Your search keyword '"E. coli Cell cycle"' showing total 190 results

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

Author

Casaregola S, Chen M, Bouquin N, Norris V, Jacq A, Goldberg M, Margarson S, Tempete M, Mckenna S, and Sweetman H

Subjects

Cell Cycle genetics, Cell Cycle physiology, Cell Division genetics, Cell Division physiology, Drug Resistance, Microbial genetics, Escherichia coli cytology, Escherichia coli genetics, Genes, Bacterial, Mutation, Myosins metabolism, Bacterial Proteins metabolism, Calcium metabolism, Escherichia coli metabolism

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

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

Author

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

Subjects

MiniR1–1 replication, DnaA-boxes, Complete genome sequence, E. coli Cell cycle, Microbiology, QR1-502

Abstract

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.

Published

2018

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

Author

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

Published

2018

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. Whole-Genome Analysis Reveals That the Nucleoid Protein IHF Predominantly Binds to the Replication Origin oriC Specifically at the Time of Initiation.

Author

Kasho, Kazutoshi, Oshima, Taku, Chumsakul, Onuma, Nakamura, Kensuke, Fukamachi, Kazuki, and Katayama, Tsutomu

Subjects

BACTERIAL chromosomes, NUCLEOTIDE sequencing, CELL cycle, BINDING sites, PROTEINS, DNA replication

Abstract

The structure and function of bacterial chromosomes are dynamically regulated by a wide variety of nucleoid-associated proteins (NAPs) and DNA superstructures, such as DNA supercoiling. In Escherichia coli , integration host factor (IHF), a NAP, binds to specific transcription promoters and regulatory DNA elements of DNA replication such as the replication origin oriC : binding to these elements depends on the cell cycle but underlying mechanisms are unknown. In this study, we combined GeF-seq (genome footprinting with high-throughput sequencing) with synchronization of the E. coli cell cycle to determine the genome-wide, cell cycle-dependent binding of IHF with base-pair resolution. The GeF-seq results in this study were qualified enough to analyze genomic IHF binding sites (e.g., oriC and the transcriptional promoters of ilvG and osmY) except some of the known sites. Unexpectedly, we found that before replication initiation, oriC was a predominant site for stable IHF binding, whereas all other loci exhibited reduced IHF binding. To reveal the specific mechanism of stable oriC– IHF binding, we inserted a truncated oriC sequence in the terC (replication terminus) locus of the genome. Before replication initiation, stable IHF binding was detected even at this additional oriC site, dependent on the specific DnaA-binding sequence DnaA box R1 within the site. DnaA oligomers formed on oriC might protect the oriC –IHF complex from IHF dissociation. After replication initiation, IHF rapidly dissociated from oriC , and IHF binding to other sites was sustained or stimulated. In addition, we identified a novel locus associated with cell cycle-dependent IHF binding. These findings provide mechanistic insight into IHF binding and dissociation in the genome. [ABSTRACT FROM AUTHOR]

Published

2021

7. Microfluidics and AI for single-cell microbiology

Author

Karempudi, Praneeth and Karempudi, Praneeth

Abstract

Most of the biological sciences deal with understanding the relationships between phenotypes and the underlying molecular mechanisms of organisms. This thesis is an engineering, computational, and experimental exercise in expanding the scope and scale of phenotype-genotype mapping techniques in single-cell microbiology using microscopy, microfluidics, and image processing. To this end, we use mother-machine-based microfluidic devices together with recently developed techniques in deep learning and optics. We use optical microscopes to observe cells of different genotypes, physically move cells, and image molecules inside them. We have designed a novel microfluidic device to expand the throughput of single-cell lineage tracing an order of magnitude compared to existing methods. We demonstrate the ability to isolate single cells from such a device using optical tweezers after phenotypic characterization in real time. We have developed analysis algorithms of various kinds with the prime intention of performing high-throughput real-time image processing in conjunction with experimental runs to identify interesting cells for further investigation. We have also developed an experimental protocol for bacterial species identification using fluorescence-in-situ hybridization (FISH) in microfluidic chips to complement an existing phenotype-based antibiotic-susceptibility test (AST). We apply this method together with deep-learning-based cell segmentation and tracking algorithms, and image classification methods to perform species-ID of up to 10 species in 2-3 hrs. Lastly, we have developed a 3D dot localization method to investigate how the chromosome structure changes during the E. coli cell cycle. Different loci on the E. coli chromosome were labeled using DNA-binding fluorescent proteins and imaged using an optical setup with an astigmatic point-spread-function. Mother-machine devices were used to constrain the movement of cells to the lateral plane during growth. A deep-l

Published

2023

8. Three-dimensional localization and tracking of chromosomal loci throughout the Escherichia coli cell cycle.

Author

Karempudi, Praneeth, Gras, Konrad, Amselem, Elias, Zikrin, Spartak, Schirman, Dvir, and Elf, Johan

Subjects

LOCUS (Genetics), BACTERIAL loci, ESCHERICHIA coli, CELL cycle, FLUORESCENT proteins

Abstract

The intracellular position of genes may impact their expression, but it has not been possible to accurately measure the 3D position of chromosomal loci. In 2D, loci can be tracked using arrays of DNA-binding sites for transcription factors (TFs) fused with fluorescent proteins. However, the same 2D data can result from different 3D trajectories. Here, we have developed a deep learning method for super-resolved astigmatism-based 3D localization of chromosomal loci in live E. coli cells which enables a precision better than 61 nm at a signal-to-background ratio of ~4 on a heterogeneous cell background. Determining the spatial localization of chromosomal loci, we find that some loci are at the periphery of the nucleoid for large parts of the cell cycle. Analyses of individual trajectories reveal that these loci are subdiffusive both longitudinally (x) and radially (r), but that individual loci explore the full radial width on a minute time scale. The intracellular position of genes in the chromosome may impact their expression. To measure the 3D positions of chromosomal loci over the bacterial cell cycle, we have developed a combination of microfluidics, optics, and deep learning. [ABSTRACT FROM AUTHOR]

Published

2024

9. Genetic requirements for uropathogenic E. coli proliferation in the bladder cell infection cycle.

Author

Mediati, Daniel G., Blair, Tamika A., Costas, Ariana, Monahan, Leigh G., Söderström, Bill, Charles, Ian G., and Duggin, Iain G.

Published

2024

10. 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

11. Absence of RstA results in delayed initiation of DNA replication in Escherichia coli.

Author

Yao, Yuan, Ma, Yong, Chen, Xiuli, Bade, Rengui, Lv, Cuilan, and Zhu, Runxiu

Subjects

ESCHERICHIA coli, DNA replication, MICROBIAL cell cycle, PHENOTYPES, GENETIC mutation

Abstract

RstB/RstA is an uncharacterized Escherichia coli two-component system, the regulatory effects of which on the E. coli cell cycle remain unclear. We found that the doubling time and average number of replication origins per cell in an ΔrstB mutant were the same as the wild-type, and the average number of replication origins in an ΔrstA mutant was 18.2% lower than in wild-type cells. The doubling times were 34 min, 35 min, and 40 min for the wild-type, ΔrstB, and ΔrstA strains, respectively. Ectopic expression of RstA from plasmid pACYC-rstA partly reversed the ΔrstA mutant phenotypes. The amount of initiator protein DnaA per cell was reduced by 40% in the ΔrstA mutant compared with the wild-type, but the concentration of DnaA did not change as the total amount of cellular protein was also reduced in these cells. Deletion or overproduction of RstA does not change the temperature sensitivity of dnaA46, dnaB252 and dnaC2. The expression of hupA was decreased by 0.53-fold in ΔrstA. RstA interacted with Topoisomerase I weakly in vivo and increased its activity of relaxing the negative supercoiled plasmid. Our data suggest that deletion of RstA leads to delayed initiation of DNA replication, and RstA may affect initiation of replication by controlling expression of dnaA or hupA. Furthermore, the delayed initiation may by caused by the decreased activity of topoisomerase I in RstA mutant. [ABSTRACT FROM AUTHOR]

Published

2018

12. Bacterial image analysis using multi-task deep learning approaches for clinical microscopy.

Author

Chin, Shuang Yee, Dong, Jian, Hasikin, Khairunnisa, Ngui, Romano, Lai, Khin Wee, Yeoh, Pauline Shan Qing, and Wu, Xiang

Subjects

OBJECT recognition (Computer vision), MICROSCOPY, ESCHERICHIA coli, IMAGE analysis, BACTERIA classification

Abstract

Background: Bacterial image analysis plays a vital role in various fields, providing valuable information and insights for studying bacterial structural biology, diagnosing and treating infectious diseases caused by pathogenic bacteria, discovering and developing drugs that can combat bacterial infections, etc. As a result, it has prompted efforts to automate bacterial image analysis tasks. By automating analysis tasks and leveraging more advanced computational techniques, such as deep learning (DL) algorithms, bacterial image analysis can contribute to rapid, more accurate, efficient, reliable, and standardised analysis, leading to enhanced understanding, diagnosis, and control of bacterial-related phenomena. Methods: Three object detection networks of DL algorithms, namely SSD-MobileNetV2, EfficientDet, and YOLOv4, were developed to automatically detect Escherichia coli (E. coli) bacteria from microscopic images. The multi-task DL framework is developed to classify the bacteria according to their respective growth stages, which include rod-shaped cells, dividing cells, and microcolonies. Data preprocessing steps were carried out before training the object detection models, including image augmentation, image annotation, and data splitting. The performance of the DL techniques is evaluated using the quantitative assessment method based on mean average precision (mAP), precision, recall, and F1-score. The performance metrics of the models were compared and analysed. The best DL model was then selected to perform multi-task object detections in identifying rod-shaped cells, dividing cells, and microcolonies. Results: The output of the test images generated from the three proposed DL models displayed high detection accuracy, with YOLOv4 achieving the highest confidence score range of detection and being able to create different coloured bounding boxes for different growth stages of E. coli bacteria. In terms of statistical analysis, among the three proposed models, YOLOv4 demonstrates superior performance, achieving the highest mAP of 98% with the highest precision, recall, and F1-score of 86%, 97%, and 91%, respectively. Conclusions: This study has demonstrated the effectiveness, potential, and applicability of DL approaches in multi-task bacterial image analysis, focusing on automating the detection and classification of bacteria from microscopic images. The proposed models can output images with bounding boxes surrounding each detected E. coli bacteria, labelled with their growth stage and confidence level of detection. All proposed object detection models have achieved promising results, with YOLOv4 outperforming the other models. [ABSTRACT FROM AUTHOR]

Published

2024

13. 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

14. Transcription–replication interactions reveal bacterial genome regulation.

Author

Pountain, Andrew W., Jiang, Peien, Yao, Tianyou, Homaee, Ehsan, Guan, Yichao, McDonald, Kevin J. C., Podkowik, Magdalena, Shopsin, Bo, Torres, Victor J., Golding, Ido, and Yanai, Itai

Abstract

Organisms determine the transcription rates of thousands of genes through a few modes of regulation that recur across the genome1. In bacteria, the relationship between the regulatory architecture of a gene and its expression is well understood for individual model gene circuits2,3. However, a broader perspective of these dynamics at the genome scale is lacking, in part because bacterial transcriptomics has hitherto captured only a static snapshot of expression averaged across millions of cells4. As a result, the full diversity of gene expression dynamics and their relation to regulatory architecture remains unknown. Here we present a novel genome-wide classification of regulatory modes based on the transcriptional response of each gene to its own replication, which we term the transcription–replication interaction profile (TRIP). Analysing single-bacterium RNA-sequencing data, we found that the response to the universal perturbation of chromosomal replication integrates biological regulatory factors with biophysical molecular events on the chromosome to reveal the local regulatory context of a gene. Whereas the TRIPs of many genes conform to a gene dosage-dependent pattern, others diverge in distinct ways, and this is shaped by factors such as intra-operon position and repression state. By revealing the underlying mechanistic drivers of gene expression heterogeneity, this work provides a quantitative, biophysical framework for modelling replication-dependent expression dynamics.Single-cell expression data from bacteria are used to classify gene regulatory architectures in relation to gene expression dynamics and the cell cycle, revealing distinct categories of gene regulatory mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

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

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 thecell division apparatus to the low DNA-density zones that develop between the regularly spaced nucleoids originating from theconcurrent replication and segregation of genomic DNA. In most bacteria, the process is simplified because the genome is encodedon 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 currentknowledge on the cell cycle regulation of multi-chromosomal species derives from the study of replication, segregation and celldivision in Vibrio cholerae, the agent of the deadly epidemic human diarrheal disease cholera. A nicety of this model is that it isclosely related to E. coli in the phylogenetic tree of bacteria. Here, we review recent findings on the V. cholerae cell cycle in thecontext of what was previously known on the E. coli cell cycle.

Published

2018

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

Author

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

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 thecell division apparatus to the low DNA-density zones that develop between the regularly spaced nucleoids originating from theconcurrent replication and segregation of genomic DNA. In most bacteria, the process is simplified because the genome is encodedon 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 currentknowledge on the cell cycle regulation of multi-chromosomal species derives from the study of replication, segregation and celldivision in Vibrio cholerae, the agent of the deadly epidemic human diarrheal disease cholera. A nicety of this model is that it isclosely related to E. coli in the phylogenetic tree of bacteria. Here, we review recent findings on the V. cholerae cell cycle in thecontext of what was previously known on the E. coli cell cycle.

Published

2018

17. Spatial and temporal organization of replicating Escherichia coli chromosomes.

Author

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

Subjects

ESCHERICHIA coli, CHROMOSOME replication, DNA, CELL cycle

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. [ABSTRACT FROM AUTHOR]

Published

2003

18. 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

19. Simulation-based Reconstructed Diffusion unveils the effect of aging on protein diffusion in Escherichia coli.

Author

Mantovanelli, Luca, Linnik, Dmitrii S., Punter, Michiel, Kojakhmetov, Hildeberto Jardón, Śmigiel, Wojciech M., and Poolman, Bert

Subjects

ESCHERICHIA coli, EUKARYOTIC cells, DIFFUSION coefficients, TRAFFIC cameras, OPTICAL diffraction, CELL compartmentation, CELLULAR aging

Abstract

We have developed Simulation-based Reconstructed Diffusion (SbRD) to determine diffusion coefficients corrected for confinement effects and for the bias introduced by two-dimensional models describing a three-dimensional motion. We validate the method on simulated diffusion data in three-dimensional cell-shaped compartments. We use SbRD, combined with a new cell detection method, to determine the diffusion coefficients of a set of native proteins in Escherichia coli. We observe slower diffusion at the cell poles than in the nucleoid region of exponentially growing cells, which is independent of the presence of polysomes. Furthermore, we show that the newly formed pole of dividing cells exhibits a faster diffusion than the old one. We hypothesize that the observed slowdown at the cell poles is caused by the accumulation of aggregated or damaged proteins, and that the effect is asymmetric due to cell aging. Author summary: Knowledge of the location and mobility of molecules in living cells is paramount to understand cellular processes, protein interactions, folding and function. However, accurately measuring protein mobility in small compartments, such as bacterial cells, is challenging due to various factors. These include the effects of boundaries and compartment geometry, as well as technical limitations like the properties of fluorophores, the diffraction limit of light, and the camera speed. In Escherichia coli cells, the poles are important regions where most of the cellular proteins are synthesized by ribosomes organized in polysomes. At the same time, aggregated or misfolded proteins accumulate at the cell poles, increasing the local macromolecular crowding. We have developed Simulation-based Reconstructed Diffusion to separate the boundary and geometry effects from crowding effects on the observed protein diffusion. Using this method, we investigated how the accumulation of misfolded or damaged proteins at the poles affects the lateral diffusion of various native proteins. We also observed an increase in apparent crowding in the older pole of dividing cells. We related differences in macromolecular crowding in the pole regions of E. coli to aging of the cells, which may impact cellular functions like they do in eukaryotic cells. [ABSTRACT FROM AUTHOR]

Published

2023

20. IHF and Fis as Escherichia coli Cell Cycle Regulators: Activation of the Replication Origin oriC and the Regulatory Cycle of the DnaA Initiator.

Author

Kasho, Kazutoshi, Ozaki, Shogo, and Katayama, Tsutomu

Subjects

ESCHERICHIA coli, CELL cycle, DNA replication, BINDING sites, CARRIER proteins

Abstract

This review summarizes current knowledge about the mechanisms of timely binding and dissociation of two nucleoid proteins, IHF and Fis, which play fundamental roles in the initiation of chromosomal DNA replication in Escherichia coli. Replication is initiated from a unique replication origin called oriC and is tightly regulated so that it occurs only once per cell cycle. The timing of replication initiation at oriC is rigidly controlled by the timely binding of the initiator protein DnaA and IHF to oriC. The first part of this review presents up-to-date knowledge about the timely stabilization of oriC-IHF binding at oriC during replication initiation. Recent advances in our understanding of the genome-wide profile of cell cycle-coordinated IHF binding have revealed the oriC-specific stabilization of IHF binding by ATP-DnaA oligomers at oriC and by an initiation-specific IHF binding consensus sequence at oriC. The second part of this review summarizes the mechanism of the timely regulation of DnaA activity via the chromosomal loci DARS2 (DnaA-reactivating sequence 2) and datA. The timing of replication initiation at oriC is controlled predominantly by the phosphorylated form of the adenosine nucleotide bound to DnaA, i.e., ATP-DnaA, but not ADP-ADP, is competent for initiation. Before initiation, DARS2 increases the level of ATP-DnaA by stimulating the exchange of ADP for ATP on DnaA. This DARS2 function is activated by the site-specific and timely binding of both IHF and Fis within DARS2. After initiation, another chromosomal locus, datA, which inactivates ATP-DnaA by stimulating ATP hydrolysis, is activated by the timely binding of IHF. A recent study has shown that ATP-DnaA oligomers formed at DARS2-Fis binding sites competitively dissociate Fis via negative feedback, whereas IHF regulation at DARS2 and datA still remains to be investigated. This review summarizes the current knowledge about the specific role of IHF and Fis in the regulation of replication initiation and proposes a mechanism for the regulation of timely IHF binding and dissociation at DARS2 and datA. [ABSTRACT FROM AUTHOR]

Published

2023

21. The Nordström Question.

Author

Donachie, William D.

Subjects

ESCHERICHIA coli, NUCLEOIDS, SISTERS

Abstract

It is suggested that the absolute dimensions of cells of Escherichia coli may be set by the separation distance between newly completed sister nucleoids. [ABSTRACT FROM AUTHOR]

Published

2023

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

Author

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

Subjects

*CELL division, *BACTERIAL reproduction, *VIBRIO cholerae, *BACTERIAL cell cycle, *BACTERIAL genomes, *BACTERIA

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. [ABSTRACT FROM AUTHOR]

Published

2017

23. 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

24. 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

25. Beyond the average: An updated framework for understanding the relationship between cell growth, DNA replication, and division in a bacterial system.

Author

Sanders, Sara, Joshi, Kunaal, Levin, Petra Anne, and Iyer-Biswas, Srividya

Subjects

CELL growth, DNA replication, CELL cycle, BACTERIAL cells

Abstract

Our understanding of the bacterial cell cycle is framed largely by population-based experiments that focus on the behavior of idealized average cells. Most famously, the contributions of Cooper and Helmstetter help to contextualize the phenomenon of overlapping replication cycles observed in rapidly growing bacteria. Despite the undeniable value of these approaches, their necessary reliance on the behavior of idealized average cells masks the stochasticity inherent in single-cell growth and physiology and limits their mechanistic value. To bridge this gap, we propose an updated and agnostic framework, informed by extant single-cell data, that quantitatively accounts for stochastic variations in single-cell dynamics and the impact of medium composition on cell growth and cell cycle progression. In this framework, stochastic timers sensitive to medium composition impact the relationship between cell cycle events, accounting for observed differences in the relationship between cell cycle events in slow- and fast-growing cells. We conclude with a roadmap for potential application of this framework to longstanding open questions in the bacterial cell cycle field. [ABSTRACT FROM AUTHOR]

Published

2023

26. A review of methods for predicting DNA N6-methyladenine sites.

Author

Han, Ke, Wang, Jianchun, Wang, Yu, Zhang, Lei, Yu, Mengyao, Xie, Fang, Zheng, Dequan, Xu, Yaoqun, Ding, Yijie, and Wan, Jie

Subjects

DNA, DEEP learning, MACHINE learning, FORECASTING

Abstract

Deoxyribonucleic acid(DNA) N6-methyladenine plays a vital role in various biological processes, and the accurate identification of its site can provide a more comprehensive understanding of its biological effects. There are several methods for 6mA site prediction. With the continuous development of technology, traditional techniques with the high costs and low efficiencies are gradually being replaced by computer methods. Computer methods that are widely used can be divided into two categories: traditional machine learning and deep learning methods. We first list some existing experimental methods for predicting the 6mA site, then analyze the general process from sequence input to results in computer methods and review existing model architectures. Finally, the results were summarized and compared to facilitate subsequent researchers in choosing the most suitable method for their work. [ABSTRACT FROM AUTHOR]

Published

2023

27. 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

28. In vitro studies of the protein-interaction network of cell-wall lytic transglycosylase RlpA of Pseudomonas aeruginosa.

Author

Avila-Cobian, Luis F., De Benedetti, Stefania, Kim, Choon, Feltzer, Rhona, Champion, Matthew M., Fisher, Jed F., and Mobashery, Shahriar

Subjects

PSEUDOMONAS aeruginosa, IN vitro studies, BINDING site assay, GLYCOSYLTRANSFERASES, PROTEOMICS

Abstract

The protein networks of cell-wall-biosynthesis assemblies are largely unknown. A key class of enzymes in these assemblies is the lytic transglycosylases (LTs), of which eleven exist in P. aeruginosa. We have undertaken a pulldown strategy in conjunction with mass-spectrometry-based proteomics to identify the putative binding partners for the eleven LTs of P. aeruginosa. A total of 71 putative binding partners were identified for the eleven LTs. A systematic assessment of the binding partners of the rare lipoprotein A (RlpA), one of the pseudomonal LTs, was made. This 37-kDa lipoprotein is involved in bacterial daughter-cell separation by an unknown process. RlpA participates in both the multi-protein and multi-enzyme divisome and elongasome assemblies. We reveal an extensive protein-interaction network for RlpA involving at least 19 proteins. Their kinetic parameters for interaction with RlpA were assessed by microscale thermophoresis, surface-plasmon resonance, and isothermal-titration calorimetry. Notable RlpA binding partners include PBP1b, PBP4, and SltB1. Elucidation of the protein-interaction networks for each of the LTs, and specifically for RlpA, opens opportunities for the study of their roles in the complex protein assemblies intimately involved with the cell wall as a structural edifice critical for bacterial survival. An extensive protein-interaction network of cell-wall biosynthesis assemblies in P. aeruginosa is elucidated using a pulldown strategy with mass-spectrometry-based proteomics and binding assays. [ABSTRACT FROM AUTHOR]

Published

2022

29. Control mechanisms: Explaining the integration and versatility of biological organisms.

Author

Bich, Leonardo and Bechtel, William

Abstract

Living organisms act as integrated wholes to maintain themselves. Individual actions can each be explained by characterizing the mechanisms that perform the activity. But these alone do not explain how various activities are coordinated and performed versatilely. We argue that this depends on a specific type of mechanism, a control mechanism. We develop an account of control by examining several extensively studied control mechanisms operative in the bacterium E. coli. On our analysis, what distinguishes a control mechanism from other mechanisms is that it relies on measuring one or more variables, which results in setting constraints in the control mechanism that determine its action on flexible constraints in other mechanisms. In the most basic arrangement, the measurement process directly determines the action of the control mechanism, but in more complex arrangements signals mediate between measurements and effectors. This opens the possibility of multiple responses to the same measurement and responses based on multiple measurements. It also allows crosstalk, resulting in networks of control mechanisms. Such networks integrate the behaviors of the organism but also present a challenge in tailoring responses to particular measurements. We discuss how integrated activity can still result in differential, versatile, responses. [ABSTRACT FROM AUTHOR]

Published

2022

30. The NMR structure of the Orf63 lytic developmental protein from lambda bacteriophage.

Author

Khan N, Graham T, Franciszkiewicz K, Bloch S, Nejman-Faleńczyk B, Wegrzyn A, and Donaldson LW

Subjects

Shiga Toxin genetics, Bacteriophage lambda genetics, Bacteriophage lambda metabolism, Enterohemorrhagic Escherichia coli metabolism, Enterohemorrhagic Escherichia coli virology, Viral Proteins metabolism

Abstract

The orf63 gene resides in a region of the lambda bacteriophage genome between the exo and xis genes and is among the earliest genes transcribed during infection. In lambda phage and Shiga toxin (Stx) producing phages found in enterohemorrhagic Escherichia coli (EHEC) associated with food poisoning, Orf63 expression reduces the host survival and hastens the period between infection and lysis thereby giving it pro-lytic qualities. The NMR structure of dimeric Orf63 reveals a fold consisting of two helices and one strand that all make extensive intermolecular contacts. Structure-based data mining failed to identify any Orf63 homolog beyond the family of temperate bacteriophages. A machine learning approach was used to design an amphipathic helical ligand that bound a hydrophobic cleft on Orf63 with micromolar affinity. This approach may open a new path towards designing therapeutics that antagonize the contributions of Stx phages in EHEC outbreaks., (© 2024. The Author(s).)

Published

2024

31. The NMR structure of the Ea22 lysogenic developmental protein from lambda bacteriophage.

Author

Goddard C, Nejman-Faleńczyk B, and Donaldson LW

Subjects

Humans, Bacteriophage lambda genetics, Bacteriophage lambda metabolism, Lysogeny genetics, Shiga Toxin genetics, Bacteriophages genetics, Bacteriophages metabolism, Enterohemorrhagic Escherichia coli genetics, Escherichia coli Infections microbiology

Abstract

The ea22 gene resides in a relatively uncharacterized region of the lambda bacteriophage genome between the exo and xis genes and is among the earliest genes transcribed upon infection. In lambda and Shiga toxin-producing phages found in enterohemorrhagic E. coli (EHEC) associated with food poisoning, Ea22 favors a lysogenic over lytic developmental state. The Ea22 protein may be considered in terms of three domains: a short amino-terminal domain, a coiled-coiled domain, and a carboxy-terminal domain (CTD). While the full-length protein is tetrameric, the CTD is dimeric when expressed individually. Here, we report the NMR solution structure of the Ea22 CTD that is described by a mixed alpha-beta fold with a dimer interface reinforced by salt bridges. A conserved mobile loop may serve as a ligand for an unknown host protein that works with Ea22 to promote bacterial survival and the formation of new lysogens. From sequence and structural comparisons, the CTD distinguishes lambda Ea22 from homologs encoded by Shiga toxin-producing bacteriophages., (© 2024. The Author(s).)

Published

2024

32. DeepBacs for multi-task bacterial image analysis using open-source deep learning approaches.

Author

Spahn, Christoph, Gómez-de-Mariscal, Estibaliz, Laine, Romain F., Pereira, Pedro M., von Chamier, Lucas, Conduit, Mia, Pinho, Mariana G., Jacquemet, Guillaume, Holden, Séamus, Heilemann, Mike, and Henriques, Ricardo

Subjects

IMAGE analysis, ARTIFICIAL neural networks, CYTOLOGY, BACTERIOLOGY, CELL morphology, ANTIBIOTIC residues, DEEP learning

Abstract

This work demonstrates and guides how to use a range of state-of-the-art artificial neural-networks to analyse bacterial microscopy images using the recently developed ZeroCostDL4Mic platform. We generated a database of image datasets used to train networks for various image analysis tasks and present strategies for data acquisition and curation, as well as model training. We showcase different deep learning (DL) approaches for segmenting bright field and fluorescence images of different bacterial species, use object detection to classify different growth stages in time-lapse imaging data, and carry out DL-assisted phenotypic profiling of antibiotic-treated cells. To also demonstrate the ability of DL to enhance low-phototoxicity live-cell microscopy, we showcase how image denoising can allow researchers to attain high-fidelity data in faster and longer imaging. Finally, artificial labelling of cell membranes and predictions of super-resolution images allow for accurate mapping of cell shape and intracellular targets. Our purposefully-built database of training and testing data aids in novice users' training, enabling them to quickly explore how to analyse their data through DL. We hope this lays a fertile ground for the efficient application of DL in microbiology and fosters the creation of tools for bacterial cell biology and antibiotic research. DeepBacs guides users without expertise in machine learning methods to leverage state-of-the-art artificial neural networks to analyse bacterial microscopy images. [ABSTRACT FROM AUTHOR]

Published

2022

33. 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

34. Quantitative Examination of Five Stochastic Cell-Cycle and Cell-Size Control Models for Escherichia coli and Bacillus subtilis.

Author

Le Treut, Guillaume, Si, Fangwei, Li, Dongyang, and Jun, Suckjoon

Subjects

ESCHERICHIA coli, CELL cycle proteins, CELL cycle, BACTERIOLOGY, STATISTICAL models, BACILLUS subtilis

Abstract

We examine five quantitative models of the cell-cycle and cell-size control in Escherichia coli and Bacillus subtilis that have been proposed over the last decade to explain single-cell experimental data generated with high-throughput methods. After presenting the statistical properties of these models, we test their predictions against experimental data. Based on simple calculations of the defining correlations in each model, we first dismiss the stochastic Helmstetter-Cooper model and the Initiation Adder model, and show that both the Replication Double Adder (RDA) and the Independent Double Adder (IDA) model are more consistent with the data than the other models. We then apply a recently proposed statistical analysis method and obtain that the IDA model is the most likely model of the cell cycle. By showing that the RDA model is fundamentally inconsistent with size convergence by the adder principle, we conclude that the IDA model is most consistent with the data and the biology of bacterial cell-cycle and cell-size control. Mechanistically, the Independent Adder Model is equivalent to two biological principles: (i) balanced biosynthesis of the cell-cycle proteins, and (ii) their accumulation to a respective threshold number to trigger initiation and division. [ABSTRACT FROM AUTHOR]

Published

2021

35. Whole-Genome Analysis Reveals That the Nucleoid Protein IHF Predominantly Binds to the Replication Origin oriC Specifically at the Time of Initiation

Author

Kazutoshi Kasho, Taku Oshima, Onuma Chumsakul, Kensuke Nakamura, Kazuki Fukamachi, and Tsutomu Katayama

Subjects

Escherichia coli, cell cycle, IHF, GeF-seq, oriC, Microbiology, QR1-502

Abstract

The structure and function of bacterial chromosomes are dynamically regulated by a wide variety of nucleoid-associated proteins (NAPs) and DNA superstructures, such as DNA supercoiling. In Escherichia coli, integration host factor (IHF), a NAP, binds to specific transcription promoters and regulatory DNA elements of DNA replication such as the replication origin oriC: binding to these elements depends on the cell cycle but underlying mechanisms are unknown. In this study, we combined GeF-seq (genome footprinting with high-throughput sequencing) with synchronization of the E. coli cell cycle to determine the genome-wide, cell cycle-dependent binding of IHF with base-pair resolution. The GeF-seq results in this study were qualified enough to analyze genomic IHF binding sites (e.g., oriC and the transcriptional promoters of ilvG and osmY) except some of the known sites. Unexpectedly, we found that before replication initiation, oriC was a predominant site for stable IHF binding, whereas all other loci exhibited reduced IHF binding. To reveal the specific mechanism of stable oriC–IHF binding, we inserted a truncated oriC sequence in the terC (replication terminus) locus of the genome. Before replication initiation, stable IHF binding was detected even at this additional oriC site, dependent on the specific DnaA-binding sequence DnaA box R1 within the site. DnaA oligomers formed on oriC might protect the oriC–IHF complex from IHF dissociation. After replication initiation, IHF rapidly dissociated from oriC, and IHF binding to other sites was sustained or stimulated. In addition, we identified a novel locus associated with cell cycle-dependent IHF binding. These findings provide mechanistic insight into IHF binding and dissociation in the genome.

Published

2021

36. 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

37. Mutagenesis and more: UmuDC and the Escherichia coli SOS response.

Author

Smith, Bradley T. and Walker, Graham C.

Subjects

*MUTAGENESIS, *ESCHERICHIA coli, *SCIENTIFIC experimentation

Abstract

Discusses SOS response and the functions of the umuD+C+ gene products in SOS mutagenesis, while highlighting the discovery of the role of the umuD+C+ operon in the regulation of the Escherichia coli (E. coli) cell cycle after an alteration of deoxyribonucleic acid (DNA). Reference to a repressor protein that binds to a site in the promoters of the SOS response genes; What steps must be taken to avoid a lethal interruption of DNA replication.

Published

1998

38. Replication, recombination and chromosome segregation in Escherichia coli

Author

White, Martin A. and Leach, David

Subjects

572.8, E. coli, replication, recombination, chromosome segregation, palindrome, SbcCD

Abstract

SbcCD has been shown to cleave a DNA hairpin formed by a palindromic DNA sequence on the lagging strand template of the E. coli chromosome. This activity was exploited to create a unique system for inducing a single site-specific DNA double-strand break (DSB) once per replication cycle. First, this work shows that the SOS response induced by this DSB is only essential for viability following multiple cycles of cleavage and repair. Next, the SOS-inducible inhibitor of cell division SfiA is shown to be dispensable for survival, despite demonstrating that cleavage of the palindrome causes both an increase in cell size and a delay in nucleoid segregation. A model of the E. coli cell cycle is presented to reconcile the observation that growth under chronic DSB induced conditions has no effect on generation time despite causing an increase in cell size. This system of DSB induction was then coupled with fluorescence markers on both sides of the palindrome to visualise the consequence of the DSB in vivo. Cleavage of the DNA hairpin by SbcCD in a recAmutant was used to selectively degrade the chromosome that replicated the palindrome on the lagging strand of replication, allowing two genetically identical sister chromosomes to be distinguished. This approach was used to show that chromosome segregation in E. coli is not random, but results in the segregation of lagging strand replicated DNA to mid-cell and leading strand replicated DNA to cell poles. Finally, this system for visualising the site of an inducible DSB was optimised for use in various other mutant backgrounds to allow the events of DSB repair to be dissected. This work provides a solid basis for further investigation into the relationship between replication, recombination and chromosome segregation in the model organism E. coli.

Published

2010

39. Inhibition of Escherichia coli chromosome replication by rifampicin treatment or during the stringent response is overcome by de novo DnaA protein synthesis.

Author

Riber, Leise and Løbner‐Olesen, Anders

Subjects

CHROMOSOME replication, PROTEIN synthesis, ESCHERICHIA coli, CHLORAMPHENICOL, MOLECULAR biology, RIFAMPIN

Abstract

Initiation of Escherichia coli chromosome replication is controlled by the DnaA initiator protein. Both rifampicin‐mediated inhibition of transcription and ppGpp‐induced changes in global transcription stops replication at the level of initiation. Here, we show that continued DnaA protein synthesis allows for replication initiation both during the rifampicin treatment and during the stringent response when the ppGpp level is high. A reduction in or cessation of de novo DnaA synthesis, therefore, causes the initiation arrest in both cases. In accordance with this, inhibition of translation with chloramphenicol also stops initiations. The initiation arrest caused by rifampicin was faster than that caused by chloramphenicol, despite of the latter inhibiting DnaA accumulation immediately. During chloramphenicol treatment transcription is still ongoing and we suggest that transcriptional events in or near the origin, that is, transcriptional activation, can allow for a few extra initiations when DnaA becomes limiting. We suggest, for both rifampicin treated cells and for cells accumulating ppGpp, that a turn‐off of initiation from oriC requires a stop in de novo DnaA synthesis and that an additional lack of transcriptional activation enhances this process, that is, leads to a faster initiation stop. [ABSTRACT FROM AUTHOR]

Published

2020

40. 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

41. Characterization, modes of action, and application of a novel broad-spectrum bacteriocin BM1300 produced by Lactobacillus crustorum MN047.

Author

Lu, Yingying, Aizhan, Rakhmanova, Yan, Hong, Li, Xin, Wang, Xin, Yi, Yanglei, Shan, Yuanyuan, Liu, Bianfang, Zhou, Yuan, and Lü, Xin

Published

2020

42. Combined Methylome, Transcriptome and Proteome Analyses Document Rapid Acclimatization of a Bacterium to Environmental Changes.

Author

Srivastava, Abhishek, Murugaiyan, Jayaseelan, Garcia, Juan A. L., De Corte, Daniele, Hoetzinger, Matthias, Eravci, Murat, Weise, Christoph, Kumar, Yadhu, Roesler, Uwe, Hahn, Martin W., and Grossart, Hans-Peter

Subjects

PROTEOMICS, GENETIC regulation, ACCLIMATIZATION, ULTRAVIOLET radiation, GENE expression, FRESHWATER habitats, ACCLIMATIZATION (Plants)

Abstract

Polynucleobacter asymbioticus strain QLW-P1DMWA-1T represents a group of highly successful heterotrophic ultramicrobacteria that is frequently very abundant (up to 70% of total bacterioplankton) in freshwater habitats across all seven continents. This strain was originally isolated from a shallow Alpine pond characterized by rapid changes in water temperature and elevated UV radiation due to its location at an altitude of 1300 m. To elucidate the strain's adjustment to fluctuating environmental conditions, we recorded changes occurring in its transcriptomic and proteomic profiles under contrasting experimental conditions by simulating thermal conditions in winter and summer as well as high UV irradiation. To analyze the potential connection between gene expression and regulation via methyl group modification of the genome, we also analyzed its methylome. The methylation pattern differed between the three treatments, pointing to its potential role in differential gene expression. An adaptive process due to evolutionary pressure in the genus was deduced by calculating the ratios of non-synonymous to synonymous substitution rates for 20 Polynucleobacter spp. genomes obtained from geographically diverse isolates. The results indicate purifying selection. [ABSTRACT FROM AUTHOR]

Published

2020

43. Direct observation of independently moving replisomes in Escherichia coli.

Author

Japaridze, Aleksandre, Gogou, Christos, Kerssemakers, Jacob W. J., Nguyen, Huyen My, and Dekker, Cees

Subjects

DNA replication, BACTERIAL chromosomes, ESCHERICHIA coli, REPLISOMES, CHROMOSOME replication, CHROMOSOME segregation

Abstract

The replication and transfer of genomic material from a cell to its progeny are vital processes in all living systems. Here we visualize the process of chromosome replication in widened E. coli cells. Monitoring the replication of single chromosomes yields clear examples of replication bubbles that reveal that the two replisomes move independently from the origin to the terminus of replication along each of the two arms of the circular chromosome, providing direct support for the so-called train-track model, and against a factory model for replisomes. The origin of replication duplicates near midcell, initially splitting to random directions and subsequently towards the poles. The probability of successful segregation of chromosomes significantly decreases with increasing cell width, indicating that chromosome confinement by the cell boundary is an important driver of DNA segregation. Our findings resolve long standing questions in bacterial chromosome organization. How chromosome replication and segregation is organised in E. coli is a matter of debate. Here the authors visualise the bacterial chromosome and the replisomes during DNA replication, providing support for a previously suggested train track model. [ABSTRACT FROM AUTHOR]

Published

2020

44. Insights into the Structure, Function, and Dynamics of the Bacterial Cytokinetic FtsZ-Ring.

Author

McQuillen, Ryan and Xiao, Jie

Abstract

The FtsZ protein is a highly conserved bacterial tubulin homolog. In vivo, the functional form of FtsZ is the polymeric, ring-like structure (Z-ring) assembled at the future division site during cell division. While it is clear that the Z-ring plays an essential role in orchestrating cytokinesis, precisely what its functions are and how these functions are achieved remain elusive. In this article, we review what we have learned during the past decade about the Z-ring's structure, function, and dynamics, with a particular focus on insights generated by recent high-resolution imaging and single-molecule analyses. We suggest that the major function of the Z-ring is to govern nascent cell pole morphogenesis by directing the spatiotemporal distribution of septal cell wall remodeling enzymes through the Z-ring's GTP hydrolysis–dependent treadmilling dynamics. In this role, FtsZ functions in cell division as the counterpart of the cell shape–determining actin homolog MreB in cell elongation. [ABSTRACT FROM AUTHOR]

Published

2020

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

Author

Utsumi, R, Noda, M, Kawamukai, M, and Komano, T

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

46. 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

47. Role of orf73 in the development of lambdoid bacteriophages during infection of the Escherichia coli host.

Author

Zdrojewska, Karolina, Dydecka, Aleksandra, Nejman-Faleńczyk, Bożena, Topka, Gracja, Necel, Agnieszka, Węgrzyn, Alicja, Węgrzyn, Grzegorz, and Bloch, Sylwia

Published

2019

48. 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

49. Absence of RstA results in delayed initiation of DNA replication in Escherichia coli.

Author

Yuan Yao, Yong Ma, Xiuli Chen, Rengui Bade, Cuilan Lv, and Runxiu Zhu

Subjects

Medicine, Science

Abstract

RstB/RstA is an uncharacterized Escherichia coli two-component system, the regulatory effects of which on the E. coli cell cycle remain unclear. We found that the doubling time and average number of replication origins per cell in an ΔrstB mutant were the same as the wild-type, and the average number of replication origins in an ΔrstA mutant was 18.2% lower than in wild-type cells. The doubling times were 34 min, 35 min, and 40 min for the wild-type, ΔrstB, and ΔrstA strains, respectively. Ectopic expression of RstA from plasmid pACYC-rstA partly reversed the ΔrstA mutant phenotypes. The amount of initiator protein DnaA per cell was reduced by 40% in the ΔrstA mutant compared with the wild-type, but the concentration of DnaA did not change as the total amount of cellular protein was also reduced in these cells. Deletion or overproduction of RstA does not change the temperature sensitivity of dnaA46, dnaB252 and dnaC2. The expression of hupA was decreased by 0.53-fold in ΔrstA. RstA interacted with Topoisomerase I weakly in vivo and increased its activity of relaxing the negative supercoiled plasmid. Our data suggest that deletion of RstA leads to delayed initiation of DNA replication, and RstA may affect initiation of replication by controlling expression of dnaA or hupA. Furthermore, the delayed initiation may by caused by the decreased activity of topoisomerase I in RstA mutant.

Published

2018

50. 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