Elongation of DNA complementary to the 5'' end of the avian sarcoma virus genome by the virion-associated RNA-dependent DNA polymerase.

RNA-dependent DNA synthesis in a virion-associated reaction has been described as being dependent upon the detergent concentration used for disruption of the virion. In this study, the Triton X-100 concentration was found to affect the elongation of the initially synthesized DNA complementary to the last approximately 100 nucleotides at the 5' end of the RNA (cDNA100). Whereas elongation of cDNA100 increased with time of incubation at the optimal detergent concentration, this process was retarded at higher detergent concentrations. At the optimal detergent concentration, elongated DNA was of low chemical complexity, indicating that extension of cDNA100 occurred at a unique site on the RNA. Higher than optimal detergent concentrations resulted in nonspecific elongation and in DNA of high chemical complexity. This was shown by oligopyrimidine tract analysis. Furthermore, actinomycin D was observed to inhibit the elongation of cDNA100 at the optimal detergent concentration. The nature of the elongation process was elucidated by analysis of DNA synthesized in a virion-associated reaction in the presence of bacteriophage Qbeta RNA. At the optimal detergent concentration DNA complementary only to avian sarcoma virus RNA was synthesized, whereas at higher concentrations DNA was copied from both avian sarcoma virus and Qbeta RNA. We conclude that the elongation mechanism of cDNA100 is affected by the detergent concentration and elongation is unspecific at higher than optimal detergent concentrations. The mechanism by which the nonionic detergent stimulates DNA synthesis has not yet been resolve. We assume that other factors in addition to DNA polymerase are involved in elongation of cDNA100.     

Effects of rifampicin, streptolydigin and actinomycin D on the replication of Col E1 plasmid DNA in Escherichia coli

We recently reported (Clewell et al., 1972) on an inhibitory effect of rifampicin on Col E1 plasmid replication. The present study represents a further characterization of this phenomenon as well as a study of the effects of two other known inhibitors of RNA synthesis, Streptolydigin and actinomycin D.During treatment of cells with chloramphenicol the colicinogenic factor E₁ (Col E1) continues to replicate for more than ton hours. During this time 4 to 5 S RNA is also synthesized. When varying concentrations of rifampicin were included during chloramphenicol treatment, inhibition of plasmid DNA synthesis correlated very closely with inhibition of cellular RNA synthesis. Similar experiments testing the effects of Streptolydigin and actinomycin D (during chloramphenicol treatment) showed that cellular RNA synthesis was at least 100 times more sensitive to these drugs than was plasmid DNA synthesis.When actively growing cells (i.e. cells not treated with chloramphenicol) were treated with a high concentration of rifampicin (250 μg/ml), chromosomal DNA synthesis continued to an extent representing about a 50% increase in DNA, while plasmid DNA synthesis appeared to stop abruptly.     

Dependence of mammalian DNA synthesis on DNA supercoiling. III. Characterization of the inhibition of replicative and repair-type DNA synthesis by novobiocin and nalidixic acid

Novobiocin and nalidixic acid, inhibitors of the bacterial enzyme DNA gyrase, inhibit DNA, RNA and protein synthesis in several human and rodent cell lines. The sensitivity of DNA synthesis (both replicative and repair) to inhibition by novobiocin and nalidixic acid is greater than that of protein synthesis. Novobiocin inhibits RNA synthesis about half as effectively as it does DNA synthesis, whereas nalidixic acid inhibits both equally well. Replicative DNA synthesis, as measured by incorporation of [3H]thymidine, is blocked by novobiocin in a number of cell strains; the inhibition is reversible with respect to both DNA synthesis and cell killing, and continues for as long as 20--30 h if the cells are kept in novobiocin-containing growth medium. Both novobiocin and nalidixic acid inhibit repair DNA synthesis (measured by BND-cellulose chromatography) induced by ultraviolet light or N-methyl-N'-nitro-N-nitrosoguanidine (but not that induced by methyl methanesulfonate) at lower concentration (as low as 5 micrograms/ml) than those required to inhibit replicative DNA synthesis (50 micrograms/ml or greater). Neither novobiocin nor nalidixic acid alone induces DNA repair synthesis. Incubation of ultraviolet-irradiated cells with 10--100 micrograms/ml novobiocin results in little, if any, further reduction of colony-forming ability (beyond that caused by the ultraviolet irradiation). Novobiocin at sufficiently low concentrations (200 micrograms/ml) apparently generates a quiescent state (in terms of cellular DNA metabolism) from which recovery is possible. Under more drastic conditions of time in contact with cells and concentration, however, novobiocin itself induces mammalian cell killing.     

Trypanosoma cruzi: effect of olivacine on macromolecular synthesis, ultrastructure, and respiration of epimastigotes.

Olivacine (a pyridocarbazole derivative) causes ultrastructural and metabolic alterations in Trypanosoma cruzi epimastigotes. The cytoplasm of cells grown in the presence of olivacine appears vacuolated, and swelling of the mitochondria is observed. Concomitant with the ultrastructural alterations, there was a reduction of the respiratory rate as well as inhibition of pyruvate oxidation. A marked inhibition of protein synthesis and a slower although significant inhibition of DNA, RNA, and lipid synthesis were also observed. The in vivo activity of olivacine does not parallel its in vitro effects suggesting inactivation of the drug by the host.     

The influence of chloramphenicol on synthesis of ribosomes and beta and beta' subunits of RNA polymerase]

The effect of low chloramphenicol concentrations on the biosynthesis of RNA, ribosomal proteins and RNA polymerase in E. coli CP 78 cells was studied. When protein synthesis was decreased by 50--70%, 14C-uracil incorporation in DNA increased twice, the rRNA synthesis being stimulated preferentially. In the presence of antibiotic the RNA/DNA ratio increased from 5,7 to 13,3. The differential rate of r-protein synthesis increased simultaneously with the stimulation of rRNA synthesis, so that alphar rises from 0,083 (without antibiotic) to 0,122 and 0,161 at 5 and 10 microgram/ml of chloramphenicol, respectively. The inhibition of protein synthesis by chloramphenicol is accompanied also by the increase of differential rate of synthesis of beta and beta' subunits of RNA polymerase. In the presence of 5 and 10 microgram/ml of chloramphenicol, alphap increased from 0,90% to 1,44 and 1,57%, respectively. It is assumed that the genes for beta and beta' subunits of RNA polymerase as the ribosomal genes are negatively controlled by guanosine tetraphosphate which intracellular concentration decreased in the presence of chloramphenicol. The known data on the influence of streptolydigin and rifampicin on the RNA polymerase biosynthesis are discussed in view of proposed hypothesis.     

Effects of acronycine on nucleic acid synthesis and population growth in mammalian tumor cell cultures

Acronycine — an alkaloid with antineoplastic activity against a wide range of experimental tumors — at concentrations of 0.5-12 μg/ml rapidly inhibits RNA synthesis in L5178Y mouse lymphoma and IRC rat monocytic leukemia cultures. Culture growth is arrested only at acronycine concentrations which markedly inhibit RNA synthesis. DNA synthesis is inhibited at rather higher concentrations but this is not a prerequisite of the arrest of growth. It is suggested that the arrest of growth may be a consequence of the inhibition of RNA synthesis. In both cultures arrest of growth coincides with the appearance of many cells with two apparently normal nuclei. Cells are not arrested in mitosis. It is shown these binucleated cells very probably arise from an inhibition of cell cleavage. Studies with synchronized cultures show that at low drug concentrations, more than one cell cycle may elapse before growth is arrested and binucleated cells appear, indicating the effect on cytokinesis is not immediate. The results suggest that the arrest of growth may be a result of a slow depletion of a component essential for cell cleavage. The disturbance at division is a major factor in arresting growth at low drug concentrations. At higher acronycine concentrations, when RNA synthesis may be inhibited by 80–90%, the cytotoxic effects appear earlier and are less specifically directed at cytokinesis; DNA synthesis is then also rapidly and markedly inhibited.     

Characterization of the RNA synthesizing activity of isolated kidney nuclei.

The limiting factor in RNA synthesis by isolated kidney nuclei is RNA nucleotidyltransferase at high salt concentrations but at low salt concentrations template availability becomes limiting. alpha-Amanitin inhibits 85% of the activity at high salt concentrations but only 20-50% of the activity at low salt concentrations. Exogenous DNA is utilized at low salt concentrations [up to 0-1M (NH4)2SO4] but not at high salt concentrations. The effect of increasing salt concentration is mainly to cause an increase in the length of chains synthesized. Initiation rates are not increased by high salt concentrations. The apparent Km for UTP is 8-10 muM at high salt concentrations, indicating that assays performed at low UTP concentrations are likely to give inaccurate results. The activation energy for the reaction at low salt concentration is less than that for the reaction at high salt concentration. The RNA synthesizing capacity of kidney nuclei is dependent on the method of isolation, and preparation by a modification of the Chauveau method (Chauveau et al. 1956) yields the most active nuclei.     

Survival and Macromolecular Synthesis During Incubation of Escherichia coli in Limiting Thymine

Survival and the synthesis of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein were measured during incubation of a thymine auxotroph of Escherichia coli in a series of media containing thymine concentrations below the optimal level of 2 mug/ml. The rate of increase in viable count gradually diminishes to no net growth with 0.2 mug/ml. With lower concentrations of thymine, the rate of cell death gradually increases, resulting in a typical thymineless death curve with 0.02 mug/ml. Both the rate of cell growth and the rate of cell inactivation vary linearly with the thymine concentration. Thirty minutes of incubation in media containing limiting concentrations of thymine before a shift to complete thymine starvation results in a progressive decrease in the length of the lag period preceding thymineless death. These data suggest that only one type of cellular damage occurs during the various degrees of thymine limitation. Prolonged preincubation in media containing 0.1 to 0.2 mug/ml of thymine results in an immunity to thymineless death. This immunity differs from that observed with amino acid-starved cells in its kinetics; ultraviolet irradiation of preincubated cells indicates that the cells are inactivated at the same rate as log-phase cells. These results suggest that the immunity is not associated with chromosome alignment. Thymine concentrations between 2 mug/ml and 0.2 mug/ml permit essentially the same amount of protein and RNA synthesis. The total amount of synthesis then decreases linearly to 40 to 50% of the control level with further reduction in the amount of thymine present. Protein and RNA synthesis are first affected at the same thymine concentration at which lethality is first detectable, and this correlation suggests that the synthesis of these macromolecules is involved in the mechanism of thymineless death. DNA synthesis, on the other hand, is directly dependent on the thymine concentration for levels of 0.5 mug/ml or less. There are no critical changes in DNA synthesis associated with lethality, and DNA synthesis is still occurring under conditions of thymine limitation which result in immunity. These observations suggest that DNA synthesis is not directly involved in thymineless death.     

The UvsY protein of bacteriophage T4 modulates recombination-dependent DNA synthesis in vitro

An in vitro system containing the T4 gene 43, 45, 44/62, 32, dda, and uvsX proteins catalyzes DNA synthesis that is dependent on the synapsis step of homologous genetic recombination. The rate of DNA synthesis in this system is highly dependent on the concentration of the uvsX recombinase (a recA-like protein). Here we report the effect of the T4 uvsY protein, a recombination accessory protein, on this reaction. Low concentrations of uvsY protein greatly stimulate DNA synthesis at low concentrations of uvsX protein, but these same concentrations inhibit DNA synthesis at high concentrations of uvsX protein. As a result, the addition of small amounts of uvsY protein lowers the minimum concentration of uvsX protein needed for the reaction 8-fold, and it lowers the uvsX protein concentration for maximum activity 4-fold. The uvsY protein can affect either the initiation or elongation phase of DNA synthesis, depending on the concentration of uvsX protein present. The implications of these results for the function of the uvsY protein in T4 DNA replication in vivo are discussed.