Fluorosugars inhibit biological properties of different enveloped viruses.

Both 2-deoxy-2-fluoro-D-glucose and 2-deoxy-2-fluoro-D-mannose were found to be potent inhibitors of the synthesis of infectious Semliki forest and fowl plague virus in chicken embryo cells and also of pseudorabies virus grown in rabbit kidney cells. It was found that the pseudorabies virus-mediated cell fusion and the synthesis of functional hemagglutinin of fowl plague virus were blocked. In all cases the 2-deoxy-2-fluoro-D-mannose-caused inhibition was stronger than the 2-deoxy-2-fluoro-D-glucose- or 2-deoxy-D-glucose-mediated blocks. Studies on the virus-specified proteins from Semiliki forest virus-infected cells grown in the presence of the inhibitors show that the target of the fluorosugar action, parallel to the well-studied effects of 2-deoxy-D-glucose, is the glycoprotein biosynthesis.     

Interference of nucleoside diphosphate derivatives of 2-deoxy-D-glucose with the glycosylation of virus-specific glycoproteins in vivo.

The predominant effect of 2-deoxy-D-glucose on chick embryo cells infected with Semliki Forest virus is an interference with glycosylation of virus-specific glycoproteins; this results in a block of synthesis of infectious virus. Incorporation of radioactive mannose is blocked severely in the presence of 2-deoxyglucose in the cultural medium although it is readily phosphorylated and subsequently activated by GTP to yield GDP-mannose, which accumulates under these conditions. The intracellular concentrations of GDP-mannose and UDP-N-acetyl-D-hexosamine are not reduced in the presence of the inhibitor. An equimolar concentration of mannose in the cultural medium competes with the inhibitory effect of the deoxysugar and drops the cellular pool of GDP-2-deoxy-D-glucose below the level of detection, at the same time restoring the synthesis of infectious virus. When the intracellular concentration of UDP-2-deoxyglucose is reduced by addition of glucose into the cultural medium the inhibition of virus synthesis by the deoxysugar and the concentration of GDP-2-deoxyglucose within the cells remain near to the values when the inhibitor is present alone. It is concluded that among the metabolites of 2-deoxyglucose which occur in vivo after addition of 2-deoxyglucose to the culture medium, GDP-2-deoxyglucose is the agent responsible for inhibition of glycosylation of viral glycoproteins.     

Synthesis of beta-glucanase and other extracellular proteins by cells and protoplasts of the yeast Pichia polymorpha: effect of 2-deoxy-D-glucose.

The synthesis of beta-glucanase either by cells or by protoplasts of the yeast Pichia polymorpha has been found to occur in the presence of 2-deoxy-D-glucose in the growth medium. On the other hand, the synthesis of typical extracellular proteins such as invertase and acid phosphatase is strongly affected by the presence of the drug. The degree of inhibition is, however, directly related to the 2-deoxy-D-glucose concentration.     

Influence of 2-deoxy-D-glucose on galactofuranosidase and peptidophosphogalactomannan synthesis in Penicillium charlesii

2-deoxy-D-glucose inhibits synthesis of the glyco-enzyme $\text{exo}$-β-D-galactofuranosidase and its secretion into the growth medium of $\text{Penicillium charlesii}$ cultures. In contrast, the synthesis of peptidophosphogalactomannan, an extracellular glycopeptide (peptido-polysaccharide) occurs in nearly normal quantities in the presence of 2-deoxy-D-glucose. The peptidophosphogalactomannan's composition in cultures containing 2-deoxy-D-glucose was comparable to that obtained from cultures containing no added 2-deoxy-D-glucose. We conclude peptidophosphogalactomannan is not derived from mural or extracellular glycoprotein(s) whose synthesis is inhibited by 2-deoxy-D-glucose.     

Reversible alterations in the mitotic cycle of chick embryo cells in various states of growth regulation

Chick embryo cells which have been kept overnight at pH 6.8 in the absence of serum multiply very slowly. Only a small fraction of cells is in the S period at any given time, and the rate of uptake of 2-deoxy-D-glucose is very low. Upon raising the pH to 7.4 and adding serum (“turn-on”) the uptake of 2-deoxy-D-glucose increases immediately; the rate of DNA synthesis increases after a lag of about 4 hours, and represents an increase in the fraction of cells synthesizing DNA. The uptake of 2-deoxy-D-glucose is rapidly returned to its original low rate at any time by again lowering the pH and removing serum (“turn-off”). The synthesis of DNA in the culture remains constant or continues to rise at a markedly reduced rate following the same treatment. Lowering pH or removing serum independently of each other is less efficient at inhibiting the increase in DNA synthesis than the combined treatment but each accomplishes a similar result. Cultures which have been “turnedoff” during the early stages of the rapid increase in DNA synthesis, resume their prior rate of increase immediately if “turned-on” again within 2.5 hours. If the cultures have been “turned-off” for 5.5 hours before restoring the “turn-on,” there is a 2 hour delay before they resume an increased rate of DNA synthesis. The results indicate that chick embryo cells do not become committed to the initiation of DNA synthesis until shortly before, or at the time of the onset of the S period. Up to 96% of the cells in post-confluent cultures growing in conventional medium become labeled upon continuous, prolonged exposure to ³H-thymidine. Seventy-eight percent of the cells in serum-deprived cultures growing at a very low rate become labeled. These and other considerations suggest that the inhibition of cell multiplication by high population density or serum deprivation is caused by a lengthening of the time cells remain in the prereplicative G₁ period rather than by shifting cells into a qualitatively distinct G₀ period. There may, however, be a period common to all cells regardless of growth rate, in which cells are not progressing toward the S period. The length of this variable period would then determine the growth rate of a population of cells.     

Effect of certain inhibitors of glycoprotein synthesis on cell fusion induced by vesicular stomatitis virus.

The effect of certain metabolic inhibitors on the fusion of BHK-21 cells induced by vesicular stomatitis virus (VSV) was studied. The polykaryocyte formation in infected cells and virus growth were inhibited by 2-deoxy-D-glucose and D-glucosamine. Host-cell proteins synthesis was suppressed profoundly in both BHK-21-KB and B cells infected with VSV. On the other hand, glycoprotein synthesis was significantly enhanced during the polykaryocyte formation in BHK-21-KB cells, while it was suppressed in BHK-21-B cells which were not sensitive to cell fusion by VSV.     

Inhibition of unscheduled DNA synthesis and repair of potentially lethal X-ray damage by 2-deoxy-D-glucose in yeast.

The effects of the glucose antimetabolite, 2-deoxy-D-glucose (2-DG), on DNA repair (assayed by unscheduled DNA synthesis) and on the repair of potentially-lethal damage (assayed by cell viability after irradiation) have been studied in X-irradiated respiratory-deficient yeast cells (auxotroph for 5'-thymidine-monophosphate). Experimental results show that: (a) both these phenomena can be inhibited by 2-DG; (b) the repair of potentially-lethal damage occurs after the unscheduled DNA synthesis is almost complete; and (c) the repair of potentially-lethal damage can be inhibited by 2-DG even after the completion of the unscheduled DNA synthesis.     

Characterization of unstable poly (A)-RNA in Caulobacter crescentus

Antabuse (disulfiram) is widely used in the treatment of chronic alcoholism. We have examined the effect of this drug on malignant transformation by Rous sarcoma virus, on eukaryotic cell synthesis, and on nucleic acid binding. It was found that: (1) Disulfiram inhibits the activity of the RNA dependent DNA polymerase of Rous sarcoma virus and inactivates the ability of the virus to malignantly transform chick embryo cells. The monomer of disulfiram, diethyldithiocarbamate does not affect the virus. (2) Disulfiram induced the synthesis of four proteins in normal chick embryo and human foreskin cells. The monomer diethyldithiocarbamate, induced these proteins also. Cellular DNA synthesis is more sensitive to disulfiram than are RNA and protein synthesis. (3) Disulfiram binds to neither DNA or RNA in the presence or absence of copper. However, diethyldithiocarbamate in the presence of, but not in the absence of, copper binds to HeLa cell DNA and to Rous sarcoma virus 70 S genome RNA. These results indicate that this compound, which causes no symptoms in people who do not consume alcohol, may have significant effects on a cellular level.     

Inhibition of Herpes Simplex Virus Type 2 Replication by Thymidine

Replication of herpes simplex virus type 2 (HSV-2) was impeded in KB cells which were blocked in their capacity to synthesize DNA by 2 mM thymidine (TdR). The degree of inhibition was dependent upon the concentration of TdR. In marked contrast, HSV-1 is able to replicate under these conditions. The failure of HSV-2 to replicate is probably due to the inhibition of viral DNA synthesis; there was a marked reduction in the rate of DNA synthesis as well as the total amount of HSV-2 DNA made in the presence of 2 mM TdR. We postulated that the effect of TdR on viral replication occurs at the level of ribonucleotide reductase in a manner similar to KB cells. However, unlike KB cells, an altered ribonucleotide reductase activity, highly resistant to thymidine triphosphate inhibition, was found in extracts of HSV-2-infected KB cells. This activity was present in HSV-2-infected cells incubated in the presence or absence of TdR. Ribonucleotide reductase activity in extracts of HSV-1-infected KB cells showed a similar resistance to thymidine triphosphate inhibition. These results suggest that the effect of TdR on HSV-2 replication occurs at a stage of DNA synthesis other than reduction of cytidine nucleotides to deoxycytidine nucleotides.     

Visna virus synthesized in absence of host-cell division and DNA synthesis

Visna virus is similar to the avian and the murine oncornaviruses. Oncornavirus replication is dependent upon the provirus being integrated into the host cell's DNA but integration and subsequent oncornavirus synthesis is blocked when the host cells are prevented from synthesizing cellular DNA or dividing. The synthesis of visna virus is restricted in vivo and may be dependent upon the host cell's ability to synthesize cellular DNA or divide. Treatment of sheep choroid plexus (SCP) cells with ultraviolet light or with mitomycin C prior to infection irreversibly inhibited plexus (ScP) cells with ultraviolet light or with mitomycin C prior to infection irreversibly inhibited both cell division and cellular nucleic acid synthesis but did not inhibit visna virus synthesis. Similarly, the synthesis of visna virus in cultures of SCP cells which had been prevented from dividing by being deprived of serum and in cultures of SCP cells which were incapable of synthesizing host cell nucleic acids by being treated with miracil D or sodium hexachloroiridate was equivalent to the synthesis of visna virus in cultures of SCP cells which were allowed to both synthesize cellular nucleic acids and divide. The synthesis of visna virus in the presence of ethidium bromide further demonstrated that integration of the visna provirus into the host cell's DNA is not required for visna virus synthesis to occur.     

Molecular-genetic effects of cadmium chloride

We studied the effect of cadmium chloride on: (1) the DNA of human cells; (2) the mutagenic effect of reproducing Kilham virus; (3) the synthesis of virus-induced interferon, and (4) the reproduction of oncogenic (mammalian leucosis) virus. Cadmium chloride caused degradation of DNA in human- and rat-embryo cells. Culture infected by the virus in the presence of cadmium sulphate had the highest yield of cells with chromosomal aberrations. Cadmium chloride caused marked inhibition of the virus-induced synthesis of interferon. The introduction of cadmium chloride into diploid cells infected by the leucosis virus caused a 3-4 fold increase in the yield of virus-induced transformation foci.     

Effect of glycosylation inhibitors on the release of enveloped vaccinia virus.

Addition of 1 to 10 mM 2-deoxy-D-glucose (2-dg) or glucosamine (gln) to the growth medium of vaccinia virus-infected cells inhibited the release of extracellular enveloped vaccinia virus (EEV) without affecting the production of intracellular naked vaccinia virus (INV) particles. In contrast, INV infectivity (particles per PFU) was decreased sevenfold by 50 mM 2-dg. Treatment with 2-dg reduced but did not eliminate glycosylation of the INV 37,000-molecular-weight glycoprotein. The kinetics of sensitivity to inhibitor addition experiments and inhibitor reversal experiments indicated that EEV release was dependent on glycosylation before 8 h postinfection. This was supported by polyacrylamide gel electrophoretic analysis of the synthesis kinetics for cell membrane-associated vaccinia glycoproteins in 2-dg-inhibited infected cells. The dependence of vaccinia protein glycosylation before 8 h postinfection for efficient EEV release was observed in spite of the fact that the period of greatest glycoprotein synthesis was 8 to 12 h postinfection. The presence of 2-dg resulted in an incompletely glycosylated 89,000-molecular-weight glycoprotein, as indicated by a reduction in the apparent glycoprotein molecular weight. The morphological event affected by the inhibitors was the acquisition by INV of a double-membrane structure from the Golgi apparatus. This morphological intermediate is necessary for release of EEV.     

Inhibition of Cellular DNA Synthesis in Cells Infected with Infectious Pancreatic Necrosis Virus

In asynchronous RTG-2 cell cultures infected with infectious pancreatic necrosis (IPN) virus, inhibition of cellular DNA synthesis, but not protein synthesis, was detected 5 to 6 h postinfection and was 80 to 90% complete by 7 to 8 h. Inhibition of DNA synthesis was largely abolished by UV irradiation of the virus. Sedimentation analyses of phenol-extracted DNA indicated that native cellular DNA was not degraded during infection. Sedimentation on alkaline sucrose gradients of DNA from cells pulsed with radioactive thymidine for varying periods indicated that elongation of nascent DNA chains proceeded normally in infected cells. These and previous results suggest that IPN virus infection results in a reduction of the number of chromosomal sites active in DNA synthesis but does not affect the rate of polymerization at active sites. Cells synchronized with excess thymidine and hydroxyurea and infected with virus at the time of release from the block demonstrated an inhibition of DNA synthesis 3 h postinfection. Cells infected 4 h prior to release continued to synthesize normal amounts of DNA for 1 to 2 h after release. These results indicated that DNA synthesis in early synthetic phase is relatively insensitive to inhibition by IPN virus.     

Herpes simplex virus resistance and sensitivity to phosphonoacetic acid.

Phosphonoacetic acid (PAA) inhibited the synthesis of herpes simplex virus DNA in infected cells and the activity of the virus-specific DNA polymerase in vitro. In the presence of concentrations of PAA sufficient to prevent virus growth and virus DNA synthesis, normal amounts of early virus proteins (alpha- and beta-groups) were made, but late virus proteins (gamma-group) were reduced to less than 15% of amounts made in untreated infected cells. This residual PAA-insensitive synthesis of gamma-polypeptides occurred early in the virus growth cycle when rates were identical in PAA-treated and untreated infected cells. Passage of virus in the presence of PAA resulted in selection of mutants resistant to the drug. Stable clones of mutant viruses with a range of drug sensitivities were isolated and the emergence of variants resistant to high concentrations of PAA involved the sequential selection of mutants progressively better adapted to growth in the presence of the drug. Increased drug resistance of virus yield or plaque formation was correlated with increased resistance of virus DNA synthesis, gamma-protein synthesis, and resistance of the virus DNA polymerase reaction in vitro to the inhibitory effects of the drug. PAA-resistant strains of herpes simplex virus type 1 (HSV-1) complemented the growth of sensitive strains of homologous and heterologous types in mixed infections in the presence of the drug. Complementation was markedly dependent upon the proportions of the resistant and sensitive partners participating in the mixed infection. Intratypic (HSV-1A X HSV-1B) recombination of the PAA resistance marker(s), Pr, occurred at high frequency relative to plaque morphology (syn) and bromodeoxyuridine resistance (Br, thymidine kinase-negative phenotype) markers, with the most likely order being syn-Br-Pr. Recombinant viruses were as resistant or sensitive to PAA as the parental viruses, and viruses recombinant for their PAA resistance phenotype were also recombinant for the PAA resistance character of the virus DNA polymerase. The results provide additional evidence that the herpesvirus DNA polymerase is the site of action of PAA and illustrate the potential usefulness of PAA-resistant mutants in genetic studies of herpesviruses.     

Accumulation of human immunodeficiency virus type 1 DNA in T cells: results of multiple infection events.

Human immunodeficiency virus type 1 DNA synthesis was followed in a CD4+ line of T cells (C8166) grown in the presence or absence of a monoclonal antibody to CD4 that blocks infection By 48 h after infection, cultures grown in the presence of the antibody contained approximately 4 copies of human immunodeficiency virus type 1 DNA per cell, whereas those grown in the absence of the antibody contained approximately 80 copies of viral DNA per cell. Most of the viral DNA in cultures grown in the absence of the antibody was present in a broad smear of apparently incomplete viral sequences. In cultures grown in the presence or absence of the antibody, the 9.6-kilobase linear duplex of viral DNA appeared to undergo integration within 24 h of its appearance. These results demonstrate that T cells accumulate unintegrated human immunodeficiency virus type 1 DNA as a result of multiple virions entering cells.     

Role of 2-deoxy-D-glucose in the inhibition of phagocytosis by mouse peritoneal macrophage

2-Deoxy-D-glucose inhibits Fc and complement receptor-mediated phagocytosis of mouse peritoneal macrophages. To understand the mechanism of this inhibition, we analyzed the 2-deoxy-D-glucose metabolites in macrophages under phagocytosis inhibition conditions and conditions of phagocytosis reversal caused by glucose, mannose and 5-thio-D-glucose, and compared their accumulations under these conditions. Macrophages metabolized 2-deoxy-D-glucose to form 2-deoxy-D-glucose 6-phosphate, 2-deoxy-D-glucose 1-phosphate, UDP-2-deoxy-D-glucose, 2-deoxy-D-glucose 1, 6-diphosphate, 2-deoxy-D-gluconic acid and 2-deoxy-6-phospho-D-gluconic acid. The level of bulk accumulation as well as the accumulation of any of these 2-deoxy-D-glucose metabolites did not correlate with changes in macrophage phagocytosis capacities caused by the reversing sugars. 2-Deoxy-D-glucose inhibited glycosylation of thioglycolate-elicited macrophage by 70-80%. This inhibition did not cause phagocytosis inhibition, since (1) the reversal of phagocytosis by 5-thio-D-glucose was not followed by increases in the incorporation of radiolabelled galactose, glucosamine, N-acetylgalactosamine or fucose; (2) cycloheximide at a concentration that inhibited glycosylation by 70-80% did not affect macrophage phagocytosis. The inhibition of protein synthesis by 2-deoxy-D-glucose similarly could not account for phagocytosis inhibition, since cycloheximide, when used at a concentration that inhibited protein synthesis by 95%, did not affect phagocytosis. 2-Deoxy-D-glucose lowered cellular nucleoside triphosphates by 70-99%, but their intracellular levels in the presence of different reversing sugars did not correlate with the magnitude of phagocytosis reversal caused by these sugars. The results show that 2-deoxy-D-glucose inhibits phagocytosis by a mechanism distinct from its usual action of inhibiting glycosylation, protein synthesis and depleting energy supplies, mechanisms by which 2-deoxy-D-glucose inhibits other cellular processes.     

Synthesis of herpes simplex virus, vaccinia virus, and adenovirus DNA in isolated HeLa cell nuclei. I. Effect of viral-specific antisera and phosphonoacetic acid.

Purified nuclei, isolated from appropriately infected HeLa cells, are shown to synthesize large amounts of either herpes simplex virus (HSV) or vaccinia virus DNA in vitro. The rate of synthesis of DNA by nuclei from infected cells is up to 30 times higher than the synthesis of host DNA in vitro by nuclei isolated from uninfected HeLa cells. Thus HSV nuclei obtained from HSV-infected cells make DNA in vitro at a rate comparable to that seen in the intact, infected cell. Molecular hybridization studies showed that 80% of the DNA sequences synthesized in vitro by nuclei from herpesvirus-infected cells are herpesvirus specific. Vaccinia virus nuclei from vaccinia virus-infected cells, also produce comparable percentages of vaccinia virus-specific DNA sequences. Adenovirus nuclei from adenovirus 2-infected HeLa cells, which also synthesize viral DNA in vitro, have been included in this study. Synthesis of DNA by HSV or vaccinia virus nuclei is markedly inhibited by the corresponding viral-specific antisera. These antisera inhibit in a similar fashion the purified herpesvirus-induced or vaccinia virus-induced DNA polymerase isolated from infected cells. Phosphonoacetic acid, reported to be a specific inhibitor of herpesvirus formation and the herpesvirus-induced DNA polymerase, is equally effective as an inhibitor of HSV DNA synthesis in isolated nuclei in vitro. However, we also find phosphonoacetic acid to be an effective inhibitor of vaccinia virus nuclear DNA synthesis and the purified vaccinia virus-induced DNA polymerase. In addition, this compound shows significant inhibition of DNA synthesis in isolated nuclei obtained from adenovirus-infected or uninfected cells and is a potent inhibitor of HeLa cell DNA polymerase alpha.     

Reovirus: Effect of Noninfective Viral Components on Cellular Deoxyribonucleic Acid Synthesis

We determined the effects of noninfective reovirus components on cellular deoxyribonucleic acid (DNA) synthesis. Reovirus inactivated by ultraviolet light inhibited cellular DNA synthesis, whereas reovirus cores and empty capsids did not. Both cores and empty capsids were adsorbed to cells. Adenine-rich ribonucleic acid (RNA) from reovirus, adsorbed to cells in the presence of diethyl-aminoethyl-dextran, produced a partial inhibition of DNA synthesis. RNA was synthesized in the presence of actinomycin D after infection with ultraviolet light-irradiated reovirus, and this RNA synthesis was not due to multiplicity reactivation of virus infectivity. These data suggest that viral structural proteins do not inhibit DNA synthesis and that the inhibition produced by ultraviolet-irradiated virus may be mediated in part or in toto by a newly synthesized viral product.     

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.     

Replication and supercoiling of simian virus 40 DNA in cell extracts from human cells.

Soluble extracts prepared from the nucleus and cytoplasm of human 293 cells are capable of efficient replication and supercoiling of added DNA templates that contain the origin of simian virus 40 replication. Extracts prepared from human HeLa cells are less active than similarly prepared extracts from 293 cells for initiation and elongation of nascent DNA strands. DNA synthesis is dependent on addition of purified simian virus 40 tumor (T) antigen, which is isolated by immunoaffinity chromatography of extracts from cells infected with an adenovirus modified to produce large quantities of this protein. In the presence of T antigen and the cytoplasmic extract, replication initiates at the origin and continues bidirectionally. Initiation is completely dependent on functional origin sequences; a plasmid DNA containing an origin mutation known to affect DNA replication in vivo fails to replicate in vitro. Multiple rounds of DNA synthesis occur, as shown by the appearance of heavy-heavy, bromodeoxyuridine-labeled DNA products. The products of this reaction are resolved, but are relaxed, covalently closed DNA circles. Addition of a nuclear extract during DNA synthesis promotes the negative supercoiling of the replicated DNA molecules.