Photochemistry and photobiology of 5-azacytidine: effect of repair on photostabilization of Escherichia coli.

The photochemical stability of the anomalous nucleic acid base 5-azacytidine (z5Cyd) on irradiation at 254 nm is by about one order of magnitude less than that of cytidine (Cyd). Contrary to the photochemical behaviour, incorporation of z5Cyd into the nucleic acids of E. coli strains SR 20 (uvr+ rec+), SR 74 (uvr+ rec-) and SR 22 (uvr- rec+) produced a higher resistance to UV light. Only the SR 73 (uvr- rec-) strain was shown to have an increased UV sensitivity. This latter finding is in accord with the photochemical properties of z5Cyd. The results led to the conclusion that excision and recombination repair processes contribute to the observable protective effect. The fact that inhibition of excission repair by caffeine or proflavine of the mutant uvr+ rec- changes protection into sensitization supports this idea.     

Action of tetracycline and sodium deoxycholate combinations on protein and nucleic acid synthesis in the cells of the NAG vibrio, Staphylococcus aureus and Escherichia coli]

The effect of tetracycline combination with sodium desoxycholate, a surface-active substance, on the synthesis of proteins and nucleic acids in the cells of NAG-vibrio, Staph. aureus and E. coli was studied by incorporation of 1-14C-glycine and 8-14C-adenine into proteins and nucleic acids. It was found that sodium desoxycholate suppressed the synthesis of proteins and nucleic acids in the cells of NAG-vibrio and Staph. aureus. Its combination with tetracycline resulted in summation or increase of the suppressive effects on proteins and nucleic acids as compared to the effect of the substances used alone. Sodium desoxycholate even in very high concentration, up to 12800 gamma/ml, had no effect on the synthesis of proteins and nucleic acids in the cells of E. coli and respectively it did not change the activity of tetracycline on combined use.     

Regulation of fatty acid synthesis during the cessation of phospholipid biosynthesis in Escherichia coli.

In 1975, Cronan et al. (J. Biol. Chem. 250:5835-5840) reported that free fatty acids accumulated during glycerol starvation of an Escherichia coli glycerol auxotroph. On the basis of labeling experiments showing significant incorporation of [14C]acetate into the fatty acid fraction of glycerol-starved cells, these authors concluded that fatty acid synthesis proceeded normally in the absence of phospholipid synthesis. Since these findings might have been due to an increase in the intracellular specific activity of the [1-14C]acetyl coenzyme A pool of the glycerol-starved cells, we reexamined the effect of glycerol starvation on fatty acid synthesis. We found that (i) the incorporation of 3H2O and/or [2,3-14C]succinate into the fatty acid fraction of glycerol auxotrophs is severely reduced during starvation, (ii) the incorporation of [1-14C]acetate into the lipid fraction of an acetate-requiring glycerol auxotroph is inhibited by 95% during glycerol starvation, and (iii) the accumulation of fatty acids, as measured by microtitration, in glycerol-starved cells is less than 10% that of glycerol-supplemented cells. These results indicate that fatty acid synthesis is inhibited in the absence of phospholipid synthesis of E. coli.     

Effects of 4-nitro- and 4-sulpho-7-substituted benzofurazans on nucleic acid and protein synthesis of a malignant fibrosarcoma cell line in combination with mild hyperthermia

The inhibitory effects of substituted nitro- and sulphobenzofurazans on DNA, RNA and protein synthesis were compared in a new malignant fibrosarcoma cell line at 37°C and 41°C. The effects of these drugs with and without mild hyperthermia were evaluated by determining the % inhibition of incorporation of ³H-precursors into DNA, RNA and protein. None of the sulphobenzofurazan derivatives (Sbf) were effective inhibitors of nucleic acid and protein synthesis at 37°C nor did they enhance the inhibitory effect of hyperthermia alone. The nitrobenzofurazan derivatives (Nbf) at concentrations 10% that used for the Sbf derivatives strongly inhibited biopolymer synthesis in a dose related manner; 4-chloro-7-nitrobenzofurazan (Nbf-Cl) being the most potent inhibitor. Hyperthermia amplified the effect of all the Nbf compounds tested on RNA and protein synthesis but did not further affect DNA synthesis. This selective synergistic effect was most pronounced when the lowest concentrations of Nbf compounds were studied. The synergism however, did not follow a uniform pattern. 6-Mercaptopurine and 6-(1-methyl-4-nitro-5-imidazoyl)thiopurine (Azathioprine) (100 μM) had marginal effects on nucleic acid and protein synthesis when the cells were exposed to these two thiopurines for 1 h at both 37°C and 41°C and they had only a moderate inhibitory effect after exposure for 15 h.     

Effects of colchicine on nucleic acid metabolism during metamorphosis of Tenebrio molitor L. and in some mammalian tissues

1. Administration of 10mug. of colchicine/pupa of the beetle Tenebrio molitor L. arrests its differentiation, the pupa remaining alive for 2-3 weeks. 2. The same concentration of colchicine inhibits DNA synthesis and stimulates RNA synthesis (as shown by incorporation into the nucleic acids of labelled adenine, labelled uridine and labelled thymidine). The effects of colchicine on nucleic acid metabolism are first detected 3 days after its administration to first-day pupae. 3. No effects of colchicine are seen on [1-(14)C]glycine incorporation into protein in vivo. 4. Relatively high concentrations of colchicine (e.g. 10mm) suppress incorporation of [8-(14)C]adenine into RNA in dorsal abdominal wall in vitro. Such concentrations have no effect on its incorporation into acid-soluble nucleotides. 5. Colchicine (1mm) suppresses incorporation of [8-(14)C]adenine into DNA to a greater extent than into RNA in various mammalian tissues in vitro (e.g. rat spleen, regenerating rat liver, rat embryo, guinea-pig intestinal mucosa, Ehrlich ascites cells). Colchicine (1mm) has no effect on the rate of respiration of, or on incorporation of radioactivity into acid-soluble nucleotides in, the mammalian tissues tested. 6. Further evidence indicates complex-formation between colchicine and DNA, and it is suggested that the effect of colchicine in suppressing DNA synthesis is due to its combination with the DNA primer (template).     

Effects of 8-substituted analogs of cyclic adenosine 3'',5''-monophosphate on in vivo and in vitro syntheses of beta-galactosidase in Escherichia coli.

Several 8-substituted alkylthio and alkylamino cyclic adenosine 3',5'-monophosphate (cAMP) derivatives were tested for their ability to stimulate beta-galactosidase synthesis in Estherichia coli in vivo and in vitro and to inhibit the cAMP phosphodiesterase activity of E. coli. Stimulation of beta-galactosidease synthesis in vivo by cAMP derivatives decreased with increasing length of the unbranched carbon chain of the substituent. On the other hand, the stimulation in vitro was increased as the carbon chain elongated. The 8-decylthio- and 8-dodecylthio-cAMP compounds stimulated beta-galactosidase synthesis almost eight-fold compared with cAMP, whereas 8-undecyl-, 8-dodectyl-, and 8-tridecylamino-cAMP stimulated beta-galactosidase synthesis about threefold. However, in in vitro experiments with a phosphodiesterase-deficient strain of E. coli, the Crooks strain, the stimulatory effects of the derivatives disappeared, except for 8-dodecylthio cAMP which stimulated beta-galactosidase about 1.4- to 1.6-fold. All derivatives were quite resistant to hydrolysis by phosphodiesterase. Most derivatives competitively inhibited the hydrolysis of cAMP by phosphodiesterase.     

Isolation of fatty acids from the mycelium ofPenicillium stipitatum thom and their effect on ehrlich ascites carcinoma cells

A total of 5 fractions were isolated from the mycelium ofPenicillium stipitatum Thom obtained by submerged cultivation. Three of them inhibited the incorporation of¹⁴C-labelled precursors into Ehrlich ascitic cells (EAC) at concentrations lower than 100 μg/ml. The fraction M-72-3, inhibiting mainly adenine incorporation, was further separated into 6 fractions. The highest effect on EAC cells was exerted by subfraction IV which consisted of free fatty acids; its main effective components were oleic linoleic and linolenic acid. Their cyto-inhibitory effect on EAC cells was confirmed by their application in a pure form.     

Stringent control of peptidoglycan biosynthesis in Escherichia coli K-12.

[3H]Diaminopimelic acid (Dap) was incorporated exclusively into peptidoglycan by Escherichia coli strains auxotrophic for both lysine and Dap. The rate of [3H]Dap incorporation by stringent (rel+) strains was significantly decreased when cells were deprived of required amino acids. The addition of chloramphenicol to amino acid-starved rel+ cultured stimulated both peptidoglycan and ribonucleic acid synthesis. In contrast, a relaxed (relA) derivative incorporated [3H]Dap at comparable rates in the presence or absence of required amino acids. Physiologically significant concentrations of guanosine 5'-diphosphate 3'-diphosphate (ppGpp) inhibited the in vitro synthesis of both carrier lipid-linked intermediate and peptidoglycan catalyzed by a particulate enzyme system. The degree of inhibition was dependent on the concentration of ppGpp in the reaction mixture. Thus, the results of in vivo and in vitro studies indicate that peptidoglycan synthesis is stringently controlled in E. coli.     

DNA synthesis in vivo and in vitro in Escherichia coli irradiated with ultraviolet light

DNA synthesis was followed in vivo and in permeable Escherichia coli after ultraviolet light irradiation, irradiation and incubation in a growth medium containing chloramphenicol and in unirradiated cells. In vitro, replicative type DNA synthesis was partially restored after incubation of cells in medium containing chloramphenicol, but not in vivo. The DNA was pulse-labeled in permeable cells in the presence of deoxyribonucleoside triphosphates and ribonucleoside triphosphates. dCTP was replaced by 5-Hg-dCTP as a substrate for DNA synthesis. Hg-DNA was separated from cellular nucleic acids on thiol-agarose affinity columns. The 5' termini of newly synthesized DNA were analyzed after treatment with alkaline phosphatase and rephosphorylation with polynucleotide kinase and [gamma-32P]ATP. DNA synthesis in unirradiated permeable E. coli represents a replicative process dependent on ATP and inhibited by novobiocin. About 70% of the nascent DNA carried terminally labeled RNA moiety at its 5' end. In vitro DNA synthesis in irradiated cells was suppressed and hardly influenced by the presence of ATP or novobiocin. The 5'-RNA content of this cell population was less than 5%.     

Mechanism of Action of the Antifungal Antibiotic Pyrrolnitrin

Pyrrolnitrin at 10 mug/ml inhibited the growth of Saccharomyces cerevisiae, Penicillium atrovenetum, and P. oxalicum. The primary site of action of pyrrolnitrin on S. cerevisiae was the terminal electron transport system between succinate or reduced nicotinamide adenine dinucleotide (NADH) and coenzyme Q. At growth inhibitory concentrations, pyrrolnitrin inhibited endogenous and exogenous respiration immediately after its addition to the system. In mitochondrial preparations, the antibiotic inhibited succinate oxidase, NADH oxidase, succinate-cytochrome c reductase, NADH-cytochrome c reductase, and succinate-coenzyme Q(6) reductase. In addition, pyrrolnitrin inhibited the antimycin-insensitive reduction of dichlorophenolindophenol and of the tetrazolium dye 2,2'-di-p-nitrophenyl-(3,3'-dimethoxy-4,4'-bi-phenylene)5,5'-diphenylditetrazolium. The reduction of another tetrazolium dye, 2-p-iodophenyl-3-p-nitrophenyl-5-phenyltetrazolium chloride, that was antimycin-sensitive, was also inhibited by pyrrolnitrin. The antibiotic had no effect on the activity of cytochrome oxidase, and it did not appear to bind with flavine adenine dinucleotide, the coenzyme of succinic dehydrogenase. In whole cells of S. cerevisiae, pyrrolnitrin inhibited the incorporation of (14)C-glucose into nucleic acids and proteins. It also inhibited the incorporation of (14)C-uracil, (3)H-thymidine, and (14)C-amino acids into ribonucleic acid, deoxyribonucleic acid, and protein, respectively. The in vitro protein synthesis in Rhizoctonia solani and Escherichia coli was not affected by pyrrolnitrin. Pyrrolnitrin also inhibited the uptake of radioactive tracers, but there was no general damage to the cell membranes that would result in an increased leakage of cell metabolites. Apparently, pyrrolnitrin inhibits fungal growth by inhibiting the respiratory electron transport system.     

Studies on the inhibition of protein synthesis by selenodiglutathione.

Amino acid incorporation in a cell-free system derived from rat liver has previously been found to be inhibited by GSSeSG (selenodiglutathione). In the present experiments the effect of GSSeSG on protein synthesis in 3T3-f cells, on growth and protein synthesis in Escherichia coli, and on amino acid incorporation in a cell-free system derived from E. coli, was studied. GSSeSG inhibits the incorporation of [3H]leucine into protein by 3T3-f cells. This inhibition cannot be reversed by removing GSSeSG and is correlated with the uptake of GSSeSG. Sodium selenite (Na2SeO3) and oxidized glutathione had no inhibitory effect in this system. [3H]Uridine or [3H]thymidine incorporation into RNA or DNA was not inhibited, indicating that the primary action of GSSeSG was on protein synthesis. GSSeSG did not influence the growth of E. coli in a synthetic medium, although enhanced amino acid incorporation was observed. In the cell-free system derived from E. coli, amino acid incorporation was not changed by GSSeSG, indicating that elongation factor G, in contrast to elongation factor 2 of mammalian cell systems, is not blocked by GSSeSG.     

Monoclonal antibodies as probes to investigate the molecular changes of C5 associated with the different stability of the molecule on sheep erythrocytes and Escherichia coli 0111:B4

The fifth C component (C5) exhibits a different stability when bound to sheep E or Escherichia coli 0111:B4, being fairly stable on the bacterial intermediate sensitized E. coli 0111:B4 coated with C components up to C5 (BAC1-5) and extremely labile on the RBC intermediate sensitized sheep E coated with C components up to C5 (EAC1-5). We examined the possibility that molecular changes of membrane-bound C5 might be responsible for the different functional behavior of the two intermediates using mAb to C5 and sensitive immunoassays to detect bound C5. The decay of EAC1-5 over 30 min of incubation at 37 degrees C was associated with a significant drop in the reactivity of bound C5 with three of four mAb used. These results contrasted with those obtained with BAC1-5, which showed unchanged reactivity with all mAb tested over the same period of incubation. The effect of mAb on the activity of C5 was then investigated in an attempt to relate the change of the reactivity pattern of EAC1-5 with the functional modification of bound C5. MAb 1.5 and 1.6 were the only antibodies that interfered with the functional activity of C5, although through a different mechanism. In particular, mAb 1.5 was active both on fluid-phase and on membrane-bound C5 and is therefore likely to interact with the binding site for the late components on C5. Conversely, mAb 1.6 was only effective on fluid-phase C5 and acted by promoting a decay of BAC1-5 similar to the spontaneous decay of EAC1-5. We suggest that the bacterial outer membrane may protect C5 from functional decay and that mAb 1.6 interferes with the stabilizing effect of the bacteria in an as yet unclear manner.     

Effects of Mitomycin C on Macromolecular Synthesis in Escherichia coli

When cells of Escherichia coli B growing in a glucose-synthetic medium were treated with mitomycin C, the effects produced by the antibiotic varied, depending on the concentration. When the concentration was reduced to less than 0.1 mug/ml, the action of the antibiotic was bacteriostatic; cell elongation resulted, but no effect on the synthesis of cellular macromolecules was apparent. At higher levels (more than 5 mug/ml), mitomycin C was highly bactericidal and inhibited deoxyribonucleic acid synthesis almost completely. The exposure of growing cells to a bactericidal level of mitomycin C resulted also in a delayed inhibition of the synthesis of ribonucleic acid (RNA) and protein. The capacity of the treated cells to synthesize beta-galactosidase inducibly in a medium free from a carbon source remained constant for the first 30 min and then was destroyed progressively with time. Prolonged incubation with the bactericidal level of mitomycin C caused a degradation of cellular nucleic acids, particularly RNA. The degraded nucleic acid components were eventually released into the medium.     

Photobiological behaviour of bacteria and phages supplemented with aza-analogoues of nucleic acid bases.

The photochemical stability of anomalous nucleic acid bases of the azatype, 5-azacytosine (I), 5-azacytidine (II), 6-azacytosine (III), 6-azacytidine (IV), 6-azathymine (V), 6-azauracil (VI), and 8-aza-adenine (VII) to U. V. light of the wavelength 254 nm differs from the U. V. stability of the normal constituents. Changes of the U.V. inactivation of Escherichia coli K12 C600, E. coli B, Bacillus cereus, as well as E. coli phages gamma cb2 and gamma b2b5 supplemented with azaderivatives prior to irradiation were investigated. It was found that I, II, III, IV, and VII are more, V and VI less sensitive to U. V. light compared with corresponding natural nucleic acid bases. Their changed U. V. sensitivities are reflected in the survival curves after U. V. -irradiation in as far as azabases are incorporated into the nucleic acids in vivo. This explains the increase in U.V. sensitivity of E. coli K12 C600, E. coli B, and B. cereus supplemented with I, II, III, IV, and VII and the decrease in U.V. sensitivity of Streptococcus faecalis supplemented with V (the latter information was taken from Gunther and Prusoff 1967). The lack of any significant influence on inactivation curves of E. coli K12 C600 by V and VI, and on E. coli phages gamma cb2 and gamma c2b5 by II, is discussed in terms of too small incorporation rates. No discrimination was put forward with respect to DNA and RNA incorporation.     

Effect of cyclic adenosine-3', 5'-monophosphate on cells of experimental lympholeukemia L-5178]

A study was made of the effect of cyclic adenosine-3',5'-monophosphate (cAMP) dibutyril-cAMP and theophylline (phosphoesterase inhibitor - an enzyme transforming adenosine-3'-5'-monophosphate into adenosine-5'-monophosphate) on the intensity of proliferation (by the increase in the content of nucleic acids in the culture), DNA synthesis (by the H3-thymidine incorporation) and on the transplantation properties (the capacity to repopulation in the animal organism) of leukemic cells of the L-5178 strain. It was found that cAMP in a concentration of 0.8 mM considerably inhibited the H3-thymidine incorporation, retarded the proliferation and decreased the transplantation capacity of leukemic cells. Theophylline and dibutyril-cAMP had a comparatively low inhibitory capacity on the DNA synthesis, proliferative activity and the transplantation properties of the cells.     

Effect of sulfochloranthine on protein and nucleic acid biosynthesis in Escherichia coli

Sulfochloranthine was shown to be bacteriostatic for Escherichia coli B cells grown in a chemically defined medium at a concentration of 0.002%, sublethal at a concentration of 0.005%, and lethal at 0.01% (0.000312, 0.00078 and 0.00156% of active chlorine, respectively). Protein synthesis by E. coli B cells was noticeably inhibited when the concentration of the preparation was 0.002%, and stopped completely at a 0.01% concentration of the preparation. Biosynthesis of nucleic acids, in particular DNA, was inhibited to a lesser extent. The bacteriostatic concentration of the preparation had virtually no effect on DNA biosynthesis, but inhibited RNA biosynthesis by 50%. Sulfochloranthine used at sublethal doses inhibited synthesis of both DNA and RNA by 75%; DNA and RNA biosynthesis ceased at the lethal concentration of the preparation.     

RELATIONSHIP BETWEEN RNA SYNTHESIS, CELL DIVISION, AND MORPHOLOGY OF MAMMALIAN CELLS : I. Puromycin Aminonucleoside As An Inhibitor of RNA Synthesis and Division in HeLa Cells

Logarithmically growing HeLa cell monolayers were treated with a range of concentrations of puromycin aminonucleoside (AMS). The effects of AMS were studied by the following means: microscope examination of treated cells; enumeration of the cell number using an electronic particle counter; analyses for DNA, RNA, and protein content; incorporation of P³² and H³-thymidine into nucleic acids; and fractionation of nucleic acids by column chromatography. Taking the rate of incorporation of the isotopic precursor as a measure of nucleic acid synthesis, it was found that concentrations of the inhibitor which had a rapid effect on the rate of cell division inhibited the synthesis of all types of nucleic acids and of protein, but depressed ribosomal RNA synthesis most markedly. Lower concentrations of AMS selectively inhibited ribosomal RNA and, to a lesser extent, transfer RNA synthesis. Partial inhibition of ribosomal RNA synthesis with low doses had no effect on the rate of cell division within the period studied (3 generation times). The cell content of RNA returned to normal when the inhibitor was removed.     

In vitro synthesis of colominic acid by membrane-bound sialyltransferase of Escherichia coli K-235. Kinetic properties of this enzyme and inhibition by CMP and other cytidine nucleotides

The membrane-bound sialyltransferase obtained from Escherichia coli K-235 grown in a chemically defined medium (ideal for colominic acid production) was studied. The in vivo half-life calculated for this enzyme was 20 h. Kinetic tests revealed (at 33 degrees C and pH 8.3) hyperbolic behaviour with respect to CMP-Neu5Ac (Km250 microM) and a transition temperature at 31.3 degrees C. The enzyme was inhibited by NH4+, some divalent cations and by several agents that react with thiol groups. Detergents and fatty acids also inhibited the sialyltransferase activity. In vitro synthesis of colominic acid is strongly inhibited by CMP by blocking the incorporation of [14C]Neu5Ac into a protein-complex intermediate and therefore into free polymer. CDP and CTP also inhibited (91% and 84%) this enzyme activity whereas cytosine and cytidine had no effect. CMP inhibition corresponded to a competitive model the calculated Ki was 30 microM. Incubations of protein[14C]Neu5Ac with CMP, CDP and CTP led to de novo synthesis of CMP-[14C]Neu5Ac. The presence of colominic acid, which usually displaces the reaction equilibrium towards polymer synthesis, did not affect this de novo CMP-[14C]Neu5Ac formation. CMP also inhibited in vivo colominic acid biosynthesis.     

The interaction of bisulfite and its free radical analog-nitroxyldisulfonate with periodic acid-oxidized lymphocytes and their effect on blastogenesis

Nitroxyldisulfonate [Fremy's salt; (KSO3)2NO.] and bisulfite (NaHSO3) have abolished periodic acid (H5IO6)-induced blastogenesis of human peripheral blood lymphocytes (HPBL), but only inhibited the blastogenic response of H5IO6-oxidized rat and mouse lymphocytes, as determined by the rates of nucleic acids synthesis, BrdUrd incorporation and by cell numbers in S + G2 + M phases of the cell cycle. The viability of the intact human, rat and mouse lymphocytes remained essentially unimpaired by 30 min pulses of 1 mM Fremy's salt or bisulfite. The marked inhibition of periodic acid-induced blastogenesis, exerted by Fremy's salt and by bisulfite, was attributed to the effect of the corresponding carbonyl addition derivatives formed in situ of the oxidized cell membranes. Consequently, it is concluded that Fremy's salt like bisulfite possibly forms addition derivatives with membrane carbonyls of viable target cells.     

Effect of inhibitors on the viability and protein and nucleic acid synthesis of Escherichia coli

The object of this work was to study how the synthesis of protein, RNA and DNA in Escherichia coli M17 and its viability were influenced by chloramphenicol (50 and 300 micrograms/ml) an inhibitor of protein biosynthesis, and sodium azide (200 and 2000 microM) and aminazine (50 micrograms/ml), inhibitors of respiration. The exposed were inhibitors with the bacteria for 60 min at room temperature and for 1-4 months at -10 degrees C. The inhibition of the E. coli viability by chloramphenicol was shown to be reversible. The respiration inhibitors stabilized its viability upon storage at -10 degrees C for one month. The inhibitors were found to produce a different effect on the synthesis of RNA and protein in E. coli. The rates of DNA synthesis hardly changed. No correlation was established between changes in the synthesis of protein and nucleic acids by E. coli after the action of the inhibitors and its viability.