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.     

Mapping and identification of the vaccinia virus thymidine kinase gene

The thymidine kinase gene of vaccinia virus (VV) was mapped on the viral genome by using cloned fragments of the viral DNA to hybridize to early viral mRNA. Individual DNA fragments that represented about half of the viral genome were assayed, both for their ability to arrest the cell-free synthesis of active VV thymidine kinase and for their ability to select functional mRNA for the viral enzyme. Both activities were located in HindIII fragment J, which maps near the middle of VV DNA and contains about 2.6% of the genome (4,800 base pairs). This DNA fragment encodes four known early polypeptides, and to determine which of these was thymidine kinase, early VV mRNA was fractionated by sucrose gradient centrifugation and used to direct cell-free synthesis of the active enzyme. The thymidine kinase mRNA cosedimented with several species that encoded polypeptides in the molecular weight range 15,000 to 25,000. Hybridization of these mRNAs to HindIII-J DNA selected a message that directed the synthesis of thymidine kinase and a single polypeptide with an apparent molecular weight of 19,000. The native molecular weight of VV thymidine kinase is about 80,000, so these data indicate that, unlike thymidine kinase from several other sources, the active VV enzyme is probably a tetramer of 19,000-molecular-weight subunits.     

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.     

Initiation of Vaccinia Virus Infection in Actinomycin D-pretreated Cells

The early steps in vaccinia virus infection were studied in HeLa cells which had been treated with actinomycin D (1 μg/ml) and then incubated for several hours in fresh medium prior to infection. Initiation of infection occurred in such cells even though the synthesis of cellular ribonucleic acid and deoxyribonucleic acid (DNA) was severely depressed. Thymidine kinase was synthesized in amounts that exceeded those found in untreated, infected cells. The breakdown of viral “cores” to liberate viral DNA and the synthesis of viral specific DNA-polymerase also occurred but were somewhat delayed. A deoxyribonuclease resembling an exonuclease was made by the infected, pretreated cells. The time course for these events suggested that the genetic code for synthesis of thymidine kinase can be expressed before “cores” are broken down, but the DNA-polymerase can be synthesized only after liberation of the viral DNA. The amount of viral specific DNA-polymerase which was made after infection was proportional to the total number of virus synthesizing sites even beyond the point where all the cells were infected with one infectious particle. A similar relationship was observed for the amount of thymidine kinase formed and for the rate of viral DNA synthesis from ³H-thymidine.     

Herpes simplex virus gene expression in transformed cells. I. Regulation of the viral thymidine kinase gene in transformed L cells by products of superinfecting virus.

In this paper we show that the expression of the herpes simplex virus type 1 (HSV-1) gene for thymidine kinase (tk) in HSV-transformed cells is subject to regulation by two viral products synthesized during productive infection of these cells with a tk- mutant of HSV-1. The cell line used in this study is a derivative of tk-deficient mouse L cells that, after exposure to UV-inactivated HSV-1, had acquired the HSV-1 gene for tk (which we term a resident viral gene) and consequently expressed the tk+ phenotype (LVtk+ cells). Productive infection of these cells with HSV-1(tk-) at appropriate multiplicities caused significant enhancement of the viral tk activity. The results of several experiments allow us to conclude that this enhancement was due to increased synthesis of tk specified by the HSV-1 gene resident in the LVtk+ cells and that a specific protein made early after infection with HSV-1(tk-) mediated the enhancement, probably by increasing the production of mRNA from the viral tk gene resident in the LVtk+ cells. Our data also indicate that another HSV-1(tk-) product acted to turn off tk synthesis. The finding that tk activity continued to increase for a longer time after infection of the LVtk+ cells at 2 PFU/cell than after infection at higher multiplicities suggested the synthesis of a product which inhibited tk synthesis and whose concentration reached critical levels earlier at higher multiplicities of infection. Inhibition of DNA synthesis after infection, a treatment that depresses the synthesis of late viral proteins, prolonged the synthesis of tk in LVtk+ cells infected at either 2 or 5 PFU/cell. Infection of the LVtk+ cells with HSV-2(tk-) resulted in only small increases in tk activity, indicating some type specificity in recognition of viral products that can modify the expression of the HSV-1 tk gene resident in these cells.     

Shope fibroma virus. II. Role of the virion-associated nucleases.

The effect of Shope fibroma virus (SFV) infection on host DNA synthesis was investigated. The cytocidal strain, SFV-I, inhibited the incorporation of [3H]thymidine into nuclear DNA very shortly (2 h) after infection, whereas the noncytocidal strain, SFV-W, did so later (10 h postinfection) and to a lesser extent. Furthermore, a two- to threefold stimulation of host DNA synthesis was recorded in SFV-W-infected cells 3 to 4 h after infection. Since virion-associated nucleases have been implicated in the shutoff of host synthesis, these and other enzymatic activities were measured in purified virion preparations. The SFV strains and vaccinia virus contained equivalent amounts of DNA-dependent RNA polymerase, ATPase, and protein kinase activities. However, in SFV-W the pH 4.5 exonuclease activity was lower than in SFV-I and vaccinia virus, and the level of pH 7.8 endonuclease was almost undetectable. To test whether the lack of endonucleolytic activity had some effect on the removal of the cross-links in the parental DNA that occurs after viral penetration, the fate of the virion SFV DNA was followed. The majority (80%) of the SFV-I and SFV-W DNA molecules extracted after viral adsorption sedimented in alkaline sucrose gradients as cross-linked. After 3 h of infection, 75% of the SFV-I DNA molecules lacked cross-links, whereas 78% of the SFV-W DNA still remained cross-linked. The same results were obtained when the presence of cross-links was tested in restriction fragments. Taken together, these results indicate that virion-associated nucleases are involved in the early shutoff of host DNA synthesis and in the elimination of cross-links from the parental viral DNA.     

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.     

Gene expression of herpes simplex virus. III. Effect of arabinosyladenine on viral polypeptide synthesis

Arabinosyladenine, an established antiherpetic drug, was used to block herpes simplex virus type 1 DNA synthesis quantitatively in infected xeroderma pigmentosum cells. Kinetic analyses of viral polypeptides synthesized in the presence and absence of this drug revealed that there were at least six distinct kinetic classes of polypeptides. These differed in time of appearance after infection, time of maximum rate of synthesis, kinetics of turnoff, and sensitivity to arabinosyladenine. This study showed that arabinosyladenine had the following three main effects on herpes simplex virus type 1 gene expression. (i) The turnon of immediate early and delayed early polypeptides (kinetic classes 1 and 2) was retarded. (ii) The turnoff of early (immediate early and delayed early) polypeptides (classes 1 through 3) was delayed. (iii) The synthesis of late polypeptides (class 4 through 6) was inhibited by arabinosyladenine, with class 6 severely (80 to 90%) inhibited. The kinetic data presented here, along with the findings of other workers on the effects of inhibition of viral DNA synthesis, suggest that viral DNA replication is required for optimum synthesis of late viral polypeptides.