Inhibition of arbovirus assembly by cycloheximide

Addition of cycloheximide (100 μg/ml) to cultures of chick cells infected with Semliki Forest virus (SFV) halted subsequent increase in virus titers. When added after 4 hr of infection, the drug had no effect on the rate of viral ribonucleic acid (RNA) synthesis, although marked inhibition of protein synthesis was seen. All of the previously identified forms of SFV RNA were seen in the drug-treated cells at higher concentrations than were present in untreated controls. The latter observation appeared to result from a failure to form viral “cores” or nucleocapsids in the cycloheximide-treated cells, resulting in sequestration of viral RNA intracellularly. The failure to form new virus cores was correlated with the failure of type II cytopathic vacuoles to appear in thin sections. Virus budding from the cell surface and the formation of type I cytopathic vacuoles persisted in cycloheximide-treated cells. The cellular pool of the major protein present in the virus core appeared to be small. None of this protein was found in a free pool in cytoplasm. The results indicated that, in the presence of cycloheximide, virus assembly was impaired because of the small size of the cellular pool of the major protein required for virus core formation.     

Control of thymidine kinase synthesis in IHD vaccinia virus-infected thymidine kinase-deficient LM cells.

The synthesis of vaccinia virus-induced thymidine kinase is normally arrested several hours after infection. In thymidine kinase-deficient LM cells infected with IHD strain of vaccinia virus, arrest occurs whether or not viral DNA synthesis is inhibited. With virus inactivated by UV irradiation, enzyme synthesis takes place, but arrest is abolished. It is suggested that an early viral genetic function is responsible for the cessation of thymidine kinase synthesis.     

Control of expression of the vaccinia virus thymidine kinase gene.

mRNA extracted from vaccinia virus-infected cells early after infection directs cell-free synthesis of enzymatically active viral thymidine kinase (Hruby and Ball, Virology, in press). We used this assay for a specific vaccinia virus mRNA to study the induction and repression of the viral thymidine kinase gene during infection of thymidine kinase-deficient L-cells. As observed previously by other workers, the synthesis of thymidine kinase occurred immediately after infection but was switched off after 4 h later. We observed similar kinetics of accumulation and shutoff under conditions where viral DNA synthesis and late gene expression were inhibited. Cell-free translation of mRNA from infected cells showed that the concentration of functional message for viral thymidine kinase reached a peak 3 to 4 h after infection and then decreased with a half-life of about 1 h. These kinetics indicated that significant levels of thymidine kinase mRNA persisted in cells which had stopped synthesizing the enzyme. Under conditions where late gene expression was inhibited, high concentrations of functional mRNA could be isolated from cells at late times after infection. On the basis of these results, we conclude that the repression of thymidine kinase expression is mediated at the translational level by one or more early or delayed early viral genes. Repression is accompanied by, but does not depend on, the inactivation or degradation of thymidine kinase mRNA, which is a late gene function.     

Fate of adenovirus type 12 genomes in nonpermissive cells

The fate of ³H-thymidine-labeled adenovirus type 12 deoxyribonucleic acid (DNA) was studied in Nil-2 cells of Syrian hamster origin. It was found that a substantial fraction of ³H-adenovirus type 12 DNA became degraded within 24 hr after infection and was released into the culture fluid. After infection of 5-bromodeoxyuridine (BUdR)-prelabeled cells with ³H-adenovirus type 12, viral DNA became readily separable from cellular DNA by equilibrium centrifugation in CsCl. Part of the viral radioactivity was found to shift gradually to the position of cellular DNA as time progressed after infection. When exponentially growing cells were exposed simultaneously to BUdR, 5-fluorodeoxyuridine, and ³H-adenovirus type 12, up to 50% of the viral radioactivity shifted within 24 hr from the density of viral DNA to that of cellular DNA after equilibrium centrifugation in CsCl. Upon denaturation of the cellular DNA, the isotope was preferentially found to be associated with the “heavy” strand which was synthesized after infection. Upon hybridization of the “heavy” and the “light” strands with sonically treated, denatured ³H-adenovirus type 12 DNA, small and nearly equal amounts of counts hybridized with both strands. The number of counts annealed was in a range similar to that of those annealed with the same amount of DNA derived from adenovirus type 12-transformed hamster cells. These results demonstrate that (i) a substantial proportion of the adsorbed virus becomes degraded within 24 hr; (ii) part of the degradation products is reutilized for cellular DNA synthesis; (iii) only a small fraction, mainly fragments, of viral DNA becomes integrated into both the newly synthesized and the parental strands of cellular DNA.     

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.     

Cytoplasmic viral DNA synthesis in exogenous infection of murine leukemia virus: effect of interferon and cycloheximide.

Cytoplasmic viral DNA synthesis can be followed efficiently by [3H]thymidine labeling of cells exogenously infected with Moloney murine leukemia virus. Both the negative and the positive strands of viral DNA reached their maximal level in the cytoplasm at 3.5 h postinfection. Interferon treatment before infection markedly reduced the amount of viral DNA formed during the first 3.5 h, but led to a second major wave of viral DNA synthesis, peaking at 7.5 h postinfection. No such late cytoplasmic DNA synthesis occurred in the untreated control. Inhibition of protein synthesis by cycloheximide, on the other hand, stimulated cytoplasmic viral DNA synthesis during the first 3.5 h.     

Sequential Formation of Vaccinia Virus Proteins and Viral Deoxyribonucleic Acid Replication

In vaccinia virus-infected cell cultures, cellular protein synthesis was inhibited 50% at 2 hr postinfection (PI) and 80 to 90% by 4 hr PI. Input virus was responsible for this inhibition. Five early proteins, coded for by the viral genome, could be detected at 2 to 3 hr PI. Normally, their synthesis did not continue beyond 6 hr PI, at which time synthesis of a different set of proteins began. When DNA replication was blocked, synthesis of these early proteins continued until 9 to 12 hr PI. The bulk of the proteins which were incorporated into mature virus were synthesized at 8 hr PI and thereafter. The time of their formation was close to the time at which virus maturation occurred. However, 15% of the protein found in mature virus was synthesized early in the infectious cycle. The quantity of “early viral protein” which was not incorporated into mature virus was almost as large as the quantity of viral protein which did appear in mature virus. The “early” and “late” proteins could be shown to have separate and distinct immunological properties. The role of this large quantity of “early” protein is discussed.     

Establishment of infection by spleen necrosis virus: inhibition in stationary cells and the role of secondary infection

The relationship of two early events in the establishment of infection by avian retroviruses, the inhibition of viral DNA synthesis in stationary avian cells and the secondary infection which occurs after infection of replicating cells, was investigated. When neutralizing antibody to spleen necrosis virus was used to prevent secondary infection, the amount of unintegrated linear spleen necrosis virus DNA detected was much lower in infected stationary cells than in infected replicating cells. The amount of unintegrated linear spleen necrosis virus DNA in stationary cells was less than one copy per cell even at high multiplicities of infection. Viral DNA synthesis resumed after stimulation of the cells to replicate. The time of this viral DNA synthesis was closely correlated with renewed cellular DNA synthesis. In addition, blocking secondary infection of replicating cells prevented the rate of virus production from reaching the high levels usually associated with a normal productive infection by SNV. Virus production increased if secondary infection was allowed. However, this rise in virus production was not proportional to the amounts of viral DNA integrated after secondary infection.     

Changes in DNA-polymerase and thymidine kinase activity during interferon treatment

Treatment of the human glioma cell line, U-251 MG, with human IFN-β resulted in a dose-dependent growth depression and a decreased activity of DNA-polymerase in exponentially growing cells, although paradoxally the number of cells in the S phase increased. In synchronized cells, a S block was confirmed. Both thymidine kinase and DNA-polymerase increased but with a lower rate during IFN treatment. No inhibitory effects on any of the enzymes could be seen when IFN-treated lysate was mixed with control lysate. The possible significance of depressed DNA synthesis during virus infection is discussed.     

Kinetics of Nucleic Acid Synthesis in Human Embryonic Kidney Cultures Infected with Adenovirus 2 or 12: Inhibition of Cellular Deoxyribonucleic Acid Synthesis

Infection of human embryonic kidney (HEK) cell cultures with adenovirus types 2 or 12 resulted in an initial drop in the rate of incorporation of (3)H-thymidine into deoxyribonucleic acid (DNA) during the early latent period of virus growth, followed by a marked rise in label uptake. It was shown by cesium chloride isopycnic centrifugation that, after adenovirus 2 infection, there was a decrease in the rate of incorporation of thymidine into cellular DNA. Moreover, DNA-DNA hybridization experiments revealed that, by 28 to 32 hr after infection with either adenovirus 2 or 12, the amount of isolated pulse-labeled DNA capable of hybridizing with HEK cell DNA was reduced by approximately 60 to 70%. Autoradiographic measurements showed that the inhibition of cellular DNA synthesis was due to a decrease in the ability of an infected cell to synthesize DNA. The adenovirus-induced inhibition of host cell DNA synthesis was not due to degradation of cellular DNA. (3)H-thymidine incorporated into cellular DNA at the time of infection remained acid-precipitable, and labeled material was not incorporated into viral DNA. Furthermore, when zone sedimentation through neutral or alkaline sucrose density gradients was employed, no detectable change was observed in the sedimentation rate of this cellular DNA at various times after infection with adenovirus 2 or 12. In addition, there was no increase in deoxyribonuclease activity in cells infected with either virus. Cultures infected for 38 hr with adenovirus 2 or 12 incorporated three to four times as much (3)H-uridine into ribonucleic acid (RNA) as did non-infected cultures. Furthermore, the net RNA synthesized by infected cultures substantially exceeded that of control cultures. The activity of thymidine kinase was induced, but there was no stimulation of uridine kinase.     

Deoxyribonucleic Acid Synthesis in FV-3-infected Mammalian Cells

Deoxyribonucleic acid (DNA) synthesis and virus growth in frog virus 3 (FV-3)-infected mammalian cells in suspension were examined. The kinetics of thymidine incorporation into DNA was followed by fractionating infected cells. The cell fractionation procedure separated replicating viral DNA from matured virus. Incorporation of isotope into the nuclear fraction was depressed 2 to 3 hr postinfection; this inhibition did not require protein synthesis. About 3 to 4 hr postinfection, there was an increase in thymidine incorporation into both nuclear and cytoplasmic fractions. The nuclear-associating DNA had a guanine plus cytosine (GC) content of 52%; unlike host DNA it was synthesized in the presence of mitomycin C, it could be removed from nuclei by centrifugation through sucrose, and it was susceptible to nuclease digestion. This nuclear-associating DNA appeared to be a precursor of cytoplasmic DNA of infected cells. The formation of the latter DNA class could be selectively inhibited by conditions (infection at 37 C or inhibition of protein synthesis) that permit continued incorporation of thymidine into nuclear-associating DNA. The cytoplasmic DNA class also had a GC content of 52%, was resistant to nuclease degradation, and its sedimentation profile in sucrose gradients corresponded to that of infective virus. Contrary to previous reports, we found that (i) viral DNA synthesis can continue in the absence of concomitant protein synthesis, and (ii) viral DNA synthesis is not abolished at 37 C. The temperature lesion in FV-3 replication appeared to be in the packaging of DNA into the form that appears in the cytoplasmic fraction of disrupted cells.     

Frog Virus 3 Replication: Analysis of Structural and Nonstructural Polypeptides in Infected BHK Cells by Acidic and Basic Two-Dimensional Gel Electrophoresis

Analysis of frog virus 3-infected BHK cells by two-dimensional, acidic and basic gel electrophoresis showed that at least 90 infected cell-specific polypeptides could be detected. These polypeptides represent between 70 and 85% of the coding capacity of the viral genome. The polypeptides were sequentially induced in at least three phases. The virus gradually suppressed host cell polypeptide synthesis during infection, although the synthesis of a few cell polypeptides may be “switched off” early in infection.     

Studies on Persistent Infections of Tissue Culture VI. Reversible Changes in Newcastle Disease Virus Populations as a Result of Passage in L Cells or Chick Embryos

Populations of the Victoria strain of Newcastle disease virus (NDV), reisolated from persistently infected L-cell cultures and passed twice in the embryonated hen's egg (NDV_L-E-2), were found to differ strikingly from the original, chick embryo-adapted virus (NDV_o). After exposure of L cells to NDV_o at high multiplicities of infection, all cells became abortively infected; they produced only small aggregates of viral antigen and few, if any, infectious virus particles, but they yielded large amounts of interferon. No cytopathic effects (CPE) were noted, and the cultures survived readily as viral carriers. In contrast, NDV_L-E-2 yielded under similar conditions large quantities of viral antigen and infectious virus particles, but no detectable interferon, and the cultures were rapidly destroyed. This change in “virulence” was at least partially reversible by further serial passages of NDV_L-E-2 in chick embryos, as was evident from a consecutive decrease in CPE with a concomitant increasingly rapid recovery of the L-cell cultures, gradually diminishing yields of infectious viral progeny, and the returning of a capacity to induce interferon synthesis. Thus, NDV_L-E-16 resembled NDV_o in many aspects, except for a less striking reduction in its ability to replicate in L cells. Although a selection of viral variants under the given sets of conditions has not been entirely excluded, the establishment of “avirulence” appears to be largely explained by a gradual accumulation of noninfectious, interferon-inducing components in the course of serial passages in the embryonated hen's egg, and the acquisition of “virulence” by a loss of these components. The evidence is as follows. (i) By a step-wise decrease in the dose of virus and restriction of the analyses to the first infectious cycle, a multiplicity of infection was ultimately reached for all “avirulent” populations at which infected cells produced normal yields of infectious viral progeny; i.e., the interferon-inducing components were diluted to noneffective levels. The lowest multiplicity which resulted in a measurable reduction in infectious virus replication was also the last one to induce detectable interferon synthesis. (ii) All viral clones derived from “avirulent” populations behaved like NDV_L-E-2 rather than like the parent viral suspensions, except that some of them elicited small amounts of interferon in L cells. The interferon-inducing components were reduced or lost in the cloning procedures. The nature of the interferon-inducing components has not been established. These components, which were neutralized by rabbit sera against “virulent” NDV_L-E-2 populations, may represent largely inactive or incomplete virus particles; however, the infectious virus-hemagglutinin ratios of “avirulent” populations were mostly of an order similar to those of “virulent” populations. The interferon-inducing components aborted the infectious process in cells simultaneously invaded by infectious virus particles. The implications of these findings are discussed.     

Autoradiographic study on sheeppox virus infection

Terrinha, António M. (National Laboratory for Veterinary Research, Lisbon, Portugal), José D. Vigário, José L. Nunes Petisca, J. Moura Nunes, and Armando L. Bastos. Autoradiographic study on sheeppox virus infection. J. Bacteriol. 90:1703-1709. 1965.-An autoradiographic study of sheep embryo cell cultures infected with sheeppox virus showed that viral deoxyribonucleic acid (DNA) synthesis starts at 10 to 11 hr after infection. The number of cells which supported viral DNA synthesis increased until 22 to 23 hr. The extent of cytoplasmic continuity between cells might permit the cell-to-cell transfer of mature virus or perhaps viral DNA. There is evidence of an inhibitory action on cellular DNA synthesis in cells which supported viral DNA synthesis, but, in all cellular populations infected, a small proportion of cells was encountered which supported viral DNA synthesis in compartment S. No evidence for cellular division of sheeppox virus-infected cells has been found. Enzymatic digestion by deoxyribonuclease combined with autoradiography provided an indirect demonstration of the time at which the first viral structural proteins were found to be synthesized, that is, 18 hr after infection. A progressive increase in synthesis of viral structural proteins was demonstrated. Virus maturation occurred within the cells in the cytoplasm, predominantly in the same sites as viral DNA synthesis.     

Deoxyribonucleotide metabolism in Herpes simplex virus infected HeLa cells.

The effect of Rolly No. 11 strain herpes simplex virus infection of HeLa cells in culture on deoxynucleotide metabolism and the level of various enzymes concerned with the biosynthesis of DNA has been investigated. Of 18 enzyme activities studied, thymidine kinase, DNA polymerase and deoxyribonuclease were markedly augmented, a finding in agreement with previous reports. Deoxycytidine kinase, ribonucleotide reductase, thymidylate kinase and deoxycytidylate deaminase activities, in contrast with previous reports, did not increase; the activities of the other enzymes studied, also did not increase. Whereas most of the radioactivity derived from [14-C] thymidine in the acid-soluble fraction of the uninfected cells was present as deoxythymidine triphosphate, that present in the infected cells was primarily in the form of deoxythymidine monophosphate. Thus, in the infected cell deoxythymidylate kinase is a rate-limiting enzyme in the biosynthesis of deoxythymidine triphosphate. A marked increase in the pools of the four naturally occurring deoxynucleoside triphosphates (dTTP, dCTP, dATP, dGTP) was found. The rate of formation of the virus-induced enzymes was determined, as were the various nucleoside triphosphate pools and the other phosphorylated derivatives of thymidine; a maximum was reached for all these csmponents between 6 to 8 h post infection. Although an apparent greater synthesis of DNA occurred in the uninefected cells, when the specific activity of the radioactive deoxythymidine triphosphate was taken into account, there was actually a greater rate of DNA synthesis in the infected cells, with the peak at 8 h post infection.     

Replication of Epstein–Barr Viral DNA

Epstein–Barr virus (EBV) is a paradigm for human tumor viruses: it is the first virus recognized to cause cancer in people; it causes both lymphomas and carcinomas; yet these tumors arise infrequently given that most people in the world are infected with the virus. EBV is maintained extrachromosomally in infected normal and tumor cells. Eighty-four percent of these viral plasmids replicate each S phase, are licensed, require a single viral protein for their synthesis, and can use two functionally distinct origins of DNA replication, oriP, and Raji ori. Eighty-eight percent of newly synthesized plasmids are segregated faithfully to the daughter cells. Infectious viral particles are not synthesized under these conditions of latent infection. This plasmid replication is consistent with survival of EBV’s host cells. Rare cells in an infected population either spontaneously or following exogenous induction support EBV’s lytic cycle, which is lethal for the cell. In this case, the viral DNA replicates 100-fold or more, uses a third kind of viral origin of DNA replication, oriLyt, and many viral proteins. Here we shall describe the three modes of EBV’s replication as a function of the viral origins used and the viral and cellular proteins that mediate the DNA synthesis from these origins focusing, where practical, on recent advances in our understanding.     

Low-multiplicity infection of Moloney murine leukemia virus in mouse cells: effect on number of viral DNA copies and virus production in producer cells.

Mouse cells infected with Moloney murine leukemia virus (M-MuLV) were prepared by two methods, and the number of M-MuLV-specific DNA copies in the infected cells was measured. The number of M-MuLV-specific DNA copies detected varied from one to eight per infected cell in different cell lines. Cells in which multiple rounds of viral infection occurred during establishment had on the average more viral DNA copies than cells in which infection at low multiplicity was performed, followed by cloning of the cells. However, even in cells derived by the low multiplicity of infection method, most cell lines carried more than one copy of M-MuLV-specific DNA. Virus production per cell was also measured, and no strict correlation was observed between the number of M-MuLV DNA copies present and the amount of virus produced.