Cytological studies of deoxyribonucleic acid replication in Escherichia coli 15T-: replication at slow growth rates and after a shift-up into rich medium

Fundamental principles in bacterial physiology-history, recent progress, and the future with focus on cell size control: a review

Bacterial physiology is a branch of biology that aims to understand overarching principles of cellular reproduction. Many important issues in bacterial physiology are inherently quantitative, and major contributors to the field have often brought together tools and ways of thinking from multiple disciplines. This article presents a comprehensive overview of major ideas and approaches developed since the early 20th century for anyone who is interested in the fundamental problems in bacterial physiology. This article is divided into two parts. In the first part (sections 1-3), we review the first 'golden era' of bacterial physiology from the 1940s to early 1970s and provide a complete list of major references from that period. In the second part (sections 4-7), we explain how the pioneering work from the first golden era has influenced various rediscoveries of general quantitative principles and significant further development in modern bacterial physiology. Specifically, section 4 presents the history and current progress of the 'adder' principle of cell size homeostasis. Section 5 discusses the implications of coarse-graining the cellular protein composition, and how the coarse-grained proteome 'sectors' re-balance under different growth conditions. Section 6 focuses on physiological invariants, and explains how they are the key to understanding the coordination between growth and the cell cycle underlying cell size control in steady-state growth. Section 7 overviews how the temporal organization of all the internal processes enables balanced growth. In the final section 8, we conclude by discussing the remaining challenges for the future in the field.

Threshold effect of growth rate on population variability of Escherichia coli cell lengths

A long-standing question in biology is the effect of growth on cell size. Here, we estimate the effect of Escherichia coli growth rate (r) on population cell size distributions by estimating the coefficient of variation of cell lengths (CV_L) from image analysis of fixed cells in DIC microscopy. We find that the CV_L is constant at growth rates less than one division per hour, whereas above this threshold, CV_L increases with an increase in the growth rate. We hypothesize that stochastic inhibition of cell division owing to replication stalling by a RecA-dependent mechanism, combined with the growth rate threshold of multi-fork replication (according to Cooper and Helmstetter), could form the basis of such a threshold effect. We proceed to test our hypothesis by increasing the frequency of stochastic stalling of replication forks with hydroxyurea (HU) treatment and find that cell length variability increases only when the growth rate exceeds this threshold. The population effect is also reproduced in single-cell studies using agar-pad cultures and 'mother machine'-based experiments to achieve synchrony. To test the role of RecA, critical for the repair of stalled replication forks, we examine the CV_L of E. coli ΔrecA cells. We find cell length variability in the mutant to be greater than wild-type, a phenotype that is rescued by plasmid-based RecA expression. Additionally, we find that RecA-GFP protein recruitment to nucleoids is more frequent at growth rates exceeding the growth rate threshold and is further enhanced on HU treatment. Thus, we find growth rates greater than a threshold result in increased E. coli cell lengths in the population, and this effect is, at least in part, mediated by RecA recruitment to the nucleoid and stochastic inhibition of division.

Threshold effect of growth rate on population variability of Escherichia coli cell lengths

A long-standing question in biology is the effect of growth on cell size. Here, we estimate the effect of Escherichia coli growth rate (r) on population cell size distributions by estimating the coefficient of variation of cell lengths (CV_L) from image analysis of fixed cells in DIC microscopy. We find that the CV_L is constant at growth rates less than one division per hour, whereas above this threshold, CV_L increases with an increase in the growth rate. We hypothesize that stochastic inhibition of cell division owing to replication stalling by a RecA-dependent mechanism, combined with the growth rate threshold of multi-fork replication (according to Cooper and Helmstetter), could form the basis of such a threshold effect. We proceed to test our hypothesis by increasing the frequency of stochastic stalling of replication forks with hydroxyurea (HU) treatment and find that cell length variability increases only when the growth rate exceeds this threshold. The population effect is also reproduced in single-cell studies using agar-pad cultures and 'mother machine'-based experiments to achieve synchrony. To test the role of RecA, critical for the repair of stalled replication forks, we examine the CV_L of E. coli ΔrecA cells. We find cell length variability in the mutant to be greater than wild-type, a phenotype that is rescued by plasmid-based RecA expression. Additionally, we find that RecA-GFP protein recruitment to nucleoids is more frequent at growth rates exceeding the growth rate threshold and is further enhanced on HU treatment. Thus, we find growth rates greater than a threshold result in increased E. coli cell lengths in the population, and this effect is, at least in part, mediated by RecA recruitment to the nucleoid and stochastic inhibition of division.

WITHDRAWN: Symmetries and Asymmetries Associated with Non-Random Segregation of Sister DNA Strands in Escherichia coli

The Publisher regrets that this article is an accidental duplication of an article that has already been published, http://dx.doi.org/10.1016/j.semcdb.2013.05.010. The duplicate article has therefore been withdrawn.

Symmetries and asymmetries associated with non-random segregation of sister DNA strands in Escherichia coli

The successful inheritance of genetic information across generations is a complex process requiring replication of the genome and its faithful segregation into two daughter cells. At each replication cycle there is a risk that new DNA strands incorporate genetic changes caused by miscopying of parental information. By contrast the parental strands retain the original information. This raises the intriguing possibility that specific cell lineages might inherit "immortal" parental DNA strands via non-random segregation. If so, this requires an understanding of the mechanisms of non-random segregation. Here, we review several aspects of asymmetry in the very symmetrical cell, Escherichia coli, in the interest of exploring the potential basis for non-random segregation of leading- and lagging-strand replicated chromosome arms. These considerations lead us to propose a model for DNA replication that integrates chromosome segregation and genomic localisation with non-random strand segregation.

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.

The bacterial nucleoid visualized by fluorescence microscopy of cells lysed within agarose: comparison of Escherichia coli and spirochetes of the genus Borrelia

The nucleoids of Escherichia coli and the spirochetes Borrelia burgdorferi and Borrelia hermsii, agents of Lyme disease and relapsing fever, were examined by epifluorescence microscopy of bacterial cells embedded in agarose and lysed in situ with detergent and protease. The typical E. coli nucleoid was a rosette in which 20 to 50 long loops of DNA emanated from a dense node of DNA. The percentages of cells in a population having nucleoids with zero, one, two, and three nodes varied with growth rate and growth phase. The borrelia nucleoid, in contrast, was a loose network of DNA strands devoid of nodes. This nucleoid structure difference correlates with the unusual genome of Borrelia species, which consists primarily of linear replicons, including a 950-kb linear chromosome and linear plasmids. This method provides a simple, direct means to analyze the structure of the bacterial nucleoid.

Nucleoid partitioning and the division plane in Escherichia coli

Escherichia coli nucleoids were visualized after the DNA of OsO4-fixed but hydrated cells was stained with the fluorochrome DAPI (4',6-diamidino-2-phenylindole dihydrochloride hydrate). In slowly growing cells, the nucleoids are rod shaped and seem to move along the major cell axis, whereas in rapidly growing, wider cells they consist of two- to four-lobed structures that often appear to advance along axes lying perpendicular or oblique to the major axis of the cell. To test the idea that the increase in cell diameter following nutritional shift-up is caused by the increased amount of DNA in the nucleoid, the cells were subjected to DNA synthesis inhibition. In the absence of DNA replication, the nucleoids continued to move in the growing filaments and were pulled apart into small domains along the length of the cell. When these cells were then transferred to a richer medium, their diameters increased, especially in the region enclosing the nucleoid. It thus appears that the nucleoid motive force does not depend on DNA synthesis and that cell diameter is determined not by the amount of DNA per chromosome but rather by the synthetic activity surrounding the nucleoid. Under the non-steady-state but balanced growth conditions induced by thymine limitation, nucleoids become separated into small lobules, often lying in asymmetric configurations along the cell periphery, and oblique and asymmetric division planes occur in more than half of the constricting cells. We suggest that such irregular DNA movement affects both the angle of the division plane and its position.

Intracellular location of the histonelike protein HU in Escherichia coli

Immunocytochemical labeling of thin sections of cryosubstituted, Lowicryl-embedded Escherichia coli cells with protein A-colloidal gold was used to study the structural organization of the bacterial nucleoid. We found that the histonelike protein HU was not associated with the bulk DNA in the nucleoid but was located in areas of the cell where metabolically active DNA is associated with ribosomes and where single-stranded DNA, RNA polymerase, and DNA topoisomerase I were also located. The resolution of the methods used did not allow us to decide whether HU was associated either with ribosomes or with transcriptionally active DNA, nor could we demonstrate interaction of HU with either.

Mechanism for chromosome and minichromosome segregation in Escherichia coli

A mechanism for the segregation of chromosomes and minichromosomes into daughter cells during division of Escherichia coli is presented. It is based on the idea that the cell envelope contains a large number of sites capable of binding to the chromosomal replication origin, oriC, and that a polymerizing DNA strand becomes attached to one of the sites at initiation of a round of replication. The attachment sites are distributed throughout the actively growing cell envelope, i.e. lateral envelope and septum, but not in the existing cell poles. This asymmetric distribution of oriC attachment sites accounts for the experimentally observed non-random chromosome and minichromosome segregation, and for the variation in the degree of non-random segregation with cell strain and growth rate. The multi-site attachment concept also accounts for the unstable maintenance of minichromosomes.

Autoradiographic studies of chromosome replication during the cell cycle of Streptococcus faecium

Analysis of the distribution of autoradiographic grains around cells of Streptococcus faecium which had been either continuously or pulse-labeled with tritiated thymidine (mass doubling time, 90 min) showed a non-Poisson distribution even when the distribution of cell sizes in the populations studied was taken into account. These non-Poisson distributions of grains were assumed to reflect the discontinuous nature of chromosome replication. To study this discontinuous process further, we fitted an equation to the grain distribution observed for the pulse-labeled cells that assumed that in any population of cells there were subpopulations in which there were zero, one, or two replicating chromosomes. This analysis predicted an average time for chromosome replication and for the period between completion of rounds of chromosome replication and division of 55 and 43 min, respectively, which were in excellent agreement with estimates made by other techniques. The present investigation extended past studies in indicating that the initiation and completion of rounds of chromosome replication are poorly phased with increases in cell volume and that the amount of chromosome replication may be different in different cell halves.

DNA segregation in Escherichia coli cells with 5-bromodeoxyuridine-substituted nucleoids

The pattern of segregation of DNA in Escherichia coli K-12 was analyzed by labeling replicating DNA with 5-bromodeoxyuridine followed by differential staining of nucleoids. Three types of visible arrangement were found in four-nucleoid groups derived from a native nucleoid after two replication rounds. Type A, segregation of both old strands toward cell poles, appeared with the highest frequency (0.6 to 0.8). Type B, segregation of one old strand toward the cell pole and the other toward the cell center, was twice as frequent as type C, segregation of both old strands toward the cell center. These results confirm previous data showing that DNA segregation in E. coli is nonrandom while presenting a certain degree of randomness. The proportions of the three indicated types of arrangement suggest a new probabilistic model to explain the observed segregation pattern. It is proposed that DNA strands segregate either nonrandomly, with a probability of between 0 and 1, or randomly. In nonrandom segregation, both old strands are always directed toward cell poles. Experimental data reported here or by other authors fit better with the predictions of this model than with those of other previously proposed proposed deterministic or probabilistic models.

Bacterial growth and division: genes, structures, forces, and clocks

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Completed Bacillus subtilis nucleoid as a doublet structure

When outgrowing spores of the temperature-sensitive dna initiation mutants of Bacillus subtilis, TsB134 and dna-1, were allowed to undergo a single round of replication by shifting to the restrictive temperature soon after its initiation, both segregating daughter nucleoids appeared as clearly defined doublet structures. The components of each doublet remained together as a discrete pair, even under conditions which resulted in the formation of deoxyribonucleic acid (DNA)-less cells. A doublet nucleoid was also observed at a high frequency when TsB134 spores were allowed to germinate and grow out in the complete absence of DNA synthesis at the permissive temperature. TsB134 spores were foud to contain the usual "haploid" amount of DNA. It is suggested that the doublet nucleoid reflects a folding of a single chromosome into two large domains which resolve from one another under conditions of cell extension in the absence of DNA synthesis.

Macromolecular synthesis in synchronized cultures of Anacystis nidulans

Synchronous culture of Anacystis nidulans has been induced by the light-dark-light regimen. At various time intervals during synchronous growth, samples were pulsed with radioactive labels to determine phospholipid, protein, ribonucleic acid (RNA), and deoxyribonucleic acid (DNA) syntheses within the cell division cycle. A temporal order of protein, RNA, and DNA syntheses occurred within the cell division cycle, whereas phospholipid was characteristically synthesized during midcycle (during cell enlargement) and during the time of cell division. Chemically determined protein, RNA, and DNA syntheses were found to support the schedule of these macromolecules in cultures growing at an 8-h doubling time.

Chromosome replication during the division cycle in slowly growing, steady-state cultures of three Escherichia coli B/r strains

The period of DNA synthesis C during the cell cycle was determined over a broad range of generation times in slowly growing, steady-state batch cultures in the exponential phase and in chemostat cultures of three strains of Escherichia coli, strains B/r A, B/r K, and B/r TT, utilizing measurements of average amounts of DNA per cell and cell survival after radioactive decay of 125I incorporated into the DNA of synthesizing cells. At each growth rate, values for cell survival and for C periods were the same within experimental errors for the three strains. The length of the DNA synthesis period increased linearly with generation (doubling) time T of the culture and approached a limiting value of C = 0.36T at very long generation times. In very slowly growing cultures, DNA replication was limited almost entirely to the final third of the cell cycle. D periods, between termination of DNA replication and cell division, were found to be relatively short at all growth rates for each strain. Average amounts of DNA per cell measured in slowly growing cultures of strains B/r A and B/r TT were indistinguishable from results for strain B/r K at the same growth rates. Amounts of DNA per cell calculated from the cell survival values alone are completely consistent with the measured DNA per cell.

The F plasmid may cosegregrate with either DNA strand of the Escherichia coli chromosome

A stable association exists between the plasmid Flac and one of the polynucleotide strands of the bacterial chromosome. This polynucleotide strand was isolated and tested for uniqueness by DNA-DNA hybridization analysis. The association was found to involve either bacterial DNA strand.

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.

Morphological analysis of the division cycle of two Escherichia coli substrains during slow growth

Morphological parameters of the cell division cycle have been examined in Escherichia coli B/r A and K. Whereas the shape factor (length of newborn cell/width) of the two strains was the same at rapid growth (doubling time, tau, less than 60 min), with decreasing growth rate the dimensions of the two strains did change so that B/r A cells became more rounded and B/r K cells became more elongated. The process of visible cell constriction (T period) lasted longer in B/r A than in B/r K during slow growth, reaching at tau = 200 min values of 40 and 17 min, respectively. The time between termination of chromosome replication and cell division (D period) was found to be longer in B/r A than in B/r K. As a result, in either strain completion of chromosome replication seemed always to occur before initiation of cell constriction. Nucleoplasmic separation did not coincide with termination as during rapid growth but occurred in both strains within the T period, about 10 min before cell division.

Chromosome segregation in Escherichia coli B/r at various growth rates

Chromosome segregation was analyzed in three substrains of Escherichia coli B/r growing at various rates. The cultures were pulse labeled with [14C]thymidine and bound to the bottom surface of a nitrocellulose membrane filter, and the radioactivity in newborn cells released from the surface during continuous elution with growth medium was measured. Since there was a fixed orientation in the release of newborn cells, the time course of the change in radioactivity per effluent cell could be used to investigate the orientation of chromosome segregation. If the radioactive deoxyribonucleic acid strands were partitioned at random between the progenies remaining attached to the membrane filter and those released into the effluent, the radioactivity per cell would decrease twofold after each generation of elution. The decrease in radioactivity was less than twofold at C + D min of elution and larger than twofold one generation later, indicating that chromosome segregation was nonrandom.

Growth response of Escherichia coli to nutritional shift-up: immediate division stimulation in slow-growing cells

When Escherichia coli 15T- cells growing exponentially at 70- to 80-min doubling times are subjected to a nutritional shift-up via glucose addition, cell division continues at the preshift rate for about 70 min (rate maintenance). The same cells growing at doubling times of 120 min or longer, however, begin to divide at a new faster rate immediately upon glucose addition. In both the rate maintenance and immediate division situations, cell mass, as measured by optical density (OD), begins to increase immediately upon shift-up. Consequently, the OD/cell pattern differs in the two growth-rate transitions. During rate maintenance, the OD/cell ratio increases dramatically for 60 to 70 min, and then slows appreciably and approaches the OD/cell characteristic of the new medium. During immediate division situations, the OD/cell increases only slightly for the first 180 +/- min; then the rate of increase accelerates but does not stop at the OD/cell characteristic of the new medium. Immediate division upon nutritional shift-up apparently depends upon initial doubling times in excess of 115 to 120 min and provision of a readily metabolized carbon source supporting doubling times of about 40 min. Similar immediate division occurs in E. coli B/r and K-12.

DNA synthesis by Escherichia coli B/r/l synchronized and grown under conditions of slow growth

Escherichia coli B/r/l was synchronized by a novel method and its growth was followed in a minimal salts medium containing glucose, acetate, aspartate or succinate as the sole carbon source. Thymine incorporation experiments showed agreement with the Cooper-Helmstetter model for DNA synthesis, during the division cycle, both in glucose grown culture with a doubling time 57.5 min and in acetate, aspartate and succinate where the doubling time was extended up to 90 min. The ratio C/C + D was identical or close to that predicted by the model. Prolonged growth of the synchronized cultures prior to each experiment was practised in order to ensure their physiological state without causing any considerable deterioration of synchrony.

Helical growth of Bacillus subtilis: a new model of cell growth

A multiple mutant of Bacillus subtilis that grows in an unusual double-helix morphology was studied. Construction of models led to the assumption that cell surface elongation must proceed in a helical path in this mutant. The observation that all newly formed double-helix clones propagated, after spore outgrowth in fluid culture, consisted of closed-circular structures suggested that double-helix structures are tension-registered forms.

Morphological analysis of nuclear separation and cell division during the life cycle of Escherichia coli

Quantitative electron microscope observations were performed on Escherichia coli B/r after balanced growth with doubling times (tau) of 32 and 60 min. The experimental approach allowed the timing of morphological events during the cell cycle by classifying serially sectioned cells according to length. Visible separation of the nucleoplasm was found to coincide with the time of termination of chromosome replication as predicted by the Cooper-Helmstetter model. The duration of the process of constrictive cell division (10 min) appeared to be independent of the growth rate for tau equals 60 min or less but to increase with increase doubling time in more slowly growing cells. Physiological division, i.e., compartmentalization prior to physical separation of the cells, was only observed to occur in the last minute of the cell cycle. The morphological results indicate that cell elongation continues during the division process in cells with tau equals 32 min, but fails to continue in cells with tau equals 60 min.

Estimation of the D period from residual division after exposure of exponential phase bacteria to chloramphenicol

Values of the D period, between termination of chromosome replication and cell division, were determined from measurements of residual cell division after exposure of exponential phase cultures of Escherichia coli B/r and K12 and of Salmonella typhimurium to chloramphenicol. The results obtained by this method were compared with earlier results for E. coli B/r obtained from measurements of DNA content per cell and were found to be almost identical. For each, values of the D period were independent of growth rate, and the average value of D-26.1 plus or minus 1.2 min obtained by residual division is in good agreement with the value of 25 min obtained earlier. These results indicate that the method of residual division provides a good measure of the duration of the D period. Values of D were also independent of growth rate for each of the other strains.

Deoxyribonucleic acid synthesis during the division cycle of Escherichia coli: a comparison of strains B-r, K-12, 15, and 15T- under conditions of slow growth

The rates of deoxyribonucleic acid (DNA) synthesis during the division cycles of the Escherichia coli strains B/r, K-12 3000, 15T(-), and 15 have been measured in synchronous cultures, under several conditions of slow growth. These synchronous cultures were obtained by sucrose gradient centrifugation of exponentially growing cultures, after which the smallest cells were removed from the gradient and allowed to grow. Sucrose gradient centrifugation did not adversely affect the cell cycle, since an experiment in which an exponentially growing culture was pulsed with [(3)H]thymidine prior to the periodic separation and assay of the smallest cells resulted in the same conclusions, as given below. In the strains of E. coli that were studied, a decreased rate of [(3)H]thymidine incorporation was seen late in the cell cycle, prior to cell division. No decrease in the rate of [(3)H]thymidine incorporation was seen at or near the beginning of the cell cycle. Thus, all these strains appear to regulate DNA synthesis in a similar fashion during slow growth. In addition, a correlation between the appearance of cells with visible cross-walls and the start of a new round of DNA synthesis was seen, indicating that these two events might be related.

Relationships among deoxyribonucleic acid, ribonucleic acid, and specific transfer ribonucleic acids in Escherichia coli 15T - at various growth rates

The levels of macromolecules in Escherichia coli 15T(-) growing in broth, glucose, succinate, and acetate media were determined to compare relationships among deoxyribonucleic acid (DNA), ribosomal ribonucleic acid (rRNA), transfer RNA (tRNA), and protein in cells at different growth rates. DNA and protein increased in relative amounts with decreasing growth rate; relative amounts of rRNA and tRNA decreased, tRNA making up a slightly larger proportion of RNA. For several amino acid-specific tRNAs studied, acceptor capacities per unit of DNA increased with increasing growth rate. The syntheses of tRNA and rRNA are regulated by similar, yet different, mechanisms. Chromatographic examination on columns of benzoylated diethylaminoethyl-cellulose of isoaccepting tRNAs for arginine, leucine, lysine, methionine, phenylalanine, serine, and valine did not reveal differences in the isoaccepting profiles for rapidly (broth culture) and slowly growing (acetate culture) cells. Therefore, isoacceptors for individual amino acids appear to be regulated as a group. Lower efficiencies of ribosomal function in protein synthesis can be explained, in part, by a low ratio of tRNA to the number of ribosomes available and by a decreasing concentration of tRNA with decreasing growth rate. Data on the tRNAs specific for seven amino acids indicate that the decreasing concentration of tRNA is a general event rather than a severe limitation of any one tRNA or isoaccepting tRNA.

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.

Use of fluorouracil-uracil combinations to study growth accompanied by insufficient deoxyribonucleic acid synthesis in Bacillus cereus

5-Fluorouracil (FU) at a concentration of 16 muM almost totally inhibited deoxyribonucleic acid (DNA) synthesis and cell division by Bacillus cereus, whereas growth continued at an exponential rate (25% of control for at least 3 h). In cultures simultaneously given 160 muM uracil (U) along with the FU, DNA synthesis still stopped, but cell division continued for one generation at the control rate and at a much slower rate beyond that; in the meantime, cell mass continued to increase at an essentially normal rate. The cells in cultures treated with FU or FU plus U were elongated and contained about half of the control content of DNA, with one nuclear area per cell instead of two. Loss of cloning ability, unlike mass increase, was always correlated with the continuing inhibition of DNA synthesis, in either FU- or U plus FU-treated cultures.

Deoxyribonucleic acid distribution in Bacillus subtilis independent of cell elongation

A temperature-sensitive DNA(-) mutant of Bacillus subtilis has been studied during the resumption of deoxyribonucleic acid (DNA) synthesis following a 45 to 30 C temperature shift. For several hours after return to 30 C, DNA synthesis proceeds although the cells fail to elongate appreciably. Autoradiographs of cell populations synthesizing DNA during the recovery period demonstrate that DNA can become distributed to previously unoccupied regions along the cell length. By varying the labeling regime, newly synthesized DNA as well as DNA present at the time of transfer from 45 to 30 C were followed independently. Measurements of the percent of cell length covered by grains ((3)H-thymine in DNA) demonstrate the progressive refilling of DNA-vacant cell regions by both newly synthesized and original DNA. These data indicate that cell surface growth is not an absolute requirement for segregation of bacterial DNA.

Chromosome replication and cell division in Escherichia coli at various temperatures of growth

The effect of temperature on the growth rate and the pattern of chromosome replication during the division cycle of Escherichia coli B/r growing in various media was investigated. The time between divisions, the time for a round of replication (C), and the time between completion of a round and cell division (D) were threefold longer at 21 C than at 37 C. At all temperatures and in all media, D equalled one-half C, suggesting that a common mechanism controls chromosome replication and the progression of the cell toward division after completion of a round of replication.

Chromosome replication and the division cycle of Escherichia coli B-r

The average amount of deoxyribonucleic acid (DNA) per cell was measured in steady-state cultures of Escherichia coli B/r grown at 37 C in glucose-limited chemostats or in batch cultures in the exponential growth phase as maintained with one of several carbon sources. Within experimental errors, DNA content was dependent only on growth rate and independent of the type of culture, the carbon source, or the addition of growth factors. The amount of DNA per cell increased continuously with growth rate over the range of 0.02 to 3 divisions per hour. The data over the entire range of growth rates are in agreement with a constant time for a single replication point to traverse the entire genome, 47 min, and with cell division following 25 min after termination of replication. The measured amount of DNA per genome was 4.2 x 10(-15) g (or 2.5 x 10(9) daltons).