Irreversible effects of cycloheximide during the early period of vaccinia virus replicaon

Vaccinia virus subverts xenophagy through phosphorylation and nuclear targeting of p62

Autophagy is an essential degradation program required for cell homeostasis. Among its functions is the engulfment and destruction of cytosolic pathogens, termed xenophagy. Not surprisingly, many pathogens use various strategies to circumvent or co-opt autophagic degradation. For poxviruses, it is known that infection activates autophagy, which however is not required for successful replication. Even though these complex viruses replicate exclusively in the cytoplasm, autophagy-mediated control of poxvirus infection has not been extensively explored. Using the prototypic poxvirus, vaccinia virus (VACV), we show that overexpression of the xenophagy receptors p62, NDP52, and Tax1Bp1 restricts poxvirus infection. While NDP52 and Tax1Bp1 were degraded, p62 initially targeted cytoplasmic virions before being shunted to the nucleus. Nuclear translocation of p62 was dependent upon p62 NLS2 and correlated with VACV kinase mediated phosphorylation of p62 T269/S272. This suggests that VACV targets p62 during the early stages of infection to avoid destruction and further implies that poxviruses exhibit multi-layered control of autophagy to facilitate cytoplasmic replication.

Vaccinia virus: shedding and horizontal transmission in a murine model

Vaccinia virus (VACV) has been associated with several bovine vaccinia outbreaks in Brazil, affecting cattle and humans. There are no available data about VACV environmental circulation or the role of wildlife in the emergence of an outbreak. Since VACV was isolated from rodents in Brazil, we investigated shedding and transmission of VACV strains in mice. The VACV excretion profile was assessed by PCR and chicken chorioallantoic membrane infection, revealing viral DNA and infectious virus in the faeces and urine of intranasally infected mice. Horizontal transmission was assessed by exposure of sentinel mice to wood shavings contaminated with excrement, to mimic a natural infection. Sentinel mice showed orthopoxvirus antibodies, and VACV DNA and infectious virus were detected in their faeces and intestines, even after six rounds of natural transmission. Together, these data suggest that murine excrement could play a relevant role in VACV spread and transmission, perhaps helping to explain how these viruses circulate between their natural hosts.

Molecular mechanisms of virus-mediated cytopathology

Lytic virus infections of animal cells usually lead to a variety of morphological and biochemical lesions that include inhibition of cellular macromolecular syntheses. These cytopathic effects vary in intensity for different virus-cell combinations and probably involve several overlapping mechanisms. Inhibition may be mediated by components of parental virions or require viral gene expression. In many infected cell systems the initiation of host protein synthesis is selectively blocked. This shut-off phenomenon can result from changes in membrane permeability that alter the intracellular ionic environment in favour of viral expression, successful competition of viral mRNAs for limited translational components, or a decrease in the level of cell mRNAs by inhibition of synthesis or nucleocytoplasmic transport. However, the early onset and rapidity of virus-induced inhibition, sometimes under non-permissive conditions, implies more direct mechanisms of translational inactivation. These include enhanced degradation of cellular mRNAs or specific modification of the translation apparatus in infected cells. A dramatic example of the latter occurs in poliovirus-infected HeLa cells in which intact, functional cellular mRNA persists but host protein synthesis is almost completely inhibited. The virus-induced defect is apparently related to inactivation of a protein factor that binds to the 5' end of m7G-capped mRNAs and is required for translation of host (capped) mRNAs but not for the expression of poliovirus RNA, which is not capped. This process and other possible molecular mechanisms of virus-mediated cytopathology are discussed.

Genetic and biochemical characterization of vaccinia virus genes D2L and D3R which encode virion structural proteins

Polyclonal antisera raised against fusion proteins containing portions of the vaccinia virus D2L and D3R proteins were prepared. Immunoprecipitation of pulse-labeled infected cell extracts and Western blot analysis demonstrated that genes D2L and D3R encode 16.9- and 27-kDa proteins, respectively. Both are synthesized late during infection and there is no evidence for proteolytic processing of either protein. Western blots of purified virus and subvirion fractions showed that D2L and D3R are virion components, residing in a detergent-insoluble fraction, containing viral core structural proteins. Trypsin sensitivity experiments suggest that each is found in an equivalent position within the virus core. Pulse-chase analysis showed that both proteins exhibit biphasic stability in which an unstable nascent component is replaced by a stable form. This observation suggests that the stable component results from the insertion of D2L and D3R into an immature core structure. The DNA sequence of four ts mutants previously mapped to genes D2L and D3R is reported. Analysis of the ability of each mutant to synthesize and process viral proteins showed that protein synthetic patterns were indistinguishable from wild type, however, three of the four mutants were defective in the processing of the major virion structural precursor, p4a. Unlike the biphasic stability observed in wild-type infected cells, D2L and D3R were totally degraded in cells infected at 40 degrees with any of the four ts mutants. Stability of the D2L and D3R proteins, in cells treated with rifampicin, is unaffected which demonstrates that a block in morphogenesis is not directly responsible for the observed instability of the mutant proteins.

Poxvirus pathogenesis

Poxviruses are a highly successful family of pathogens, with variola virus, the causative agent of smallpox, being the most notable member. Poxviruses are unique among animal viruses in several respects. First, owing to the cytoplasmic site of virus replication, the virus encodes many enzymes required either for macromolecular precursor pool regulation or for biosynthetic processes. Second, these viruses have a very complex morphogenesis, which involves the de novo synthesis of virus-specific membranes and inclusion bodies. Third, and perhaps most surprising of all, the genomes of these viruses encode many proteins which interact with host processes at both the cellular and systemic levels. For example, a viral homolog of epidermal growth factor is active in vaccinia virus infections of cultured cells, rabbits, and mice. At least five virus proteins with homology to the serine protease inhibitor family have been identified and one, a 38-kDa protein encoded by cowpox virus, is thought to block a host pathway for generating a chemotactic substance. Finally, a protein which has homology with complement components interferes with the activation of the classical complement pathway. Poxviruses infect their hosts by all possible routes: through the skin by mechanical means (e.g., molluscum contagiosum infections of humans), via the respiratory tract (e.g., variola virus infections of humans), or by the oral route (e.g., ectromelia virus infection of the mouse). Poxvirus infections, in general, are acute, with no strong evidence for latent, persistent, or chronic infections. They can be localized or systemic. Ectromelia virus infection of the laboratory mouse can be systemic but inapparent with no mortality and little morbidity, or highly lethal with death in 10 days. On the other hand, molluscum contagiosum virus replicates only in the stratum spinosum of the human epidermis, with little or no involvement of the dermis, and does not spread systemically from the site of infection. The host response to infection is progressive and multifactorial. Early in the infection process, interferons, the alternative pathway of complement activation, inflammatory cells, and natural killer cells may contribute to slowing the spread of the infection. The cell-mediated response involving learned cytotoxic T lymphocytes and delayed-type hypersensitivity components appears to be the most important in recovery from infection. A significant role for specific antiviral antibody and antibody-dependent cell-mediated cytotoxicity has yet to be demonstrated in recovery from a primary infection, but these responses are thought to be important in preventing reinfection.

Poxvirus pathogenesis

Poxviruses are a highly successful family of pathogens, with variola virus, the causative agent of smallpox, being the most notable member. Poxviruses are unique among animal viruses in several respects. First, owing to the cytoplasmic site of virus replication, the virus encodes many enzymes required either for macromolecular precursor pool regulation or for biosynthetic processes. Second, these viruses have a very complex morphogenesis, which involves the de novo synthesis of virus-specific membranes and inclusion bodies. Third, and perhaps most surprising of all, the genomes of these viruses encode many proteins which interact with host processes at both the cellular and systemic levels. For example, a viral homolog of epidermal growth factor is active in vaccinia virus infections of cultured cells, rabbits, and mice. At least five virus proteins with homology to the serine protease inhibitor family have been identified and one, a 38-kDa protein encoded by cowpox virus, is thought to block a host pathway for generating a chemotactic substance. Finally, a protein which has homology with complement components interferes with the activation of the classical complement pathway. Poxviruses infect their hosts by all possible routes: through the skin by mechanical means (e.g., molluscum contagiosum infections of humans), via the respiratory tract (e.g., variola virus infections of humans), or by the oral route (e.g., ectromelia virus infection of the mouse). Poxvirus infections, in general, are acute, with no strong evidence for latent, persistent, or chronic infections. They can be localized or systemic. Ectromelia virus infection of the laboratory mouse can be systemic but inapparent with no mortality and little morbidity, or highly lethal with death in 10 days. On the other hand, molluscum contagiosum virus replicates only in the stratum spinosum of the human epidermis, with little or no involvement of the dermis, and does not spread systemically from the site of infection. The host response to infection is progressive and multifactorial. Early in the infection process, interferons, the alternative pathway of complement activation, inflammatory cells, and natural killer cells may contribute to slowing the spread of the infection. The cell-mediated response involving learned cytotoxic T lymphocytes and delayed-type hypersensitivity components appears to be the most important in recovery from infection. A significant role for specific antiviral antibody and antibody-dependent cell-mediated cytotoxicity has yet to be demonstrated in recovery from a primary infection, but these responses are thought to be important in preventing reinfection.

Ribosomal protein phosphorylation in vivo and in vitro by vaccinia virus

Ribosomal protein phosphorylation was investigated in Ehrlich ascites tumor cells infected with vaccinia virus (Copenhagen strain). After 90 min of simultaneous infection and 32P-labelling, ribosomal proteins Sa, S2 and S13 appear specifically phosphorylated as well as Sb/La, P1 and S6, which are also phosphorylated in control cells. Sa is an acidic protein, whose phosphorylation has not been observed previously. A kinetic study showed that S2 is phosphorylated very rapidly within 10 min after the beginning of infection and it is complete 1 h later. The phosphorylation of S13 begins after a lag time of about 1 h and is completed after about 2.5 h of infection. Moreover only one phosphate is incorporated into S13 on a serine residue while up to four phosphates are incorporated into S2, the first on a serine and the three following on threonine residues. In vivo experiments, carried out in the presence of cycloheximide and cordycepin, suggest a viral origin for the kinase involved in the phosphorylation of S2 and S13. Moreover, in vitro experiments demonstrated that the kinase associated with the viral cores is capable of phosphorylating S2 on a serine residue only. In our cell/virus system, no significant difference in S6 phosphorylation was detected, when compared to uninfected cells. It is concluded that the specific and efficient phosphorylation of three ribosomal proteins from the 40S ribosomal subunit correlate well with possible translational mechanisms ensuring the efficient expression of early and late genes of vaccinia virus. In the light of these and previous results [Person, A. and Beaud, G. (1986) J. Biol. Chem. 261, 8283-8289], a mechanism is proposed for the shut-off of host protein synthesis and the selective translation of mRNAs of viral origin.

Core transcription restores in vitro inhibition of protein synthesis induced by vaccinia virus

When Ehrlich acistes tumor cell lysate is incubated in the presence of vaccinia core, protein synthesis is impaired. However, when the same system is coupled with viral transcription, protein synthesis is restored. The reversal of endogenous protein synthesis is inhibited by actinomycin D, suggesting that de novo RNA synthesis is required for the reversal of total protein synthesis. When the in vitro products of synthesis are analysed by polyacrylamide gel electrophoresis, two newly synthesized peptides which are not present in the noncoupled transcription-translation system are observed. These two peptides have molecular weights of 31 000 and 25 000, similar to viral early proteins.

Vaccinia-mediated rescue of encephalomyocarditis virus from the inhibitory effects of interferon

Coinfection of mouse L cells with vaccinia virus rescues encephalomyocarditis virus (EMC) from the inhibitory effect of interferon (IFN). The vaccinia-mediated rescue of EMC growth increases the yield of EMC as much as 1000-fold and is optimum when vaccinia is used at a multiplicity of infection of 1. This rescue correlates with a vaccinia-dependent stimulation of EMC gene expression. Evidence is presented to indicate that the rescue by vaccinia does not involve a block of the 2'-5'A synthetase pathway. However, the vaccinia rescue function is correlated with a vaccinia-mediated inhibition of the IFN-induced protein kinase.

Regulation of protein synthesis in virus-infected animal cells

This chapter summarizes the structural features that govern the translation of viral mRNAs: where the synthesis of a protein starts and ends, how many proteins can be produced from one mRNA, and how efficiently. It focuses on the interplay between viral and cellular mRNAs and the translational machinery. That interplay, together with the intrinsic structure of viral mRNAs, determines the patterns of translation in infected cells. It also points out some possibilities for translational regulation that can only be glimpsed at present, but are likely to come into focus in the future. The mechanism of selecting the initiation site for protein synthesis appears to follow a single formula. The translational machinery displays a certain flexibility that is exploited more frequently by viral than by cellular mRNAs. Although some of the parameters that determine efficiency have been identified, how efficiently a given mRNA will be translated cannot be predicted by summing the known parameters.

Interferon-mediated, double-stranded RNA-dependent protein kinase is inhibited in extracts from vaccinia virus-infected cells

The interferon-inducible, double-stranded RNA (dsRNA)-dependent protein kinase which phosphorylates an endogenous HeLa 69 kilodalton polypeptide or exogenous initiation factor eIF2 was inhibited during vaccinia virus infection. High interferon doses (20,000 reference units per ml) did not prevent this inhibition. The inhibition required protein synthesis but not viral DNA synthesis during infection, suggesting that an early vaccinia virus gene function was responsible. An active dsRNA-dependent protein kinase could be recovered from an inactive extract by purification on polyinosinate X polycytidylate-cellulose. An inhibitor of the protein kinase, therefore, must be present in the inactive extract. Similar results have been obtained with mouse L929 cells. At early time points of infection, the protein kinase in cell extracts required exogenous dsRNA for activity. This argues against endogenous viral dsRNA and activation of the kinase in the intact cell. At late time points of infection (when vaccinia virus dsRNA was almost certainly formed), the inhibitor of the kinase is present. Accordingly, it seems unlikely that the kinase played any role in the interferon-mediated inhibition of virus growth observed in these cells under these particular conditions.

Vaccinia rescue of VSV from interferon-induced resistance: reversal of translation block and inhibition of protein kinase activity

Coinfection with vaccinia virus rescues vesicular stomatitis virus (VSV) from the inhibitory effects of interferon (IFN) in mouse L cells. While vaccinia infection does not significantly affect VSV RNA synthesis, coinfection with vaccinia dramatically increases VSV protein synthesis in IFN-treated cells. Evidence is provided that vaccinia inhibits the activity of the IFN-induced dsRNA-dependent protein kinase.

Isolation of early viral proteins from poxvirus-infected chick embryo fibroblasts by DNA-cellulose chromatography and inhibition of their synthesis by chicken interferon

Up to seven early poxvirus-specific proteins have been isolated from vaccinia-WR-infected and cowpox-virus-infected chick embryo fibroblasts by affinity chromatography on native DNA-cellulose columns. The proteins have been characterized by one-dimensional sodium dodecyl sulfate/polyacrylamide gel electrophoresis and by nonequilibrium pH-gradient electrophoresis. The molecular weights of the viral proteins were determined by comparison with proteins of known molecular weight and are comparable to several of the vaccinia-WR-specific DNA-binding proteins isolated previously from infected L-929 cells by Solosky J. M., Esteban M. and Holowczak J.A. [J. Virol. 25, 263-273 (1978)]. The viral proteins binding reversibly to native DNA have been classified as immediate early viral gene products. Synthesis of cowpox-virus-induced early DNA-binding proteins is inhibited in chick cells pretreated with homologous interferon at a concentration of 500--1000 units/ml.

The white pock mutants of rabbit poxvirus: V. In vitro translation of early host range mutant mRNA

The abortive infections of pig kidney (PK) cells by both RP mu hr23 and RP mu hr31, two early (DNA minus) white pock (mu) host range (hr) mutants of rabbit poxvirus (RPV), are characterized by the in vivo inhibition of both host and viral protein synthesis by 10 hr postinfection although viral RNA synthesis continues. Further analysis reveals that large quantities of functional viral mRNA can be isolated from PK cells abortively infected with RP mu hr23 and translated in vitro throughout the 10-hr period of infection, even though these mRNAs are almost totally inactive in vivo. The in vitro translation of accumulated mRNA isolated from PK cells abortively infected by RP mu hr31 shows a quite different pattern where the maximum amount of RNA translatable in vitro is found at 6 hr postinfection with lesser amounts at 10 hr postinfection. Although early or prereplicative viral proteins are detected with each mutant both in vivo and after in vitro translation of isolated RNA, few, if any, late proteins are observed under any conditions.

Solubilization of a protein synthesis inhibitor from vaccinia virions

The protein synthesis inhibitor previously demonstrated to be associated with vaccinia cores was quantitatively solubilized from vaccinia virions or cores after an endogenous protein kinase reaction at pH 10. The presence of the inhibitor in the soluble extract correlated with the presence of soluble virion proteins phosphorylated in vitro. Partially purified inhibitor blocked methionyl-tRNAfMet-40S initiation complex formation, as was the case in cell-free extracts derived from vaccinia virus-infected cells.

Reversible inhibition of poxvirus replication by cycloheximide during the early phase of infection

Infection of primary chick embryo fibroblasts with Vaccinia WR, IHD-W, and cowpox virus even at high m.o.i. does not cause drastic early inhibition of host cell protein synthesis. This contrasts with the infection by these viruses of many eucaryotic cells. Cellular protein synthesis of mouse L cells is also only partially inhibited after infection with cowpox virus up to a m.o.i. of 2500 e.b. As predicted by Moss and Filler (1970, J. Virol. 5, 99-108) no irreversible inhibition of poxvirus replication is observed in these cells following the addition of cycloheximide early after infection. The viral cores which accumulate in chick embryo fibroblasts in the presence of cycloheximide are further uncoated after removal of the protein synthesis inhibitor. These poxvirus host cell systems can be used to identify in vivo immediate and putative delayed early viral gene products. Formation of progeny virus, viral DNA synthesis, the sequential formation of viral proteins, and sensitivity to interferon has been demonstrated in chick embryo fibroblasts after reversal of the cycloheximide block. These studies indicate a synchronized replication cycle of poxvirus after reversal of the cycloheximide block.

Expression of vaccinia virus early mRNA in Ehrlich ascites tumor cells. 1. Translation of cellular and viral early mRNA in cell-free systems from uninfected and virus-infected cells at the early stage

Translation of cellular and early vaccinia RNA in nuclease-treated lysates, derived from uninfected and vaccinia-virus-infected cells at the early stage, has been investigated. When using limiting amounts of RNA no discrimination of translation was observed in the infected cells lysates; this conclusion was confirmed by sensitive RNA competition experiments for translation in vitro and also when using two different fractionated systems for protein synthesis in vitro. This absence of detectable discrimination in vitro was established both by comparing incorporation of [35S]methionine into proteins and by analysis of the products thus synthesized by sodium dodecylsulfate gel electrophoresis. However, a modification of the translational machinery from vaccinia-virus-infected cells did occur since the only the ribosomal salt wash derived from infected cells was able to reverse the inhibition of protein synthesis in vitro resulting from excess RNA (control or early). This property of vaccinia-virus-infected cell lysates may result from the synthesis l machinery from vaccinia-virus-infected cells did occur since the only the ribosomal salt wash derived from infected cells was able to reverse the inhibition of protein synthesis in vitro resulting from excess RNA (control or early). This property of vaccinia-virus-infected cell lysates may result from the synthesis l machinery from vaccinia-virus-infected cells did occur since the only the ribosomal salt wash derived from infected cells was able to reverse the inhibition of protein synthesis in vitro resulting from excess RNA (control or early). This property of vaccinia-virus-infected cell lysates may result from the synthesis of an early protein involved in translation or from a better recovery of translational factors from the infected cells, as suggested in the accompanying paper.

Inhibition of 40S--Met--tRNAfMet ribosomal initiation complex formation by vaccinia virus

Infection with vaccinia virus (a poxvirus) quickly and efficiently shuts off host protein synthesis in the presence of actinomycin D (refs 3--5) or cycloheximide. The cellular messenger RNA apparently remains stable in the infected cells exposed to inhibitors of viral gene transcription. In some cases vaccinia viral RNA or poly(A) synthesis have been implicated in the establishment of this effect. However, in the presence of cordycepin (3-deoxyadenosine) which blocks viral gene transcription and cytoplasmic poly(A) synthesis, cellular protein synthesis is still efficiently inhibited in vaccinia virus-infected cells. This shutoff is also observed in vitro, in the corresponding cell-free extracts, and in a reticulocyte lysate. Therefore the shutoff of host protein synthesis is probably mediated by a factor associated with vaccinia virions. We now report that the formation of the 40S--Met-tRNAfMet initiation complex is inhibited in cytoplasmic extracts derived from vaccinia virus-infected cells exposed to cordycepin to block viral gene expression. A similar inhibition is found in reticulocyte lysates incubated with purified vaccinia cores, confirming the hypothesis that the factor associated with the viral cores is responsible for the inhibition observed in vaccinia virus-infected cells exposed to inhibitors of transcription.

Phosphorylation in vivo of a vaccinia-virus structural protein found associated with the ribosomes from infected cells

When vaccinia-virus-infected cells were labeled with radioactive phosphate in the absence of viral gene expression an additional phosphoprotein, containing phosphoserine, was found specifically associated with the ribosomes. The phosphoprotein was removed from the ribosomes following a 0.5 M KCl washing or after EDTA treatment. This additional phosphoprotein was found in infected cells after either a long (3-4 h) or a short (30 min) labeling period; it was detected when the infected cells were incubated in the presence or absence of an inhibitor of RNA or protein synthesis. This phosphoprotein originated from the phosphorylation of vaccinia virion structural protein VP11b (Mr 11,000) at a specific site since only a single major phosphopeptide was obtained after trypsin digestion. This phosphoprotein was also present in purified vaccinia virions labeled with radioactive phosphate. VP11b protein was phosphorylated in vitro by the protein kinase associated with the cores. When the reaction was carried out at an alkaline pH the phosphorylation in vitro occurred at different sites in the protein; at neutral pH the phosphorylation of VP11b was more specific and, as judged by tryptic peptide analysis, occurred mainly at the same site as in the phosphorylation in vivo. A role for the involvement of phosphoprotein VP11b in the establishment of the shut off of host protein synthesis by vaccinia virus is suggested.

Host range restriction of vaccinia virus in Chinese hamster ovary cells: relationship to shutoff of protein synthesis

Chinese hamster ovary cells were found to be nonpermissive for vaccinia virus. Although early virus-induced events occurred in these cells (RNA and polypeptide synthesis), subsequent events appeared to be prevented by a very rapid and nonselective shutoff of protein synthesis. Within less than 2 h after infection, both host and viral protein syntheses were arrested. At low multiplicities of infection, inhibition of RNA synthesis with cordycepin resulted in failure of the virus to block protein synthesis. Moreover, infection of the cells in the presence of cycloheximide prevented the immediate onset of shutoff after reversal of cycloheximide. Inactivation of virus particles by UV irradiation also impaired the capacity of the virus to inhibit protein synthesis. These results suggested that an early vaccinia virus-coded product was implicated in the shutoff of protein synthesis. Either the nonpermissive Chinese hamster ovary cells were more sensitive to this inhibition than permissive cells, or a regulatory control of the vaccinia shutoff function was defective.

Characteristics of a coupled cell-free transcription and translation system directed by vaccinia cores

1. A coupled transcription and translation system is described in which protein synthesis is directed by mRNA synthesised in situ by vaccinia virus cores. The cell-free system is based on a micrococcal-nuclease-treated reticulocyte lysate. 2. The polypeptides made in vitro include many authentic early vaccinia proteins, but also other proteins which were not detected in infected cells. 3. Concentrations of cores which inhibit host cell protein synthesis in vivo caused a delayed inhibition of translation in vitro; this was partly, but not entirely, due to dsRNA associated with the cores. 4. The mRNA made was methylated by core enzymes. Inhibition of methylation reduced the rate of translation tenfold; unmethylated RNA bound ribosomes poorly, but was nevertheless translated faithfully.

Inhibition of host protein synthesis in vaccinia virus-infected cells in the presence of cordycepin (3'-deoxyadenosine)

Cordycepin inhibited efficiently viral mRNA and polyadenylic acid syntheses in vaccinia virus-infected cells, but allowed the shutoff of host protein synthesis to occur. Therefore, cordycepin was used to study this shutoff in the absence of gene expression. Ribosome transit time was increased in infected cells, revealing an inhibition at the level of elongation and/or release of polypeptide chains. However, the disappearance of heavy polysomes in vaccinia virus-infected cells showed that the inhibition of host protein synthesis resulted predominantly from a block at the stage of initiation. This conclusion was confirmed by the recovery of heavy polyribosomes when low levels of cycloheximide were added to slow down ribosome release from the mRNA. Similar amounts of cellular mRNA (present in the polyribosomes) were found in vaccinia virus-infected cells and in mock-infected cels (exposed to cordycepin), showing that the cellular mRNA was not inactivated in these conditions. It was concluded that a component of the vaccinia virion inhibits, in the absence of viral RNA and polyadenylic acid syntheses, host protein synthesis at the level of initiation and, to a lesser extent, at the level of elongation (and/or release) of polypeptide chains.

Messenger activity of RNA transcribed in vitro by DNA-RNA polymerase associated to vaccinia virus cores

The coding properties of RNA transcribed in vitro by purified vaccinia cores have been investigated using Krebs ascites tumor cells, L cells, and reticulocyte lysates. Six to 10 proteins synthesized in vitro are separated on polyacrylamide gels by electrophoresis in the presence of sodium dodecyl sulfate. Their molecular weights vary from 10,000 to 44,000. The electrophoretic behavior of these proteins is similar to that of early proteins isolated from infected L cells. The tryptic peptide analysis of one of these proteins indicates similarity in amino acid sequences. These results show fidelity of both in vitro transcription and molecular weight above 44,000 are synthesized in vitro does not seem due to a competition between 12S mRNA synthesized in excess and RNA of a higher sedimentation coefficient present in a lower amount.

Early events in cell-animal virus interactions

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Mechanism of antiviral action of acetone on rabbitpox virus replication

Acetone added to the maintenance medium in a 1% concentration reduces the yield of infectious rabbitpox virus in L-cell monolayer cultures by 90 to 97%. This concentration of the inhibitor is not toxic for cells. It was established that there is an inhibitor-sensitive stage late in the infectious cycle. Acetone exerted no significant influence on production of early viral messenger ribonucleic acid, formation of polyribosomes, deoxyribonucleic acid (DNA) replication, or protein synthesis. In the presence of acetone, the assembly of so-called "acetone particles" occurred. These particles are similar to normal virions by morphological and sedimentation properties but are slightly different from them in buoyant density. The amount of virus-specific DNA and the optical density of the "acetone particles" are the same as those of normal virions despite a 10- to 25-fold difference in the infectivity of the preparations.

Analysis of arbovirus ribonucleic acid forms by polyacrylamide gel electrophoresis

Viral ribonucleic acid (RNA) from Semliki Forest virus- and Sindbis virus-infected cells was analyzed by electrophoresis on polyacrylamide gels. In contrast to earlier results obtained by sucrose density gradient centrifugation, all of the known viral RNA forms (i.e., the 42S, 26S, replicative form, and replicative intermediate) were very clearly separated. The high resolution of the electrophoretic method permitted the identification of two new single-stranded RNA species. In addition, the replicative form was shown to be heterogeneous and to consist of at least two forms. The results suggested that the replicative forms occur in vivo although in relatively small amounts.

Basis for variable response of arboviruses to guanidine treatment

The effect of guanidine on the replication of the group A arboviruses, Sindbis virus, and Semliki Forest virus (SFV) was studied. Guanidine rapidly, but reversibly, inhibited SFV ribonucleic acid (RNA) synthesis. The synthesis of all species of viral RNA was inhibited, but that of ribonuclease-resistant forms was least affected. This inhibition occurred when the drug was added at any point during the log phase of virus growth. The growth of SFV was also markedly inhibited, but Sindbis virus growth was unimpaired. Infection of guanidine-treated cells with the viruses together resulted in a significant inhibition of the yields of both. It appears that, in the case of Sindbis virus, viral RNA is ordinarily produced in such excess that inhibition of its synthesis does not reduce virus yields. In the case of SFV, guanidine also markedly distorts the pattern of RNA synthesis by greatly decreasing the production of the 26S interjacent RNA form. This may account for the observed inhibition of SFV growth in the presence of guanidine.