Replication of Deoxyribonucleic Acid in Escherichia coli C Mutants Temperature Sensitive in the Initiation of Chromosome Replication

An Escherichia coli HF4704S mutant temperature sensitive in deoxyribonucleic acid (DNA) synthesis and different from any previously characterized mutant was isolated. The mutated gene in this strain was designated dnaH. The mutant could grow normally at 27 C but not at 43 C, and DNA synthesis continued for an hour at a decreasing rate and then ceased. After temperature shift-up, the increased amount of DNA was 40 to 50%. When the culture was incubated at 43 C for 70 min and then transferred to 27 C, DNA synthesis resumed after about 50 min, initiating synchronously at a fixed region on the bacterial chromosome. The initiation step in DNA replication sensitive to 30 mug of chloramphenicol per ml occurs synchronously before the resumption of DNA replication after the temperature shift-down, being completed about 30 min before the start of DNA replication. When the cells incubated at 27 C in the presence of 30 mug of chloramphenicol per ml after the temperature shift-down to 27 C were transferred to 43 C with simultaneous removal of the antibiotic, no resumption of DNA replication was observed. When the culture was returned to 43 C after being released from high-temperature inhibition at 30 min before the start of DNA replication, no recovery replication was observed; whereas at 20 min, the recovery of replication was observed. These results indicated that HF4704S was temperature sensitive in the initiation of DNA replication. Analysis of HF4704S, by an interrupted conjugation experiment, indicated that gene dnaH was located at about 64 min on the E. coli C linkage map. In E. coli S1814 (a K-12 derivative), which was a dnaH(ts) transductant from HF4704S (C strain) with phage P1, the mutated gene (dnaH) was demonstrated to be closely linked to the thyA marker by conjugation and P1 transduction experiments and to be distinct from genes dnaA through dnaG.     

Residual Thymidine Incorporation in the Presence of Chloramphenicol in Synchronous Cultures of Escherichia coli B/r

Escherichia coli B/r ATCC 12407 which grew synchronously with interdivision times of 45 and 85 min were exposed at intervals to chloramphenicol (200 mug/ml) and [(14)C]thymidine for short or long (residual) periods. The results suggested that the pattern of residual thymidine incorporation in 85-min cells yielded an estimate of the length of the D period rather than the time of initiation of chromosome replication.     

Temporal sequence of events during the initiation process in Escherichia coli deoxyribonucleic acid replication: roles of the dnaA and dnaC gene products and ribonucleic acid polymerase.

Three thermosensitive deoxyribonucleic acid (DNA) initiation mutants of Escherichia coli exposed to the restrictive temperature for one to two generations were examined for the ability to reinitiate DNA replication after returning to the permissive temperature in the presence of rifampin, chloramphenicol, or nalidixic acid. Reinitiation in the dnaA mutant was inhibited by rifampin but not by chloramphenicol, whereas renitiation was not inhibited by rifampin but not by chloramphenicol, whereas reinitiation was not inhibited in two dnaC mutants by either rifampin or chloramphenicol. To observe the rifampin inhibition, the antibiotic must be added at least 10 min before return to the permissive temperature. The rifampin inhibition of reinitiation was not observed when a rifampin-resistant ribonucleic acid ((RNA) polymerase gene was introduced into the dnaA mutant, demonstrating that RNA polymerase synthesizes one or more RNA species required for the initation of DNA replication (origin-RNA). Reinitiation at 30 degrees C was not inhibited by streptolydigin in a stretolydigin-sensitive dnaA muntant. Incubation in the presence of nalidixic acid prevented subsequent reinitiation in the dnaC28 mutant but did not inhibit reinitiation in the dnaA5 muntant. These results demonstrate that the dnaA gene product acts before or during the synthesis of an origin-RNA, RNA polymerase synthesizes this origin RNA, and the dnaC gene product is involved in a step after this RNA synthesis event. Furthermore, these results suggest that the dnaC gene product is involved in the first deoxyribounucleotide polymerization event wheareas the dnaA gene product acts prior to this event. A model is presented describing the temporal sequence of events that occur during initiation of a round of DNA replication, based on results in this and the accompanying paper.     

Use of Miracil D to Suppress Bacterial Ribonucleic Acid and Protein Synthesis During Bacteriophage MS2 Infection

Under certain culture conditions, Miracil (35 mug/ml) halts the growth of uninfected Escherichia coli. Cellular ribonucleic acid (RNA) synthesis is almost completely suppressed, whereas deoxyribonucleic acid and protein synthesis are inhibited to a lesser extent. When the drug is added to host bacteria prior to infection with bacteriophage MS2, the phage adsorb to the cells, but penetration of the viral RNA is inhibited. Penetration may be achieved without further viral development by infection in the presence of chloramphenicol. If the bacteria are infected with MS2 in the presence of chloramphenicol, subsequently washed to remove the chloramphenicol, and then treated with Miracil at any time between 0 and 20 min postinfection, a second viral function is inhibited and the yield of progeny phage is reduced. Addition of the drug after 20 min postinfection does not inhibit the infection process. When Miracil is present from early times in infection, only a limited synthesis of both double- and single-stranded virus-specific RNA is observed. The viral RNA species thus produced do not appear to differ from those made in the absence of the drug. A comparison of the activities of the viral RNA synthetase produced during the course of infection in the presence and in the absence of Miracil suggests that a possible cause of the inhibition is the synthesis of an unstable enzyme in the presence of the drug.     

Derepression of anthranilate synthase in purified minicells of Escherichia coli containing the Col-trp plasmid

Purified minicells of Escherichia coli K-12 containing the plasmid Col-trp(+) or Col-trpA2 could be derepressed for the synthesis of anthranilate synthase, the first enzyme encoded in the trp operon. Non-plasmid-containing, deoxyribonucleic acid-deficient minicells could not be derepressed. Derepressed enzyme synthesis was initiated by l-tryptophan starvation. The kinetics of derepression were studied with minicells containing the Col-trpA2 plasmid. The derepression curves were biphasic with a rapid initial rate of enzyme synthesis followed by a slower rate of synthesis. The presence of l-tryptophan (20 to 50 mug/ml) or chloramphenicol (200 mug/ml) abolished enzyme synthesis. The presence of rifamycin SV (280 mug/ml) partially inhibited enzyme synthesis after at least 3.5 min of exposure. The ratio of minicell-to-cell synthetic capacity was 1:2.4 when compared on the basis of derepressed enzyme activity per unit cell volume. This work demonstrates that plasmid-containing minicells are capable of considerable functional protein and messenger ribonucleic acid synthesis and that the regulation of at least the trp operon is similar in minicells to that observed in cells.     

Mode of initiation of constitutive stable DNA replication in RNase H-defective mutants of Escherichia coli K-12.

The alternative pathway of DNA replication in rnh mutants of Escherichia coli can be continuously initiated in the presence of chloramphenicol, giving rise to constitutive stable DNA replication (cSDR). We conducted a physiological analysis of cSDR in rnh-224 mutants in the presence or absence of the normal DNA replication system. The following results were obtained. cSDR allowed the cells to grow in the absence of the normal replication system at a 30 to 40% reduced growth rate and with an approximately twofold-decreased DNA content. cSDR initiation was random with respect to time in the cell cycle as well as choice of origins. cSDR initiation continued to increase exponentially for more than one doubling time when protein synthesis was inhibited by chloramphenicol. cSDR initiation was inhibited during amino acid starvation in stringent (relA+) but not in relaxed (relA1) strains, indicating its sensitivity to ppGpp. cSDR initiation was rifampin sensitive, demonstrating that RNA polymerase was involved. cSDR functioned in dnaA+ rnh-224 strains parallel to the normal oriC+ dnaA+-dependent chromosome replication system.     

Initiation and Termination of Bacterial Deoxyribonucleic Acid Replication in Low Concentrations of Chloramphenicol

Escherichia coli 15T(-) can initiate a cycle of deoxyribonucleic acid replication with equal efficiency in the presence of 25 or 50 mug of chloramphenicol/ml. However, these replication cycles are not completed in the presence of these drug concentrations, and the amount of replication decreases with increasing drug concentration.     

Optimal Combination and Concentration of Antibiotics in Media for Isolation of Pathogenic Fungi and Nocardia asteroides

Strains of Blastomyces dermatitidis, Sporothrix schenckii, Histoplasma capsulatum, Cryptococcus neoformans, Nocardia asteroides, and Coccidioides immitis were tested for in vitro susceptibility to polymyxin, gentamicin, kanamycin, chloramphenicol, and neomycin at concentrations of 1, 2, 4, 8, and 16 mug/ml. Polymyxin was the most inhibitory and gentamicin was the least inhibitory of the five antibiotics. Two Histoplasma mycelial strains were partially inhibited by 2 and 8 mug of gentamicin per ml and showed at least a 2+ growth at the higher antibiotic concentration. Kanamycin and neomycin produced significant inhibition of N. asteroides but otherwise were noninhibitory. A combination of chloramphenicol and kanamycin, each at 16 mug/ml, and gentamicin, at 4 mug/ml, was noninhibitory to the strains tested except for N. asteroides. Chloramphenicol at 16 mug/ml was not inhibitory for N. asteroides. The results suggest that the optimal antibiotic combination to use in the isolation of fungi and higher bacteria is chloramphenicol, 16 mug/ml, and gentamicin, 4 mug/ml. Addition of sheep blood (5%) had no effect on antibiotic susceptibility of the organisms studied.     

Replication of lambda plasmid in amino acid-starved strains of Escherichia coli.

We found that lambda plasmid replication, as measured by the increase in plasmid content per bacterial mass, proceeds for hours in an amino acid-starved, relaxed mutant of Escherichia coli K-12, whereas is inhibited in its wild-type stringent partner. Replication of lambda plasmid in amino acid-starved, relaxed cells reveals absolute lambda O dependence and is not inhibited by chloramphenicol at 200 micrograms/ml. The replication also occurs in wild-type cells treated with chloramphenicol. We conclude that lambda plasmid replication is under stringent control, probably as a result of the action of ppGpp, the signal for the stringent response, on RNA polymerase.     

Deoxyribonucleic acid synthesis after inhibition of initiation of rounds of replication in Escherichia coli B/r.

The theory describing the effect of inhibition of initiation of rounds of deoxyribonucleic acid (DNA) replication on the accumulation of DNA is derived, and an analysis is presented which allows the determination of the time C taken to replicate the bacterial chromosome from the kinetic changes in the accumulation of DNA. This analysis is applied to experiments in which inhibition of initiation was achieved by inhibiting protein or protein and ribonucleic acid synthesis with chloramphenicol or rifampin. The results for both antibiotics are identical and indicate that there is a delay of 6 to 11 min in the effect of the antibiotics on initiation of rounds of replication. If this delay is taken into account, then the value of the C period estimated from such experiments agrees with values obtained by other methods, whereas by conventional data evaluation of such experiments the C period would be overestimated. In the low thymine-requiring derivative of Escherichia coli B/r ATCC 12407 used here, the C period was found to be between 38 and 41 min for cultures growing with a mass doubling time of 29 min in glucose-amino acids medium, supplemented with 20 micrograms of thymine/ml.     

Reactivation of Ribonucleic Acid and Protein Synthesis During Germination of Blastocladiella Zoospores and the Role of the Ribosomal Nuclear Cap

Freshly harvested zoospores of Blastocladiella emersonii begin to germinate about 15 min after inoculation into a defined growth medium at a density of 10(6) zoospores per ml. Flagellum retraction accompanies encystment, and dispersal of the ribosomal nuclear cap takes place shortly thereafter. The primary rhizoid begins to emerge at 25 to 30 min and starts to branch at ca. 60 min. The first nuclear division occurs between 120 and 190 min. The dry weight per cell increases linearly after 60 min, whereas the deoxyribonucleic acid per cell doubles between 120 and 240 min. A linear increase in total ribonucleic acid (RNA) is detectable beginning at 40 to 45 min, and in total protein beginning at 80 min; neither process is interrupted during nuclear division. Encystment and nuclear cap disorganization are associated with a sharp rise in the rates of precursor incorporation into RNA and protein. Cycloheximide at 20 mug/ml prevents leucine incorporation at all stages and inhibits development beyond the earliest encystment stage. Actinomycin D at 25 mug to 50 mug/ml prevents uracil incorporation, but it has no effect on leucine incorporation or development until 40 to 45 min. At the latter stage, actinomycin D causes a sharp developmental arrest and begins to inhibit leucine incorporation. It is concluded that early protein synthesis must occur on the ribosomes formed during the prior growth phase and conserved through the zoospore stage in the nuclear cap. The results further indicate that this synthesis is dependent upon messenger RNA already present in the zoospore before germination.     

Effect of Growth Conditions on the Formation of the Relaxation Complex of Supercoiled ColE1 Deoxyribonucleic Acid and Protein in Escherichia coli

Colicinogenic factor E1 (ColE1) is present in Escherichia coli strain JC411 (ColE1) cells to the extent of about 24 copies per cell. This number does not appear to vary in situations which give rise to twofold differences in the amount of chromosomal deoxyribonucleic acid (DNA) present per cell. If cells are grown in the absence of glucose, approximately 80% of the ColE1 molecules can be isolated as strand-specific DNA-protein relaxation complexes. When glucose is present in the medium, only about 30% of the plasmid molecules can be isolated as relaxation complexes. Medium shift experiments in which glucose was removed from the medium indicate that within 15 min after the shift the majority (>60%) of the plasmid can be isolated as relaxation complex. This rapid shift to the complexed state is accompanied by a two- to threefold increase in the rate of plasmid replication. The burst of replication and the shift to the complexed state are both inhibited by the presence of chloramphenicol. Inhibition of protein synthesis in log cultures by the addition of chloramphenicol or amino acid starvation allows ColE1 DNA to continue replicating long after chromosomal replication has ceased. Under these conditions, noncomplexed plasmid DNA accumulates while the amount of DNA that can be isolated in the complexed state remains constant at the level that existed prior to treatment. In the presence of chloramphenicol, there appears to be a random dissociation and association of ColE1 DNA and “relaxation protein” during or between rounds of replication.     

The Characteristics and Genetic Map Location of a Temperature Sensitive DNA Mutant of E. COLI K12

A temperature sensitive strain of E. coli K12 has been isolated in which residual DNA synthesis occurs at the 40 degrees C restrictive temperature; syntheses of RNA, protein and DNA precursors are not directly affected. The mutation has been designated dna-325 and is located at 89 min on the E. coli map in the same region where the dnaC locus is found. dnaC mutants are considered to be defective in DNA initiation. Some of the data are consistent with the view that the dna-325 mutation is temperature sensitive in the process of DNA initiation rather than DNA chain elongation: (1) more than two cell divisions occur after a shift to 40 degrees C; (2) upon a shift down to 30 degrees C, cell division occurs again only after the DNA content of the cells has doubled; (3) 80% more DNA is made at 30 degrees C in the presence of chloramphenicol after prior inhibition of DNA synthesis at 40 degrees C. These three observations indicate that rounds of DNA replication were completed at 40 degrees C. Also (4) infective lambda particles can be made at 40 degrees C long after bacterial DNA replication has ceased. It appears however that some DNA initiation can occur at 40 degrees C since (1) a limited amount of DNA synthesis does occur at 40 degrees C after prior alignment of the chromosomes by amino acid starvation at 30 degrees C, and (2) after incubation in bromouracil at the restrictive temperature, heavy DNA is found with both strands containing bromouracil.     

Control of Deoxyribonucleic Acid Synthesis in a Bacillus subtilis Mutant Temperature Sensitive for Initiation of Chromosome Replication

We used a Bacillus subtilis mutant described previously, which is temperature sensitive for initiation of replication. The inhibition of deoxyribonucleic acid synthesis occurring at 45 C was shown to be reversed when the temperature is lowered even in the absence of protein synthesis. If the bacteria are returned to 30 C, after a prior period at 45 C, they are able to initiate the first round of replication in the presence of chloramphenicol, but the initiation of the second round still requires protein synthesis. This paper shows that the proteins necessary to initiate the second round of replication can be present in bacteria long before this round is initiated. In addition, the appearance of these proteins seems to be influenced by the length of the previous 45 C period. Although similar reinitiation kinetics are observed at 30 C after prior 45 C periods of 30 or 65 min, the ability to initiate the second round without further protein synthesis appears much earlier after a longer exposure at 45 C. To explain these results, a hypothesis is presented which assumes that two different proteins are both necessary for initiation. Only one of these proteins could be accumulated at 45 C during the inhibition of deoxyribonucleic acid synthesis. A peculiarity of initiation material in mutant Ts 37 is that it may be active at 45 C if it has been exposed previously at 30 C.     

Inhibition of the Peptide Bond Synthesizing Cycle by Chloramphenicol

To study the mechanism by which chloramphenicol inhibits bacterial protein synthesis, we examined the kinetics of the puromycin-induced release of peptides from transfer ribonucleic acid (tRNA) in the presence and in the absence of chloramphenicol. Washed Escherichia coli ribosomes with nascent peptides which had been radioactively labeled in vivo were used for this study. When such ribosomes were incubated in the presence of 10 mug of puromycin per ml, approximately one-fourth of the radioactive peptide material was rapidly released from tRNA. This rapid, puromycin-dependent reaction is assumed to be equivalent to the peptidyl transferase reaction. Chloramphenicol inhibited the extent of the puromycin-induced release of peptides by only 50%, demonstrating that some of the peptide chains which are present on active ribosomes react with puromycin, even in the presence of chloramphenicol. The addition of the supernatant fraction and guanosine triphosphate (GTP) increased the extent of the puromycin-induced release; this additional release was completely inhibited by chloramphenicol. Peptidyl chains on washed ribosomes prepared from chloramphenicol-inhibited cells were not released by puromycin in the presence of chloramphenicol and reacted slowly with puromycin in the absence of chloramphenicol. The release of peptidyl groups from these ribosomes became largely insensitive to chloramphenicol after preincubation of the ribosomes with GTP and the supernatant fraction. We conclude that chloramphenicol does not inhibit the peptidyl transferase reaction as measured by the puromycin-induced release of peptides from tRNA, but rather inhibits some step in the peptide synthesis cycle prior to this reaction.     

Timing of initiation of chromosome replication in individual Escherichia coli cells.

The synchrony of initiation of chromosome replication at multiple origins within individual Escherichia coli cells was studied by a novel method. Initiation of replication was inhibited with rifampicin or chloramphenicol and after completion of ongoing rounds of replication the numbers of fully replicated chromosomes in individual cells were measured by flow cytometry. In rapidly growing cultures, with parallel replication of several chromosomes, cells will end up with 2n (n = 1, 2, 3) chromosomes if initiation occurs simultaneously at all origins. A culture with asynchronous initiation may in addition contain cells with irregular numbers (not equal to 2n) of chromosomes. The frequency of cells with irregular numbers of chromosomes is a measure of the degree of asynchrony of initiation. After inhibition of initiation and run-out of replication in rapidly growing B/r A and K-12 cultures, a small fraction of the cells (2-7%) contained 3, 5, 6 or 7 chromosomes. From these measurements it was calculated that initiation at four origins in a single cell occurred within a small fraction, 0.1, of the doubling time (tau). A dnaA(Ts) mutant strain grown at permissive temperature exhibited a very large fraction of cells with irregular numbers of chromosomes after drug treatment demonstrating virtually random timing of initiation. A similar pattern of chromosome number per cell was found after treatment of a recA strain.     

Transcription of specific genes in isolated nuclei from HeLa cells in vitro.

Isolated HeLa cell nuclei were employed to catalyze the synthesis of RNA in vitro. In the presence of low concentrations of alpha-amanitin (1 mug/ml), used to suppress the formation heterogeneous nRNA, these nuclei synthesize RNA very efficiently for extended periods of time (at least 60 min) at an elongation rate of about seven nucleotides per second. The product, analyzed on sucrose density gradients and polyacrylamide gels was found to exist of two predominant size classes. Synthesis of the 45-S ribosomal precursor was completely resistant even to high concentrations of alpha-amanitin (150 mug/ml) and hence was catalyzed by enzyme A (or I). A limited degree of processing of the 45-S precursor occurred in vitro. In addition, a second RNA class of low molecular weight (4-8 S) was synthesized by HeLa cell nuclei in the presence of 1 mug/ml alpha-amanitin in vitro. Analysis on 8% polyacrylamide gels resolved the RNA into four distinct components. Their synthesis was resistant to low (1 mug/ml) but clearly sensitive to high (150 mug/ml) concentrations of alpha-amanitin. Consequently the synthesis of all these small-molecular-weight RNA species is catalyzed by RNA polymerase C (or III). For the assessment of the initiation frequency of the individual classes of RNA, a new technique was developed independent of labelling the 5' end of the RNA molecule with the gamma-phosphate of the initiating nucleotide. It employs the double labelling of an RNA molecule with two different isotopes added sequentially at different stages of completion of the chain. From the incorporation ratio of the two isotopes into a particular class of RNA, conclusions can be drawn concerning their initiation frequency. The results obtained have shown a high reinitiation frequency for the small-molecular-weight RNA species at all stages of the incubation reaction. In contrast, reinitiation of the 45-S precursor RNA occurs only to a limited extent in isolated HeLa cell nuclei in vitro.     

Physiological and biochemical effects of the mycotoxin patulin on Chang liver cell cultures.

Patulin exhibits both cytotoxic and cytopathic effects on cultured Chang liver cells. The LD50 found was 1.85 mug per ml of patulin. Effects on growth were observed with as little as 0.1 mug per ml of patulin; a 50% reduction in growth was observed at 0.38 mug per ml of patulin. Using a challenge dose of 2.5 mug per ml of patulin, the cytotoxic effect was reversible after an exposure of 10 min, but was not reversible after 20 min. Protein synthesis was depressed after 60 min and RNA synthesis after 20 min of contact with patulin. Neither protein nor RNA synthesis was completely inhibited after 260 min.