Cell division and the production of cells lacking nuclear bodies in a mutant of Salmonella typhimurium

Summary There are two distinct division phases when the temperature-sensitive DNA synthesis initiation mutant Salmonella typhimurium strain 11G is shifted from 25° to 38°. The first phase appears to represent segregation of the nuclear bodies formed at 38°. Division in this phase takes place at the normal size and produces mainly organisms with one nuclear body. It is dependent on the termination of the rounds of replication in operation at the time of the temperature shift and sensitive to low doses of penicillin. This division phase continues for 60–75 min and then after a short lag division restarts. At first the cells undergoing the second division phase are only slightly larger than normal but they soon grow into short filaments which bud off cells at both ends even if only one nuclear body is present. The cells budded off in this division phase are about 3 long on both broth and M M. They lack nuclear bodies but have a small amount of DNA which may be exclusively in the form of a large plasmid. This second division phase is also dependent on rounds of replication being allowed to terminate at 38° and is sensitive to low levels of penicillin. It is 80–90 min after the temperature shift before the second division phase starts and this lag is maintained even if rounds of replication have been completed prior to the temperature shift by amino acid starvation at 25°. The occurrence of this lag and the demonstration (using penicillin) of potential division sites at regular intervals along 11G filaments suggest that division is initiated some time before the actual division event.     

Alteration of the rate of cell division independent of the rate of DNA synthesis in a mutant of Salmonella typhimurium

Summary Salmonella typhimurium strain IIG has a temperature—sensitive DNA synthesis initiation apparatus and completes rounds of DNA replication when shifted to 38°. At this temperature there is a period of apparently normal division followed by a second phase in which DNA-less cells are produced. The rate of division in this second phase can be markedly increased if a culture growing in MM is shifted to nutrient broth at the time of the temperature shift. The extra divisions induced by the nutritional shift are not due to extra replication forks being introduced by this process nor to the rapid growth of ts ⁺ revertants. It is concluded that in this strain at 38°, the rate of division can be increased without altering the rate of DNA synthesis. The extra divisions induced by the shift-up do not take place for about 90 min. The possible occurrence of such a period between the triggering of division and the division event in normal cells is discussed.     

Deoxyribonucleic acid replication time in Mycobacterium tuberculosis H37 Rv

The DNA increment method, designed for measuring the increment in the amount of DNA after inhibition of initiation of fresh rounds of replication initiation was employed to measure the rate of deoxyribonucleic acid (DNA) chain growth in Mycobacterium tuberculosis H37Rv growing in Youman and Karlson's medium at 37°C with a generation time of 24 h and also in relatively fast growing species like Mycobacterium smegmatis and Escherichia coli. From the results obtained, the time required for a DNA replication fork to traverse the chromosome from origin to terminus (C period) was calculated. The chain elongation rates of DNA of the three organisms was determined from the C period and the known genome sizes assuming that all these genomes have a single replication origin and bidirectional replication fork. The rate for M. tuberculosis was 3,200 nucleotides per min about 11 times slower than that of M. smegmatis and about 13–18 times slower than that of E. coli.Abbreviations DNA deoxyribonucleic acid - td delay in initiation - OD optical density - CAM chloramphenicol - RIF rifampicin     

Studies on the alteration of chromosome copy number and cell division potential in a dnaA mutant of Escherichia coli

Summary The dnaA167 mutant of Escherichia coli, N167, maintains, on the average, two replicating chromosomes per cell at the perimissive growth temperature of 30°C and only one per cell at the higher permissive growth temperature of 38°C. When the growth temperature of this mutant is changed from 30° to 38°C the cells rapidly readjust their chromosome copy number from two to one. I have examined the kinetics of this transition with reference to DNA replication and cell division. My results indicate that this mutant uncouples cell division from chromosome duplication to achieve the appropriate copy number, suggesting that the dnaA gene product may be involved in the coordination between these two cellular events.     

Temperature sensitive initiation of DNA synthesis in a mutant of Salmonella typhimurium

Summary A mutant (dna-1) of Salmonella typhimurium defective in DNA synthesis is described. DNA synthesis is stopped in this mutant at 42° after a residual synthesis amounting to about 50 to 60% of the total cellular DNA in minimal medium and about 120 to 200% in a medium enriched with amino acids. Reshift back to permissive temperature after the inhibition of DNA synthesis at 42° allows for recovery of DNA synthesis after a lag of about 30 min. Protein synthesis is required during that lag for the recovery of DNA synthesis at permissive temperature. The density transfer experiments indicate that in the mutant dna-1 chromosome termini are replicated normally at 42° while the initiation of new rounds of replication is inhibited although the mutation is probably leaky at this temperature. The mutant is hypersensitive to sodium deoxycholate at 42° which suggests alteration of the membrane structure.     

On the termination of the DNA replication cycle in Escherichia coli.

The initiation of the DNA replication cycle in Escherichia coli requires protein synthesis. Marunouchi &; Messer (1973) have hypothesized that an additional protein synthesis step is required for the replication of the terminal segment of the chromosome, and that replication of this segment is a prerequisite for subsequent cell division. We have not confirmed the existence of a unique terminal segment using a protocol designed to label the hypothesized segment with [³H]dThd². Our protocol avoids the increased incorporation of [³H]dThd into DNA caused by abrupt increases in temperature, a complication implicit in the technique of Marunouchi &; Messer (1973).Treatment with nalidixic acid (an inhibitor of semiconservative DNA synthesis) in sufficient concentration to prevent replication of the postulated terminal segment prevents cell division but also causes loss of viability. This makes it difficult to correlate the effect of nalidixic acid on cell division with DNA synthesis inhibition alone.     

Initiation of chromosome replication in Escherichia coli. I. Requirements for RNA and protein synthesis at different growth rates

The effects of inhibition of protein and RNA synthesis on initiation of chromosome replication in Escherichia coli$\text{B}\text{r}$ were determined by measuring rates of DNA synthesis during the division cycle before and after addition of chloramphenicol and rifampicin. The ability of cells to initiate a round of replication depended upon the pattern of chromosome replication during the division cycle. Initiation in the presence of chloramphenicol (200 μ/ml) and rifampicin (100 gmg/ml) was observed only in slowly growing cells which normally initiated a new round between the end of the previous round and the subsequent division (i.e. in the D period of the division cycle). The cells that initiated were in the D period at the time of addition of the drugs. Rapidly growing cells which normally initiated before the D period and slowly growing cells which normally initiated after the D period did not initiate in the presence of the drugs. The contrasting effects of the drugs in cells possessing different chromosome replication patterns, and the coupling between septum-crosswall formation (the D period) and initiation suggest that the timing of initiation of chromosome replication in E. coli is controlled by the cell envelope.     

Characterization of a combined DNA initiation and cell division mutant of Bacillus subtilis.

Summary The temperature-sensitive mutation in Bacillus subtilis 168-134ts, a conditional lethal DNA initiation mutant, was transferred to the minicell producing strain, CU 403 div IV-B1, to study he relationship of DNA synthesis to cell division. Markers in the combined mutant were verified by transduction. DNA replication kinetics, genome location by autoradiography, and clonal analysis of cell division patterns during spore outgrowths were investigated. Growth of the double mutant at the restrictive temperature results in an impressive reduction of the percentage cell length covered by DNA grain clusters (60.2% at 30° C compared to 8.6% after 2 h at 45° C). The probability of a minicell producing division in double mutant clones is essentially the same at 30° C and during the initial 2–3 h growth at 45° C at which time lysis begins. Residual division at 45° C is attributable to processes initiated at 30° C. The CU 403 div IV-B1, 134ts, double mutant divides about 25% as frequently relative to growth as do wild type CU 403 clones when incubated at permissive temperature. This is approximately 15% greater division suppression than previously found in the CU 403 div IV-B1 mutant strain, and is presumably due to interactions of the mutant gene products both of which affect DNA.     

Replication and maturation of phage P22 in a mutant of Salmonella typhimurium temperature sensitive in initiation of DNA replication.

Summary TB37 is a dna A-mutant of Salmonella typhimurium in which the initiation of DNA replication at the origin is stopped at 42°C. DNA synthesis in uninfected cells of this strain and in cells infected by phage P22 was followed by the pulse labelling technique. DNA replication ceases completely after about 50 minutes at the high temperature. After lytic infection with P22 (c2) at this time, DNA synthesis starts immediately and increases at a rate well comparable to the permissive control. Obviously the temperature sensitive function of the dnaA-product is dispensable for P22 DNA replication, especially for its initiation. This result is confirmed by the normal yield of phage particles under these conditions, provided that a late step in P22 maturation which naturally is temperature sensitive can proceed at low temperature. If TB37 is infected at 42°C with P22 wild type, an unexpected high rate of phage controlled DNA synthesis is observed. Preliminary results seem to indicate that the process of integration is a prerequisite for part of this synthesis.     

Participation of the intracellular enzymes in the control of the mutation process

Summary The influence of repair and replication on the frequency of spontaneous chromosome aberrations and of those induced by gamma-irradiation is reported.Using the technique of labelling DNA with radioactive ³H-thymidine and measuring the radioactivity of DNA isolated from embryos, the time of initiation and the duration of DNA synthesis in barley seeds was studied after the soaking of the seeds had begun. The average duration of each phase of the first DNA synthesis cycle in soaking barley seeds was found to be as follows: pre-DNA synthesis stage, 10–11 hrs; DNA synthesis stage, 8 hrs. After gamma-irradiation, the intensity of DNA synthesis decreased and the beginning of DNA synthesis was delayed.It was found that the inhibition of repair by caffeine led to an increase in the frequency of both spontaneous and induced chromosome aberrations. Caffeine enhanced several times the frequency of chromosome and chromatid aberrations at the time of the maximal activity of repair enzymes. During DNA replication, caffeine had a lower effect on the realization of premutational lesions.An inhibitor of DNA replication — hydroxyurea — had no influence on the frequency of spontaneous chromosome aberrations during the replication period, whereas after gamma-irradiation, hydroxyurea enhanced the frequency of aberrations mainly at the stage of DNA replication.The relatively small mutagenic action of both agents (caffeine and hydroxyurea) was observed during all stages of the cell cycle of germinating barley seeds.     

Suppressor mutations (rin) that specifically suppress the recA+ dependence of stable DNA replication in Escherichia coli K-12

Summary The sdrA102 mutation confers upon cells the ability to replicate DNA in the absence of protein synthesis. This mutation was combined with the recA200 mutation, which renders the recA protein thermolabile, and had little effect on normal replication. However, the sdrA102 recA200 double mutant exhibited temperature-sensitive stable DNA replication: it replicated DNA continuously in the presence of chloramphenicol at 30°C, whereas at 42°C DNA replication ceased after the DNA content increased only 40–45%. Suppressor mutants (rin; recA-independent) capable of stable DNA replication at 42°C were isolated from the double mutant. The suppressor mutant retained all other recA ^– characteristics, i.e., deficient general recombination, severe UV-sensitivity, and incapability of prophage induction in lysogens. This indicates that the rin mutation specifically suppresses the recA ⁺ dependency of stable DNA replication. It is suggested that the recA ⁺ protein stabilizes a specific structure, similar to an intermediate in recombination, which may function in the initiation of stable DNA replication.     

Temperature-sensitive initiation of DNA replication in a mutant of Escherichia coli K12

Summary A mutant of E. coli K12 appears to be temperature-sensitive in the process of initiation of DNA replication. After a temperature shift from 33 to 42°C, the amount of residual DNA synthesis (Fig. 1) and the number of residual cell divisions (Figs. 2,4) indicate that rounds of DNA replication in process are completed, but new rounds cannot be initiated. Following the alignment of chromosomal DNA by amino acid starvation at 33° C no residual DNA synthesis at 42°C takes place (Fig. 5). When the temperature is lowered to 33°C after a period of inhibition at 42°C, the following observations are made: 1. DNA replication resumes and proceeds synchroneously, (Figs. 7, 8a), 2. cells start to divide again only after a lag period of about 1 hour 3. a temporary increase in cell volume is correlated with the frequency of initiation of DNA synthesis (Fig. 8a, b). In a lysogenic mutant strain prophage is inducible; with all bacteriophages tested, replication of phage DNA is not inhibited at 42°C.     

Imparired DNA synthesis and envelope defect in a mutant of Salmonella typhimurium

Summary S. typhimurium mutants with temperature-sensitive synthesis of DNA have been isolated. One of these mutants,dna-26, has been studied in detail. DNA synthesis is stopped indna-26 without any residual replication after shift to 42° though increase in cell mass is not inhibited. Mutantdna-26 shows increased sensitivity to deoxycholate, to nalidixic acid and rifampicin. This suggests a cell envelope defect. Inhibition of DNA synthesis at 42° can be phenotypically cured indna-26 by 0.25 M NaCl and KCl and 0.44 M sucrose but not by 0.44 M glycerol. This DNA synthesis induced by hypertonic medium proceeds at a slower rate than increase in cell mass but is predominantly due to normal sequential chromosome replication. The position of mutationdna-26 has been approximately mapped in thepurD region of the chromosome.     

Replication of the F''lac sex factor in the cell cycle of Escherichia coli

Summary The timing of replication of an F'lac during the cell cycle of Escherichia coli B/r has been investigated at different growth rates to clarify the relationship of F factor replication to cell division and the replication of the bacterial chromosome.Cells of a lacZ — strain carrying an F'lac were separated according to their ages in an exponentially growing population after the culture was pulse labelled with a radioactive precursor of DNA and pulse induced for the synthesis of -galactosidase. The amount of label incorporated at different cell ages reflects the state of replication of the bacteriial chromosome, while the amount of enzyme synthesized in response to a short period of induction is assumed to reflect the state of replication of the F'lac.The F'lac replicates at a time somewhat more than half way through the cell cycle at all growth rates investigated. This time is clearly distinguishable from the time of initiation of chromosomal replication at some of the growth rates studied, implying the existence of at least some different control elements in the replication of these two replicons.The regulation of F'lac replication has been further studied by following F'lac replication in temperature sensitive mutants, which are defective in the initiation of chromosomal replication at elevated temperatures.     

The cell cycle in Escherichia coli B/r

Cell division and DNA synthesis were measured in synchronous cultures of E. coll B/r growing in glucose minimal medium at 37 °. The kinetic curves were analysed in order to find the variability of replication initiation, termination, and cell division events during the cell cycle. It is inferred that under the conditions used, cells begin to divide 17 min (D₀ = minimum D-period) after each termination of chromosome replication with a constant probability per unit of time (half-life = 4·5–6 min). This randomness produces an asymmetric frequency distribution of D-periods, similar but mirror-symmetric frequency distributions of initiation and termination periods, a symmetric, non-Gaussian distribution of interdivision intervals, and complex kinetic changes in the rate of DNA synthesis as a function of cell age. The results suggest that replication and division are precisely controlled with respect to mass accumulation, and the apparent variability of cell cycle events would only result from the use of the time of cell separation as a reference point for the definition of cell age rather than initiation or termination of replication.     

DNA synthesis in Lactobacillus acidophilus in the absence of RNA and protein synthesis: a study with rifampicin

Summary Synthesis of DNA in Lactobacillus acidophilus R-26 was investigated in the presence of rifampicin which inhibits RNA and protein synthesis. Increments in DNA of between 140 and 200% were found under these conditions. Indirect evidence is presented that these large increments are not due to the presence of several replication points in the bacterial chromosome at the time of addition of the drug. Incubation with rifampicin was found to result in a progressive decrease in the capacity for DNA synthesis. This decrease was independent of the amount of DNA synthesized during incubation with rifampicin but was dependent on the time of incubation in the presence of the drug. It is proposed that inhibition of protein and RNA synthesis in L. acidophilus does not inhibit initiation of new cycles of chromosome replication but results in a progressive loss of the capacity to replicate DNA.     

Initiation of DNA replication in Bacillus subtilis. IV. The effect of an intercalating dye, ethidium bromide

Summary The effects of an intercalating dye, ethidium bromide (EtBr), on the initiation of chromosome replication in Bacillus subtilis were studied. Spores of a thymine requiring mutant acquired the ability to initiate one round of replication in the absence of RNA and protein synthesis (initiation potential) during germination in a thymine starved medium. When EtBr was added after the initiation potential was fully established, initiation of replication was completely inhibited. This inhibition was reversible, and initiation was resumed when the drug was removed. The recovery of initiation occurred in the absence of protein synthesis but did require RNA synthesis and an active dna gene product.During germination both a DNA-protein complex and a DNA-membrane complex were formed at the replication origin in parallel with the establishment of initiation potential. EtBr destroyed both of these complexes at the concentration which inhibited initiation.The first round of replication of a plasmid DNA, pSL103, during spore germination was also prevented by EtBr. However a higher concentration was required to inhibit plasmid replication. It was found that the plasmid formed two complexes identical to the S- and M-complex of the chromosome origin. Compared to the chromosome complexes the plasmid complexes were less sensitive to EtBr. The loss of sensitivity was equivalent to that for the initiation of the plasmid compared to the chromosome. These results indicate that the target of EtBr is the DNA in the S- and M-complexes whose conformation is essential for the initiation of chromosome and plasmid replication.III of this series is Murakami et al. 1976     

Strand-specific DNA degradation in a mutant of Escherichia coli

Summary A dna B mutant of Escherichia coli which is thermosensitive for DNA synthesis at 42° C degrades DNA at the restrictive temperature. The degradation specifically affects newly synthesized DNA, begins at the replication forks and proceeds toward the replication origin, and is limited to 10–15% of one chromosome. The parameters of DNA degradation, as well as DNA-DNA annealing experiments on newly synthesized DNA which is resistant to degradation, indicate a specific strand of newly synthesized DNA is degraded.     

Initiation of chromosomal DNA replication which is stimulated without oversupply of DnaA protein in Escherichia coli

Summary The temperature-sensitive dnaA46 mutation in Escherichia coli can be phenotypically suppressed at 42° C by oversupply of GroELS proteins, and the suppressed cells grow extremely slowly at 30° C. We found that the phenotype of dnaA46 showing this cold sensitivity was dominant over the phenotype of dnaA ⁺, and could not be rescued by introduction of oriC-independent replication systems. These results suggest that the cold sensitivity was not caused by a simple defect in replication. When a growing culture of a dnaA46 strain with a GroELS-overproducing plasmid was shifted from 42° to 30° C in the presence of chloramphenicol, the chromosomal DNA replicated excessively. Initiation of replication occurred at the site of oriC repeatedly four or five times during a 4 h incubation period without concomitant protein synthesis, indicating an excessive capacity for initiation. Such overreplication did not take place at 42° C in the suppressed dnaA46 strain, or at either temperature in GroELS-oversupplied dnaA ⁺ cells. No significant difference was detected between the cellular content of DnaA protein in suppressed cells where the initiation capacity was abnormally high, and that in wild-type cells in which the initiation capacity was normal. Thus, DnaA protein might function in vivo through some phase control mechanism for initiation, apart from a simple regulation by its total amount. A possible mechanism is proposed based on the participation of GroELS proteins in protein folding.A preliminary account of this work was presented at the Annual Meeting of the Molecular Biology Society of Japan in 1989.