Your search keyword '"E. coli Cell cycle"' showing total 48 results

1. PcdA promotes orthogonal division plane selection in Staphylococcus aureus.

Author

Ramos-León F, Anjuwon-Foster BR, Anantharaman V, Updegrove TB, Ferreira CN, Ibrahim AM, Tai CH, Kruhlak MJ, Missiakas DM, Camberg JL, Aravind L, and Ramamurthi KS

Subjects

Animals, Mice, Virulence, Anti-Bacterial Agents pharmacology, Female, Staphylococcus aureus genetics, Staphylococcus aureus metabolism, Bacterial Proteins metabolism, Bacterial Proteins genetics, Cell Division, Staphylococcal Infections microbiology, Cytoskeletal Proteins metabolism, Cytoskeletal Proteins genetics

Abstract

The bacterial pathogen, Staphylococcus aureus, grows by dividing in two alternating orthogonal planes. How these cell division planes are positioned correctly is not known. Here we used chemical genetic screening to identify PcdA as a division plane placement factor. Molecular biology and imaging approaches revealed non-orthogonal division plane selection for pcdA mutant bacteria. PcdA is a structurally and functionally altered member of the McrB AAA+ NTPase family, which are often found as restriction enzyme subunits. PcdA interacts with the tubulin-like divisome component, FtsZ, and the structural protein, DivIVA; it also localizes to future cell division sites. PcdA multimerization, localization and function are NTPase activity-dependent. We propose that the DivIVA/PcdA complex recruits unpolymerized FtsZ to assemble along the proper cell division plane. Although pcdA deletion did not affect S. aureus growth in several laboratory conditions, its clustered growth pattern was disrupted, sensitivity to cell-wall-targeting antibiotics increased and virulence in mice decreased. We propose that the characteristic clustered growth pattern of S. aureus, which emerges from dividing in alternating orthogonal division planes, might protect the bacterium from host defences., (© 2024. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2024

2. Analysis of a myosin-like protein and the role of calcium in the E. coli cell cycle

Author

I. B. Holland, Annick Jacq, V. Norris, S. Mckenna, H. Sweetman, N. Bouquin, M. Chen, S. Bernard, S. Casaregola, G. Mc Gurk, S. Seror, S. Margarson, M. Tempete, and M. Goldberg

Subjects

Genetics, Mutation, Cell Cycle, Drug Resistance, Microbial, General Medicine, Cell cycle, Biology, Myosins, medicine.disease_cause, Microbiology, DnaA, Chromosome segregation, Bacterial Proteins, Genes, Bacterial, Myosin, medicine, biology.protein, Escherichia coli, Calcium, FtsZ, Molecular Biology, Gene, Cell Division

Abstract

For a number of years now, we have argued that current models for the control of initiation of DNA synthesis, chromosomal partitioning and septum formation in Escherichia coli are unsatisfactory. Indeed, we could argue that despite considerable efforts, with the possible exception of dnaA and ftsZ, no genes specifically implicated in these control processes have been identified. In the cases of DnaA and FtsZ, no evidence has appeared to indicate how such molecules might be regulated to act once per cycle. In 1988, we formulated a specific proposal that the timing of cell cycle events in E. coli might be determined by a Ca++ flux, mediated by calcium-binding proteins and protein kinases and culminating, in the case of chromosome segregation and division, in the action of force-generating proteins such as myosin (Norris et al., 1988). In formulating this proposal, we took the view that the fundamental elements of cell cycle regulation are likely to be highly conserved across all species including prokaryotes. In this presentation, we shall describe the approaches we have been taking in order to test this hypothesis and to summarize the data obtained, in particular in relation to new genes identified which may play a role in the E. coli cell cycle. We shall also briefly indicate recent data from other laboratories consistent with our general hypothesis.

Published

1991

3. The E. coli cell cycle and the plasmid R1 replication cycle in the absence of the DnaA protein

Author

Rolf Bernander, Kurt Nordström, and Santanu Dasgupta

Subjects

DNA Replication, Cell Cycle, DNA Helicases, Temperature, Proteins, Eukaryotic DNA replication, Biology, Origin of replication, Pre-replication complex, Molecular biology, General Biochemistry, Genetics and Molecular Biology, DnaA, DNA-Binding Proteins, Replication factor C, SeqA protein domain, Control of chromosome duplication, Bacterial Proteins, Mutagenesis, DNA Transposable Elements, Escherichia coli, Trans-Activators, bacteria, Origin recognition complex, Cell Division, Plasmids

Abstract

In E. coli strain EC::71CW chromosome replication is under the control of the R1 miniplasmid pOU71. A dnaA850::Tn10 derivative of EC::71CW was viable, which confirmed that R1 can replicate in the absence of the DnaA protein. The frequency of initiation of replication was, however, lowered and cell division was severely disturbed due to underreplication of the chromosome. Both replication and cell division could be restored to normal by increasing the production of RepA, the rate-limiting protein for initiation of replication from the integrated R1 origin. Therefore, the RepA protein seems to compensate for the absence of DnaA in the initiation of replication and assembly of replisomes. The role of the DnaA protein in the initiation of DNA replication, and as an overall regulator of the chromosome replication and cell division cycles of E. coli, is discussed in view of these results.

Published

1991

4. Growth of the Cell Envelope in the E. coli Cell Cycle

Author

A. Ryter, Uli Schwarz, M. Ricard, and Yukinori Hirota

Subjects

chemistry.chemical_compound, Cell division, chemistry, Chromosome replication, Cell cycle, Cell envelope, Diaminopimelic acid, Cell biology

Abstract

This is a discussion of the biochemistry of cell division, intended also as an introduction to Dr. Hirota’s forthcoming contribution.

Published

1974

5. Mutations of DnaA-boxes in the oriR region increase replication frequency of the MiniR1–1 plasmid

Author

Sukhbold Enkhtsetseg, Lifei Fan, Ingvild Odsbu, Morigen Morigen, and Yuan Yao

Subjects

DNA Replication, DNA, Bacterial, 0301 basic medicine, Microbiology (medical), Cell division, R1 plasmid, Genetic Vectors, genetic processes, 030106 microbiology, lcsh:QR1-502, Cloning vector, Replication Origin, Biology, medicine.disease_cause, Microbiology, lcsh:Microbiology, DnaA-boxes, 03 medical and health sciences, Plasmid, Bacterial Proteins, Escherichia coli, MiniR1–1 replication, medicine, Complete genome sequence, Gene, Mutation, Binding Sites, Base Sequence, Escherichia coli Proteins, DNA Helicases, DNA replication, DNA, Sequence Analysis, DNA, Molecular biology, DnaA, DNA-Binding Proteins, 030104 developmental biology, Copper-Transporting ATPases, Trans-Activators, health occupations, bacteria, E. coli Cell cycle, Plasmids, Research Article

Abstract

Background The MiniR1–1 plasmid is a derivative of the R1 plasmid, a low copy cloning vector. Results Nucleotide sequencing analysis shows that the MiniR1–1 plasmid is a 6316 bp circular double-stranded DNA molecule with an oriR1 (origin for replication). The plasmid carries the repA, tap, copA and bla genes, and genes for ORF1 and ORF2. MiniR1–1 contains eight DnaA-binding sites (DnaA-boxes). DnaA-box1 is in the oriR1 region and fully matched to the DnaA-box consensus sequence, and DnaA-box8, with one mismatch, is close to the copA gene. The presence of the MiniR1–1 plasmid leads to an accumulation of the D-period cells and an increase in cell size of slowly growing Escherichia coli cells, suggesting that the presence of MiniR1–1 delays cell division. Mutations in the MiniR1–1 DnaA-box1 and DnaA-box8 significantly increase the copy number of the plasmid and the mutations in DnaA-box1 also affect cell size. It is likely that titration of DnaA to DnaA-boxes negatively controls replication of the MiniR1–1 plasmid and delays cell division. Interestingly, DnaA weakly interacts with the initiator protein RepA in vivo. Conclusion DnaA regulates the copy number of MiniR1–1 as a negative factor through interacting with the RepA protein. Electronic supplementary material The online version of this article (10.1186/s12866-018-1162-3) contains supplementary material, which is available to authorized users.

Published

2018

6. Growth of the Cell Envelope in the E. coli Cell Cycle

Author

Hirota, Y., Ryter, A., Ricard, M., Schwarz, Uli, Kolber, Alan R., editor, and Kohiyama, Masamichi, editor

Published

1974

7. AspC-Mediated Aspartate Metabolism Coordinates the Escherichia coli Cell Cycle.

Author

Liu, Feng, Qimuge, Hao, Jianfeng, Yan, Huijuan, Bach, Trond, Fan, Lifei, and Morigen

Subjects

ASPARTIC acid metabolism, ESCHERICHIA coli, MICROBIAL cell cycle, CELL growth, BACTERIA, CHROMOSOME replication, CELL division

Abstract

Background: The fast-growing bacterial cell cycle consists of at least two independent cycles of chromosome replication and cell division. To ensure proper cell cycles and viability, chromosome replication and cell division must be coordinated. It has been suggested that metabolism could affect the Escherichia coli cell cycle, but the idea is still lacking solid evidences. Methodology/Principle Findings: We found that absence of AspC, an aminotransferase that catalyzes synthesis of aspartate, led to generation of small cells with less origins and slow growth. In contrast, excess AspC was found to exert the opposite effect. Further analysis showed that AspC-mediated aspartate metabolism had a specific effect in the cell cycle, as only extra aspartate of the 20 amino acids triggered production of bigger cells with more origins per cell and faster growth. The amount of DnaA protein per cell was found to be changed in response to the availability of AspC. Depletion of (p)ppGpp by ΔrelAΔspoT led to a slight delay in initiation of replication, but did not change the replication pattern found in the ΔaspC mutant. Conclusion/Significances: The results suggest that AspC-mediated metabolism of aspartate coordinates the E. coli cell cycle through altering the amount of the initiator protein DnaA per cell and the division signal UDP-glucose. Furthermore, AspC sequence conservation suggests similar functions in other organisms. [ABSTRACT FROM AUTHOR]

Published

2014

8. Coordination between replication, segregation and cell division in multi-chromosomal bacteria: lessons from Vibrio cholerae.

Author

Espinosa E, Barre FX, and Galli E

Subjects

DNA Replication, Phylogeny, Cell Division, Chromosomes, Bacterial, Vibrio cholerae cytology

Abstract

Bacteria display a highly flexible cell cycle in which cell division can be temporally disconnected from the replication/segregation cycle of their genome. The accuracy of genetic transmission is enforced by restricting the assembly of the cell division apparatus to the low DNA-density zones that develop between the regularly spaced nucleoids originating from the concurrent replication and segregation of genomic DNA. In most bacteria, the process is simplified because the genome is encoded on a single chromosome. This is notably the case in Escherichia coli, the most well studied bacterial model organism. However, ~10% of bacteria have domesticated horizontally acquired mega-plasmids into extra-numerous chromosomes. Most of our current knowledge on the cell cycle regulation of multi-chromosomal species derives from the study of replication, segregation and cell division in Vibrio cholerae, the agent of the deadly epidemic human diarrheal disease cholera. A nicety of this model is that it is closely related to E. coli in the phylogenetic tree of bacteria. Here, we review recent findings on the V. cholerae cell cycle in the context of what was previously known on the E. coli cell cycle., (Copyright© by the Spanish Society for Microbiology and Institute for Catalan Studies.)

Published

2017

9. Insights into the Cellular Function of YhdE, a Nucleotide Pyrophosphatase from Escherichia coli.

Author

Jin, Jin, Wu, Ruijuan, Zhu, Jia, Yang, Shaoyuan, Lei, Zhen, Wang, Nan, Singh, Vinay K., Zheng, Jimin, and Jia, Zongchao

Subjects

CELL physiology, NUCLEOTIDE pyrophosphatase, ESCHERICHIA coli, BACTERIAL cells, CRYSTAL structure, CELL growth, CELL division, BACTERIA

Abstract

YhdE, a Maf-like protein in Escherichia coli, exhibits nucleotide pyrophosphatase (PPase) activity, yet its cellular function remains unknown. Here, we characterized the PPase activity of YhdE on dTTP, UTP and TTP and determined two crystal structures of YhdE, revealing ‘closed’ and ‘open’ conformations of an adaptive active site. Our functional studies demonstrated that YhdE retards cell growth by prolonging the lag and log phases, particularly under stress conditions. Morphology studies showed that yhdE-knockout cells transformed the normal rod shape of wild-type cells to a more spherical form, and the cell wall appeared to become more flexible. In contrast, YhdE overexpression resulted in filamentous cells. This study reveals the previously unknown involvement of YhdE in cell growth inhibition under stress conditions, cell-division arrest and cell-shape maintenance, highlighting YhdE’s important role in E. coli cell-cycle checkpoints. [ABSTRACT FROM AUTHOR]

Published

2015

10. The C‐terminal domain of MinC, a cell division regulation protein, is sufficient to form a copolymer with MinD.

Author

Wang, Na, Sun, Haiyu, Zhao, Kairui, Shi, Runqing, Wang, Shenping, Zhou, Yao, Zhai, Meiting, Huang, Chenghao, and Chen, Yaodong

Subjects

CELL division, CELLULAR control mechanisms, BACTERIAL cells, PSEUDOMONAS aeruginosa, PROTEINS

Abstract

Assembly of cell division protein FtsZ into the Z‐ring at the division site is a key step in bacterial cell division. The Min proteins can restrict the Z‐ring to the middle of the cell. MinC is the main protein that obstructs Z‐ring formation by inhibiting FtsZ assembly. Its N‐terminal domain (MinCN) regulates the localization of the Z‐ring by inhibiting FtsZ polymerization, while its C‐terminal domain (MinCC) binds to MinD as well as to FtsZ. Previous studies have shown that MinC and MinD form copolymers in vitro. This copolymer may greatly enhance the binding of MinC to FtsZ, and/or prevent FtsZ filaments from diffusing to the ends of the cell. Here, we investigated the assembly properties of MinCC–MinD of Pseudomonas aeruginosa. We found that MinCC is sufficient to form the copolymers. Although MinCC–MinD assembles into larger bundles, most likely because MinCC is spatially more readily bound to MinD, its copolymerization has similar dynamic properties: the concentration of MinD dominates their copolymerization. The critical concentration of MinD is around 3 μm and when MinD concentration is high enough, a low concentration MinCC could still be copolymerized. We also found that MinCC–MinD can still rapidly bind to FtsZ protofilaments, providing direct evidence that MinCC also interacts directly with FtsZ. However, although the presence of minCC can slightly improve the division defect of minC‐knockout strains and shorten the cell length from an average of 12.2 ± 6.7 to 6.6 ± 3.6 μm, it is still insufficient for the normal growth and division of bacteria. [ABSTRACT FROM AUTHOR]

Published

2023

11. Cell division in Escherichia coli minB mutants.

Author

Akerlund T, Bernander R, and Nordström K

Subjects

Cell Cycle, Cell Nucleus physiology, Colony Count, Microbial, Escherichia coli cytology, Escherichia coli growth & development, Cell Division genetics, Escherichia coli genetics

Abstract

In Escherichia coli minB mutants, cell division can take place at the cell poles as well as non-polarly in the cell. We have examined growth, division patterns, and nucleoid distribution in individual cells of a minC point mutant and a minB deletion mutant, and compared them to the corresponding wild-type strain and an intR1 strain in which the chromosome is over-replicated. The main findings were as follows. In the minB mutants, polar and non-polar divisions appeared to occur independently of each other. Furthermore, the timing of cell division in the cell cycle was found to be severely affected. In addition, nucleoid conformation and distribution were considerably disturbed. The results obtained call for a re-evaluation of the role of the MinB system in the E. coli cell cycle, and of the concept that limiting quanta of cell division factors are regularly produced during the cell cycle.

Published

1992

12. Fifty-Five Years of Research on B , C and D in Escherichia coli.

Author

Helmstetter, Charles E.

Subjects

CHROMOSOME replication, CELL division, CELL cycle, ESCHERICHIA coli

Abstract

The basic properties of the Escherichia coli duplication process can be defined by two time periods: C, the time for a round of chromosome replication, and D, the time between the end of a round of replication and cell division. Given the durations of these periods, the pattern of chromosome replication during the cell cycle can be determined for cells growing with any doubling time. In the 55 years since these parameters were identified, there have been numerous investigations into their durations and into the elements that determine their initiations. In this review, I discuss the history of our involvement in these studies from the very beginning, some of what has been learned over the years by measuring the durations of C and D, and what might be learned with additional investigations. [ABSTRACT FROM AUTHOR]

Published

2023

13. DNA double strand break repair in Escherichia coli perturbs cell division and chromosome dynamics.

Author

White, Martin A., Darmon, Elise, Lopez-Vernaza, Manuel A., and Leach, David R. F.

Subjects

DOUBLE-strand DNA breaks, DNA replication, CELL division, SINGLE-stranded DNA, ESCHERICHIA coli, CELL size, CELL cycle, CHROMOSOMES

Abstract

To prevent the transmission of damaged genomic material between generations, cells require a system for accommodating DNA repair within their cell cycles. We have previously shown that Escherichia coli cells subject to a single, repairable site-specific DNA double-strand break (DSB) per DNA replication cycle reach a new average cell length, with a negligible effect on population growth rate. We show here that this new cell size distribution is caused by a DSB repair-dependent delay in completion of cell division. This delay occurs despite unperturbed cell size regulated initiation of both chromosomal DNA replication and cell division. Furthermore, despite DSB repair altering the profile of DNA replication across the genome, the time required to complete chromosomal duplication is invariant. The delay in completion of cell division is accompanied by a DSB repair-dependent delay in individualization of sister nucleoids. We suggest that DSB repair events create inter-sister connections that persist until those chromosomes are separated by a closing septum. Author summary: The bacterium Escherichia coli has a remarkable cell cycle where overlapping rounds of DNA replication can occur in a single generation between cell birth and division. This implies a complex coordination network between growth, genome duplication and cell division to ensure that the right number of genomes are created and distributed to daughter cells at all growth rates. This network must be robust to a number of unpredictable challenges. One such challenge is broken DNA, something that in E. coli is estimated to occur in ~20% of cell division cycles. In this work we perturb the E. coli cell cycle by elevating the frequency of repairable DNA double-strand breaks to ~100% of cell division cycles to determine which parameters of the cell cycle are conserved and which are changed. Our results demonstrate that this perturbation does not alter the average cell size at initiation of DNA replication or initiation of cell division. Furthermore, it does not alter the time taken to replicate the genome or the generation time. However, it does delay the segregation of the DNA to daughter cells and the completion of cell division explaining the increase in average cell size observed previously. [ABSTRACT FROM AUTHOR]

Published

2020

14. Editorial: Bacterial transcription factors and the cell cycle, volume II.

Author

Morigen, Glinkowska, Monika, Jianping Xie, Priyadarshini, Richa, and Kazutoshi Kasho

Subjects

TRANSCRIPTION factors, CELL cycle, CELL division

Published

2023

15. How Do MinC-D Copolymers Act on Z-Ring Localization Regulation? A New Model of Bacillus subtilis Min System.

Author

Wang, Na, Zhang, Tingting, Du, Shuheng, Zhou, Yao, and Chen, Yaodong

Subjects

LIGHT scattering, CONCENTRATION gradient, CELL division, MICROSCOPY, ELECTRON microscopy

Abstract

Division site selection in rod-shaped bacteria is strictly regulated spatially by the Min system. Although many sophisticated studies, including in vitro recombination, have tried to explain these regulations, the precise mechanisms are still unclear. A previous model suggested that the concentration gradient of MinC, an FtsZ inhibitor, regulates the position of the Z-ring in the cell. In Escherichia coli , the oscillation of MinCDE proteins leads to a gradient of Min proteins with the average concentration being lowest in the middle and highest near the poles. In contrast to the Min system of E. coli , the Min system of Bacillus subtilis lacks MinE and exhibits a stable concentration distribution, which is regulated by the binding of DivIVA to the negative curvature membrane. The Min proteins first accumulate at the poles of the cell and relocalize near the division site when the membrane invagination begins. It is inconsistent with the previous model of high concentrations of MinC inhibiting Z-ring formation. Our preliminary data here using electron microscopy and light scattering technology reported that B. subtilis MinC (BsMinC) and MinD (BsMinD) also assembled into large straight copolymers in the presence of ATP, similar to the Min proteins of E. coli. Their assembly is fast and dominated by MinD concentration. When BsMinD is 5 μM, a clear light scattering signal can be observed even at 0.3 μM BsMinC. Here, we propose a new model based on the MinC-D copolymers. In our hypothesis, it is not the concentration gradient of MinC, but the MinC-D copolymer assembled in the region of high concentration MinD that plays a key role in the regulation of Z-ring positioning. In B. subtilis , the regions with high MinD concentration are initially at both ends of the cell and then appear at midcell when cell division began. MinC-D copolymer will polymerize and form a complex with MinJ and DivIVA. These complexes capture FtsZ protofilaments to prevent their diffusion away from the midcell and narrow the Z-ring in the middle of the cell. [ABSTRACT FROM AUTHOR]

Published

2022

16. Levels in Biological Organisms: Hierarchy of Production Mechanisms, Heterarchy of Control Mechanisms.

Author

Bechtel, William

Subjects

PHENOMENOLOGICAL biology, BLOOD circulation, PRODUCTION control, CELL division, ESCHERICHIA coli

Abstract

Among the notions of levels invoked in accounts of biological phenomena, I focus on two: levels of production mechanisms and levels of control mechanisms. I argue that these two notions of level exhibit different characteristics: production mechanisms are organized hierarchically while control mechanisms are often organized heterarchically. I illustrate the differences in these modes of organization by examining production and control mechanisms involved in cell division in Escherichia coli and in circulation of blood in mammals. I conclude by exploring how these two notions of levels can be integrated by adopting a perspective in which organisms are autonomous systems maintaining themselves far from equilibrium. [ABSTRACT FROM AUTHOR]

Published

2022

17. Identification of a Genetically Linked but Functionally Independent Two-Component System Important for Cell Division of the Rice Pathogen Burkholderia glumae.

Author

Marunga, Joan, Goo, Eunhye, Kang, Yongsung, and Hwang, Ingyu

Subjects

CELL division, BURKHOLDERIA, RICE, PROMOTERS (Genetics), BACTERIAL cells, GENE clusters

Abstract

Bacterial two-component regulatory systems control the expression of sets of genes to coordinate physiological functions in response to environmental cues. Here, we report a genetically linked but functionally unpaired two-component system (TCS) comprising the sensor kinase GluS (BGLU_1G13350) and the response regulator GluR (BGLU_1G13360), which is critical for cell division in the rice pathogen Burkholderia glumae BGR1. The gluR null mutant, unlike the gluS mutant, formed filamentous cells in Lysogeny Broth medium and was sensitive to exposure to 42°C. Expression of genes responsible for cell division and cell-wall (dcw) biosynthesis in the gluR mutant was elevated at transcription levels compared with the wild type. GluR-His bound to the putative promoter regions of ftsA and ftsZ is involved in septum formation, indicating that repression of genes in the dcw cluster by GluR is critical for cell division in B. glumae. The gluR mutant did not form filamentous cells in M9 minimal medium, whereas exogenous addition of glutamine or glutamate to the medium induced filamentous cell formation. These results indicate that glutamine and glutamate influence GluR-mediated cell division in B. glumae , suggesting that GluR controls cell division of B. glumae in a nutrition-dependent manner. These findings provide insight into how the recognition of external signals by TCS affects the sophisticated molecular mechanisms involved in controlling bacterial cell division. [ABSTRACT FROM AUTHOR]

Published

2021

18. Assembly properties of bacterial tubulin homolog FtsZ regulated by the positive regulator protein ZipA and ZapA from Pseudomonas aeruginosa.

Author

Rahman, Mujeeb ur, Li, Zhe, Zhang, Tingting, Du, Shuheng, Ma, Xueqin, Wang, Ping, and Chen, Yaodong

Subjects

TUBULINS, PSEUDOMONAS aeruginosa, ESCHERICHIA coli, CELL division, HYDROGEN-ion concentration

Abstract

Bacterial tubulin homolog FtsZ self-assembles into dynamic protofilaments, which forms the scaffold for the contractile ring (Z-ring) to achieve bacterial cell division. Here, we study the biochemical properties of FtsZ from Pseudomonas aeruginosa (PaFtsZ) and the effects of its two positive regulator proteins, ZipA and ZapA. Similar to Escherichia coli FtsZ, PaFtsZ had a strong GTPase activity, ~ 7.8 GTP min-1 FtsZ-1 at pH 7.5, and assembled into mainly short single filaments in vitro. However, PaFtsZ protofilaments were mixtures of straight and "intermediate-curved" (100–300 nm diameter) in pH 7.5 solution and formed some bundles in pH 6.5 solution. The effects of ZipA on PaFtsZ assembly varied with pH. In pH 6.5 buffer ZipA induced PaFtsZ to form large bundles. In pH 7.5 buffer PaFtsZ-ZipA protofilaments were not bundled, but ZipA enhanced PaFtsZ assembly and promoted more curved filaments. Comparable to ZapA from other bacterial species, ZapA from P. aeruginosa induced PaFtsZ protofilaments to associate into long straight loose bundles and/or sheets at both pH 6.5 and pH 7.5, which had little effect on the GTPase activity of PaFtsZ. These results provide us further information that ZipA functions as an enhancer of FtsZ curved filaments, while ZapA works as a stabilizer of FtsZ straight filaments. [ABSTRACT FROM AUTHOR]

Published

2020

19. Editorial: Bacterial Transcription Factors and the Cell Cycle.

Author

Morigen, Glinkowska, Monika, and Xie, Jianping

Subjects

CELL cycle, TRANSCRIPTION factors, CHROMOSOME replication, HEAT shock proteins, DNA-binding proteins, CELL division, CELL cycle regulation, PALINDROMIC DNA

Abstract

Especially, in I Caulobacter crescentus i , DnaA couples DNA replication with the expression of the two oscillating regulators GcrA and CtrA, and the DnaA/GcrA/CtrA regulatory cascade drives forward the progression of the cell cycle (Collier et al., [5]). Keywords: bacterial transcription factors; chromosome replication; cell division; cell growth; cell cycle EN bacterial transcription factors chromosome replication cell division cell growth cell cycle 1 3 3 12/29/21 20211224 NES 211224 Introduction The fluctuation in gene expression regulated by transcription factors are tightly associated with progression of the bacterial cell cycle. Other transcription factors and proteins involved in transcription control have also been shown to coordinate the cell cycle events. [Extracted from the article]

Published

2021

20. Mechanisms of Bacterial Cell Division.

Author

Vedyaykin, A. D., Ponomareva, E. V., Khodorkovskii, M. A., Borchsenius, S. N., and Vishnyakov, I. E.

Subjects

BACTERIAL cells, CELL division, MOLECULAR microbiology, GRAM-negative bacteria, BACILLUS subtilis, ESCHERICHIA coli

Abstract

Despite numerous studies, gaps still remain in our understanding of bacterial cell division. This review describes the basic mechanisms responsible for division of the bacterial cell and coordination of this process in space and time. Attention is concentrated on such well-studied, model microorganisms as gram-negative bacteria Escherichia coli and gram-positive Bacillus subtilis. The hypothetical models of cell division of mycoplasmas which lack a cell wall and have lost most of the genes encoding the homologs of the known components of the bacterial divisome are also considered. Due to the fact that the bacterial division apparatus is a promising target for new antibiotics, the investigation of this process, apart from basic importance, is also of applied interest, and therefore is one of the priorities of modern molecular microbiology. [ABSTRACT FROM AUTHOR]

Published

2019

21. Coordination of Growth, Chromosome Replication/Segregation, and Cell Division in E. coli

Author

Nancy E. Kleckner, Katerina Chatzi, Martin A. White, Jay K. Fisher, and Mathieu Stouf

Subjects

E. coli, cell cycle coordination, bacteria, chromosome, cell division, DNA replication, Microbiology, QR1-502

Abstract

Bacterial cells growing in steady state maintain a 1:1:1 relationship between an appropriate mass increase, a round of DNA replication plus sister chromosome segregation, and cell division. This is accomplished without the cell cycle engine found in eukaryotic cells. We propose here a formal logic, and an accompanying mechanism, for how such coordination could be provided in E. coli. Completion of chromosomal and divisome-related events would lead, interactively, to a “progression control complex” (PCC) which provides integrated physical coupling between sister terminus regions and the nascent septum. When a cell has both (i) achieved a sufficient mass increase, and (ii) the PCC has developed, a conformational change in the PCC occurs. This change results in “progression permission,” which triggers both onset of cell division and release of terminus regions. Release of the terminus region, in turn, directly enables a next round of replication initiation via physical changes transmitted through the nucleoid. Division and initiation are then implemented, each at its own rate and timing, according to conditions present. Importantly: (i) the limiting step for progression permission may be either completion of the growth requirement or the chromosome/divisome processes required for assembly of the PCC; and, (ii) the outcome of the proposed process is granting of permission to progress, not determination of the absolute or relative timings of downstream events. This basic logic, and the accompanying mechanism, can explain coordination of events in both slow and fast growth conditions; can accommodate diverse variations and perturbations of cellular events; and is compatible with existing mathematical descriptions of the E. coli cell cycle. Also, while our proposition is specifically designed to provide 1:1:1 coordination among basic events on a “per-cell cycle” basis, it is a small step to further envision permission progression is also the target of basic growth rate control. In such a case, the rate of mass accumulation (or its equivalent) would determine the length of the interval between successive permission events and, thus, successive cell divisions and successive replication initiations.

Published

2018

22. HflX protein protects Escherichia coli from manganese stress.

Author

Sengupta, Sandeepan, Mondal, Avisek, Dutta, Dipak, and Parrack, Pradeep

Subjects

ESCHERICHIA coli, HOMEOSTASIS, CONFOCAL microscopy, CELL growth, MOLECULAR biology

Abstract

The ribosome-binding GTPase HflX is required for manganese homeostasis in E. coli. While under normal conditions ∆hflX cells behave like wild type E. coli with respect to growth pattern and morphology, deletion of hflX makes E. coli cells extremely sensitive to manganese, characterized by arrested cell growth and filamentation. Here we demonstrate that upon complementation by hflX, manganese stress is relieved. In phenotypic studies done in a manganese-rich environment, ∆hflX cells were highly sensitive to antibiotics that bind the penicillin binding protein 3 (PBP3), suggesting that the manganese stress led to impaired peptidoglycan biosynthesis. An irregular distribution of dark bands of constriction along filaments, delocalization of the dark bands from midcell towards poles and subpoles, lack of septum formation and arrested cell division were observed in ∆hflX cells under manganese stress. However, chromosome replication and segregation of nucleoids were unaffected under these conditions, as observed from confocal microscopy imaging and FACS studies. We conclude that absence of HflX leads to manganese accumulation in E. coli cells, affecting cell septum formation, probably by modulating the activity of the cell division protein PBP3 (FtsI), a major component of the divisome apparatus. We propose that HflX acts as a gatekeeper, regulating the influx of manganese into the cell. [ABSTRACT FROM AUTHOR]

Published

2018

23. High-throughput sequencing of sorted expression libraries reveals inhibitors of bacterial cell division.

Author

Mediati, Daniel G., Burke, Catherine M., Ansari, Shirin, Harry, Elizabeth J., and Duggin, Iain G.

Subjects

FILAMENTATION instability, PLASMA instabilities, BACTERIA, DNA, GENOMES

Abstract

Background: Bacterial filamentation occurs when rod-shaped bacteria grow without dividing. To identify genetically encoded inhibitors of division that promote filamentation, we used cell sorting flow cytometry to enrich filamentous clones from an inducible expression library, and then identified the cloned DNA with high-throughput DNA sequencing. We applied the method to an expression library made from fragmented genomic DNA of uropathogenic E. coli UTI89, which undergoes extensive reversible filamentation in urinary tract infections and might encode additional regulators of division. Results: We identified 55 genomic regions that reproducibly caused filamentation when expressed from the plasmid vector, and then further localized the cause of filamentation in several of these to specific genes or sub-fragments. Many of the identified genomic fragments encode genes that are known to participate in cell division or its regulation, and others may play previously-unknown roles. Some of the prophage genes identified were previously implicated in cell division arrest. A number of the other fragments encoded potential short transcripts or peptides. Conclusions: The results provided evidence of potential new links between cell division and distinct cellular processes including central carbon metabolism and gene regulation. Candidate regulators of the UTI-associated filamentation response or others were identified amongst the results. In addition, some genomic fragments that caused filamentation may not have evolved to control cell division, but may have applications as artificial inhibitors. Our approach offers the opportunity to carry out in depth surveys of diverse DNA libraries to identify new genes or sequences encoding the capacity to inhibit division and cause filamentation. [ABSTRACT FROM AUTHOR]

Published

2018

24. Disruption of divisome assembly rescued by FtsN-FtsA interaction in Escherichia coli.

Author

Pichoff, Sebastien, Shishen Du, and Lutkenhaus, Joe

Subjects

CELL division, PEPTIDOGLYCANS, ESCHERICHIA coli, PROTEINS, PERIPLASM

Abstract

Cell division requires the assembly of a protein complex called the divisome. The divisome assembles in a hierarchical manner, with FtsA functioning as a hub to connect the Z-ring with the rest of the divisome and FtsN arriving last to activate the machine to synthesize peptidoglycan. FtsEX arrives as the Z-ring forms and acts on FtsA to initiate recruitment of the other divisome components. In the absence of FtsEX, recruitment is blocked; however, a multitude of conditions allow FtsEX to be bypassed. Here, we find that all such FtsEX bypass conditions, as well as the bypass of FtsK, depend upon the interaction of FtsN with FtsA, which promotes the backrecruitment of the late components of the divisome. Furthermore, our results suggest that these bypass conditions enhance the weak interaction of FtsN with FtsA and its periplasmic partners so that the divisome proteins are brought to the Z-ring when the normal hierarchical pathway is disrupted. [ABSTRACT FROM AUTHOR]

Published

2018

25. Absence of the Min System Does Not Cause Major Cell Division Defects in Agrobacterium tumefaciens.

Author

Flores, Sue A., Howell, Matthew, Daniel, Jeremy J., Piccolo, Rebecca, and Brown, Pamela J. B.

Subjects

CELL division, AGROBACTERIUM tumefaciens, CHROMOSOME segregation, BACTERIAL chromosomes, BACTERIA

Abstract

In A. tumefaciens, the essential FtsZ protein is located at the growth pole before shifting to the mid-cell right before division. Loss of FtsZ causes a halt in cell separation and lysis of cells. To understand how FtsZ polymerization is regulated to properly localize the FtsZ ring at the mid-cell, we have conducted a systematic characterization of the Min system in A. tumefaciens. Our findings indicate that the Min system is not required for cell survival. Yet, we find that the deletion of either minE or minCDE results in a broad cell size distribution, including an increase in the proportion of short and long cells. We observe that the site of constriction is misplaced in the minE or minCDE deletion strains allowing for short cells to arise from sites of constriction near the cell poles. Remarkably, the short cells are viable and contain DNA. In order to observe chromosome replication and segregation in these strains, YFP-ParB is used as a proxy to track the origin of replication as cells elongate and divide. In the absence of the Min proteins, duplication and segregation of the origin of replication is frequently delayed. Taken together, our data suggest that the Min system contributes to the proper regulation of FtsZ placement and subsequent cell division. Furthermore, the failure to precisely place FtsZ rings at mid-cell in the min mutants impacts other cell cycle features including chromosome segregation. [ABSTRACT FROM AUTHOR]

Published

2018

26. Interaction of Type IV Toxin/Antitoxin Systems in Cryptic Prophages of Escherichia coli K-12.

Author

Zhongling Wen, Pengxia Wang, Chenglong Sun, Yunxue Guo, and Xiaoxue Wang

Subjects

ESCHERICHIA coli, ANTITOXINS, CYANOBACTERIA, CELL division, LYSIS, BACTERIA

Abstract

Toxin/antitoxin (TA) systems are widespread in prokaryotic chromosomes and in mobile genetic elements including plasmids and prophages. The first characterized Type IV TA system CbtA/CbeA was found in cryptic prophage CP4-44 in Escherichia coli K-12. Two homologous TA loci of CbtA/CbeA also reside in cryptic prophages of E. coli K-12, YkfI/YafW in CP4-6 and YpjF/YfjZ in CP4-57. In this study, we demonstrated that YkfI and YpjF inhibited cell growth and led to the formation of "lemon-shaped" cells. Prolonged overproduction of YkfI led to the formation of "gourd-shaped" cells and immediate cell lysis. YafW and YfjZ can neutralize the toxicity of YkfI or YpjF. Furthermore, we found that YkfI and YpjF interacted with cell division protein FtsZ in E. coli, but ectopic expression in Pseudomonas and Shewanella did not cause the formation of "lemon-shaped" cells. Moreover, deletion of all of the three toxin genes together decreased resistance to oxidative stress and deletion of the antitoxin genes increased early biofilm formation. Collectively, these results demonstrated that the homologous Type IV TA systems in E. coli may target cell division protein FtsZ in E. coli and may have different physiological functions in E. coli. [ABSTRACT FROM AUTHOR]

Published

2017

27. Quaternary ammonium surfactant structure determines selective toxicity towards bacteria: mechanisms of action and clinical implications in antibacterial prophylaxis.

Author

Inácio, Ângela S., Domingues, Neuza S., Nunes, Alexandra, Martins, Patrícia T., Moreno, Maria J., Estronca, Luís M., Fernandes, Rui, Moreno, António J. M., Borrego, Maria J., Gomes, João P., Vaz, Winchil L. C., and Vieira, Otília V.

Subjects

QUATERNARY ammonium compounds, SURFACE active agents, MOLECULAR structure, ANTI-infective agents, SEXUALLY transmitted disease treatment, ESCHERICHIA coli physiology, ANTIBIOTICS, BACTERICIDES, CELL division, CELL membranes, ESCHERICHIA coli, METABOLISM, NEISSERIA, PHARMACODYNAMICS, PHYSIOLOGY, THERAPEUTICS

Abstract

Objectives: Broad-spectrum antimicrobial activity of quaternary ammonium surfactants (QAS) makes them attractive and cheap topical prophylactic options for sexually transmitted infections and perinatal vertically transmitted urogenital infections. Although attributed to their high affinity for biological membranes, the mechanisms behind QAS microbicidal activity are not fully understood. We evaluated how QAS structure affects antimicrobial activity and whether this can be exploited for use in prophylaxis of bacterial infections.Methods: Acute toxicity of QAS to in vitro models of human epithelial cells and bacteria were compared to identify selective and potent bactericidal agents. Bacterial cell viability, membrane integrity, cell cycle and metabolism were evaluated to establish the mechanisms involved in selective toxicity of QAS.Results: QAS toxicity normalized relative to surfactant critical micelle concentration showed n-dodecylpyridinium bromide (C12PB) to be the most effective, with a therapeutic index of ∼10 for an MDR strain of Escherichia coli and >20 for Neisseria gonorrhoeae after 1 h of exposure. Three modes of QAS antibacterial action were identified: impairment of bacterial energetics and cell division at low concentrations; membrane permeabilization and electron transport inhibition at intermediate doses; and disruption of bacterial membranes and cell lysis at concentrations close to the critical micelle concentration. In contrast, toxicity to mammalian cells occurs at higher concentrations and, as we previously reported, results primarily from mitochondrial dysfunction and apoptotic cell death.Conclusions: Our data show that short chain (C12) n-alkyl pyridinium bromides have a sufficiently large therapeutic window to be good microbicide candidates. [ABSTRACT FROM AUTHOR]

Published

2016

28. Chromosome replication, cell growth, division and shape: a personal perspective.

Author

Zaritsky, Arieh, Woldringh, Conrad L., Cooley, Jason W., Zakrzewska, Jolanta, and Duggin, Iain

Subjects

CHROMOSOME replication, CELL growth, CELL division

Abstract

The origins of Molecular Biology and Bacterial Physiology are reviewed, from our personal standpoints, emphasizing the coupling between bacterial growth, chromosome replication and cell division, dimensions and shape. Current knowledge is discussed with historical perspective, summarizing past and present achievements and enlightening ideas for future studies. An interactive simulation program of the bacterial cell division cycle (BCD), described as "The Central Dogma in Bacteriology," is briefly represented. The coupled process of transcription/translation of genes encoding membrane proteins and insertion into the membrane (so-called transertion) is invoked as the functional relationship between the only two unique macromolecules in the cell, DNA and peptidoglycan embodying the nucleoid and the sacculus respectively. We envision that the total amount of DNA associated with the replication terminus, so called "nucleoid complexity," is directly related to cell size and shape through the transertion process. Accordingly, the primary signal for cell division transmitted by DNA dynamics (replication, transcription and segregation) to the peptidoglycan biosynthetic machinery is of a physico-chemical nature, e.g., stress in the plasma membrane, relieving nucleoid occlusion in the cell's center hence enabling the divisome to assemble and function between segregated daughter nucleoids. [ABSTRACT FROM AUTHOR]

Published

2015

29. A ten-year search for synchronous cells: obstacles, solutions, and practical applications.

Author

Helmstetter, Charles E.

Subjects

ESCHERICHIA coli, BACTERIAL cells, ESCHERICHIA coli cell cycle, CHROMOSOME replication, CELL division

Abstract

My effort to use synchronously dividing cultures to examine the Escherichia coli cell cycle involved a 10-year struggle with failure after failure punctuated by a few gratifying successes, especially at the end. In this essay, I recount my personal journey in this obsessive experimental pursuit. That narrative is followed by a description of a simplified version of the "baby machine," a technique that was developed to obtain minimally disturbed, synchronously growing E. coli cells. Subsequent studies with this methodology led to an understanding of the basic properties of the relationship between chromosome replication and cell division. Accordingly, I end this reminiscence with a simple, fool-proof graphical strategy for deducing the pattern of chromosome replication during the division cycle of cells growing at any rate. [ABSTRACT FROM AUTHOR]

Published

2015

30. The FtsK Family of DNA Translocases Finds the Ends of Circles.

Author

Crozat, Estelle, Rousseau, Philippe, Fournes, Florian, and Cornet, François

Subjects

DNA, BACTERIAL chromosomes, CELL cycle, CELL division, BACILLUS subtilis, BACTERIAL sporulation

Abstract

A global view of bacterial chromosome choreography during the cell cycle is emerging, highlighting as a next challenge the description of the molecular mechanisms and factors involved. Here, we review one such factor, the FtsK family of DNA translocases. FtsK is a powerful and fast translocase that reads chromosome polarity. It couples segregation of the chromosome with cell division and controls the last steps of segregation in time and space. The second model protein of the family SpoIIIE acts in the transfer of the Bacillus subtilis chromosome during sporulation. This review focuses on the molecular mechanisms used by FtsK and SpoIIIE to segregate chromosomes with emphasis on the latest advances and open questions. © 2015 S. Karger AG, Basel [ABSTRACT FROM AUTHOR]

Published

2015

31. FtsZ-less prokaryotic cell division as well as FtsZ- and dynamin-less chloroplast and non-photosynthetic plastid division.

Author

Mami Nakamura, Akihiro Uzuka, Shin-ya Miyagishima, and Atsuko Era

Subjects

CELL division, CHLOROPLASTS, MOLECULAR genetics, PLANTS

Abstract

The chloroplast division machinery is a mixture of a stromal FtsZ-based complex descended from a cyanobacterial ancestor of chloroplasts and a cytosolic dynamin-related protein (DRP) 5B-based complex derived from the eukaryotic host. Molecular genetic studies have shown that each component of the division machinery is normally essential for normal chloroplast division. However, several exceptions have been found. In the absence of the FtsZ ring, non-photosynthetic plastids are able to proliferate, likely by elongation and budding. Depletion of DRP5B impairs, but does not stop chloroplast division. Chloroplasts in glaucophytes, which possesses a peptidoglycan (PG) layer, divide without DRP5B. Certain parasitic eukaryotes possess non-photosynthetic plastids of secondary endosymbiotic origin, but neither FtsZ nor DRP5B is encoded in their genomes. Elucidation of the FtsZ- and/or DRP5B-less chloroplast division mechanism will lead to a better understanding of the function and evolution of the chloroplast division machinery and the finding of the as-yet-unknown mechanism that is likely involved in chloroplast division. Recent studies have shown that FtsZ was lost from a variety of prokaryotes, many of which lost PG by regressive evolution. In addition, even some of the FtsZ-bearing bacteria are able to divide when FtsZ and PG are depleted experimentally. In some cases, alternative mechanisms for cell division, such as budding by an increase of the cell surface-to-volume ratio, are proposed. Although PG is believed to have been lost from chloroplasts other than in glaucophytes, there is some indirect evidence for the existence of PG in chloroplasts. Such information is also useful for understanding how non-photosynthetic plastids are able to divide in FtsZ-depleted cells and the reason for the retention of FtsZ in chloroplast division. Here we summarize information to facilitate analyses of FtsZ- and/or DRP5B-less chloroplast and non-photosynthetic plastid division. [ABSTRACT FROM AUTHOR]

Published

2014

32. Impact of the cell life-cycle on bacteriophage T4 infection.

Author

Storms, Zachary J., Brown, Tobin, Cooper, David G., Sauvageau, Dominic, and Leask, Richard L.

Subjects

LIFE cycles (Biology), BACTERIOPHAGE T4, ESCHERICHIA coli, CELL culture, CELL division, LYSIS, CELL physiology, BACTERIA

Abstract

Synchronized Escherichia coli cultures were infected with bacteriophage T4 at discrete points in the cell growth cycle. The cell cycle had a significant impact on the outcome of infection. Cell burst size was smallest for newly formed cells and increased dramatically as these progressed in the cell cycle. The largest burst sizes were achieved when infecting cells immediately prior to cell division. When cells were infected during cell division, the burst size was reduced back to its initial value. Interestingly, lysis time was longest for young cells, reached a minimum at the same point that burst size reached its maximum value, and then increased at the commencement of cell division. Consequently, phage productivity in cells about to undergo cell division was almost three times greater than the productivity of young, newly formed cells. The availability of intracellular resources is believed to be the major driving force behind phage productivity during infection. Indeed, intracellular RNA contents at the time of infection were found to correlate strongly with phage productivity. There was no significant relationship between cell DNA levels and phage productivity. Finally, burst size experiments suggested that the cell cycle also influenced the likelihood of a phage to undergo productive infection. [ABSTRACT FROM AUTHOR]

Published

2014

33. The Kil Peptide of Bacteriophage λ Blocks Escherichia coli Cytokinesis via ZipA-Dependent Inhibition of FtsZ Assembly.

Author

Haeusser, Daniel P., Hoashi, Marina, Weaver, Anna, Brown, Nathan, Pan, James, Sawitzke, James A., Thomason, Lynn C., Court, Donald L., and Margolin, William

Subjects

PEPTIDES, BACTERIOPHAGE lambda, ESCHERICHIA coli, CYTOKINESIS, CELL division

Abstract

Assembly of the essential, tubulin-like FtsZ protein into a ring-shaped structure at the nascent division site determines the timing and position of cytokinesis in most bacteria and serves as a scaffold for recruitment of the cell division machinery. Here we report that expression of bacteriophage λ kil, either from a resident phage or from a plasmid, induces filamentation of Escherichia coli cells by rapid inhibition of FtsZ ring formation. Mutant alleles of ftsZ resistant to the Kil protein map to the FtsZ polymer subunit interface, stabilize FtsZ ring assembly, and confer increased resistance to endogenous FtsZ inhibitors, consistent with Kil inhibiting FtsZ assembly. Cells with the normally essential cell division gene zipA deleted (in a modified background) display normal FtsZ rings after kil expression, suggesting that ZipA is required for Kil-mediated inhibition of FtsZ rings in vivo. In support of this model, point mutations in the C-terminal FtsZ-interaction domain of ZipA abrogate Kil activity without discernibly altering FtsZ-ZipA interactions. An affinity-tagged-Kil derivative interacts with both FtsZ and ZipA, and inhibits sedimentation of FtsZ filament bundles in vitro. Together, these data inspire a model in which Kil interacts with FtsZ and ZipA in the cell to prevent FtsZ assembly into a coherent, division-competent ring structure. Phage growth assays show that kil+ phage lyse ∼30% later than kil mutant phage, suggesting that Kil delays lysis, perhaps via its interaction with FtsZ and ZipA. [ABSTRACT FROM AUTHOR]

Published

2014

34. Chromosome Replication in Escherichia coli: Life on the Scales.

Author

Norris, Vic and Amar, Patrick

Subjects

CHROMOSOME replication, CELL division, ESCHERICHIA coli, ESCHERICHIA, LIFE (Biology)

Abstract

At all levels of Life, systems evolve on the 'scales of equilibria'. At the level of bacteria, the individual cell must favor one of two opposing strategies and either take risks to grow or avoid risks to survive. It has been proposed in the Dualism hypothesis that the growth and survival strategies depend on non-equilibrium and equilibrium hyperstructures, respectively. It has been further proposed that the cell cycle itself is the way cells manage to balance the ratios of these types of hyperstructure so as to achieve the compromise solution of living on the two scales. Here, we attempt to re-interpret a major event, the init iat ion of chromosome replication in Escherichia coli, in the light of scales of equilibria. This entails thinking in terms of hyperstructures as responsible for intensity sensing and quantity sensing and how this sensing might help explain the role of the DnaA protein in initiation of replication. We outline experiments and an automaton approach to the cell cycle that should test and refine the scales concept. [ABSTRACT FROM AUTHOR]

Published

2012

35. CtrA response regulator binding to the Caulobacter chromosome replication origin is required during nutrient and antibiotic stress as well as during cell cycle progression.

Author

Bastedo, D. Patrick and Marczynski, Gregory T.

Subjects

CHROMOSOME replication, BINDING sites, CELLS, GENETIC mutation, PROTEINS, CELL division, GROWTH factors

Abstract

The Caulobacter crescentus chromosome replication origin ( Cori) has five binding sites for CtrA, an OmpR/PhoB family ‘response regulator’. CtrA is degraded in replicating ‘stalked’ cells but is abundant in the non-replicating ‘swarmer’ cells, where it was proposed to repress replication by binding to Cori. We systematically mutated all Cori CtrA binding sites, and examined their consequences in the contexts of autonomous Cori-plasmid replication and in the natural chromosome locus. Remarkably, the C. crescentus chromosome tolerates severe mutations in all five CtrA binding sites, demonstrating that CtrA is not essential for replication. Further physiological and cell cycle experiments more rigorously supported the original hypothesis that CtrA represses replication. However, our experiments argued against another hypothesis that residual and/or replenished CtrA protein in stalked cells might prevent extra or unscheduled chromosome replication before cell division. Surprisingly, we also demonstrated that Cori CtrA binding sites are very advantageous and can become essential when cells encounter nutrients and antibiotics. Therefore, the CtrA cell cycle regulator co-ordinates replication with viable cell growth in stressful and rapidly changing environments. We argue that this new role for CtrA provided the primary selective pressure for evolving control by CtrA. [ABSTRACT FROM AUTHOR]

Published

2009

36. A Complete Set of Escherichia coli Open Reading Frames in Mobile Plasmids Facilitating Genetic Studies.

Author

Saka, Kimiko, Tadenuma, Maki, Nakade, Shinsuke, Tanaka, Noriko, Sugawara, Hideaki, Nishikawa, Ken, Ichiyoshi, Nobuyuki, Kitagawa, Masanari, Mori, Hirotada, Ogasawara, Naotake, and Nishimura, Akiko

Abstract

To facilitate genetic studies of Escherichia coli, we constructed a complete set of mobile plasmid clones of intact open reading frames (ORFs). Their expression is strictly controlled by Ptac/lacIq. The plasmids carrying each ORF were introduced into an F+ recA strain and stored in 96-well microtiter plates. In this way, 96 clones can be transferred simultaneously to F−bacteria using the conjugative system. This provides a convenient procedure for systematic identification of ORFs that suppress or complement mutations. We created two types of clone sets: the original set contained individual clones in 45 microtiter plates, and a second set contained pools of 48 clones stored in a single microtiter plate. Using these clone sets, we have identified 403 genes that can correct in trans the temperature-sensitive defect of cell division mutants, which would suggest multiple global regulators for bacterial cell division. [ABSTRACT FROM PUBLISHER]

Published

2005

37. Titration of the Escherichia coli DnaA protein to excess datA sites causes destabilization of replication forks, delayed replication initiation and delayed cell division.

Author

Løbner-Olesen, Anders and Skarstad, Kirsten

Subjects

ESCHERICHIA coli, CELL division, GENETICS

Abstract

Summary In Escherichia coli , the level of the initiator protein DnaA is limiting for initiation of replication at oriC . A high-affinity binding site for DnaA, datA , plays an important role. Here, the effect of extra datA sites was studied. A moderate increase in datA dosage (≈ fourfold) delayed initiation of replication and cell division, but increased the rate of replication fork movement about twofold. At a further increase in the datA gene dosage, the SOS response was induced, and incomplete rounds of chromosome replication were detected. Overexpression of DnaA protein suppressed the SOS response and restored normal replication timing and rate of fork movement. In the presence of extra datA sites, cells showed a dependency on PriA and RecA proteins, indicating instability of the replication fork. The results suggest that wild-type replication fork progression normally includes controlled pausing, and that this is a prerequisite for normal replication fork function. [ABSTRACT FROM AUTHOR]

Published

2003

38. The role of c-myc in cellular growth control.

Author

Schmidt, Emmett V

Subjects

DNA, CELL division

Abstract

Cell division is coupled to cell growth. Since some c-myc target genes are regulators of cell growth while others function in cell division pathways, c-myc is apparently poised at the interface of these processes. Cell culture systems have shown specific myc-associated growth phenotypes. Increased cell growth precedes DNA synthesis after myc activation in cells expressing myc-estrogen receptor fuson constructs and cells lacking c-myc exhibit a marked loss of protein synthesis. A number of candidate c-myc target genes regulate processes required for cell growth including rRNA transcription and processing, ribosomal protein transcription and translation, and translation initiation. These interactions all have the potential to account for the growth phenotypes in c-myc mutant cells. The ability of translation initiation factors, including eIF4E, to transform cells makes them particularly interesting targets of c-myc. Further evaluation of these target genes will provide important insights into growth control and c-myc's functions in cellular proliferation. [ABSTRACT FROM AUTHOR]

Published

1999

39. The cell cycle of Bacillus subtilis as studied by electron microscopy.

Author

Nanninga, N., Koppes, L., and Vries-Tijssen, F.

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

1979

40. Coordination of Growth, Chromosome Replication/Segregation, and Cell Division in E. coli

Author

Mathieu Stouf, Nancy Kleckner, Martin White, Jay K. Fisher, and Katerina E. Chatzi

Subjects

0301 basic medicine, Microbiology (medical), cell division, licensing, Cell division, lcsh:QR1-502, Review, Biology, Permission, DNA replication, Microbiology, lcsh:Microbiology, Chromosome segregation, 03 medical and health sciences, 0302 clinical medicine, Nucleoid, chromosome, bacteria, E. coli, Chromosome, Cell cycle, Cell biology, 030104 developmental biology, Replication Initiation, cell cycle coordination, 030217 neurology & neurosurgery

Abstract

Bacterial cells growing in steady state maintain a 1:1:1 relationship between an appropriate mass increase, a round of DNA replication plus sister chromosome segregation, and cell division. This is accomplished without the cell cycle engine found in eukaryotic cells. We propose here a formal logic, and an accompanying mechanism, for how such coordination could be provided in E. coli. Completion of chromosomal and divisome-related events would lead, interactively, to a “progression control complex” (PCC) which provides integrated physical coupling between sister terminus regions and the nascent septum. When a cell has both (i) achieved a sufficient mass increase, and (ii) the PCC has developed, a conformational change in the PCC occurs. This change results in “progression permission,” which triggers both onset of cell division and release of terminus regions. Release of the terminus region, in turn, directly enables a next round of replication initiation via physical changes transmitted through the nucleoid. Division and initiation are then implemented, each at its own rate and timing, according to conditions present. Importantly: (i) the limiting step for progression permission may be either completion of the growth requirement or the chromosome/divisome processes required for assembly of the PCC; and, (ii) the outcome of the proposed process is granting of permission to progress, not determination of the absolute or relative timings of downstream events. This basic logic, and the accompanying mechanism, can explain coordination of events in both slow and fast growth conditions; can accommodate diverse variations and perturbations of cellular events; and is compatible with existing mathematical descriptions of the E. coli cell cycle. Also, while our proposition is specifically designed to provide 1:1:1 coordination among basic events on a “per-cell cycle” basis, it is a small step to further envision permission progression is also the target of basic growth rate control. In such a case, the rate of mass accumulation (or its equivalent) would determine the length of the interval between successive permission events and, thus, successive cell divisions and successive replication initiations.

Published

2018

41. Coordination between replication, segregation and cell division in multi-chromosomal bacteria: lessons from Vibrio cholerae

Author

Elena, Espinosa, François-Xavier, Barre, and Elisa, Galli

Subjects

DNA Replication, Chromosomes, Bacterial, Vibrio cholerae, Cell Division, Phylogeny

Abstract

Bacteria display a highly flexible cell cycle in which cell division can be temporally disconnected from the replication/segregation cycle of their genome. The accuracy of genetic transmission is enforced by restricting the assembly of the cell division apparatus to the low DNA-density zones that develop between the regularly spaced nucleoids originating from the concurrent replication and segregation of genomic DNA. In most bacteria, the process is simplified because the genome is encoded on a single chromosome. This is notably the case in Escherichia coli, the most well studied bacterial model organism. However, ~10% of bacteria have domesticated horizontally acquired mega-plasmids into extra-numerous chromosomes. Most of our current knowledge on the cell cycle regulation of multi-chromosomal species derives from the study of replication, segregation and cell division in Vibrio cholerae, the agent of the deadly epidemic human diarrheal disease cholera. A nicety of this model is that it is closely related to E. coli in the phylogenetic tree of bacteria. Here, we review recent findings on the V. cholerae cell cycle in the context of what was previously known on the E. coli cell cycle.

Published

2017

42. Etude du rôle de la région terminale du chromosome dans le positionnement, la ségrégation du chromosome et le contrôle de la division cellulaire chez Escherichia coli

Author

Lebailly, Elise, Laboratoire de microbiologie et génétique moléculaires (LMGM), Centre de Biologie Intégrative (CBI), Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Université Paul Sabatier - Toulouse III, and François Cornet

Subjects

Cell division, Ter region, Division cellulaire, Escherichia coli, Région ter, Ségrégation des chromosomes, SimA, [SDV.BC]Life Sciences [q-bio]/Cellular Biology, Chromosome segregation, MatP, TopoIV, SlmA

Abstract

Escherichia coli, as the majority of bacteria, has a unique circular chromosome. Faithfull cell proliferation requires that a least one copy of the chromosome is transmitted to sister cells prior to cell division. A strict temporal and spatial coupling of chromosome segregation with cell division is thus required to ensure the accurate separation of the two fully replicated chromosomes. The terminal region of the chromosome (ter) is the last one to be replicated and segregated, and moves from the pole to the middle of the cell where the division septum is formed, at the end of the cell cycle. Loci of the ter region display an extended cohesion period. This extended cohesion is controlled by the MatP protein, which binds specific matS sites restricted to the ter region. MatP binds DNA as a dimer and forms tetramers via its N-terminal and C-terminal domains respectively. Tetramerisation is stimulated by binding to DNA and pairs remote matS sites. MatP also interacts with ZapB, a component of the divisome, the protein machinery that contributes to septum formation. While tetramerisation of MatP appears important for compacting the ter region, its interaction with ZapB, which is localized at the septum via ZapA and FtsZ, is involved in the positioning and the extended cohesion of this region. The linkage of the ter region with the divisome is required for the success of many later events of the cell cycle : (i) the active, ordered and progressive segregation of the ter region by FtsK, a component of the divisome, (ii) resolution of chromosome dimers via the site-specifique recombination XerCD/dif, activated by FtsK, (iii) the resolution of intercatenation links by TopoIV and (iv) the positive regulation of divisome assembly in the absence of the negative regulators MinCDE and SlmA. During my thesis, I first studied the role of MatP in the chromosome management. By using pairs of loci tagged with parSp1 and parSpMT1 sites recognized by cognate ParB-XFP proteins, we directly analysed chromosome positioning and orientation in the cell. We show that MatP is required for normal positioning and orientation of the whole chromosome at the end of the cell cycle. The localisation of SlmA in wt and Delta matP strains proves that inactivation of MatP leads to inaccuracy of nucleoid positioning accompanied by defects in SlmA localisation, and thus induces division inhibition. Take together, these results show that MatP, SlmA and their interplay are important for chromosome management and control of cell division in E. coli. In collaboration with O. Espeli's team, we have used genomic and molecular biology methods to characterize TopoIV regulation during the E. coli cell cycle. We show that at the dif site, TopoIV binging and cleavage are enhanced by the presence of the XerCD recombinases and MatP. This enhancement of TopoIV activity at dif promotes decatenation of fully replicated chromosomes and ensure, through interaction with other processes, accurate separation of sister chromosomes. These results provide insight into the protein network dedicated to the final step of chromosome management during the cell cycle, and how the chromosome management is linked to cell division.; Escherichia coli, comme la majorité des bactéries, possède un unique chromosome circulaire. Au moins une copie du chromosome doit être transmise à chacune des cellules filles avant la division cellulaire afin d'assurer une prolifération cellulaire correcte. Une couplage spatio-temporel précis de la ségrégation avec la division cellulaire est donc nécessaire pour assurer la bonne répartition des deux chromosomes après réplication. La région terminale du chromosome (ter) est la dernière à être répliquée et ségrégée, et migre du pôle vers le centre de la cellule au moment de la mise en place du septum de division, à la fin du cycle cellulaire. Les loci de la région ter présentent une période de cohésion post-réplicative étendue. Cette cohésion étendue est contrôlée par la protéine MatP, qui se fixe spécifiquement au niveau des sites matS, présents uniquement dans ter. MatP se fixe à l'ADN sous forme de dimère, via son domaine N-terminal, et tétramérise via son domaine C-terminal. La tétramérisation est stimulée par la liaison à l'ADN et permet le pontage de deux sites matS distants. MatP interagit aussi avec ZapB, un composant du divisome, la machinerie protéique participant à la formation du septum. Alors que la tétramérisation de MatP semble importante pour la compaction de la région ter, son interaction avec ZapB, qui est localisée au septum via ZapA et FtsZ, participe au positionnement et à la cohésion étendue de cette région. Le couplage de la région ter avec le divisome est essentiel pour le bon déroulement de nombreux évènements tardifs du cycle cellulaire : (i) la ségrégation active, ordonnée et progressive de la région ter par FtsK, un composant du divisome, (ii) la résolution des dimères de chromosomes via la recombinaison spécifique de site XerCD/dif, activée par FtsK, (iii) la résolution des liens d'intercaténation par la TopoIV et (iv) la régulation positive de l'assemblage du divisome en absence des régulateurs négatifs MinCDE et SlmA. Pendant ma thèse, je me suis tout d'abord intéressée au rôle de MatP dans la structuration globale du chromosome. En utilisant un système permettant de visualiser deux loci marqués avec un site parSp1 et un site parSpMT1, reconnu par ParBp1 et ParBpMT1 spécifiquement, nous avons analysé le positionnement et l'orientation du chromosome dans la cellule. Nous avons montré que MatP est nécessaire au positionnement et à l'orientation de tout le chromosome à la fin du cycle cellulaire. La localisation de SlmA dans des souches wt et DeltamatP prouve que l'inactivation de MatP, induisant une mauvais positionnement du chromosome, s'accompagne d'une défaut de localisation de SlmA, et induit donc une inhibition de la division. Ces résultats pris ensemble montre que MatP, SlmA et leur communication à travers la structuration globale du chromosome sont importants pour le management du chromosome et le contrôle de la division cellulaire. En collaboration avec l'équipe d'Olivier Espeli, nous avons utilisé des méthodes de génomiques et de biologie moléculaire pour caractériser la régulation de la TopoIV au cours du cycle cellulaire d'E. coli. Nous avons montré qu'au site dif, les activités de fixation et de clivage de la TopoIV sont améliorées par la présence des recombinases XerCD et de MatP. L'amélioration de l'activité de la TopoIV favorise la décaténation des chromosomes nouvellement répliqués et assure, en lien avec d'autres processus, la séparation précise des chromosomes frères. Ces résultats permettent de mieux comprendre le réseau d'interactions dédiées au management du chromosome à la fin du cycle cellulaire, et l'influence du management du chromosome sur le contrôle de la division cellulaire.

Published

2016

43. Spatial and temporal organization of replicating Escherichia coli chromosomes

Author

Ole Andreas Økstad, Britta Søballe, Sergio R. Filipe, François-Xavier Barre, David J. Sherratt, and Ivy F. Lau

Subjects

Genetics, Cell division, Repressor, ParABS system, Biology, medicine.disease_cause, Microbiology, Cell biology, Bacterial genetics, Chromosome segregation, chemistry.chemical_compound, chemistry, medicine, biology.protein, FtsZ, Molecular Biology, Escherichia coli, DNA

Abstract

The positions of DNA regions close to the chromosome replication origin and terminus in growing cells of Escherichia coli have been visualized simultaneously, using new widely applicable reagents. Furthermore, the positions of these regions with respect to a replication factory-associated protein have been analysed. Time-lapse analysis has allowed the fate of origins, termini and the FtsZ ring to be followed in a lineage-specific manner during the formation of microcolonies. These experiments reveal new aspects of the E. coli cell cycle and demonstrate that the replication terminus region is frequently located asymmetrically, on the new pole side of mid-cell. This asymmetry could provide a mechanism by which the chromosome segregation protein FtsK, located at the division septum, can act directionally to ensure that the septal region is free of DNA before the completion of cell division.

Published

2004

44. Characterization of a prokaryotic SMC protein involved in chromosome partitioning

Author

Daniel C.-H. Lin, Robert A. Britton, and Alan D. Grossman

Subjects

Recombinant Fusion Proteins, ParABS system, Biology, Origin of replication, Models, Biological, Research Communication, Bacterial Proteins, Genetics, Nucleoid, Spores, Bacterial, Dosage compensation, Circular bacterial chromosome, Plasmid partitioning, SMC protein, fungi, Temperature, Chromosomes, Bacterial, musculoskeletal system, Phenotype, Genes, Bacterial, Chromosomal region, Mutation, cardiovascular system, Cell Division, Developmental Biology, Bacillus subtilis, Subcellular Fractions

Abstract

Efficient partitioning of chromosomes into dividing cells is important for cell survival. In Escherichia coli and Bacillus subtilis, chromosomes partition to daughter cells with high fidelity (Hiraga et al. 1989; Ireton et al. 1994). Although proteins, sites, and mechanisms involved in physical separation (decatenation) of bacterial chromosomes have been characterized, much less is known about the mechanisms governing efficient partitioning to daughter cells (for review, see Hiraga 1992; Wake and Errington 1995). Recent work has shown that the chromosomal region around the origin of replication (oriC) is in a defined orientation for most of the bacterial (B. subtilis and E. coli) cell cycle and that newly replicated oriC regions are rapidly separated from each other (Glaser et al. 1997; Gordon et al. 1997; Lin et al. 1997; Webb et al. 1997). The origin regions are found toward the poles of the highly condensed nucleoid body, oriented toward the ends of the cell. The rapid separation and localization of oriC regions indicate the function of a mitotic-like apparatus in prokaryotes (Glaser et al. 1997; Gordon et al. 1997; Lin et al. 1997; Webb et al. 1997). Cellular proteins contributing to efficient chromosome partitioning have recently been characterized. Spo0J from B. subtilis and ParB from Caulobacter crescentus are required for efficient chromosome partitioning and are similar to a family of plasmid-encoded proteins required for plasmid partitioning in E. coli (e.g., ParB for P1 and SopB for F). ParB of C. crescentus is essential for growth, and overexpression causes a defect in chromosome partitioning (Mohl and Gober 1997). Deletion of spo0J in B. subtilis causes an ∼100-fold increase in the number of anucleate cells, resulting in accumulation of 1%–2% anucleate cells in a growing culture (Ireton et al. 1994). Spo0J binds to at least eight sites located in the origin proximal 20% of the chromosome (Lin and Grossman 1998). Spo0J is found in the cell in single discrete foci located near the poles of the nucleoid body (Glaser et al. 1997; Lin et al. 1997), in a pattern similar to that observed for the region around the origin of replication (Lewis and Errington 1997; Webb et al. 1997). Visualization of the foci of Spo0J by immunofluorescence microscopy or by use of a Spo0J–green fluorescent protein (GFP) fusion indicates the assembly of a large nucleoprotein complex containing Spo0J. The function of Spo0J and other proteins of this family is still unknown, though they are thought to be involved in pairing and/or positioning sister chromosomes (Nordstrom and Austin 1989; Niki and Hiraga 1997; Lin and Grossman 1998). The muk genes of E. coli were identified in an elegant screen for mutants that produce anucleate cells (Hiraga et al. 1989). The mukB gene product has features of a myosin-like motor protein and is involved in chromosome condensation and/or movement [(Niki et al. 1991; Hiraga 1992; Wake and Errington 1995; Hu et al. 1996), and references therein]. mukE and mukF, which are in an operon with mukB, are also required for efficient partitioning and their products are thought to interact with MukB (Yamanaka et al. 1996). Of the ∼12 bacterial genomes that have been sequenced, mukB, mukE, and mukF are found only in E. coli and Haemophilus influenzae. B. subtilis, along with many other bacterial species (but not E. coli or H. influenzae), contains a homolog of the eukaryotic Smc (structural maintenance of chromosomes) proteins (Oguro et al. 1996). Several eukaryotes have multiple smc genes, and eukaryotic Smc proteins play a role in chromosome condensation, pairing, and/or segregation (for review, see Hirano et al. 1995; Koshland and Strunnikov 1996; Heck 1997). For example, mutations in the SMC genes of Saccharomyces cerevisiae cause defects in chromosome condensation, segregation, and sister chromatid cohesion (Guacci et al. 1997; Michaelis et al. 1997). DNA condensation by the 13S condensin of Xenopus laevis requires two Smc proteins, XCAP-C and XCAP-E (Hirano et al. 1997). Dosage compensation in Caenorhabditis elegans involves specific interaction of an Smc homolog, Dpy-27, and other proteins, with the X chromosome (Chuang et al. 1994, 1996). Although the precise biochemical function of the Smc proteins is not known, recent work has shown that Smc proteins, or complexes containing Smc proteins, can affect DNA topology in vitro (Kimura and Hirano 1997; Sutani and Yanagida 1997). The smc gene of B. subtilis encodes a 135-kD protein that is homologous to eukaryotic Smc proteins (Oguro et al. 1996). B. subtilis Smc is ∼24% identical and ∼46% similar to SMC1 and SMC2 (S. cerevisiae), XCAP-C and XCAP-E (X. laevis), Dpy-27 (C. elegans), and Cut3 and Cut14 (Schizosaccaromyces pombe). It contains all of the domains associated with the Smc family; an amino-terminal NTP-binding domain, two internal coiled–coil regions separated by a hinge, and the carboxy-terminal signature “DA-box” motif (Hirano et al. 1995; Koshland and Strunnikov 1996). Whereas the existence of Smc proteins in eukaryotes is well documented, their prevalence in bacteria and archaebacteria is only beginning to be appreciated. A search of GenBank and individual sequence databases (both completed and in progress) revealed that at least 11 bacteria and 2 archaebacteria contain genes encoding homologs of Smc. In addition to B. subtilis, the list includes Streptococcus pyogenes, Streptococcus pneumoniae, Mycobacterium tuberculosis, several Mycoplasma species (M. genitalium, M. pneumoniae, and M. hyorhinis), Borrelia burgdorferi, Treponema pallidum, Synechocystis sp., Neisseria gonorrhoeae, and the archaebacteria Methanococcus jannaschii and Archaeoglobus fulgidus. We report the characterization of the B. subtilis smc gene. Null mutations in smc caused a conditional lethal phenotype, alterations in nucleoid appearance, a defect in chromosome partitioning, and a synthetic phenotype with a null mutation in spo0J. These findings indicate that the function of Smc proteins is highly conserved.

Published

1998

45. Cell division in Escherichia coli minB mutants

Author

Kurt Nordström, Thomas Åkerlund, and Rolf Bernander

Subjects

Genetics, Cell Nucleus, Cell division, Mutant, Cell, Cell Cycle, Colony Count, Microbial, Chromosome, Biology, Cell cycle, medicine.disease_cause, Microbiology, Cell biology, Cell nucleus, medicine.anatomical_structure, medicine, Escherichia coli, Nucleoid, Molecular Biology, Cell Division

Abstract

In Escherichia coli minB mutants, cell division can take place at the cell poles as well as non-polarly in the cell. We have examined growth, division patterns, and nucleoid distribution in individual cells of a minC point mutant and a minB deletion mutant, and compared them to the corresponding wild-type strain and an intR1 strain in which the chromosome is over-replicated. The main findings were as follows. In the minB mutants, polar and non-polar divisions appeared to occur independently of each other. Furthermore, the timing of cell division in the cell cycle was found to be severely affected. In addition, nucleoid conformation and distribution were considerably disturbed. The results obtained call for a re-evaluation of the role of the MinB system in the E. coli cell cycle, and of the concept that limiting quanta of cell division factors are regularly produced during the cell cycle.

Published

1992

46. Analysis of the bacterial cell cycle using strains in which chromosome replication is controlled by plasmid R1

Author

Santanu Dasgupta, Rolf Bernander, and Kurt Nordström

Subjects

Genetics, DNA Replication, DNA, Bacterial, R Factors, Cell Cycle, Eukaryotic DNA replication, General Medicine, Biology, Chromosomes, Bacterial, Origin of replication, Pre-replication complex, Microbiology, DnaA, DNA replication factor CDT1, Replication factor C, Control of chromosome duplication, biology.protein, DNA Transposable Elements, Escherichia coli, Origin recognition complex, Replicon, Molecular Biology, Cell Division

Abstract

As an alternative approach in the study of the Escherichia coli cell cycle, we have constructed strains in which chromosome replication is under the control of various plasmid R1 derivatives, IntR1 strains. The physiological properties of such strains are described. In intR1 strains, chromosome replication can be manipulated independently of cell-cycle-related control mechanisms, and the effects on cell division can be analysed. Using this approach, we have found that the timing of replication during the cell cycle is random in intR1 strains, that overreplication of the chromosome is lethal, and that chromosome replication does not trigger cell division. Current investigations include the study of the E. coli cell cycle in the absence of the DnaA protein, the effect on cell division of a specific inhibition of the initiation of chromosome replication, and the molecular basis of uni- and bidirectional replication.

Published

1991

47. Bacterial cell model

Author

Z. Simon

Subjects

Statistics and Probability, chemistry.chemical_classification, General Immunology and Microbiology, Cell division, Applied Mathematics, General Medicine, Cell cycle, Biology, Division (mathematics), General Biochemistry, Genetics and Molecular Biology, Bacterial cell structure, Cell biology, chemistry.chemical_compound, Enzyme, chemistry, Modeling and Simulation, RNA polymerase, Ploidy, General Agricultural and Biological Sciences, Macromolecule

Abstract

A repliconic Helmstetter type model for the E. coli cell cycle is considered. In this model the syntheses of various enzymes compete for a common precursor and the transcription rate is limited by the cellular quantity of RNA polymerase. Enrichment of the nutritive medium is considered to turn off the synthesis of several enzymes and thus to favour the activity of enzymes directly involving cell division. The model predicts a division rate, μ, inversely proportional to the total genome activation degree, Σ A i ; a cell volume and ploidy constant at low division rates and proportional to μ at high division rates, and explains why size and composition do not depend much on temperature.

Published

1973

48. Control mechanism of the Escherichia coli K-12 cell cycle is triggered by the cyclic AMP-cyclic AMP receptor protein complex

Author

M Kawamukai, Ryutaro Utsumi, Manjiro Noda, and T Komano

Subjects

Cell division, Cyclic AMP Receptor Protein, Mutant, Cell Cycle, LacUV5, Peptidoglycan, Cell cycle, Biology, medicine.disease_cause, Microbiology, Molecular biology, Receptors, Cyclic AMP, Biochemistry, Gene Expression Regulation, Cell Wall, Mutation, medicine, biology.protein, Cyclic AMP, Escherichia coli, Receptor, FtsZ, Molecular Biology, Research Article

Abstract

The role of cyclic AMP (cAMP) in the cell cycle of Escherichia coli K-12 was studied in three mutant strains. One was KI1812, in which the cya promoter is replaced by the lacUV5 promoter. In KI1812, isopropyl-beta-D-thiogalactopyranoside induced the synthesis of cya mRNA, and at the same time cell division was inhibited and short filaments containing multiple nuclei were formed. The other strains were constructed as double mutants (NC6707 cya sulB [ftsZ(Ts)] and TR3318 crp sulB [ftsZ(Ts)]). In both double mutants, filamentation was repressed at 42 degrees C, but it was induced again by addition of cAMP in strain NC6707 and introduction of pHA7 containing wild-type crp in TR3318. These results indicate that lateral wall synthesis in the E. coli cell cycle is triggered by the cAMP-cAMP receptor protein complex.

Published

1989