The effect of proflavine on HeLa cells

1. The effect of proflavine on the metabolism of RNA, DNA and protein of HeLa cells was studied. 2. The synthesis of RNA, DNA and protein was progressively inhibited by concentrations of proflavine up to 43mum. 3. There was no simple relationship between the degrees of inhibition of synthesis of RNA, DNA and protein by increasing concentrations of proflavine: the synthesis of RNA was most readily inhibited, and the synthesis of protein was relatively insensitive. 4. A concentration of 22mum-proflavine inhibited synthesis of RNA and DNA and caused a progressive loss of RNA from both nucleus and cytoplasm without any accompanying loss of DNA or dry weight from the cells. 5. The rapidly labelled RNA in the nucleus was preferentially degraded and was not transferred in a stable form to the cytoplasm.     

Studies on the mechanism by which prolactin regulates protein, RNA, and DNA synthesis in Nb2 node lymphoma cells

Specific aspects of the prolactin stimulation of RNA, DNA and protein synthesis in the Nb2 node lymphoma cell line were determined. In time sequence studies the onset of the prolactin stimulation of the incorporation of radiolabeled precursors into these macromolecules was found to be 0.5-1 h for [3H]uridine incorporation into RNA, 1-2 h for [3H]leucine incorporation into protein, and 4-8 h for [3H]thymidine incorporation into DNA. The total DNA content of the cell cultures was increased by 12-18 hours after addition of prolactin. Amiloride, an inhibitor of the plasma-membrane-bound Na+/H+ antiporter, was found to inhibit the mitogenic effects of prolactin. Amiloride was also found to inhibit the prolactin stimulation of DNA, RNA and protein synthesis, thus suggesting that the initial regulation of the Na+/H+ antiporter may initiate these responses as well as the mitogenic effect of prolactin. In contrast, H-7, a drug which inhibits protein kinase C, had no effect on the magnitude of the prolactin stimulation of DNA, RNA or protein synthesis at a drug concentration (100 muM) that abolished the mitogenic effect of prolactin. The early effects of prolactin on RNA, DNA and protein synthesis would therefore appear not to involve an activation of protein kinase C.     

Inhibition of mitosis in pisum root meristems by continuous gamma radiation: the influence of temperature on the synthesis of DNA, RNA and protein during inhibition

Tritiated precursors of DNA, RNA and protein were used to measure synthesis at 10 and 20C in root meristem cells of Pisum after they were mitotically arrested by continuous irradiation with gamma rays. The experiments were designed to determine if the arrested cells accumulated in a certain part of interphase, to determine the effect on DNA, RNA and protein synthesis, to find out if the effects were temperature dependent, and finally to reveal possible relationships between growth inhibition and altered synthesis. The results showed that the incorporation of DNA and RNA precursors was impaired by irradiation and that decreased temperature further increased radiation impairment of DNA synthesis. Protein synthesis on the other hand was not impaired by irradiation at either temperature. Irradiation at 20C reduced the number of DNA-synthesizing cells; at 10C this number was reduced to near zero. Although irradiated cells synthesizing RNA showed a reduction in grain counts when compared to the controls, they still retained the ability to incorporate tritiated uridine at 10C. It was hypothesized that the combination of reduced DNA and RNA synthesis and unaffected protein synthesis resulted in precocious maturation of the arrested meristem cells. Growth which occurred in the absence of cell division was attributed to meristematic cells which precociously matured and cells which were in the region of elongation.     

Action of heliomycin on protein and mucleic acid synthesis in Staphylococcus aureus]

Heliomycin inhibited synthesis of RNA in Staph. aureua which was clearly shown in the study of the antibiotic effect on RNA synthesis in the lag phase of the culture development: heliomycin markedly lowered the maximum RNA level in the biomass observed in the culture at the beginning of the exponential growth. On further growth of the culture heliomycin induced a significant retardness of the process of the natural decrease in the RNA biomass level resulting in increased content of RNA in the cells growing in the presence of heliomycin as compared to the control culture. Retarded natural decrease in the RNA biomass level in the presence of heliomycin was observed also on the antibiotic addition just at the beginning of the exponential growth, during the period of maximum RNA accumulation in the cells. Heliomycin had no effect on synthesis and biomass levels of DNA. Heliomycin inhibited the protein synthesis and was close to chloramphenicol by the level of inhibition of the summation protein synthesis in the biomass. However, comparison of the effect of the above antibiotics on synthesis of beta-galactosidase, an individual enzyme protein showed that heliomycin was much less active as an inhibitor of protein synthesis in comparison to chloramphenicol.     

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.     

Metabolic effects of manganese deficiency in Aspergillus niger: evidence for increased protein degradation

The effect of manganese deficiency on macromolecule synthesis has been studied in a citric acid producing strain of Aspergillus niger: pulse labelling experiments showed that the synthesis of both protein and RNA was not influenced by the presence of manganese; however, increased protein degradation occurred under manganese deficiency. This was also reflected by the increased activity of an intracellular proteinase activity under these conditions. In replacement cultures addition of inhibitors of RNA, DNA or protein synthesis revealed that only emetine and cycloheximide (which both act at the ribosome) successfully antagonized the adverse effect of manganese ions on citric acid accumulation. Manganese deficiency was also characterized by a decreased portion of polysomes and 80 S ribosomes.     

Exposure to caffeine and suppression of DNA replication combine to stabilize the proteins and RNA required for premature mitotic events

Caffeine had been shown to induce mitotic events in Syrian hamster fibroblast (BHK) cells that were arrested during DNA replication (Schlegel and Pardee, Science 232:1264-1266, 1986). Inhibition of protein synthesis blocked these caffeine-induced events, while inhibition of RNA synthesis showed little effect. We now report that the protein(s) that are required for inducing mitosis in these cells were synthesized shortly after caffeine addition, the activity was very labile in the absence of caffeine, and the activity was lost through an ATP-dependent mechanism. Caffeine dramatically increased the stability of these putative proteins while having no effect on overall protein degradation. Experiments with an inhibitor of RNA synthesis indicated that mitosis-related RNA had accumulated during the suppression of DNA replication, and this RNA was unstable when replication was allowed to resume. These results suggest that the stability of RNA needed for mitosis is regulated by the DNA replicative state of the cell and that caffeine selectively stabilizes the protein product(s) of this RNA. Conditions can therefore be selected that permit mitotic factors to accumulate in cells at inappropriate times in the cell cycle. Two-dimensional gel electrophoresis has demonstrated several protein changes resulting from caffeine treatment; their relevance to mitosis-inducing activity remains to be determined.     

Studies on the inhibition of bacterial macromolecule synthesis by roquefortine,a mycotoxin from Penicillium roqueforti

Summary The inhibitory effect of roquefortine, a secondary metabolite of Penicillium roqueforti, on bacterial protein, RNA and DNA synthesis was studied. Similar results were obtained in colorimetric measurements and in studying the incorporation of radioactive precursors. They show that RNA synthesis was most significantly affected by roquefortine. Inhibition of protein and DNA synthesis was less pronounced and might be a result of primary inhibition of RNA synthesis.Abbreviations RNA ribonucleic acid - DNA desoxyribonucleic acid - DMSO dimethylsulfoxide - Cpm counts per min - ATCC American Type Culture Collection     

SENESCENCE: HORMONAL CONTROL OF RNA AND PROTEIN SYNTHESIS IN EXCISED BEAN POD TISSUE

The kinetics of degradation of RNA, total protein, ribosomal and soluble (R-S) protein and DNA were followed over 24 hours in excised segments of Kentucky Wonder pole beans (Phaseolus vulgaris). In absence of exogenous auxin, RNA degradation proceeded from about zero time. By 15 hours, after about 20% of the RNA had degraded, the degradation of DNA, total protein and R-S protein was initiated. Exogenous auxin (25 ppm α-napthaleneacetic acid) prevented these degradations. The addition of kinetin had little or no effect. Auxin enhanced incorporation of orotic acid into RNA two to several times more than it did amino acids into protein. Actinomycin D repressed RNA synthesis about 75% including a repression of auxin-induced synthesis. It had no effect on the basal level of protein synthesis but did repress auxin-induced synthesis. The results indicate that the primary action of auxin in preventing senescence of bean endocarp tissue is at the site of RNA synthesis, and the effect of auxin on DNA and protein is a consequence of the effect of auxin on RNA metabolism.     

Changes in the metabolism of muscle RNA in rats given a high protein diet

The effect of a high protein diet (20% casein + D,L-methionine) administered to adult Wistar rats on some aspects of muscle RNA metabolism has been studied. Body weight increased in spite of lower intake. However, gastrocnemius muscle remained unmodified, although protein content increased. Total RNA decreased in the whole muscle although RNA/DNA ratio did not change. Protein synthesis capacity diminished 81% relative to controls in spite the fact that an excessive amount of available amino acids exists. RNA loss might depend on a high catabolism, since acid RNase activity increased over control values. Therefore, it may be concluded that a high protein diet leads to a lower protein synthesis capacity through an elevated RNA breakdown.     

Mode of Action of Myxin on Escherichia coli

The effect of the new antibiotic, myxin, on the syntheses of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein in Escherichia coli (strains B and 15T(-)) was examined. Within 7 min of the addition of myxin at 5 mug/ml, the synthesis of new bacterial DNA was almost completely inhibited. This was followed by an extensive degradation of the pre-existing DNA to an acid-soluble form. All of the evidence indicated that the primary effect of the antibiotic was on cellular DNA. The synthesis of RNA was completely inhibited after 15 min of exposure to myxin (5 mug/ml), and the synthesis of protein was markedly reduced after 30 min. There was no measurable breakdown of either RNA or protein in the myxin-treated cells. A marked stimulation of (14)C-uracil incorporation was found in the presence of myxin in 15T(-) cells only. This did not result from an increased rate of RNA synthesis but was due to an increase in the proportion of exogenous uracil, relative to endogenous uracil, incorporated into cellular RNA. This probably reflected a partial inhibition of the biosynthesis of uridine monophosphate from orotate. At 4.5 mug of myxin per ml and with 0.8 x 10(8) cells per ml, 50% of the antibiotic was reduced in 15 min from the biologically active oxidized form to the biologically inactive state. Under these conditions, a maximum of 0.6% (27 mumug/ml) of the myxin was retained in the cells.     

Toxicity of methylglyoxal towards rat enterocytes and colonocytes.

Effect of methylglyoxal, a bacterial metabolic product, on protein, DNA, and RNA synthesis in rat enterocytes and colonocytes was investigated. Results showed that 1 mM methylglyoxal inhibited protein, DNA, and RNA synthesis to the extent of 65-85, 65-80, and 10-20 per cent, respectively, in villus and crypt cells and colonocytes. The inhibitory pattern was similar in these various cell types. The inhibitory effect on protein and DNA synthesis was more marked than that on RNA synthesis. Inclusion of thiol compounds up to 4 mM concentration did not protect the cells from the inhibitory effect of methylglyoxal. No alteration in the level of cellular reduced glutathione and glyoxalase enzyme activity was observed when cells were incubated with 2 mM methylglyoxal. These results suggest that the antiproliferative action of methylglyoxal on eukaryotic cells may be through the inhibition of macromolecular synthesis.     

Stimulation of guanylate cyclase and RNA polymerase II activities in HeLa cells and fibroblasts by biotin

HeLa cells cultured in a biotin-deficient medium showed reduced rates of protein synthesis, DNA synthesis and growth. Continuous synthesis is required for the increase in DNA synthesis observed upon addition of biotin to cells cultured in biotin-deficient medium. The addition of biotin to the biotin-deficient culture medium increased the activity of guanylate cyclase in both HeLa cells and fibroblasts. Both cell types cultured in biotin deficient medium showed reduced activity of RNA Polymerase II. The exogenous addition of biotin to the biotin-deficient cell cultures also resulted in increased activity of RNA Polymerase II in HeLa cells and fibroblasts. The maximal response was observed in 4 hours. Significant increase in enzyme activity was observed at 10^–8 M biotin in the culture medium. The growth promoting effect of biotin seems to involve stimulations of cellular guanylate cyclase and RNA Polymerase II activity.     

Enhancement of ribosomal ribonucleic acid synthesis by deoxyribonucleic acid gyrase activity in Escherichia coli.

The effect of the deoxyribonucleic acid (DNA) gyrase inhibitors coumermycin A1, novobiocin, and oxolinic acid on ribonucleic acid (RNA) synthesis in Escherichia coli was studied in vivo and in vitro. Preferential inhibition of ribosomal RNA (rRNA) synthesis was observed. No effect of oxolinic acid and coumermycin on rRNA synthesis was seen in mutants having a DNA gyrase which is resistant to these inhibitors. In a temperature-sensitive DNA gyrase mutant rRNA synthesis was decreased at nonpermissive temperatures. Thus, a functional DNA gyrase is required for rRNA synthesis. Purified DNA gyrase had no effect on rRNA synthesis in a purified system. However, DNA gyrase does show preferential stimulation of rRNA synthesis in a system supplemented with other proteins. Apparently, DNA gyrase stimulation of rRNA synthesis requires another protein.     

Macromolecular syntheses during biosynthesis of prodigiosin by Serratia marcescens.

Amino acids that were utilized as sole sources of carbon and nitrogen for growth of Serratia marcescens Nima resulted in biosynthesis of prodigiosin in non-proliferating bacteria. Addition of alanine, proline, or histidine to non-proliferating cells incubated at 27 C increased the rate of protein synthesis and also caused biosynthesis of prodigiosin. No increase in the rate of protein synthesis was observed upon the addition of amino acids that did not stimulate prodigiosin biosynthesis. Increased rates of synthesis of ribonucleic acid (RNA) and of deoxyribonucleic acid (DNA) (a small amount) also occurred after addition of amino acids that resulted in biosynthesis of prodigiosin. After incubation of 24 h, the total amount of protein in suspensions of bacteria to which alanine or proline was added increased 67 and 98%, respectively. Total amounts of DNA and of RNA also increased before synthesis of prodigiosin. The amounts of these macromolecules did not increase after addition of amino acids that did not induce biosynthesis of progidiosin. However, macromolecular synthesis was not related only to prodigiosin biosynthesis because the rates of DNA, RNA, and protein synthesis also increased in suspensions of bacteria incubated with proline at 39 C, at which temperature no prodigiosin was synthesized. The quantities of DNA, RNA, and protein synthesized were lower in non-proliferating cells than in growing cells. The data indicated that amino acids causing biosynthesis of prodigiosin in non-proliferating cells must be metabolized and serve as sources of carbon and of nitrogen for synthesis of macromolecules and intermediates. Prodigiosin was synthesized secondarily to these primary metabolic events.     

Differences in inhibition by IDF45 (an inhibitory diffusible factor) of early RNA synthesis stimulation induced by pp60 v-src and various mitogens.

Factors inhibiting cell growth have been isolated from different cell types. However, little information is available concerning their mode of action. A novel growth inhibitory factor of 45 kDa (IDF45) was recently purified to homogeneity from medium conditioned by 3T3 cells. This molecule was able to inhibit DNA synthesis and the growth of chick embryo fibroblasts (CEF) in a reversible manner. By contrast, DNA synthesis stimulated by v-src expression in CEF was poorly inhibited by IDF45. In order to gain further insight into the IDF45 mode of action in normal and transformed CEF, we compared the effects of IDF45 on early stimulation of RNA synthesis induced in CEF by different mitogenic factors and by v-src gene expression. Stimulation, by serum, of RNA synthesis was inhibited by IDF45; however, inhibition increased when cells were preincubated with IDF45 before addition of serum and cell labeling for 2 h. IDF45 was also able to inhibit partially the stimulation of RNA synthesis induced by PMA and PDGF but was unable to inhibit stimulation of RNA synthesis induced by insulin and v-src expression. By contrast, stimulation of RNA synthesis induced by IGF-I was rapidly 100% inhibited by IDF45. The effect of IDF45 on DNA synthesis stimulated by the different mitogens was also determined and was correlated with the effect of IDF45 on RNA synthesis. These results suggest that the modes of action of IDF45 on stimulation of RNA synthesis by v-src and by insulin are similar. Our present results agree with others showing the bifunctional activity of IDF45 as an IGF-binding protein and as an inhibitory molecule in DNA stimulation induced by serum.     

Effect of mutation of amino acids 246-251 (KRKHKK) in HSP72 on protein synthesis and recovery from hypoxic injury

Heat shock protein (HSP)72, the inducible form of HSP70, protects cells against a variety of injuries, but underlying mechanisms are poorly defined. To investigate the protective effects of HSP72, multiple clones expressing wild-type (WT) HSP72 and two mutants with defective nucleolar and nuclear localization (M45 and 985A, respectively) were made with the tet-off system in C2C12 cells. Four different parameters of cell function/injury were examined after simulated ischemia: protein synthesis, polysome formation, DNA synthesis, and lactate dehydrogenase (LDH release). Overexpression of WT HSP72 was also compared to nontransfected C2C12 cells. As expected, overexpression of HSP72 protected against simulated ischemia and reoxygenation for all parameters. In contrast, both M45 and 985A showed abnormal protein synthesis and polysome formation, both after simulated ischemia and under control conditions. Total RNA was slightly reduced in M45 and 985A at baseline, but 1 h after hypoxia, RNA levels were protected in all clones but significantly decreased in nontransfected C2C12 cells. Clones expressing 985A had nuclear retention of mRNA, suggesting that HSP72 is needed for nuclear export of RNA. All clones, both WT and mutant, had protection of DNA synthesis compared to C2C12 cells, but 985A had greater release of LDH after injury than any other group. These results support a multifactoral protective effect of HSP72, some aspects dependent on nuclear localization with stress and some not. The protection of protein synthesis and polysome formation, and abnormalities in these with the mutants, support a role for HSP72 in these processes both in the normal cell and in injury.