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     

Duplication of Escherichia coli during inhibition of net phospholipid synthesis.

In Escherichia coli BB26-36, the inhibition of net phospholipid synthesis during glycerol starvation affected cell duplication in a manner that was similar in some respects to that observed during the inhibition of protein synthesis. Ongoing rounds of chromosome replication continued, and cells in the D period divided. The initiation of new rounds of chromosome replication and division of cells in the C period were inhibited. Unlike the inhibition of protein synthesis, however, the accumulation of initiation potential in dnaA and dnaC mutants at the nonpermissive temperature was not affected by the inhibition of phospholipid synthesis. Furthermore, proteins synthesized during the inhibition of phospholipid synthesis can be utilized later for division. The results are consistent with a dual requirement for protein and phospholipid synthesis for both the inauguration of new rounds of chromosome replication and the initiation of septum formation. Once initiated, both processes progress to completion independent of continuous phospholipid and protein synthesis.     

Isolation of a dnaA mutant of Bacillus subtilis defective in initiation of replication: amount of DnaA protein determines cells'' initiation potential.

The dnaA gene is essential for initiation of chromosomal replication in Escherichia coli. A gene homologous with the E. coli dnaA was found in the replication origin region of the Bacillus subtilis chromosome. We have now isolated a temperature sensitive mutant of the B. subtilis dnaA by in vitro mutagenesis of the cloned gene. At a nonpermissive temperature, 49 degrees C, DNA replication stops completely after 60% increase in a rich medium, while cell mass continues to increase exponentially at 2.5 times the rate at 30 degrees C. A ratio of gene frequency between purA (origin marker) and metB (terminus marker) changes gradually from 2.7 at 30 degrees C to 1.0 in 45 min at 49 degrees C, indicating completion of the ongoing replication cycle. Upon the temperature shift down to 30 degrees C after the incubation at 49 degrees C for 60 min, DNA replication resumes without delay, and the purA/metB ratio increases rapidly to 6, i.e. consecutive initiation of more than two rounds of replication. Addition of chloramphenicol at the time of the temperature shift down did not inhibit the increase in the purA/metB ratio, while rifampicin inhibited the re-initiation completely. The mutation is a single base change from C to T in the dnaA gene resulting in an amino acid substitution from Ser to Phe in the DnaA protein. The mutation was responsible for both temperature sensitive growth and the defect in initiation of chromosomal replication. We observed a remarkable correlation between the amount of DnaA protein and the amount of initiation potential accumulated during incubation at the non-permissive temperature.     

Initiation and termination of deoxyribonucleic acid replication in bacteria after a stepwise increase in the velocity of replication.

The theoretical relations between replication, initiation, termination, and deoxyribonucleic acid (DNA) accumulation were derived for experiments in which the length of the time required for the replication of the bacterial chromosome (C period) can be varied. This theory enables one to determine absolute values of the C period from kinetics of DNA accumulation after a "stepup" with thymine-requiring bacteria that are subjected to a sudden increase in the exogenous thymine concentration. Application of this method of data evaluation to an observed step-up experiment with a thy-derivative of Escherichia coli B/r (ATCC 12407) indicated that the theory describes the observed post-step accumulation of DNA accurately within experimental errors. It is also concluded that changes in the replication velocity (C) do not measurably affect the timing of initiation events in a culture.     

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.     

LIMITED DNA SYNTHESIS IN THE ABSENCE OF PROTEIN SYNTHESIS IN PHYSARUM POLYCEPHALUM

Actidione (cycloheximide), an antibiotic inhibitor of protein synthesis, blocked the incorporation of leucine and lysine during the S phase of Physarum polycephalum. Actidione added during the early prophase period in which mitosis is blocked totally inhibited the initiation of DNA synthesis. Actidione treatment in late prophase, which permitted mitosis in the absence of protein synthesis, permitted initiation of a round of DNA replication making up between 20 and 30% of the unreplicated nuclear DNA. Actidione treatment during the S phase permitted a round of replication similar to the effect at the beginning of S. The DNA synthesized in the presence of actidione was replicated semiconservatively and was stable through at least the mitosis following antibiotic removal. Experiments in which fluorodeoxyuridine inhibition was followed by thymidine reversal in the presence of actidione suggest that the early rounds of DNA replication must be completed before later rounds are initiated.     

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.     

DNA replication initiation, doubling of rate of phospholipid synthesis, and cell division in Escherichia coli.

In synchronized culture of Escherichia coli, the specific arrest of phospholipid synthesis (brought about by glycerol starvation in an appropriate mutant) did not affect the rate of ongoing DNA synthesis but prevented the initiation of new rounds. The initiation block did not depend on cell age at the time of glycerol removal, which could be before, during, or after the doubling in the rate of phospholipid synthesis (DROPS) and as little as 10 min before the expected initiation. We conclude that the initiation of DNA replication is not triggered by the preceding DROPS but requires active phospholipid synthesis. Conversely, when DNA replication initiation was specifically blocked in a synchronized culture of a dnaC(Ts) mutant, two additional DROPS were observed, after which phospholipid synthesis continued at a constant rate for at least 60 min. Similarly, when DNA elongation was blocked by thymine starvation of a synchronized culture, one additional DROPS was observed, followed by linear phospholipid accumulation. Control experiments showed that specific inhibition of cell division by ampicillin, heat shock, or induction of the SOS response did not affect phospholipid synthesis, suggesting that the arrest of DROPS observed was due to the DNA replication block. The data are compatible with models in which the DROPS is triggered by an event associated with replication termination or chromosome segregation.     

Stoichiometric use of the transposase of bacteriophage Mu

The transposase of bacteriophage Mu (gene A protein) mediates the coupled replication and integration processes that constitute transposition during the lytic cycle. Our previous results showed that the activity of the A protein is unstable, as its continued synthesis is required to maintain Mu DNA replication throughout the lytic cycle. We present here the results of experiments in which the A protein is used stoichiometrically and must be synthesized de novo for each round of Mu DNA replication. Induction of a Mu lysogen in the absence of DNA replication allows accumulation of potential for a single round of Mu DNA replication. Once achieved, this potential is stable even in the absence of further protein synthesis. Release of inhibition of DNA replication leads to a single semi-conservative replicative transposition event, followed by later rounds only if additional synthesis of the A protein is allowed.     

Inhibition of initiation of mini-F plasmid replication in temperature-sensitive mafA mutants of Escherichia coli K-12

When temperature-sensitive mafA mutants of Escherichia coli K-12 carrying mini-F plasmid (pSC138) are transferred from 30 to 42 °C, plasmid DNA replication as determined by incorporation of [³H]thymidine into covalently closed circular (CCC) mini-F DNA or by DNA-DNA hybridization is inhibited markedly within 10 min. The results of extensive pulse-chase experiments suggest that the initiation rather than the chain elongation step of plasmid replication is affected under these conditions. The replication inhibition in the mutant is accompanied by appearance of a class of plasmid DNA with a buoyant density higher than that of CCC DNA observed in the wild type, and is followed by gradual inhibition of host cell growth. The inhibition of plasmid replication is reversible at least for 60 min under the conditions used, and the recovery at low temperature (30 °C) depends on the synthesis of untranslated RNA. These results taken together with other evidence suggest that the mafA mutations primarily affect the initial step(s) of F DNA replication, presumably at or before the synthesis of untranslated RNA.     

Establishment of exponential growth after a nutritional shift-up in Escherichia coli B/r: accumulation of deoxyribonucleic acid, ribonucleic acid, and protein.

The accumulation of deoxyribonucleic acid (DNA), ribonucleic acid (RNA), and protein was followed in cultures of Escherichia coli B/r during exponential growth in different media and for 2 h after a nutritional shift-up from succinate minimal medium (growth rate [mu1] = 0.67 doublings per h) to glucose plus amino acids medium (mu2 = 3.14 doublings per h). During postshift growth of the culture, the amounts of RNA (R), DNA (D), and protein (P) increased such that the ratios of the increments (delta R/delta P; delta D/delta P) were constants (k1, k2). This implies that the rates of accumulation of nuclei1:k2:1. These constants change from their preshift value to their final postshift value (i.e., k1 and k2) within a few minutes after the shift. k1 is a function of the activity of ribosomes, whereas k2 is related to the initiation of rounds of DNA replication. These parameters and the observed change in the doubling time of RNA (= mu2/mu1) were used to derive kinetic equations that describe the accumulation of DNA, RNA, protein, and cell mass during the 2- to 3-h transition period after a shift-up. The calculated kinetics agree closely with the observed kinetics.     

Roles of bacteriophage lambda gene products O and P during early and late phases of infection cycle.

Ring-to-ring (early) replication of bacteriophage lambda DNA was blocked after heat inactivation of the P protein. Rolling circle (late) replication continued for several rounds at the rate reached when the temperature shift was carried out. The same differential effect was observed after inhibition of RNA or protein synthesis during the two different phases of replication. In contrast, inactivation of the O protein resulted in a fast stop of lambda DNA synthesis at early and late times after infection. The results were consistent with the following interpretations. (i) The lambda P gene product plays a role in the initiation of the ring-to-ring replication. (ii) Ring-to-ring replication continues parallel to rolling circle replication, possibly diminishing with time after infection. (iii) The O function is stable in and necessary for the structural integrity of an elongation complex. It is unstable in free form and probably released from such a replication complex after each round of replication at the ring-to-ring stage.     

Inhibition of sporulation in Bacillus subtilis by bromodeoxyuridine and the effect on DNA replication

A 5-bromo-2'-deoxyuridine (BUdR)-tolerant derivative of a thymidine (TdR)-requiring strain of Bacillus subtilis was used to examine the effect of BUdR, an analogue of TdR, on sporulation. At a TdR:BUdR ratio which had little effect on growth, sporulation was inhibited if cells were exposed to BUdR during the period of DNA synthesis at the onset of the process. Cells recovered from BUdR inhibition of sporulation if the analogue was removed and DNA replication allowed to continue with TdR alone. BUdR prolonged the period of DNA synthesis during sporulation and experiments with chloramphenicol suggested that this was due in part to unscheduled initiation of new rounds of replication.     

Dependence of timing of mitotic events on the rate of protein synthesis and DNA replication in sea urchin early cleavages

Abstract. To understand what processes affect the cell-cycle timing of mitotic events in early cleavage cycles of sea urchin embryos, a study was made on the effects of (a) reducing protein synthesis with emetine and (b) DNA replication with aphidi-colin, on the timing of nuclear envelope breakdown, anaphase onset and cytokinesis. When protein synthesis was slightly inhibited by administration of emetine, the delay in the mitotic events increased, with an increase in the delay in accumulation of proteins up to the levels to which cells must synthesize the proteins to execute the cleavage. This indicated that protein synthesis affects the timing of mitotic events. The delay in cleavage cycles caused by a slight inhibition of DNA replication with aphidicolin was in proportion to the concentration of aphidicolin administered, suggesting that DNA replication also affects the timing of mitotic events. Furthermore, it was confirmed that accumulation of the proteins to the levels required for execution of the first cleavage precedes completion of DNA replication as a requirement for execution of the first cleavage. These results imply the existence of process(es) affected by protein synthesis that are included in a feedback control system which prevents the initiation of mitosis until after the completion of DNA replication; it is the characteristic of a cell-cycle control system that has been predicted theoretically.     

DNA-replication recovery inhibition and subsequent reinitiation in UV-radiation-damaged E. coli: a strategy for survival

Using the incorporation of [14C]thymine to measure DNA accumulation, it was shown that exposure of the B/r strain of Escherichia coli to 10 J/m2 of ultraviolet radiation (UV) inhibits replication for about 20 min, but then resumption of replication occurs. Pulse-labelling with [3H]thymidine after exposure of the WT strain to this fluence confirmed the transient inhibition and recovery of DNA replication. After recovery, the rate of accumulation of DNA in the culture increases, to exceed that of the exponentially growing culture, so that eventually the amount of DNA almost equals that of the unirradiated culture. After a higher fluence (20 J/m2), an inhibition of replication recovery was revealed. This fluence delays the reinitiation of DNA accumulation in the culture, measured by [14C]thymine incorporation, for 25 min more, in addition to the 20-min recovery period. This finding was confirmed with pulse-labelling studies, which revealed that the higher exposure represses the rates of replication for 45 min before replication at the normal rate reinitiates in the culture. It was proposed that the inhibition of recovery revealed by these investigations is effected by the UV-induction of an active DNA-replication recovery-inhibition process. With the uvrA strain, rate studies revealed that 1.5 J/m2 of UV (a reduced fluence necessary because of the greater sensitivity of the strain) induces a transient inhibition of DNA replication, with considerable recovery following. Exposure to 3.0 J/m2 induces the transient inhibition of replication, followed by massive recovery inhibition after 20 min of incubation. With uvrA recA, both the lower and the higher fluence resulted in an immediate block of replication with no recovery, confirming the recA gene dependency of the recovery process. The decrease in rate of replication comparable to that seen in the uvrA strain after 20 min, and taken as evidence of the function of the recovery-inhibition process, was not seen. The evidence supports the concept that a process somehow triggered by higher UV fluences functions to repress replication temporarily, presumably allowing time for repair processes to take place before replication overruns closely linked pyrimidine dimers on opposite strands to create lethal lesions.     

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.     

RNase H is not involved in the induction of stable DNA replication in Escherichia coli.

rnh mutations of Escherichia coli inactivating RNase H activity allow the initiation of rounds of DNA replication in the absence of protein synthesis (stable DNA replication). However, levels of RNase H did not change during or after the induction of stable DNA replication in rnh+ strains by incubation with nalidixic acid or UV irradiation.     

Three additional genes required for deoxyribonucleic acid synthesis in Saccharomyces cerevisiae

Deoxyribonucleic acid (DNA) synthesis was examined in asynchronous and synchronous cultures of a number of cdc (cell division cycle) temperature-sensitive mutant strains. The kinetics of DNA synthesis after a shift to the restrictive temperature was compared with that obtained after inhibition of protein synthesis at the permissive temperature, a condition that specifically blocks the initiation of new rounds of DNA replication, but does not block those in progress. Mutations in three genes (cdc 4, 7, and 28) appear to block a precondition for DNA synthesis since cells carrying these lesions cannot start new rounds of DNA replication after a shift from permissive to restrictive temperature, but can finish rounds that were in progress. These three genes are classified as having roles in the "initiation" of DNA synthesis. Mutations in two genes (cdc 8 and 21) block DNA synthesis, itself, since cells harboring these lesions that had started DNA synthesis at the permissive temperature arrest synthesis abruptly upon a shift to the restrictive temperature. Mutations in 13 other cdc genes do not impair DNA synthesis in the first cell cycle at the restrictive temperature.     

Initiation and termination of chromosome replication at 45 degree C in a temperature-sensitive deoxyribonucleic acid initiation mutant of Bacillus subtilis 168, TsB134.

Deoxyribose nucleic acid transfer experiments showed that upon shifting Bacillus subtilis TsB134 to 45 degree C, initiation of new rounds of replication was effectively blocked and the majority of existing rounds terminated.