RNA-directed DNA polymerase and virus-induced leukemia in mice

The potential of nucleotide analogs as inhibitors of retroviruses and tumors

The biologically active form of most purine or pyrimidine analogs is the nucleoside 5'-mono, di- or triphosphate. The nucleoside form is most often administered because of the ease with which it penetrates cells by facilitated transport. However, many nucleoside derivatives fail to exhibit significant antiviral or antitumor activity because they are not phosphorylated by cellular enzymes to the active nucleotide form. In this review, the potential use of suitable nucleotide analogs as selective inhibitors of ribonucleotide reductase and viral reverse transcriptase is considered. Masked nucleotides such as phosphoramidates or methyl phosphates could be employed to allow transport across cellular membranes. Furthermore, phosphonocarboxamide, phosphonoformate or sulfamidophosphoramidate may mimic nucleotide di- and triphosphates. Tumor cells and virally infected cells are often more permeable to nucleotides and their analogs than normal cells, which could provide a therapeutic advantage. There could be considerable therapeutic potential for nucleotide analogs that can penetrate the tumor cell membranes and that are resistant to enzymatic hydrolysis and are non-incorporable into DNA or RNA.

Antivirion effects of streptovaricin complex against Friend virus

The in vitro antivirion activities of five different streptovaricin complex lots against the polycythemic strain of the Friend virus were evaluated. The assay system was based on the inhibition of the Friend virus-induced spleen foci. The virus inactivation process was shown to be susceptible to variation in temperature, pH, and time. The antivirion activity and the acute toxicity for mice, as well as the optical properties of these streptovaricin complexes, do not co-vary; this suggests that their biological activities are not associated with a single molecular structure. In addition, the antivirion activity of the five preparations of streptovaricin complex differs about 30-fold, indicating that this activity does not reside in a major component of the complex.

Synthesis of globin RNA in enucleated differentiating murine erythroleukemia cells

In an earlier report (Volloch, V., 1986, Proc. Natl. Acad. Sci. USA., 83:1208-1212) we had presented evidence for the occurrence of the cytoplasmic synthesis of globin mRNA and of RNA complementary to globin mRNA which differed from DNA-dependent transcription by its insensitivity to actinomycin D. In this paper, we describe the use of enucleated differentiating mouse erythroleukemia cells to demonstrate directly the occurrence of cytoplasmic synthesis of both positive- and negative-strand globin RNA. For this purpose, we developed an enucleation procedure which yielded pure cytoplasts from differentiated mouse erythroleukemia cells in the absence of cytochalasin B and selectively permeabilized the cytoplasts to small molecules by treatment with dextran sulfate and saponin. The permeabilized cytoplasts incorporated [3H]dUTP into positive- and negative-strand globin RNA and experiments with mercurated nucleotide substrate suggested that this process involved de novo RNA synthesis rather than limited terminal nucleotide addition. Globin RNA synthesis required Mg++, was inhibited by Mn++, and was unaffected by the addition of Zn++. Studies of its response to inhibitors of DNA-dependent RNA synthesis showed that it differed from that process in its insensitivity to actinomycin D and alpha-amanitin, but that like many other macromolecular biosynthetic reactions it was inhibited by rifamycin AF/ABDP and aurintricarboxylic acid. These observations provide additional evidence for the occurrence of cytoplasmic RNA-dependent RNA synthesis in differentiated cells and show permeabilized enucleated cells to be a useful experimental system for further studies of the characteristics of that process.

Characterization of a continuous T-cell line susceptible to the cytopathic effects of the acquired immunodeficiency syndrome (AIDS)-associated retrovirus

We have developed a continuous human T-cell line (A3.01) for the study of acquired immunodeficiency syndrome (AIDS)-associated retrovirus that mimics normal peripheral blood lymphocytes in susceptibility to viral cytopathic effect without the need for cell activation or conditioned medium. Following infection, substantial quantities of virus are produced during a 3- to 5-day period; the associated killing of cells can be monitored in a microtiter assay as a function of virus input. Southern blot hybridization of infected cellular DNAs indicated that no gross alteration occurred in the restriction maps of the proviral DNA during the transfer of virus to and its passage in A3.01 cells. This cell system offers an alternative to other AIDS retrovirus cell systems because it permits the monitoring of viral cytopathic effects.

Study of ansamycin inhibition of a ribonucleic acid-directed deoxyribonucleic acid polymerase by an immobilized template assay

A series of structurally related ansamycins have been analyzed, in a new immobilized template assay, to determine the mechanism by which they inhibit a ribonucleic acid-directed deoxyribonucleic acid (DNA) polymerase from Moloney murine leukemia virus. By this assay, we can better correlate specific structures of these drugs with inhibitory mechanisms. Using an immobilized template, we were also able to observe drug effects on the stability of complexes formed between the polymerase, a template (polyadenylic acid-agarose), and a primer, as well as to monitor the synthesis of DNA in the presence of drug. For each drug, we determined the complex (intermediate in DNA synthesis) which was primarily affected and whether the effect was due to a destabilization process. Although the activity and specificity of the unsubstituted ansamycins (streptovaricins and rifamycin SV) were modulated by conformation of the molecule and electron density of the aromatic ring, the principal mode of inhibition is, apparently, drug binding to a polymerase-template complex; the drug binds in a manner which prevents subsequent formation of a polymerase-template-primer complex. However, some derivatives of rifamycin SV, when substituted at carbon-3 with bulky or hydrophobic side chains, displayed markedly different modes of action. For example, demethyl dimethyl rifampin prevented the formation of polymerase-template complexes, whereas rifazacyclo 16 acted by promoting the dissociation of polymerase-template-primer complexes.

Differential susceptibility of spleen focus-forming virus and murine leukemia viruses to ansamycin antibiotics

The streptovaricin complex (SvCx) and rifamycin SV derivatives display potent antiviral activity against the polycythemic strain of Friend leukemia virus (FV-P), as measured by a reduction in the number of spleen foci produced in mice. Such reductions may be explained by inactivation of functions of (i) the spleen focus-forming virus (SFFV), (ii) its "helper" murine leukemia virus (MuLV), or (iii) both viruses normally present in FV-P. We noted that preincubation of FV-P with fractionation products of SvCx, or derivatives of rifamycin SV, at low concentrations (3 to 5 mug/ml) reduces the number of spleen foci 80 to 97%, whereas titers of MuLV (from the same inoculum) remain unaffected (MuLV titers were measured by XC, S(+)L(-), and "helper activity" assays). Our findings indicate a remarkable biological selectivity of ansamycins, as well as nonansamycin components of SvCx, against the transforming and defective spleen focus-forming virus as compared to MuLV. Thus, the drugs might be useful in distinguishing other types of oncornaviruses.

Interruption of oncornavirus replication by modified rifamycin antibiotics

Thirteen rifamycin SV derivatives containing 3'-alkylaminomethyl substituents fail to inhibit the activities of the simian sarcoma virus Type 1 DNA polymerase, and of cellular DNA, RNA, and poly(A) polymerases prepared from NIH Swiss mouse embryos. These compounds show a range in their toxicities for NIH Swiss mouse 3T3 cells and in their capacities to inhibit production of foci of morphologically altered cells by murine sarcoma virus (MSV). Three compounds--the N-methyl-N-hydroxyethylaminomethyl, the N,N-dimethyl-aminomethyl, and the N4-methylpiperazinomethyl rifamycin derivatives--are comparable to adenine arabinoside and ribavirin in their toxicity for 3T3 cells, but these compounds show superior focus inhibition. These compounds inhibit oncornavirus production apparently by exacerbation of a delay in growth that results from infection of 3T3 cells with MSV.

Selective inhibition of RNA tumor virus replication in vitro and evaluation of candidate antiviral agents in vivo

A limited number of biologically active materials were examined for their relative ability to selectively inhibit the replication of Gross or Rauscher murine leukemia virus (MLV) in Swiss mouse embryo cells by means of the UV-XC plaque-reduction assay. Among the compounds demonstrating significant antiviral activity against Gross MLV in vitro were 1-(4-fluorobenzyloxy) adenosine (FBAR), polyadenylic acid [poly(A)], the carbocyclic analogue of 6-methylthiopurine ribonucleoside (C-MeMPR), 3-(2,4-dinitrophenylhydrazonemethyl)rifamycin SV (AF/DNFI), and phosphonoacetic acid (PAA). Five compounds that exhibited significant antiviral activity against MLV in vitro were tested for similar activity against Rauscher MLV in vivo. Three of these selected compounds, pyrazofurin (pyrazomycin), ribavirin (Virazole), and 9-beta-D-arabinofuranosyladenine (ara-A), produced a significant (50%-100%) inhibition of virus-induced splenomegaly development in mice, whereas the other two candidate inhibitors, 3-deazauridine (deazaUR) and rifamycin SV, the other two candidate inhibitors, 3-deazauridine (deazaUR) and rifamycin SV, failed to demonstrate any in vivo activity in this 21-day leukemogenesis assay. The administration of an inhibitor of adenosine deaminase (Co-vidarabine) in combination with ara-A resulted in an enhanced antiviral response in both infected cell cultures and animals. Co-vidarabine also increased the potency of ara-AMP against Gross MLV in vitro, indicating the probable dephosphorylation of the compound to ara-A and its subsequent deamination to ara-H in this system.

Synthesis of type C virus particles from murine-cultured cells induced by iododeoxyuridine. V. Effect of interferon and its interaction with dexamethasone

Previous studies have shown that in certain cell systems dexamethasone may enhance the production of type C viruses. Conversely, interferon has been shown to inhibit their production. Both appear to exert their influence late in the viral replication cycle rather than on the synthesis of viral-specific RNA. In this report dexamethasone and interferon have been used to study some aspects of the mechanisms involved in the synthesis of type C viruses in murine K-BALB cells following induction of virus production by iododeoxyuridine. Interferon inhibited production of xenotropic type C virus induced by iododeoxyuridine from K-BALB cells both in the absence and presence of dexamethasone, but it did not affect production of N-tropic type C virus. Exposure of the cells to interferon for longer than 12 h was required for maximum effect. Two types of inhibitory effects were observed: one diminished by dexamethasone when the steroid was added 24 h after interferon removal, and the second resistant to dexamethasone. The concentration of intracellular group-specific antigen was diminshed after interferon and increased after dexamethasone exposure. When induced cells were treated with both interferon and dexamethasone, the intracellular group-specific protein concentration was slightly increased, but virus production was reduced 10-fold compared with induced cells treated with dexamethasone alone. We conclude that interferon and dexamethasone may affect both the synthesis of viral proteins and the assembly or release of virus particles and that dexamethasone can partially nullify the inhibitory activity of interferon. The results also support previous conclusions that the regulatory mechanisms for synthesis of viral proteins and for the release of viral particles may differ and that controls for xenotropic and ecotropic virus formation may not be identical.

Activity of pure streptovaricins and fractionated streptovaricin complex against Friend virus

Chromatographic fractionation of streptovaricin complex yields two stable components enriched (4- to 16-fold) in activity directed against the polycythemic strain of Friend virus; both components apparently contain no streptovaricins. When compared with their unfractionated parent streptovaricin complex, eight individual intact streptovaricins (A through G and J) show at least a 30-fold reduction in antiviral activity. These results further support the conclusion that the diversified biological properties of streptovaricin complex probably reside in different molecular structures.

Mechanism of stimulation of murine type-C RNA tumor virus production by glucocorticoids: post-transcriptional effects

We have previously shown that dexamethasone stimulates production of type-C virus from seemingly normal murine fibroblasts (BALB/3T3) and from transformed (Kirsten sarcoma-leukemia virus) nonproducing cells (BALB/K3T3) induced by 5-iododeoxyuridine. In this report, we further examine the mechanism of this effect by using BALB/K3T3 cells. Several observations suggest that this effect is post-transcriptional. The optimal stimulation by dexamethasone is obtained when dexamethasone is given 24 to 48 h after 5-iododeoxyuridine induction. Although this effect is late, time course experiments suggest that dexamethasone does not act to promote release of preformed virions. The stimulation by dexamethasone is blocked when cells are treated with cordycepin (3'-deoxyadenosine) during the first 24 h of induction, but not when cordycepin is added later. Conversely, interferon, which inhibits virus production, interferes with dexamethasone when it is added late or after removal of the steroid. The results of molecular hybridization experiments show that there is no detectable increase in Kirsten sarcoma-leukemia virus-specific RNA in dexamethasone-treated cells (with or without 5-iododeoxyuridine). The results of the time course studies, and the cordycepin, interferon, and hybridization experiments, suggest that the effect of dexamethasone on type-C virus production in this system is post-transcriptional.

The specificity of dimethylbenzylrifampicin as an inhibitor of viral induced transformation

The effect of 2',6'-dimethyl-N(4')-benzyl-N(4')- [desmethyl]rifampicin on viral transformation induced by two unrelated oncogenic viruses was compared. Transformation of Balb/3T3 cells by the small, DNA-containing papova virus simian virus 40 was completely normal under conditions where transformation by the large, RNA-containing oncornavirus murine sarcoma virus was inhibited more than 150-fold. For these experiments a resistant variant of Balb/3T3 was selected that grows well in high concentrations of the drug, is not dependent on the drug for growth, and is probably not blocked at the level of drug uptake. These data show that dimethyl-benzylrifampicin specifically inhibits oncornavirus-induced transformation rather than nonspecifically inhibiting cellular growth or transformation.

Preferential inhibition of the growth of virus-transformed cells in culture by rifazone-82, a new rifamycin derivative

Rifazone-8(2), a new rifamycin derivative, is shown to preferentially inhibit the growth of virus-transformed chick cells in culture. Macromolecular synthesis and glucose uptake of transformed cells are also appreciably decreased in the presence of low concentrations of rifazone-8(2) where the normal cells appear unaffected. While rifazone-8(2) is shown to be a selective inhibitor of RNA-directed DNA polymerase in vitro, its action on the growth of transformed cells may involve some other mechanism.

Separation of ribonuclease H and RNA directed DNA polymerase (reverse transcriptase) of murine type-C RNA tumor viruses

Ribonuclease H (RNA.DNA-hybrid ribonucleotidohydrolase, EC 3.1.4.34) has been reported to copurify with reverse transcriptase (RNA directed DNA polymerase) of RNA tumor viruses. In addition, viral specific ribonuclease H and reverse transcriptase of avian type-C viruses are thought to be part of the same polypeptide. In this report we show that a fraction of the ribonuclease H activity from Rauscher murine leukemia and Kirsten murine sarcoma viruses was separated from reverse transcriptase by anion exchange chromatography while the remaining portion co-purified with the viral polymerase. The amount of this co-purified nuclease activity was about 4- to 8-fold lower than the activity found in avian myeloblastosis virus (with respect to the ratio of ribonuclease H to reverse transcriptase) and this nuclease activity can only be detected by using labeled substrate of high specific radioactivity. However, a complete separation of ribonuclease H activity from reverse transcriptase was obtained by purifying core structures of the virus by sucrose density gradient centrifugation. While reverse transcriptase was present in the cores, there was no detectable ribonuclease H. Furthermore, a specific antibody against Rauscher leukemia virus reverse transcriptase did not inhibit any virion associated ribonuclease H activity. Our results suggest that in these virions these two enzyme activities reside in two separate molecules and probably in two different compartments of the virus. These findings emphasize a basic difference between the avian and murine type-C virus DNA polymerases.

Responses of the murine myeloid colony-forming cell to ansamycin antibiotics

The in vitro susceptibility of murine myeloid colony-forming cells to the antiproliferative activities of three ansamycin antibiotics was determined. These cells were found to be 10- to 40-fold more susceptible than the corresponding human ones.

Reticulocyte RNA-dependent RNA polymerase

A cytoplasmic, microsomal bound RNA-dependent RNA polymerase has been purified 2500-fold from rabbit reticulocyte lysates. The synthesis of RNA with the purified enzyme is absolutely dependent on the addition of an RNA template. The best template is hemoglobin messenger RNA, while bacteriophage RNA and poly(A,G) are less active, and DNA is completely inactive as a template. With poly(A,G) as a template, only UTP and CTP are incorporated into polynucleotide chains, indicating that the RNA polymerase is an RNA replicase and not a terminal transferase. With messenger RNA as a template, all four ribonucleoside triphosphates are required for maximal activity. The RNA-dependent RNA polymerase reaction is extremely sensitive to low concentrations of heme, rifamycin AF/013, and ribonuclease and resistant to actinomycin D and DNase. The discovery of RNA-directed RNA synthesis in reticulocytes offers an additional site for control of gene expression in mammalian cells and provides a possible mechanism for amplification of the expression of specific genes.