protein.     

Effect of Ultraviolet Irradiation and Actinomycin D on Polyoma Virus Replication in Mouse Embryo Cell Cultures

Ultraviolet irradiation and actinomycin D impair the capacity of mouse embryo (ME) cells to support the replication of polyoma virus, but not of encephalomyocarditis (EMC) virus. The loss in capacity for polyoma virus synthesis was an “all-or-none” effect and followed closely upon the loss in cellular capacity for clone formation. Cells treated with either agent produced polyoma “T” antigen, but did not synthesize polyoma structural protein. Infection of untreated ME cells with polyoma virus produced marked stimulation of both deoxyribonucleic acid (DNA) synthesis and ribonucleic acid (RNA) synthesis. ME cell cultures irradiated with ultraviolet for 30 sec at 60 μw/cm² or treated with actinomycin D at 0.1 μg/ml for 6 hr prior to infection were incapable of synthesizing DNA or RNA, even after infection with polyoma virus. Irradiation of cells during infection produced cessation of synthesis of both RNA and DNA. Addition of actinomycin D during infection did not inhibit DNA synthesis but abolished RNA synthesis and reduced the yield of polyoma virus to 10% of that in untreated infected cultures. Both agents lost the ability to prevent replication of a full yield of polyoma virus when administered 30 hr after infection or later. The period after which neither agent inhibited polyoma replication corresponded with the period at which maximal RNA synthesis in untreated infected cultures had subsided. It can be concluded on the basis of the data presented that the functional integrity of the mouse embryo cell genome is required for the replication of polyoma virus, but not for EMC virus. Whereas the requirement for cellular DNA-dependent RNA synthesis for polyoma virus replication has been demonstrated, the exact nature of the host-cell function remains to be elucidated.     

Host-dependent restriction of mengovirus replication. II. Effect of host restriction on late viral RNA synthesis and viral maturation.

Restricted mengovirus replication in Mandin-Darby bovine kidney (MDBK) cells is characterized by a 400-fold reduction in infectious virus yield and a 40-fold increase in the production of noninfectious virus. Using conditions which insure that all MDBK cells are infected, virus-specific RNA and protein synthesis were measured in the restrictive host and in a permissive host for mengovirus, HeLa cells. Labeling kinetics and sucrose gradient analysis of mengovirus-specific RNA from MDBK cells show a reduction of 10-fold in virion RNA, 5-fold in double-stranded RNA, and 12.5-fold in single-stranded RNA. The viral RNA biosynthetic processes which occur late in the replicative cycle and result in the production of 90% of the single-stranded viral RNA that is packaged into capsid proteins in the permissive host are absent in restrictive MDBK cells. Viral protein synthesis as measured by labeled viral-specific polysome is decreased, and there is an accumulation of 80S subviral particles in the restricted host. It is suggested that restriction may act at a number of stages of viral replication and maturation.