Velocity of chromosome replication in thymine-requiring and independent strains of Bacillus subtilis

Instructive simulation of the bacterial cell division cycle

The coupling between chromosome replication and cell division includes temporal and spatial elements. In bacteria, these have globally been resolved during the last 40 years, but their full details and action mechanisms are still under intensive study. The physiology of growth and the cell cycle are reviewed in the light of an established dogma that has formed a framework for development of new ideas, as exemplified here, using the Cell Cycle Simulation (CCSim) program. CCSim, described here in detail for the first time, employs four parameters related to time (replication, division and inter-division) and size (cell mass at replication initiation) that together are sufficient to describe bacterial cells under various conditions and states, which can be manipulated environmentally and genetically. Testing the predictions of CCSim by analysis of time-lapse micrographs of Escherichia coli during designed manipulations of the rate of DNA replication identified aspects of both coupling elements. Enhanced frequencies of cell division were observed following an interval of reduced DNA replication rate, consistent with the prediction of a minimum possible distance between successive replisomes (an eclipse). As a corollary, the notion that cell poles are not always inert was confirmed by observed placement of division planes at perpendicular planes in monstrous and cuboidal cells containing multiple, segregating nucleoids.

A mathematical model for examining growth and sporulation processes of Bacillus subtilis

A mathematical model for the growth process of the bacterium Bacillus subtilis is described. The model is a highly structured one. The driving motivation for development of the model and explicit accounting of major interactions of metabolic networks in the model is related to our eventual goal that the model will be used in the analysis of complex biological patterns. Bacillus subtilis was chosen in our study due to the interesting sporulation process that these cells undergo in response to adverse environmental conditions including nutrient limitation. Sporulation process in B. subtilis represents a primordial prototype of cellular differentiation in higher cellular systems. Thus a model for the B. subtilis growth process should prove extremely useful for understanding questions of developmental biology. The model is capable of simulating the transition between the exponential and stationary phase of growth in a batch culture. Since during the transition period the growth process and the metabolism become decoupled and many transient processes are taking place, such predictions are a severe test for the validity of any model. A strategy to examine the leading hypothesis on B. subtills sporulation implementing GTP as a component which signals sporulation initiation is described.

Dynamic, mitotic-like behavior of a bacterial protein required for accurate chromosome partitioning

The Bacillus subtilis spo0J gene is required for accurate chromosome partitioning during growth and sporulation. We have characterized the subcellular localization of Spo0J protein by immunofluorescence and, in living cells, by use of a spo0J-gfp fusion. We show that the Spo0J protein forms discrete stable foci usually located close to the cell poles. The foci replicate in concert with the initiation of new rounds of DNA replication, after which the daughter foci migrate apart inside the cell. This migration is independent of cell length extension, and presumably serves to direct the daughter chromosomes toward opposite poles of the cell, ready for division. During sporulation, the foci move to the extreme poles of the cell, where they function to position the oriC region of the chromosome ready for polar septation. These observations provide strong evidence for the existence of a dynamic, mitotic-like apparatus responsible for chromosome partitioning in bacteria.

Characterization of cell cycle events during the onset of sporulation in Bacillus subtilis

To elucidate the process of asymmetric division during sporulation of Bacillus subtilis, we have measured changes in cell cycle parameters during the transition from vegetative growth to sporulation. Because the propensity of B. subtilis to grow in chains of cells precludes the use of automated cell-scanning devices, we have developed a fluorescence microscopic method for analyzing cell cycle parameters in individual cells. From the results obtained, and measurements of DNA replication fork elongation rates and the escape time of sporulation from the inhibition of DNA replication, we have derived a detailed time scale for the early morphological events of sporulation which is mainly consistent with the cell cycle changes expected following nutritional downshift. The previously postulated sensitive stage in the DNA replication cycle, beyond which the cell is unable to sporulate without a new cell cycle, could represent a point in the division cycle at which the starved cell cannot avoid attaining the initiation mass for DNA replication and thus embarking on another round of the cell cycle. The final cell cycle event, formation of the asymmetric spore septum, occurs at about the time in the cell cycle at which the uninduced cell would have divided centrally, in keeping with the view that spore septation is a modified version of vegetative division.

Growth kinetics of individual Bacillus subtilis cells and correlation with nucleoid extension

The growth rate of individual cells of Bacillus subtilis (doubling time, 120 min) has been calculated by using a modification of the Collins-Richmond principle which allows the growth rate of mononucleate, binucleate, and septate cells to be calculated separately. The standard Collins-Richmond equation represents a weighted average of the growth rate calculated from these three major classes. Both approaches strongly suggest that the rate of length extension is exponential. By preparing critical-point-dried cells, in which major features of the cell such as nucleoids and cross-walls can be seen, it has also been possible to examine whether nucleoid extension is coupled to length extension. Growth rates for nucleoid movement are parallel to those of total length extension, except possibly in the case of septate cells. Furthermore, by calculating the growth rate of various portions of the cell surface, it appears likely that the limits of the site of cylindrical envelope assembly lie between the distal tips of the nucleoid; the old poles show zero growth rate. Coupling of nucleoid extension with increase of cell length is envisaged as occurring through an exponentially increasing number of DNA-surface attachment sites occupying most of the available surface.

Density gradient analysis of DNA replicated during Bacillus subtilis sporulation

Density gradient centrifugation was used to monitor DNA replication during sporulation of a 5-bromo-2'-deoxyuridine-tolerant, thymidine-requiring strain of Bacillus subtilis. DNA of heavy, intermediate, and light density was found in cells induced to sporulate in the presence of bromodeoxyuridine, but only intermediate DNA was detected in mature spores. Cells grown with bromodeoxyuridine until DNA was in the heavy form formed spores containing intermediate and light DNA when sporulated with thymidine alone.

Chromosome replication in sporulating cells of Bacillus subtilis

A method of specifically labeling the chromosomal terminus of Bacillus subtilis is described. When sporulating cultures were pulse-labeled with [(3)H]thymidine and then treated with 6-(p-hydroxyphenylazo)uracil, a drug which inhibits deoxyribonucleic acid (DNA) synthesis rapidly and completely, the only labeled spores formed were those that had completed replication during the pulse period. DNA-mediated transformation was used to show that the DNA of spores formed in the presence of 6-(p-hydroxyphenylazo)uracil had the same ratio of origin to terminus markers as DNA from untreated spores. Furthermore, spores formed in the presence of 6-(p-hydroxyphenylazo)uracil had the same DNA content as untreated spores. These two observations indicated that spores formed in the presence of 6-(hydroxyphenylazo)uracil contained completed chromosomes. The rate of termination of chromosomes destined to be packaged into spores was determined by this method, using the Sterlini-Mandelstam replacement system and a single medium exhaustion system for inducing sporulation. With both systems the rate of termination reached a broad peak 2 h after the start of sporogenesis. This was measured from the time of resuspension by using the replacement system and from the point where exponential growth ceased in the exhaustion system. The amount of spore DNA synthesized in the Sterlini-Mandelstam sporulation-inducing medium was very close to one-half the amount of the DNA present in mature spores. This suggests that chromosomes destined to be packaged into spores were replicated from close to the origin and possibly initiated in the sporulation-inducing medium. A method was devised for estimating the time taken to complete replication of the chromosomes destined to be packaged into spores. This was probably no more than 50 min. Whereas starvation must have occurred almost simultaneously in most cells in the population, the chromosome replication that was essential for sporogenesis was distributed over a wide time span. Thus, in some cells, replication started within 10 min of the nutritional step-down, but the peak rate was not reached for 1 h; thereafter replication continued at a substantial rate.

Cell division of cycle of Bacillus subtilis: evidence of variability in period D

In Bacillus subtilis the deoxyribonucleic acid content and the extent of cell division during inhibition of chromosome replication increased as a function of the average cell mass, independent of the growth rate. At each growth rate, mass, deoxyribonucleic acid, and residual division varied in different cultures. The variation is consistent with a large variability in the D period. At growth rates higher than 1.5 doublings per h at 37 degrees C, the change in D accounts for the growth rate dependence of the mass and deoxyribonucleic acid content.

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.

Deoxyuridine residues in DNA of thymine-requiring Bacillus subtilis strains with defective N-glycosidase activity for uracil-containing DNA

DNA extracted from exponentially growing cells of thymine-requiring Bacillus subtilis strains with defective N-glycosidase activity for deoxyuridine residues in DNA was subjected to the action of N-glycosidase in vitro and analyzed by sedimentation in alkaline sucrose gradients. The sites attacked by N-glycosidase occurred once per 6 X 10(6) to 7 X 10(6) daltons of DNA from cells cultured in the presence of growth-supporting concentrations of thymine. The number of N-glycosidase-susceptible sites increased when the thymine concentration in the medium was lowered. Parallel to this observation, the N-glycosidase-defective mutant cells were less apt to show the detrimental effect due to thymine depletion than were the parental cells. Such sites were not detected in DNA from cells with a normal N-glycosidase activity or with a "wild type" capacity for thymidylate synthesis. The results are interpreted to mean that cells defective for thymidylate synthesis incorporate dUTP in place of TTP in DNA and that the deoxyuridine residues, once incorporated, remain in the DNA in the absence of N-glycosidase activity.

Resporulation of outgrowing Bacillus subtilis spores

Germinated spores of Bacillus subtilis were incubated in outgrowth medium and tested periodically for capacity to sporulate when suspended in sporulation medium. Concurrent measurements were made of deoxyribonucleic acid (DNA) content and numbers of cell division septa and nucleoids. Sporulation potential is shown to reach a peak at about 110 min at which time the chromosomes are probably well into the second round of replication. Experiments with nalidixic acid show that sporulation potential can be generated in the outgrowth medium even when DNA synthesis is largely prevented. Further experiments show that nalidixic acid apparently does not prevent the formation of DNA initiation complexes, which can subsequently function after resuspension in the sporulation medium. The results support those previously obtained with a temperature-sensitive DNA mutant which indicated that sporulation could only be induced at a specific stage of chromosome replication, and then only if the cells are in a state of nutritional "step-down".

Macromolecular synthesis after a nutritional shift-up of Bacillus subtilis

Effects of amino acids of macromolecular synthesis in Bacillus subtilis were studied. Two mutants, CRK4001 and NIG45, that were selected as slow growers in rich media were proved to be useful to analyse early events occurring after addition of amino acids to exponentially growing cells in a glucose-salts medium (nutritional shift-up). In a wild type strain, the rate of stable RNA (sRNA: essentially ribosomal RNA) synthesis increased 2.3 fold shortly after the shift-up to the rate characteristic of the post-shift steady state growth. In contrast,sRNA synthesis in the mutant strains responded to the shift-up in two steps. Thus, shortly after the shift the rate of sRNA synthesis increased 2.2 fold as in the wild type but this increased level was maintained temporarily for 60 min and suddenly decreased to the post-shift steady state rate (1.4 fold increase). On the other hand, rates of DNA synthesis increased some 30 min after the shift directly to the post-shift steady state rates in all strains. Ratios of an origin to a terminus marker (purA/metB) began to increase exponentially to reach maximum values at 60 min after the shift, indicating that initiation of DNA replication occurred at frequencies characteristic of respective post-shift growth rates soon after the shift. These results revealed that the initial increase in the rate of sRNA synthesis and the frequency of initation of DNA replication after nutritional shift are not related to each other and are independently affected by amino acids. In concert with these findings, the increase in sRNA synthesis was not affected by inhibition of DNA synthesis for the first 60 min after the shift, while it was completely prevented by puromycin and choramphenicol. Protein synthesis for 10 min after the shift was sufficient to fully change the sRNA synthesis rate by amino acids.

Control of membrane protein synthesis in Bacillus subtilis

In synchronous cultures of Bacillus subtilis 168/S grown on succinate as a sole carbon source (mean generation time 115 min), chromosome initiation occurs at the beginning of the cell cycle but the rate of membrane protein synthesis doubles in mid-cycle more or less coincident with nuclear segregation. In glucose-grown cultures, the doubling in rate of membrane protein synthesis occurs at about the same time as nuclear segregation and DNA initiation at the beginning of the cycle. Control of the rate of membrane synthesis by the chromosome has been demonstrated by inhibiting DNA synthesis using thymine starvation and showing that membrane protein synthesis continues at a constant rate, whereas the rate of cytoplasmic protein synthesis almost doubles. I suggest that the replication of a region at or close to the chromosome terminus is required to allow the doubling in rate of membrane synthesis.

Control of chromosome replication in thymine-requiring strains of Bacillus subtilis 168

Study of the replication pattern of a number of B. subtilis 168 strains under controlled physiological conditions revealed great interstrain variation in control of replication. Replication patterns were calculated from ratios of purA16/leu-8 and purA16/metB5 transformation frequency. The thymine-independent strains are under strict regulation with an average of one replication position per chromosome during log phase. After starvation for required amino acids or sporulation, the chromosome is in a completed state with no replication forks (class I). In contrast, several thymine-requiring strains (class III) have an average of three to four replication positions per chromosome during log phase (multiforked replication) of which one to two remain uncompleted after amino acid starvation or sporulation. The other thymine-requiring strains studied are intermediate (class II) in that they have an average of two replication positions per chromosome during log phase and one after amino acid starvation or sporulation. Pulse chase experiments indicate that the deoxyribonucleic acid which is close to the chromosomal origin on each branch of the multiforked chromosome is bound to a rapidly sedimenting cellular fraction, presumably membrane.

Completed chromosomes in thymine-requiring Bacillus subtilis spores

Origin:terminus genetic marker ratios (both purA: metB and purA:ilvA) were measured in extracts of spores of Bacillus subtilis strains W23 thy his and 168 thy. For strain W23 thy his, normalized to W23 spore deoxyribonucleic acid, both ratios were equal to unity and were consistent with the presence of only completed chromosomes in the spores. The same ratios in extracts of spores of 168 thy, normalized to strain 168 or the prototroph SB19, were abnormal, i.e., 2.26 +/- 0.10 and 0.71 +/- 0.06 for purA:metB and purA:ilvA, respectively. These values were unaffected by the extent of extraction of the spore deoxyribonucleic acid, the richness of the medium on which they are formed, and the thymine phenotype. The high ratio for purA:metB is in agreement with the results of earlier workers but, because of the low purA:ilvA ratio, cannot be explained simply by the presence of partially replicated chromosomes in spores of strain 168 thy. Furthermore, purA:leuA in such extracts is 1.01 +/- 0.06, consistent with the presence of only completed chromosomes. It is concluded that the abnormal origin:terminus marker ratios are only apparent and result from non-isogenicity between strains 168 thy and 168 in the metB thyB ilvA chromosome region introduced during construction of 168 thy by transformation of strain 168 with W23 thy deoxyribonucleic acid. It is concluded further that the chromosomes of strain 168 thy spores are in a completed form.

Thymineless death in Bacillus subtilis: correlation between cell lysis and deoxyribonucleic acid breakdown

Bacillus subtilis carrying an inducible defective phage is several times more sensitive to thymineless death than a mutagenized derivative that behaves as a nonlysogen. When the integrity of the deoxyribonucleic acid (DNA) of both strains was examined during thymine starvation by transformation experiments, sedimentation studies, and measurements of acid-soluble DNA degradation products, it was shown that extensive DNA breakdown occurred only in the lysogenic strain. During thymine starvation of this strain, there is a progressive proclivity to lysis, followed by leakage of DNA and DNA degradation products. Such leakage was not observed in the nonlysogen. A correlation between proclivity to lysis and extensive DNA degradation is indicated.

Synchronous cultures of Bacillus subtilis obtained by filtration with glass fiber filters

A simple method of potentially wide applicability for obtaining synchronous cultures of Bacillus subtilis based on size selection is described. Using glass fiber filters, a population (about 1 to 2% of the parent population) can be obtained substantially enriched for small cells which grow synchronously. A method for rapidly concentrating dilute suspensions of cells is described.