Relationship between chromosome replication and cell division in a thymineless mutant of Escherichia coli B/r.

The relationship between chromosome replication and cell division was investigated in a thymineless mutant of Escherichia coli B/r. Examination of the changes in average cell mass and DNA content of exponential cultures resulting from changes in the thymine concentration in the growth medium suggested that as the replication time (C) is increased there is a decrease in the period between termination of a round of replication and the subsequent cell division (D). Observations on the pattern of DNA synthesis during the division cycle were consistent with this relationship. Nevertheless, the kinetics of transition of exponential cultures moving between steady states of growth with differing replication velocities provided evidence to support the view that the time of cell division is determined by termination of rounds of replication under steady-state conditions.     

Replication of Deoxyribonucleic Acid During the Division Cycle of Salmonella typhimurium

The rate of thymidine incorporation into cells of Salmonella typhimurium growing in different media has been measured. In glucose-minimal medium, deoxyribonucleic acid (DNA) replication occurs during the first two-thirds of the division cycle; the final one-third of the division cycle was devoid of DNA replication. The measured doubling time of S. typhimurium in this medium is approximately 48 min, indicating that C (the time for a round of replication) and D (the time between termination and cell division) are approximately 32 and 16 min, respectively. At slower growth rates the pattern of replication is the same as glucose minimal medium. At faster growth rates the "gap" in DNA synthesis disappears. At rapid growth rates evidence for multiple forks is obtained.     

Timing of FtsZ Assembly in Escherichia coli

The timing of the appearance of the FtsZ ring at the future site of division in Escherichia coli was determined by in situ immunofluorescence microscopy for two strains grown under steady-state conditions. The strains, B/rA and K-12 MC4100, differ largely in the duration of the D period, the time between termination of DNA replication and cell division. In both strains and under various growth conditions, the assembly of the FtsZ ring was initiated approximately simultaneously with the start of the D period. This is well before nucleoid separation or initiation of constriction as determined by fluorescence and phase-contrast microscopy. The durations of the Z-ring period, the D period, and the period with a visible constriction seem to be correlated under all investigated growth conditions in these strains. These results suggest that (near) termination of DNA replication could provide a signal that initiates the process of cell division.     

Regulation of Deoxyribonucleic Acid Replication and Cell Division in Escherichia coli B/r

Synchronous cultures of Escherichia coli strain B/r were used to investigate the relationship between deoxyribonucleic acid (DNA) replication and cell division. We have determined that terminal steps in division can proceed in the absence of DNA synthesis. Inhibition of DNA replication with nalidixic acid prior to the start of a new round of replication does not stop cell division, which indicates that the start of the round is not essential in triggering cell division. Inhibition of DNA replication at any time prior to the termination of a round of replication completely blocks cell division, which suggests that there may be a link between the end of the replication cycle and the commitment of the cell to divide. Studies that use a temperature-sensitive mutant which is unable to synthesize DNA at the nonpermissive temperature are in complete agreement with those that use nalidixic acid to inhibit DNA synthesis. This adds support to the idea that the treatments employed limit their action to DNA synthesis. Investigation of minicell production indicates that the production of minicells is blocked when DNA synthesis is inhibited with nalidixic acid. Although nuclear segregation is not required for cell division, DNA synthesis is still required to trigger division. The evidence presented suggests strongly that (i) DNA synthesis is essential for cell division, (ii) the end of a round of replication triggers cell division, and (iii) there is considerable time lapse (one-half generation) between the completion of a round of DNA replication and physical separation of the cells.     

Variation in periodic replication of the chromosome in Escherichia coli B/rTT.

A method using 5-bromouracil photolysis induction with 313 nm radiation was employed to estimate the variation in the period between successive rounds of DNA replication in rapidly growing cultures of Escherichia coli$\text{B}\text{rTT}$ The coefficient of variation of this period was 9.3%, which is significantly less than the corresponding value of about 20% reported for variation in the cell interdivision period. Thus chromosome replication is much more tightly controlled than is cell division. The reduced variability of the DNA replication cycle indicates that the period (D) between termination of a round of DNA replication and cell division and the following period ending in initiation of the next round of DNA replication (B) are riot independent of each other but tend to have compensatory variations. The results suggest that other events in the cell cycle are related more closely to DNA replication rather than to the much less regular event of cell division.     

dnaT, dominant conditional-lethal mutation affecting DNA replication in Escherichia coli.

Normally, bacteria cease DNA replication in the absence of protein synthesis. A variety of treatments, such as thymine starvation or a shift-up to rich medium, lead to continued DNA replication in the absence of protein synthesis. Mutants are described which always terminate replication under these conditions. These conditional lethal mutants, dnaT1 and dnaT2, contransduce with serB and dnaC. The mutation also affects cell division. All aspects of the mutant phenotype (obligatory termination of replication, temperature sensitivity of DNA replication and growth, and aberrant cell division at permissive growth temperatures) were transdominant to the wild-type phenotype. Episomes carrying the dnaT mutation appeared to be unstable. The existence of such a dominant mutation was predicted by a model of chromosome termination proposed by Kogoma and Lark (J. Mol. Biol. 94:243-256, 1975).     

A calcium flux at the termination of replication triggers cell devision in Escherichia coli : Hypothesis

Cell division in Escherichia coli is coupled to chromosome replication. Even in the absence of known inducible division inhibitors, perturbations of chromosome replication affect cell division. Early studies suggested that a signal at the termination of replication might trigger subsequent division. Although later studies have suggested that fork encounter during termination is an active process involving specific termination sites and the tus protein, the coupling mechanism between termination and cell division remains to be elucidated. Recently it has been shown that the chromosome of a bacterium, Pseudomonas tabaci, contains a high proportion of calcium. E. coli maintains an intracellular concentration of free calcium identical to that of higher organisms and in dividing cells of E. coli a twenty-fold increase in the level of total calcium in the cytoplasm, a flux, occurs. In this article I propose that during the replication of the chromosome calcium entry balances calcium binding to DNA. At the termination of replication, there is a brief interval between the end of calcium binding to the chromosome and the end of calcium entry or release into the cytoplasm. During this interval the level of free calcium therefore rises. This rise may result in the observed flux by triggering the entry of calcium directly via voltage-gated calcium channels or indirectly via changes in phospholipid configurations. Mechanisms whereby these changes in calcium levels might be coupled to cell division and to a phospholipid control of the cell cycle are discussed.     

Coupling between the initiation of DNA replication and cell division in the blue-green alga Anacystis nidulans

The effect of mitomycin C on cell mass increase, cell division, RNA synthesis and DNA synthesis in the blue-green alga Anacystis nidulans has been examined. Data suggests that the initiation of DNA replication, rather than its termination was the necessary event for cell division to occur.     

Coordinating DNA replication with cell division: lessons from outgrowing spores

Progress in solving the long-standing puzzle of how a cell coordinates chromosome replication with cell division is significantly aided by the use of synchronous cell populations. Currently three systems are employed for obtaining such populations: the Escherichia coli 'baby machine', the developmentally-controlled cell cycle of Caulobacter crescentus, and Bacillus subtilis germinated and outgrowing spores. This review examines our current understanding of the relationship between replication and division and how the use of B. subtilis outgrowing spores and, more recently its combination with immunofluorescence microscopy, has contributed significantly to this important area of biology. About 20 years ago, and also more recently, this system was used to show convincingly that termination of DNA replication is not essential for a central septum to form, raising the possibility that the early stages of division occur well before termination. It has also been demonstrated that there is no major synthesis of the division initiation proteins, FtsZ and DivIB, linked to initiation, progression or completion of the first round of chromosome replication accompanying spore outgrowth. This has led to the suggestion that the primary link between chromosome replication and cell division at midcell is not likely to occur through a control over the levels of these proteins. Very recent work has employed a combination of the use of B. subtilis outgrowing spores with immunofluorescence microscopy to investigate the relationship between midcell Z ring assembly and the round of chromosome replication linked to it. The results of this work suggest a role for initiation and progression into the round of replication in blocking midcell Z ring formation until the round is complete or almost complete, thereby ensuring that cell division occurs between two equally-partitioned chromosomes.     

DNA synthesis —Dependent cell division ofEscherichia coli 15 TAU after arginine and uracil starvation

Extensive cell division after synchronization ofEscherichia coli 15 TAU by arginine and uracil starvation occurs only when DNA synthesis is permitted to proceed by at least a short pulse of thymine applied between 30 and 60 min after transfer of synchronized culture to thymine-free medium with arginine and uracil. The time schedule of synchronized cell division in dependence on the schedule of intervals of DNA synthesis and inhibition of DNA synthesis was determined. The termination of replication cycles which were not completed to the very end during arginine and uracil starvation seems to be the decisive event for subsequent cell division after synchronization.     

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.     

The cell cycle of Bacillus subtilis as studied by electron microscopy

Bacillus subtilis strain Marburg was grown exponentially with a doubling time of 65 min. To follow the time course of various cell cycle events, cells were collected by agar filtration and were then classified according to length. The DNA replication cycle was determined by a quantitative analysis of radioautograms of tritiated thymidine pulse labeled cells. The DNA replication period was found to be 45 min. This period is preceded and followed by periods without DNA synthesis of about 10 min.The morphology and segregation of nucleoplasmic bodies was studied in thin sections. B. subtilis contains two sets of genomes. DNA replication and DNA segregation seem to go hand in hand and DNA segregation is completed shortly after termination of DNA replication.Cell division and cell separation were investigated in whole mount preparations (agar filtration) and in thin sections. Cell division starts about 20 min after cell birth; cell separation starts at about 45 min and before completion of the septum.     

Linkages between deoxyribonucleic acid synthesis and cell division in Myxococcus xanthus.

Addition of chloramphenicol or 0.5 M glycerol to growing Myxococcus xanthus resulted in an immediate cessation of cell division and 40% net increase in deoxyribonucleic acid (DNA). Although the chloramphenicol-treated cells divided in the presence of nalidixic acid after chloramphenicol was removed, glycerol-induced myxospores required DNA synthesis for subsequent cell division. Myxospores prepared from chloramphenicol-treated cells lost this potential to divide in the presence of nalidixic acid. The "critical period" of DNA synthesis necessary for cell division after germination overlapped in time (3 to 5 h) with initiation of net DNA synthesis. The length of the critical period of DNA synthesis was estimated at 12 min, or 5% of the M. xanthus chromosome. The requirement for cell division during germination also involved ribonucleic acid and protein synthesis after DNA synthesis. The data suggest that replication at or near the origin of the chromosome triggers the formation of a protein product that is necessary but not sufficient for subsequent cell division; DNA termination is also required. During myxospore formation, the postulated protein is destroyed, thereby reestablishing and making apparent this linkage between early DNA synthesis and cell division.     

Size variations and correlation of different cell cycle events in slow-growing Escherichia coli.

Cell lengths have been determined at which cycle events occur in the slow-growing Escherichia coli B/r substrains A, K, and F26. The radioautographic and electron microscope analyses allowed determination of the variations in length at birth, initiation and termination of DNA replication, and initiation of the constriction process and of cell separation. In all three substrains the standard deviation increased between cell birth and initiation of DNA replication. From there on, the standard deviation remained relatively constant until cell separation. These observations are consistent with the presence of a deterministic phase during the cell cycle in which the cell sizes at initation of DNA replication and at cell division are correlated.     

Control of cell division by sex factor F in Escherichia coli. II. Identification of genes for inhibitor protein and trigger protein on the 42.84-43.6 F segment

The genetic structure of the 42.84-43.6 F (BamHI-PstI) segment of the F plasmid, which contains all the F DNA sequences necessary for coupling cell division of F+ bacteria with plasmid DNA replication, was analyzed by isolating a series of amber mutants. Two cistrons were found in this region and they were designated letA and letD (an abbreviation for lethal mutation). The letA and letD cistrons were mapped on the 42.84-43.35 F (BamHI- XmaI ) segment and the 43.07-43.6 F (HincII-PstI) segment, respectively, and are presumed to correspond to the first (43.04-43.26 F) and second (43.26-43.57 F) open reading frames, respectively, which were found in this region by nucleotide sequencing. The letD gene product acts to inhibit cell division of the host bacteria and to induce prophages in lysogenic bacteria, whereas the letA gene product acts to suppress the activity of the letD gene product. Taking into consideration the fact that the 42.84-43.6 F segment carries all the F plasmid genes necessary for coupling cell division with plasmid DNA replication, and that the expression of the genes is likely to be controlled by plasmid DNA replication, we constructed the following hypothesis. Before completion of plasmid DNA replication, LetD protein acts to prevent cell division of the host bacteria. When plasmid DNA replication is completed, synthesis of LetA protein (and also LetD protein) takes place and the LetA protein synthesized acts to suppress the activity of LetD protein and make the cell ready for cell division. Actual cell division will take place when replication of both chromosomal and plasmid DNA is completed and the termination protein of the chromosome and the LetA protein of F plasmid are both synthesized. When cell division takes place LetA protein is consumed, and as a result LetD protein becomes active and prevents cell division until the next round of DNA replication is completed.     

Chromosomal DNA replication initiates at the same origins in meiosis and mitosis.

Autonomously replicating sequence (ARS) elements are identified by their ability to promote high-frequency transformation and extrachromosomal replication of plasmids in the yeast Saccharomyces cerevisiae. Six of the 14 ARS elements present in a 200-kb region of Saccharomyces cerevisiae chromosome III are mitotic chromosomal replication origins. The unexpected observation that eight ARS elements do not function at detectable levels as chromosomal replication origins during mitotic growth suggested that these ARS elements may function as chromosomal origins during premeiotic S phase. Two-dimensional agarose gel electrophoresis was used to map premeiotic replication origins in a 100-kb segment of chromosome III between HML and CEN3. The pattern of origin usage in premeiotic S phase was identical to that in mitotic S phase, with the possible exception of ARS308, which is an inefficient mitotic origin associated with CEN3. CEN3 was found to replicate during premeiotic S phase, demonstrating that the failure of sister chromatids to disjoin during the meiosis I division is not due to unreplicated centromeres. No origins were found in the DNA fragments without ARS function. Thus, in both mitosis and meiosis, chromosomal replication origins are coincident with ARS elements but not all ARS elements have chromosomal origin function. The efficiency of origin use and the patterns of replication termination are similar in meiosis and in mitosis. DNA replication termination occurs over a broad distance between active origins.     

EVIDENCE FOR A TEMPORAL INCOMPATIBILITY BETWEEN DNA REPLICATION AND DIVISION DURING THE CELL CYCLE OF TETRAHYMENA

The mechanism of coordination between DNA replication and cell division was studied in Tetrahymena pyriformis GL-C by manipulation of the timing of these events with heat shocks and inhibition of DNA synthesis. Preliminary experiments showed that the inhibitor combination methotrexate and uridine (M + U) was an effective inhibitor of DNA synthesis. Inhibition of the progression of DNA synthesis with M + U in exponentially growing cells, in which one S period usually occurs between two successive divisions, or in heat-shocked cells, when successive S periods are known to occur between divisions, resulted in the complete suppression of the following division. In further experiments in which the division activities were reassociated with the DNA synthetic cycle by premature termination of the heat-shock treatment, it was shown that (a) the completion of one S period during the treatment was sufficient for cell division, (b) the beginning of division events suppressed the initiation of further S periods, and (c) if further S periods were initiated while the heat-shock treatment was continued, division preparations could not begin until the necessary portion of the S period was completed, even though DNA had previously been duplicated. It was concluded that a temporal incompatibility exists between DNA synthesis and division which may reflect a coupling mechanism which insures their coordination during the normal cell cycle.     

Division septation in the absence of chromosome termination in Bacillus subtilis.

Germinating spores of the temperature-sensitive DNA initiation mutants of Bacillus subtilis, TsB134 and dna-1(Ts), were allowed to undergo a single round of replication by shifting to the restrictive temperature shortly after its initiation. To monitor the progress of the round 5-bromouracil was added at various times and DNA extracted after a further time, sufficient to allow completion of the chromosome. Average replication was measured from the relative amounts of LL and LH material in Cs₂SO₄ gradients. The replication state of origin (purA), intermediate (leuA) and terminus (metB) markers at the times of 5-bromouracil addition were obtained from genetic analysis of the density species fractionated in gradients of CsCl.The DNA replication inhibitor, 6-(p-hydroxyphenylazo)-uracil (HPUra), was added at various stages of the single round and the outgrown cells examined at later times for the frequency and type of septation. Under the conditions of the experiment, central division septation was blocked if HPUra (20 μm) was added before 70% (approximately) of the chromosome was replicated. Using higher concentrations of HPUra, 40 and 100 μm, it was shown that central division septation would occur at about its normal time if replication was blocked after this 70% stage but before termination. In these circumstances there was a distinct tendency for the DNA to remain close to the septum on both sides of it. The B. subtilis spore contains a single chromosome, which means that the central septum that forms in the absence of termination must pass through a partially completed chromosome. Electron microscopic evidence for such a situation has already been described (Van Iterson &; Aten, 1976). It is concluded that, at least under the restrictive conditions of the present experiments, termination of chromosome replication is not obligatory for the formation of the division septum with which it is normally coupled.     

Cell cycle characteristics of crenarchaeota: unity among diversity

The hyperthermophilic archaea Acidianus hospitalis, Aeropyrum pernix, Pyrobaculum aerophilum, Pyrobaculum calidifontis, and Sulfolobus tokodaii representing three different orders in the phylum Crenarchaeota were analyzed by flow cytometry and combined phase-contrast and epifluorescence microscopy. The overall organization of the cell cycle was found to be similar in all species, with a short prereplicative period and a dominant postreplicative period that accounted for 64 to 77% of the generation time. Thus, in all Crenarchaeota analyzed to date, cell division and initiation of chromosome replication occur in close succession, and a long time interval separates termination of replication from cell division. In Pyrobaculum, chromosome segregation overlapped with or closely followed DNA replication, and further genome separation appeared to occur concomitant with cellular growth. Cell division in P. aerophilum took place without visible constriction.     

Inhibition of an early event in the cell division cycle of Escherichia coli by FL1060, an amidinopenicillanic acid.

Analysis of exponential and synchronous cultures of Escherichia coli B/r after the addition of FL1060 indicates a block point for division by this agent some 15 to 20 min before the end of the preceding cell division cycle, a time corresponding to the beginning of the C period of the cell division cycle. Morphological examination of FL1060-treated synchronous cultures of E. coli /r was consistent with inhibition by FL1060 of a very early event in the cell division cycle. This event appears to be essential for normal cell surface elongation in a rod configuration. Temporary treatment of synchronous cultures of E. coli B/r with FL1060 resulted in division delay, the extent of which was a function of the duration of exposure to FL1060. However, even after relatively long times of FL1060 treatment the delayed divisions were still synchronous. Although FL1060 had no direct effect on deoxyribonucleic acid (DNA) synthesis, the synchronous delayed division occuring after temporary treatment with FL1060 were accompanied by a delay in the attainment of resistance of cell division to inhibitors of DNA, ribonucleic acid, and protein synthesis. These results suggest aht an FL1060-sensitive event initiates at the beginning of the C period of the cell division cycle of E. coli and is responsible for normal cell elongation. This cell elongation pathway procedes independently of DNA synthesis, but there is an interaction between this pathway and termination of a round of DNA replication in which a normal rod configuration is necessary to allow a signal for cell division to be generated upon completion of DNA replication.