Mengovirus Replication in Novikoff Rat Hepatoma and Mouse L Cells: Effects on Synthesis of Host-Cell Macromolecules and Virus-specific Synthesis of Ribonucleic Acid

Novikoff cells (strain N1S1-67) and L-67 cells, a nutritional mutant of the common strain of mouse L cells which grows in the same medium as N1S1-67 cells, were infected with mengovirus under identical experimental conditions. The synthesis of host-cell ribonucleic acid (RNA) by either type of cell was not affected quantitatively or qualitatively until about 2 hr after infection, when viral RNA synthesis rapidly displaced the synthesis of cellular RNA. The rate of synthesis of protein by both types of cells continued at the same rate as in uninfected cells until about 3 hr after infection, and a disintegration of polyribosomes occurred only towards the end of the replicative cycle, between 5 and 6 hr. The time courses and extent of synthesis of single-stranded and double-stranded viral RNA and of the production of virus were very similar in both types of cells, in spite of the fact that the normal rate of RNA synthesis and the growth rate of uninfected N1S1-67 cells are about three times greater than those of L-67 cells. In both cells, the commencement of viral RNA synthesis coincided with the induction of viral RNA polymerase, as measured in cell-free extracts. Viral RNA polymerase activity disappeared from infected L-67 cells during the period of production of mature virus, but there was a secondary increase in activity in both types of cells coincidental with virus-induced disintegration of the host cells. Infected L-67 cells, however, disintegrated and released progeny virus much more slowly than N1S1-67 cells. The two strains of cells also differed in that replication of the same strain of mengovirus was markedly inhibited by treating N1S1-67 cells with actinomycin D prior to infection; the same treatment did not affect replication in L-67 cells.     

Effect of Mengovirus Replication on Choline Metabolism and Membrane Formation in Novikoff Hepatoma Cells

Infection of Novikoff rat hepatoma cells (subline NlSL-67) with mengovirus resulted in a two- to threefold increase in the rate of choline incorporation into membrane phosphatidylcholine at about 3 hr after infection, without affecting the rate of transport of choline into the cell or its phosphorylation. The time course of virus-stimulated phosphatidylcholine synthesis was compared with the time courses of other virus-induced processes during a single cycle of replication. The formation of viral ribonucleic acid (RNA) polymerase and of viral RNA commenced about 1 hr earlier than the virus-stimulated choline incorporation. Further, isopycnic centrifugation of cytoplasmic extracts indicated that the excess of phosphatidylcholine synthesized by infected cells is not located in the membrane structures associated with the viral RNA replication complex, but with structures of a lower density (1.08 to 1.14 g/cc). These membrane structures probably represent the smooth vesicles which accumulate in the cytoplasm of infected cells during the period of increased phosphatidylcholine synthesis between 3 and 5 hr after infection. They are formed with both newly synthesized phosphatidylcholine and phosphatidylcholine present prior to infection. However, concomitant protein synthesis is not required for the stimulated synthesis of membranes; the effect was not inhibited by treating the cells with inhibitors of protein synthesis at 3 hr after infection, although virus production was inhibited about 90% and virus-induced cell degeneration was markedly reduced and delayed. Production of mature virus began normally at about the same time as the stimulation of phosphatidylcholine synthesis. Treatment of infected cells with puromycin at 2 hr, on the other hand, completely inhibited the stimulation of phosphatidylcholine synthesis.     

Effects of Elevated Temperatures on Mengovirus Ribonucleic Acid Synthesis and Virus Production in Novikoff Rat Hepatoma Cells

The production of mengovirus in Novikoff rat hepatoma cells is progressively reduced with an increase in incubation temperature of the cells from 34 to 40 C, in spite of the fact that about the same amounts of single-stranded and double-stranded viral ribonucleic acid (RNA) are synthesized at 34, 37, and 40 C; the rate of overall protein synthesis is as high at 40 C as at 37 C. At 40 C, progeny viral RNA accumulates in an undegraded form without being incorporated into virus particles. The results suggest that virus maturation is preferentially inhibited at supraoptimal temperatures. At 42 C, on the other hand, no viral RNA is produced and no viral RNA polymerase activity is detectable in cell lysates. Failure of infected cells to form viral RNA polymerase at 42 C is probably due to an impairment of protein synthesis since most of the polyribosomes are rapidly lost during incubation at 42 C and the rate of amino acid incorporation into protein is 70% lower at 42 C than at 37 C. When infected cells are shifted from 37 to 42 C during the period of active viral RNA synthesis, viral RNA polymerase activity is rapidly lost from the cells, and viral RNA synthesis ceases within 45 min. In contrast, the RNA polymerase is as active in vitro at 42 C as at 37 C, and the activity is relatively stable at 42 C.     

Alterations of protein synthesis in arbovirus-infected L cells

Lust, George (Fort Detrick, Frederick, Md.). Alterations of protein synthesis in arbovirus-infected L cells. J. Bacteriol. 91:1612-1617. 1966.-Cellular protein synthesis and ribonucleic acid (RNA) synthesis in mouse L cells were markedly depressed 1 hr after infection with Venezuelan equine encephalomyelitis virus. Host RNA and protein synthesis were inhibited more rapidly by the virus infection than by actinomycin D. In cells infected 4 hr, a cytoplasmic RNA polymerase was demonstrated which was absent in uninfected cells. At this time, deoxyribonucleic acid-directed RNA synthesis catalyzed by the nuclear RNA polymerase was inhibited in vitro in enzyme preparations from nuclei of virus-infected cells. For optimal activity, the cytoplasmic RNA polymerase required the four nucleoside triphosphates, Mg(++), and RNA. The enzyme was insensitive to actinomycin D and deoxyribonuclease, indicating that it catalyzed RNA-directed RNA synthesis. Attempts to purify the induced polymerase further were unsuccessful. Fresh preparations had to be used because the enzymatic activity was unstable.     

Physiological characterization of temperature-sensitive mutants of mengovirus.

Twenty-four temperature-sensitive mutants of mengovirus were characterized physiologically with respect to phenotype. The mutants were separated into four classes on the basis of viral RNA synthesis. L-67-S cells infected with five of the mutants synthesized little viral RNA at 39.5 C. These mutants are designated RNA-. One mutant is designated RNA* since its RNA synthesis is altered at both 39.5 and 31.5 C. The other mutants were divided into two groups, RNA plus or minus (25 TO 49% of wild-type RNA synthesis) and RNA plus (50 to 100% of wild-type RNA synthesis). The time of expression of the mutation in the RNA- mutants was estimated from the results of reciprocal temperature-shift experiments. The mutatation in ts12 appears to be expressed at the time RNA synthesis normally begins. The defect in three of the mutants was expressed 1 to 2 h before RNA synthesis is normally detectable. Protein synthesis is required before RNA synthesis begins when the cells are shifted from 39.5 to 31.5 C. The RNA polymerase synthesized by cells infected with these RNA- mutants at 31.5 C was stable and fully active when assayed at 39.5 C in vitro. The sedimentation profiles of the viral RNA synthesized by cells infected with RNA plus and RNA plus or minus mutants are similar to wild-type profiles with the exception of ts148. Cells infected with this RNA plus or minus mutant synthesize RNA that sediments in a sucrose gradient like replicative-intermediate RNA, but little mature viral RNA is evident. The results of step-up experiments indicate that the temperature-sensitive period for the majority of the RNA plus and RNA plus and minus mutants extends through most of the replicative cycle. The temperature-sensitive defect of four of the mutants, however, was expressed in the first hour, suggesting that some undefined early function is required for the eventual maturation of mengovirus. The virions of three of the RNA- mutants were more thermolabile than wild-type virions. Five of the RNA plus and RNA plus or minus mutants were also thermolabile. Genetic complementation at a significant level was not detectable in mixed infections of the mutants described.     

Replication of Mengovirus in HeLa Cells Preinfected with Nonreplicating Poliovirus

The replication of mengovirus in HeLa cells preinfected with poliovirus in the presence of 10(-3) M guanidine was investigated. Although host cell protein synthesis is inhibited by the presence of nonreplicating poliovirus, it is found that mengovirus ribonucleic acid (RNA) and protein synthesis proceed normally under the same conditions. Furthermore, no effects on mengovirus growth by poliovirus can be detected either when Mengo protein synthesis is interrupted by Acti-Dione or when its RNA synthesis is reduced by incubation at 28 C. It is suggested that the poliovirus inhibitory factor may be able to distinguish between an RNA element required in the protein-synthesizing apparatus of the host cell and a comparable element in that of the heterologous virus.     

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.     

Restricted viral RNA synthesis in establishment of persistent infection in Vero cells with a Sendai virus mutant

It was previously shown that a temperature-sensitive mutant of Sendai virus, ts-23, readily establishes persistent infection in Vero cells at 37 C, a permissive temperature for growth of the mutant. In the present study, it was demonstrated that the virus yield from ts-23-infected Vero cells at 37 C began to decrease 48 to 72 hr postinfection, after an initial phase of high virus production. Before the decrease in virus production, the formation of viral nucleoprotein declined, although synthesis of all species of viral protein continued. It was suggested that the limited formation of viral nucleoprotein and the decrease in virus production were due to the restriction of viral RNA synthesis which began to occur early after infection in ts-23-infected cells at 37 C. The mutant has a temperature-sensitive defect in RNA polymerase activity and the temperature 37 C, used for establishment of persistent infection, would be a semi-permissive temperature for the RNA polymerase activity of the mutant. The ts-23 mutant interfered with the replication of the parental wild virus in Vero cells at 37 C.     

Selective Irreversible Inactivation of Replicating Mengovirus by Nucleoside Analogues: a New Form of Viral Interference

We describe the selective irreversible inhibition of mengovirus growth in cultured cells by a combination of two pyrrolopyrimidine nucleoside analogues, 5-bromotubercidin (BrTu) and tubercidin (Tu). At a concentration of 5 microgram/ml, BrTu reversibly blocked the synthesis of cellular mRNA and rRNA but did not inhibit either mengovirus RNA synthesis or multiplication. BrTu is a potent inhibitor of adenosine kinase, and low concentrations of BrTu (e.g., 0.5 microgram/ml), which did not by themselves inhibit cell growth, blocked phosphorylation of Tu and thus protected uninfected cells against irreversible cytotoxicity resulting from Tu incorporation into nucleic acids. In contrast, in mengovirus-infected cells, BrTu did not completely inhibit Tu incorporation into mengovirus RNA, allowing the formation of Tu-containing functionally defective polynucleotides that aborted the virus development cycle. This increased incorporation of Tu coupled to mengovirus infection could be attributed either to a reduction in the inhibitory action of BrTu and/or its nucleotide derivatives at the level of nucleoside and nucleotide kinases and/or, perhaps, to an effect upon the nucleoside transport system. The virus life cycle in nucleoside-treated cells progressed to the point of synthesis of negative strands and probably to the production of a few defective new positive strands. Irreversible virus growth arrest was achieved if the nucleoside mixture of BrTu (0.5 to 10 microgram/ml) and Tu (1 to 20 microgram/ml) was added no later than 30 min after virus infection and maintained for periods of 2 to 8 h. The cultures thus "cured" of mengovirus infection could be maintained and transferred for several weeks, during which they neither produced detectable virus nor showed a visible cytopathic effect; however, the infected and cured cells themselves, while metabolically viable, were permanently impaired in RNA synthesis and unable to divide. Although completely resistant to superinfecting picornaviruses, they retained the ability to support the growth of several other viruses (vaccinia virus, reovirus, and vesicular stomatitis virus), showing that cured cells had, in general, retained the metabolic and structural machinery needed for virus production. The resistance of cured cells to superinfection with picornaviruses seemed attributable neither to interferon action nor to destruction or blockade of virus receptors but more likely to the consumption of some host factor(s) involved in the expression of early viral functions during the original infection.     

Host-Dependent Restriction of Mengovirus Replication

Mengovirus infection of a restrictive cell line, Maden's bovine kidney (MDBK), results in a virus yield 1,000-fold less than that obtained from productively infected cell lines such as L cells or Ehrlich ascites tumor cells (EAT). Cells of both types of host systems are infected with comparable efficiencies and are completely killed as a consequence of infection. Infective center assays, coupled with the observation of total cell killing, suggest that comparable numbers of cells synthesize viral antigen and release virus in both types of host system. Viral-specific ribonucleic acid (RNA) synthesis is initiated and proceeds in an identical fashion for approximately 4 hr after the infection of MDBK, EAT, or L-cells. At this time, viral RNA synthesis in MDBK ceases, whereas viral RNA synthesis in EAT and L-cells continues at a linear rate. These results indicate that none of the early viral events leading to the initiation of viral-specific RNA synthesis constitutes the primary site of mengovirus restriction in MDBK. Rather it appears that the cessation of viral RNA synthesis in restrictive cells constitutes the primary limiting event. Based on its delayed interaction with mengovirus RNA synthesis, it appears that the host-related restrictive agent is initially compartmentalized and then released as a consequence of infection subsequent to those early events in mengovirus infection leading to the initiation and continued synthesis of viral RNA.     

Synthesis of Saint Louis Encephalitis Virus Ribonucleic Acid in BHK-21/13 Cells

Infection of baby hamster kidney cells (BHK-21/13) with Saint Louis encephalitis (SLE) virus depressed the rate of protein and ribonucleic acid (RNA) synthesis until viral RNA synthesis began 6 hr postinfection (PI). Virus-directed RNA synthesis was subsequently inhibited until 12 hr PI when virion maturation began. The rate of protein synthesis reached a peak 6 hr PI and was subsequently depressed until just before the onset of virion maturation. Density gradient analysis of phenol-extracted RNA from actinomycin-treated infected cells indicated that, at 6 to 8 hr and again at 12 to 20 hr PI, three species of viral-specific RNA were synthesized. The most rapid sedimenting form (43S) was ribonuclease-sensitive and had a base composition similar to the RNA isolated from mature virions. The 20S RNA species was ribonuclease-resistant and had a sedimentation coefficient and base composition similar to the replicative form associated with other arbovirus infections. The 26S RNA was ribonuclease-resistant (0.2 mug/ml, 0.1 m NaCl, 25 C, 30 min) and had a nucleotide base composition closer to the 20S form than to the values for 43S RNA. Five-minute pulse labeling of infected cultures during the period viral RNA synthesis was maximal resulted in labeling of only the 20S to 22S RNA fractions. With pulse-labeling periods of 10 min, both the 20S and 26S RNA species were radioactive. Periods of radioactive labeling of as long as 15 min were required before the 43S form was radioactively labeled. These results suggest that the 20S and 26S RNA may be intermediate forms in the synthesis of 43S viral RNA.     

Selective activation of RNA polymerase I in fat body nuclei of Sarcophaga peregrina larvae by beta-ecdysone.

RNA synthesis in fat body nuclei of Sarcophaga peregrina larvae was temporarily activated after injection of β-ecdysone: increased synthesis was detectable 2 hr after injecting the hormone and lasted for at least 2 hr. This increased RNA synthesis was insensitive to α-amanitin and was observed in KCl-free reaction mixture, indicating that β-ecdysone activated RNA polymerase I but not RNA polymerase II. No activation was observed when protein synthesis was inhibited by cycloheximide, suggesting that protein synthesis was essential for the activation of the nuclei.     

Ribonucleic Acid and protein synthesis in chick embryo cells infected with fowl plague virus

Fowl plague virus comprised four major protein components and several minor ones, two strains of the virus giving similar results. One of the components was identified as the nucleocapsid protein. Synthesis of the virion proteins could readily be detected in infected cells 3 hr after infection. The two subcellular fractions associated with viral ribonucleic acid (RNA) polymerase activity (nuclei and ribosomal pellet) were associated with the protein of the nucleocapsid and a second virion protein of unidentified function. Measurement of viral RNA and protein synthesis in cells infected with preparations of ultraviolet irradiated virus showed that the capacity to synthesise the RNA and protein species of highest molecular weight was lost most quickly, suggesting that the pieces of viral RNA function independently.     

Respiration of mengovirus-infected L-929 cells

Iglewski, W. J. (The Pennsylvania State University, University Park), and E. H. Ludwig. Respiration of mengovirus-infected L-929 cells. J. Bacteriol. 92:733-738. 1966.-Polarographic techniques were employed to study the oxidative metabolism of L-929 cells during a one-step mengovirus growth cycle. Virus maturation began 3.5 hr after infection and was complete with 7 hr. Virus maturation was accompanied by a decreased rate of endogenous respiration and an increased rate of oxidation of succinate and alpha-glycerophosphate by L-929 cells. The rate of glucose uptake was the same for mengovirus-infected and control L-929 cells. However, there was a decreased oxidation of glucose to carbon dioxide and a decreased production of lactic acid by L cells infected with mengovirus under aerobic conditions. Mengovirus was produced equally well under aerobic and anaerobic conditions. The implications of the alterations in metabolism with respect to virus synthesis are discussed.     

Inhibition of Synchronized Cellular Deoxyribonucleic Acid Synthesis During Newcastle Disease Virus, Mengovirus, or Reovirus Infection

Cultures of L cells were synchronized with respect to deoxyribonucleic acid (DNA) synthesis with thymidine and 5-fluoro-2'-deoxyuridine (FUdR) and infected with Newcastle disease virus (NDV), mengovirus, or reovirus 3. Inhibition of incorporation of (3)H-cytidine into the DNA of synchronized cells is partially inhibited 2 hr after infection with NDV or mengovirus and nearly completely suppressed 4 hr after infection. With NDV and mengovirus, no evidence was obtained of differences in sensitivity of cells during early S phase as compared to later stages in DNA synthesis. When cells were infected with reovirus at the time of release from FUdR block, inhibition of cellular DNA synthesis was evident at 2 to 3 hr, and it was complete at 4 to 5 hr after infection. However, when cells were infected several hours prerelease, synthesis of DNA occurred in early S phase in spite of the fact that the cells had been infected for up to 6 hr. The results indicate that DNA synthesis in early S phase is relatively insensitive to the inhibitory function of reovirus. Colorimetric determinations (diphenylamine reaction) of the amounts of DNA produced in synchronized cells have substantiated the inhibition of DNA synthesis observed by isotope incorporation techniques.     

An investigation of the stability of messenger RNAs in cell-free,translational systems from uninfected and mengovirus-infected Ehrlich ascites tumor cells

The stabilities and translation of Ehrlich ascites tumor cell poly(A)-containing mRNA and mengovirus RNA in fractionated cell-free protein synthesizing systems from uninfected and mengovirus-infected Ehrlich ascites tumor cells were studied. During incubation of the systems about 20% of the input RNA is reduced in size and associated with ribosomes engaged in polypeptide synthesis; the remainder is rapidly degraded by RNases. At the end of active translation, both mRNA and nascent proteins are bound to polysomes which are of the same size as those formed during active protein synthesis. The kinetics of protein synthesis closely follow those of RNA hydrolysis. The stabilities of mengovirus RNA and poly(A)-containing mRNA from Ehrlich ascites tumor cells are the same in both systems.     

Propagation of MM Virus in L Cells

MM virus (mouse-brain stock) replicated to a limited extent in L cells without cytopathic effects; the average yield was less than 1 plaque-forming unit/cell. Passage in BHK-21 cells resulted in MM virus [MM(BHK)] which replicated to high titers (200 to 300 plaque-forming units/cell) in L cells with complete cytopathic effects. Appearance of mature MM(BHK) virus in L-cell cultures begins 4 hr after infection and is completed by 8 hr. Release of mature virus was slow (less than 1% at 8 hr) but was completed by 24 hr.     

Selective activation of RNA polymerase I in fat body nuclei of Sarcophaga peregrina larvae by β-ecdysone

RNA synthesis in fat body nuclei of Sarcophaga peregrina larvae was temporarily activated after injection of β-ecdysone: increased synthesis was detectable 2 hr after injecting the hormone and lasted for at least 2 hr. This increased RNA synthesis was insensitive to α-amanitin and was observed in KCl-free reaction mixture, indicating that β-ecdysone activated RNA polymerase I but not RNA polymerase II. No activation was observed when protein synthesis was inhibited by cycloheximide, suggesting that protein synthesis was essential for the activation of the nuclei.     

Ribonucleic Acid Polymerase Induced in Cells Infected with Sendai Virus

A ribonucleic acid (RNA)-dependent RNA polymerase was induced in chick embryo fibroblast cells after infection with Sendai virus (parainfluenza 1 virus). The enzyme was associated with the microsomal fraction of infected cells and reached maximum detectable activity at 18 hr after virus infection. The activity of the enzyme in vitro was dependent on the presence of added magnesium ions and all four nucleoside triphosphates and was not inhibited by actinomycin D. The RNA synthesized by the enzyme in vitro was sensitive to ribonuclease and consisted of a complex mixture of RNA species including 34S, 24S, and 18S components. Similar RNA components were detected in the microsomal fraction of Sendai virus-infected cells by labeling with (3)H-uridine from 17 to 18 hr postinfection in the presence of actinomycin D. Of the RNA synthesized by Sendai virus-induced RNA polymerase in vitro, 98% became insensitive to ribonuclease after annealing with RNA extracted from purified Sendai virus particles.