A comparative study of the protein components of ribonucleoprotein particles isolated from rat liver and hepatoma nuclei

To solve the mechanism for the complete cessation of DNA synthesis in Tetrahymena cells involved in the amino acid starvation, the nature of DNA polymerase activity was investigated in crude enzyme preparations or in toluene-permeabilized specimens. In crude enzyme preparations from growing cells, ³H-TTP incorporation into acid-insoluble products showed little dependency on exogenous DNA template, while incorporation increased markedly in the presence of ATP. These characteristics were very similar to those of replicative DNA synthesis in permeabilized Escherichia coli.Variations of DNA and RNA polymerase activities following transfer of exponentially growing Tetrahymena cells to amino acid-deprived medium showed that in the crude enzyme preparations DNA polymerase activity dropped sharply within 3 h after the transfer and practically no activity was detected thereafter, whereas RNA polymerase activity did not disappear in the same preparations. Such enzyme kinetics coincided well with the kinetics of in vivo synthesis of the corresponding nucleic acid.The cessation of DNA synthesis in the amino acid-starved cells may be due not to the activation of DNase or a soluble polymerase inhibitor, nor to the deficiency of each kind of deoxyribonucleoside triphosphate or magnesium ion or ATP generation system. It follows from this that the cessation of DNA polymerase activity in the starved cells may be due to the deficiency of DNA polymerase or its associated factor(s) as a reflection of short life-span of such a protein.     

In vitro synthesis of Escherichia coli ribosomal RNA

Synthesis of ribosomal RNA in a cell-free system was achieved using purified Escherichia coli RNA polymerase and bacterial DNA templates from E. coli, Proteus mirabilis and E. coli/P. mirabilis hybrid strains carrying an E. coli DNA enriched for ribosomal RNA genes.Both direct and indirect competition hybridization revealed that from 5 to 15% of the in vitro product, depending on the template used, had sequences homologous to rRNA. The level of synthesis of sequences homologous to rRNA was related directly to the proportion of rRNA genes in the template. The use of heterologous DNA during competition hybridization ensured at least a 100-fold greater sensitivity for the detection of rRNA sequences than from any messenger RNA sequence.     

Inhibition of Auxin-induced Deoxyribonucleic Acid Synthesis and Chromatin Activity by 5-Fluorodeoxyuridine in Soybean Hypocotyl

Rootless soybean (Glycine max) seedlings were used as a test system to examine the action of auxin on chromatin-directed RNA synthesis. Chromatin from the basal tissue of rootless seedlings (both control and auxin-treated) had RNA synthetic capacity similar to that of chromatin from comparably treated intact seedlings. When DNA synthesis normally induced in the basal tissue by auxin was blocked in the rootless seedlings by 5-fluorodeoxyuridine, the auxin enhancement of chromatin activity was inhibited 70%. This level was still three times the control level, indicating that auxin influenced the synthetic activity of existing DNA template. Experiments with Escherichia coli RNA polymerase revealed that chromatin from both auxin- and auxin plus 5-fluorodeoxyuridine-treated tissue saturated at higher levels than chromatin from control tissue.     

Template activity of chromatin during stimulation of cellular proliferation in human diploid fibroblasts

1. Contact-inhibited confluent monolayers of WI-38 human diploid fibroblasts can be stimulated to divide by replacing the medium with fresh medium containing 30% foetal calf serum. 2. Of the cells 40–75% are stimulated to divide with a peak DNA synthesis between 15 and 21h and a peak mitotic index between 28 and 30h after stimulation. 3. In the first 12h before the initiation of DNA synthesis there is a biphasic increase in the incorporation of [³H]uridine into RNA of whole cells. 4. This is paralleled by a similar biphasic stimulation of chromatin template activity measured in vitro in a system in which purified cell chromatin is incubated with an exogenous RNA polymerase isolated from Escherichia coli. 5. The changes in chromatin template activity are believed to represent activation of the genome, with more sites available for RNA synthesis, and to account almost entirely for the changes in RNA synthesis occurring in the whole cell.     

RNA SYNTHESIS BY EXOGENOUS RNA POLYMERASE ON CYTOLOGICAL PREPARATIONS OF CHROMOSOMES

Cytological preparations of Drosophila polytene chromosomes serve as templates for RNA synthesis carried out by exogenous RNA polymerase (Escherichia coli). Incorporation of labeled ribonucleoside triphosphates into RNA may be observed directly by autoradiography. Because of the effects of rifampicin, actinomycin D, ribonuclease, high salt, and the requirement for all four nucleoside triphosphates, we conclude that the labeling observed over chromosomes is due to DNA-dependent RNA polymerase activity. Using this method, one can observe RNA synthesis in vitro on specific chromosome regions due to the activity of exogenous RNA polymerase. We find that much of the RNA synthesis in this system occurs on DNA sequences which appear to be in a nondenatured state.     

Chromatin- and nuclei-directed ribonucleic Acid synthesis in sugar beet root

The synthesis of RNA by chromatin-bound RNA polymerase prepared from sugar beet (Beta vulgaris) root tissue is completely dependent on the presence of a divalent metal (Mg²⁺ or Mn²⁺) and the presence of four ribonucleoside triphosphates. Accumulation of labeled acid-insoluble product is inhibited by the addition of RNase and actinomycin D to the reaction. When beet root slices are washed for 25 hours, chromatin-associated RNA polymerase activity increases 7-fold over that of unwashed tissue. This enzyme activity declines with further washing. DNA template availability, as measured by saturating levels of added Escherichia coli RNA polymerase, was also found to follow a pattern similar to that for RNA polymerase. Nearest neighbor frequencies of the RNA synthesized by chromatin isolated from unwashed and washed tissue are different.     

INTERACTION OF POLY-L-LYSINE WITH CHROMATIN : Inhibition of In Situ RNA Synthesis Mediated by Escherichia coli RNA Polymerase

RNA polymerase from Escherichia coli was used in conjunction with labeled nucleosides as an autoradiographic reagent to study the availability of template in the chromatin of fixed nuclei and chromosomes Sequential treatments of the tissues with acid and poly-L-lysine were used to compare the effect of these treatments on the availability of template with the previously reported effects on the in situ priming for Escherichia coli DNA polymerase Acid treatment was found to increase the in situ activity of both enzymes, while poly-L-lysine strongly inhibited the in situ reactions mediated by RNA and DNA polymerases. When the DNA polymerase reaction was previously carried out on alcohol-fixed chicken blood smears, leukocyte nuclei primed extensively for DNA synthesis. In contrast, we did not detect incorporation into intact nuclei of any cell type in alcohol-fixed blood smears that were treated with RNA polymerase.     

Characterization of the replication of Escherichia coli DNA in the absence of protein synthesis: Stable DNA replication

After inhibiting DNA synthesis in Escherichia coli, repeated cycles of chromosome replication can occur in the absence of protein synthesis. This “stable” replication requires the products of all of the known dna genes.Stable replication results from inhibiting DNA synthesis by treatment with naladixic acid, cytosine arabinoside or hydroxyurea; or by placing dnaB, dnaE or dnaG mutants at non-permissive temperatures. It also follows a “shift-up” into rich medium in which RNA and protein are synthesized more rapidly than DNA. Paradoxically, stable replication is induced also by treatment with concentrations of streptolydigin which do not inhibit DNA replication but temporarily and partially inhibit RNA and protein synthesis. During all of these treatments, some protein synthesis must occur.Stable replication is not immediately expressed after a short period of thymine starvation or streptolydigin treatment, but requires a subsequent period of protein synthesis. Once established, however, the stable replication state is permanent and will persist in the absence of protein synthesis or during normal growth.After stable replication has been determined by a period of DNA inhibition, it is possible to inactivate replication by heating dnaA, B, C, E and G temperature-sensitive mutants. However, resynthesis of these gene products in the presence of thymine and at the permissive temperature restores stable replication activity. Since restoration of activity can occur under normal growth conditions which do not induce stable replication, it was concluded that the dnaA, B, C, E and G gene products do not directly determine the stabilized character of the replication fork.A model is presented which attempts to explain the ability of different treatments to induce stable replication.     

The inhibition of RNA polymerase by daunomycin

The effect of daunomycin on the in vitro activity of Escherichia coli DNA-dependent RNA polymerase has been studied under a variety of experimental conditions. The inhibition of RNA synthesis by this DNA-binding antibiotic is overcome by an increase in the DNA concentration but is unaffected by an increase in the concentration of the RNA polymerase. It is concluded that, under conditions used, the inhibition is predominantly due to the interaction of the drug with the template DNA. At the concentration used (20 μM), daunomycin is able to inhibit RNA polymerization even after its initiation. However, the possibility remains that other steps are sensitive to daunomycin. A comparison of the effect of daunomycin on RNA synthesis using different DNAs as templates suggests that the extent of inhibition depends on base composition and on the secondary structure of the DNA. The effect of base composition on the melting temperature of antibiotic-DNA complexes is consistent with the inhibiting effect on RNA synthesis.     

A novel Escherichia coli mutant capable of DNA replication in the absence of protein synthesis.

An Escherichia coli mutant capable of continued DNA synthesis in the presence of chloramphenicol has been isolated by an autoradiographic technique. The DNA synthesis represents semiconservative replication of E. coli DNA. It can occur in the presence of chloramphenicol or in the absence of essential amino acids, but not in the presence of an RNA synthesis inhibitor, rifampin. The mutant, termed constitutive stable DNA replication (Sdr^c) mutant, appears to grow normally at 37 °C with a slightly slower growth rate than that of the parental strain. DNA replication in the mutant occurs at a reduced rate after 60 minutes in the absence of protein synthesis and continues linearly for several hours thereafter. This distinct slowdown in the DNA replication rate is due to a reduced rate of DNA synthesis in all the cells in the population. Constitutive stable DNA replication appears to require the dnaA and dnaC gene products. The sdr^c mutation has been mapped near the pro-lac region of the E. coli chromosome. The mutation is recessive. Autoradiographic experiments have ruled out the possibility of multiple initiations during a cell cycle. The implication of the above findings is discussed in terms of the regulation of chromosome replication in E. coli.     

Differential effect of neomycin on DNA dependent -DNA and RNA synthesis in vitro

Neomycin inhibits $\text{in vitro}$ DNA dependent DNA and RNA synthesis catalyzed by DNA polymerase I and RNA polymerase from $\text{E. coli}$. The effect of the antibiotic is more pronounced towards DNA synthesis. The inhibition of DNA synthesis is competitive with template DNA, does not reverse with excess deoxynucleoside triphosphate, Mg²⁺ or enzyme $\text{E. coli}$ DNA polymerase I. Neomycin does not reduce the number of potential 3′ -OH end or primer. It seems to shorten the size of the newly formed polynucleotide.