review article | Q7318358 |
scholarly article | Q13442814 |
P2093 | author name string | Lucy Shapiro | |
Esteban Toro | |||
P2860 | cites work | Evidence for stable attachment of DNA to membrane at the replication origin of Escherichia coli | Q69916891 |
Binding of the origin of replication of Escherichia coli to the outer membrane | Q71452486 | ||
Nucleoid partitioning in Escherichia coli during steady-state growth and upon recovery from chloramphenicol treatment | Q71662828 | ||
Chromosome loss from par mutants of Pseudomonas putida depends on growth medium and phase of growth | Q77607646 | ||
Cell wall replication in Streptococcus pyogenes | Q79368594 | ||
Distinct segregation dynamics of the two Vibrio cholerae chromosomes | Q81183737 | ||
Bacterial chromosome segregation | Q81644953 | ||
Membrane attachment of the chromosome replication origin in Bacillus subtilis | Q93787473 | ||
Genetical Implications of the Structure of Deoxyribonucleic Acid | Q22122440 | ||
Does RNA polymerase help drive chromosome segregation in bacteria? | Q24540345 | ||
Reconstitution of DNA segregation driven by assembly of a prokaryotic actin homolog | Q24601170 | ||
Dynamic organization of chromosomal DNA in Escherichia coli | Q24610157 | ||
Characterization of a prokaryotic SMC protein involved in chromosome partitioning | Q28269862 | ||
A self-associating protein critical for chromosome attachment, division, and polar organization in caulobacter | Q28485823 | ||
A polymeric protein anchors the chromosomal origin/ParB complex at a bacterial cell pole | Q28485824 | ||
Characterization of the mycobacterial chromosome segregation protein ParB and identification of its target in Mycobacterium smegmatis | Q28487013 | ||
Dynamic control of the DNA replication initiation protein DnaA by Soj/ParA | Q28489039 | ||
spo0J is required for normal chromosome segregation as well as the initiation of sporulation in Bacillus subtilis | Q28489050 | ||
Caulobacter requires a dedicated mechanism to initiate chromosome segregation | Q30483974 | ||
Sequence-directed DNA export guides chromosome translocation during sporulation in Bacillus subtilis. | Q33911060 | ||
Plasmid and chromosome partitioning: surprises from phylogeny | Q33912681 | ||
Membrane-associated DNA transport machines | Q33931986 | ||
Recruitment of SMC by ParB-parS organizes the origin region and promotes efficient chromosome segregation | Q33943503 | ||
The ATPase SpoIIIE transports DNA across fused septal membranes during sporulation in Bacillus subtilis | Q34033039 | ||
A moving DNA replication factory in Caulobacter crescentus | Q34082088 | ||
Compatible bacterial plasmids are targeted to independent cellular locations in Escherichia coli | Q34086290 | ||
migS, a cis-acting site that affects bipolar positioning of oriC on the Escherichia coli chromosome | Q34107360 | ||
Plasmid and Chromosome Traffic Control: How ParA and ParB Drive Partition | Q34273050 | ||
Chromosome and replisome dynamics in E. coli: loss of sister cohesion triggers global chromosome movement and mediates chromosome segregation | Q34278207 | ||
Actin homolog MreB and RNA polymerase interact and are both required for chromosome segregation in Escherichia coli | Q34324082 | ||
The extrusion-capture model for chromosome partitioning in bacteria | Q34340675 | ||
ParABS systems of the four replicons of Burkholderia cenocepacia: new chromosome centromeres confer partition specificity | Q34353932 | ||
Immortal strands? Give me a break | Q34644490 | ||
The role of co-transcriptional translation and protein translocation (transertion) in bacterial chromosome segregation | Q34722979 | ||
Entropy-driven spatial organization of highly confined polymers: lessons for the bacterial chromosome | Q34887137 | ||
Control of bacterial DNA supercoiling | Q35226989 | ||
Chromosomes in living Escherichia coli cells are segregated into domains of supercoiling | Q35303880 | ||
Linear ordering and dynamic segregation of the bacterial chromosome | Q35314697 | ||
Rapid and sequential movement of individual chromosomal loci to specific subcellular locations during bacterial DNA replication | Q35316481 | ||
par genes and the pathology of chromosome loss in Vibrio cholerae. | Q35566445 | ||
The Caulobacter crescentus smc gene is required for cell cycle progression and chromosome segregation | Q35628516 | ||
Chromosome partitioning in Escherichia coli: novel mutants producing anucleate cells | Q36175041 | ||
Where asymmetry in gene expression originates. | Q36207903 | ||
In vivo localization of DNA sequences and visualization of large-scale chromatin organization using lac operator/repressor recognition | Q36257776 | ||
Insertion and fate of the cell wall in Bacillus subtilis | Q36298921 | ||
Soj (ParA) DNA binding is mediated by conserved arginines and is essential for plasmid segregation | Q36299930 | ||
Topological domain structure of the Escherichia coli chromosome | Q36661286 | ||
Effect of Rifampin on the Structure and Membrane Attachment of the Nucleoid of Escherichia coli | Q36767387 | ||
Getting organized--how bacterial cells move proteins and DNA. | Q37024474 | ||
DNA topoisomerases: harnessing and constraining energy to govern chromosome topology | Q37255381 | ||
Negative membrane curvature as a cue for subcellular localization of a bacterial protein | Q37304062 | ||
Functional consequences of improved structural information on bacterial nucleoids | Q37403664 | ||
The Folded Genome of Escherichia coli Isolated in a Protein-DNA-RNA Complex | Q37544800 | ||
The structure and function of bacterial actin homologs | Q37772701 | ||
The chromatin bodies of bacteria | Q39852554 | ||
Association of the nucleus and the membrane of bacteria: a morphological study | Q39970290 | ||
The bacterial nucleoid revisited | Q40392205 | ||
Polar localization of the replication origin and terminus in Escherichia coli nucleoids during chromosome partitioning. | Q40443585 | ||
A dynamic, mitotic-like mechanism for bacterial chromosome segregation | Q40672411 | ||
Replication of the prophage P1 during the cell cycle of Escherichia coli | Q40775086 | ||
Chromosome partitioning in bacteria. | Q41126246 | ||
Bacterial chromosome segregation: is there a mitotic apparatus? | Q41367402 | ||
E.coli MukB protein involved in chromosome partition forms a homodimer with a rod-and-hinge structure having DNA binding and ATP/GTP binding activities | Q41544008 | ||
Plasmid and chromosomal DNA replication and partitioning during the Caulobacter crescentus cell cycle | Q41762597 | ||
Localisation of DivIVA by targeting to negatively curved membranes | Q41872458 | ||
The two Escherichia coli chromosome arms locate to separate cell halves | Q41884613 | ||
Growth conditions regulate the requirements for Caulobacter chromosome segregation | Q42010156 | ||
F plasmid partition depends on interaction of SopA with non-specific DNA. | Q42442508 | ||
Localization of transcribing genes in the bacterial cell by means of high resolution autoradiography | Q44098515 | ||
MreB actin-mediated segregation of a specific region of a bacterial chromosome | Q45262711 | ||
Cell cycle-dependent polar localization of chromosome partitioning proteins in Caulobacter crescentus | Q46121025 | ||
Non-random segregation of sister chromosomes in Escherichia coli. | Q46275146 | ||
The role of topoisomerase IV in partitioning bacterial replicons and the structure of catenated intermediates in DNA replication | Q46625387 | ||
GFP tagging of budding yeast chromosomes reveals that protein-protein interactions can mediate sister chromatid cohesion | Q46864873 | ||
A Bacillus subtilis gene-encoding protein homologous to eukaryotic SMC motor protein is necessary for chromosome partition | Q47694477 | ||
Interaction between DNA and an Escherichia coli protein omega | Q47757460 | ||
Recruitment of condensin to replication origin regions by ParB/SpoOJ promotes chromosome segregation in B. subtilis | Q47777256 | ||
Partition of unit-copy miniplasmids to daughter cells. III. The DNA sequence and functional organization of the P1 partition region | Q48375246 | ||
DNA dynamics vary according to macrodomain topography in the E. coli chromosome. | Q48882956 | ||
Transcription induces a supercoil domain barrier in bacteriophage Mu. | Q50116192 | ||
Progressive segregation of the Escherichia coli chromosome. | Q50727134 | ||
MreB is important for cell shape but not for chromosome segregation of the filamentous cyanobacterium Anabaena sp. PCC 7120. | Q51044975 | ||
The tubulin homologue FtsZ contributes to cell elongation by guiding cell wall precursor synthesis in Caulobacter crescentus. | Q51985921 | ||
RacA, a bacterial protein that anchors chromosomes to the cell poles. | Q52110977 | ||
The parAB gene products of Pseudomonas putida exhibit partition activity in both P. putida and Escherichia coli. | Q52123751 | ||
The Escherichia coli chromosome is organized with the left and right chromosome arms in separate cell halves. | Q53595448 | ||
Spatial and temporal organization of replicating Escherichia coli chromosomes. | Q53647138 | ||
Electron microscopic studies on the folded chromosome of Escherichia coli. | Q53928700 | ||
On the structure of the folded chromosome of Escherichia coli | Q54101766 | ||
DNA and origin region segregation are not affected by the transition from rod to sphere after inhibition of Escherichia coli MreB by A22. | Q54439382 | ||
A cis-acting sequence involved in chromosome segregation in Escherichia coli. | Q54494141 | ||
Chromosome and low copy plasmid segregation in E. coli: visual evidence for distinct mechanisms. | Q54557741 | ||
Chromosomes segregration and development in Caulobacter crescentus. | Q54683979 | ||
The Immortal Strand Hypothesis: How Could It Work? | Q54998200 | ||
RacA and the Soj-Spo0J system combine to effect polar chromosome segregation in sporulating Bacillus subtilis | Q57990578 | ||
Bacillus subtilis spoIIIE protein required for DNA segregation during asymmetric cell division | Q57990639 | ||
Chromosome strand segregation during sporulation in Bacillus subtilis | Q57990656 | ||
Defining a Centromere-like Element in Bacillus subtilis by Identifying the Binding Sites for the Chromosome-Anchoring Protein RacA | Q57993962 | ||
Chromosome arrangement within a bacterium | Q58374830 | ||
Bipolar Localization of the Replication Origin Regions of Chromosomes in Vegetative and Sporulating Cells of B. subtilis | Q58374832 | ||
A DNA-Binding Protein Specific for the Early Replicated Region of the Chromosome Obtained from Escherichia coli Membrane Fractions | Q63341907 | ||
The Attachment of the Bacterial Chromosome to the Cell Membrane | Q66895465 | ||
Structure and properties of the bacterial nucleoid | Q67232991 | ||
Electron microscopy of membrane-associated folded chromosomes of Escherichia coli | Q67475171 | ||
Electron microscopy of membrane-free folded chromosomes from Escherichia coli | Q67499591 | ||
P433 | issue | 2 | |
P304 | page(s) | a000349 | |
P577 | publication date | 2010-02-01 | |
P1433 | published in | Cold Spring Harbor Perspectives in Biology | Q3927509 |
P1476 | title | Bacterial chromosome organization and segregation | |
P478 | volume | 2 |
Q42130953 | A MatP-divisome interaction coordinates chromosome segregation with cell division in E. coli. |
Q31026931 | A defined terminal region of the E. coli chromosome shows late segregation and high FtsK activity. |
Q33749733 | A geometrical model for DNA organization in bacteria |
Q35740517 | A model for Escherichia coli chromosome packaging supports transcription factor-induced DNA domain formation |
Q36310357 | A model for chromosome organization during the cell cycle in live E. coli |
Q35554916 | A new suite of tnaA mutants suggests that Escherichia coli tryptophanase is regulated by intracellular sequestration and by occlusion of its active site |
Q42760661 | Adding mRNA to the list of spatially organized components in bacteria |
Q55417250 | Analysis of ParAB dynamics in mycobacteria shows active movement of ParB and differential inheritance of ParA. |
Q51895168 | Bacterial polarity. |
Q50444532 | Brownian Ratchet Mechanism for Faithful Segregation of Low-Copy-Number Plasmids. |
Q30533999 | Caulobacter chromosome in vivo configuration matches model predictions for a supercoiled polymer in a cell-like confinement |
Q38014514 | Cell division and DNA segregation in Streptomyces: how to build a septum in the middle of nowhere? |
Q27320073 | Cell division site placement and asymmetric growth in mycobacteria |
Q34295789 | Characterization of a conserved interaction between DNA glycosylase and ParA in Mycobacterium smegmatis and M. tuberculosis |
Q38059056 | Chemosensory signaling controls motility and subcellular polarity in Myxococcus xanthus |
Q35111111 | Choreography of the Mycobacterium replication machinery during the cell cycle |
Q34711899 | Chromosomal organization and segregation in Pseudomonas aeruginosa |
Q35111096 | Chromosome organization and replisome dynamics in Mycobacterium smegmatis |
Q91452344 | Chromosome organization in bacteria: mechanistic insights into genome structure and function |
Q26797355 | Chromosome replication, cell growth, division and shape: a personal perspective |
Q30549630 | Chromosome segregation by the Escherichia coli Min system |
Q27317548 | Chromosome segregation impacts on cell growth and division site selection in Corynebacterium glutamicum |
Q38024839 | Compartmentalization and spatiotemporal organization of macromolecules in bacteria |
Q42414297 | Complex polar machinery required for proper chromosome segregation in vegetative and sporulating cells of Bacillus subtilis |
Q33790133 | Condensation and localization of the partitioning protein ParB on the bacterial chromosome. |
Q64100576 | Crosstalk Regulation Between Bacterial Chromosome Replication and Chromosome Partitioning |
Q34629213 | Developmental biology of Streptomyces from the perspective of 100 actinobacterial genome sequences |
Q47662611 | Developmental stage influences chromosome segregation patterns and arrangement in the extremely polyploid, giant bacterium Epulopiscium sp. type B. |
Q34504462 | Directed and persistent movement arises from mechanochemistry of the ParA/ParB system |
Q34759551 | Divin: a small molecule inhibitor of bacterial divisome assembly |
Q36211772 | EbfC (YbaB) is a new type of bacterial nucleoid-associated protein and a global regulator of gene expression in the Lyme disease spirochete |
Q34583046 | Escherichia coli sister chromosome separation includes an abrupt global transition with concomitant release of late-splitting intersister snaps. |
Q38103341 | Evolutionary cell biology of chromosome segregation: insights from trypanosomes |
Q36897132 | Four-dimensional imaging of E. coli nucleoid organization and dynamics in living cells. |
Q37925360 | From water and ions to crowded biomacromolecules: in vivo structuring of a prokaryotic cell |
Q36991061 | FtsK actively segregates sister chromosomes in Escherichia coli |
Q47172086 | Fundamental Principles in Bacterial Physiology - History, Recent progress, and the Future with Focus on Cell Size Control: A Review |
Q27311279 | Genomic location of the major ribosomal protein gene locus determines Vibrio cholerae global growth and infectivity |
Q38636000 | Geometrical ordering of DNA in bacteria |
Q44308437 | How crowded is the prokaryotic cytoplasm? |
Q54324674 | How did bacterial ancestors reproduce? Lessons from L-form cells and giant lipid vesicles: multiplication similarities between lipid vesicles and L-form bacteria. |
Q38129304 | How to get (a)round: mechanisms controlling growth and division of coccoid bacteria |
Q44677961 | HupB Is a Bacterial Nucleoid-Associated Protein with an Indispensable Eukaryotic-Like Tail |
Q51561384 | Indispensability of Horizontally Transferred Genes and Its Impact on Bacterial Genome Streamlining. |
Q92543673 | Intrinsic Disorder-Based Emergence in Cellular Biology: Physiological and Pathological Liquid-Liquid Phase Transitions in Cells |
Q36289485 | Kinetics of large-scale chromosomal movement during asymmetric cell division in Escherichia coli. |
Q33619316 | Locus of enterocyte effacement-encoded regulator (Ler) of pathogenic Escherichia coli competes off histone-like nucleoid-structuring protein (H-NS) through noncooperative DNA binding |
Q54345979 | Looped star polymers show conformational transition from spherical to flat toroidal shapes. |
Q34510132 | Mechanical force antagonizes the inhibitory effects of RecX on RecA filament formation in Mycobacterium tuberculosis |
Q36878497 | Mechanism of DNA organization by Mycobacterium tuberculosis protein Lsr2. |
Q37393849 | Mechanosensing of DNA bending in a single specific protein-DNA complex |
Q35982908 | Membrane protein expression triggers chromosomal locus repositioning in bacteria |
Q33561083 | Mitochondria, the Cell Cycle, and the Origin of Sex via a Syncytial Eukaryote Common Ancestor |
Q37080408 | Modelling of crowded polymers elucidate effects of double-strand breaks in topological domains of bacterial chromosomes |
Q47107620 | Modulation of Global Transcriptional Regulatory Networks as a Strategy for Increasing Kanamycin Resistance of the Translational Elongation Factor-G Mutants in Escherichia coli. |
Q24338466 | Nuclear pores protect genome integrity by assembling a premitotic and Mad1-dependent anaphase inhibitor |
Q53211238 | Nucleoid occlusion and bacterial cell division. |
Q35869546 | Operational Principles for the Dynamics of the In Vitro ParA-ParB System |
Q35929362 | Organization of DNA in a bacterial nucleoid |
Q27336499 | ParA and ParB coordinate chromosome segregation with cell elongation and division during Streptomyces sporulation. |
Q41886273 | ParABS system in chromosome partitioning in the bacterium Myxococcus xanthus |
Q34740849 | Participation of chromosome segregation protein ParAI of Vibrio cholerae in chromosome replication |
Q41593456 | Peptide-guided surface-enhanced Raman scattering probes for localized cell composition analysis |
Q42459699 | Persistent super-diffusive motion of Escherichia coli chromosomal loci. |
Q33780274 | Phenotypic landscape of a bacterial cell |
Q30460752 | Physical organization of DNA by multiple non-specific DNA-binding modes of integration host factor (IHF). |
Q92083691 | Preferential Localization of the Bacterial Nucleoid |
Q36938523 | Principles and concepts of DNA replication in bacteria, archaea, and eukarya |
Q35243430 | RNA-Seq analysis of the multipartite genome of Rhizobium etli CE3 shows different replicon contributions under heat and saline shock. |
Q28080460 | Redefining bacterial origins of replication as centralized information processors |
Q42167006 | Replication termination and chromosome dimer resolution in the archaeon Sulfolobus solfataricus |
Q92642966 | RocS drives chromosome segregation and nucleoid protection in Streptococcus pneumoniae |
Q26859579 | Role of RNA polymerase and transcription in the organization of the bacterial nucleoid |
Q36833104 | SMC condensation centers in Bacillus subtilis are dynamic structures |
Q45250787 | SMC is recruited to oriC by ParB and promotes chromosome segregation in Streptococcus pneumoniae |
Q35596015 | Segregation of chromosome arms in growing and non-growing Escherichia coli cells. |
Q48720565 | Short-time movement of E. coli chromosomal loci depends on coordinate and subcellular localization. |
Q34462338 | Spatial and temporal organization of chromosome duplication and segregation in the cyanobacterium Synechococcus elongatus PCC 7942. |
Q36187439 | Spatial ordering of chromosomes enhances the fidelity of chromosome partitioning in cyanobacteria |
Q39262235 | Specificity and function of archaeal DNA replication initiator proteins |
Q30499239 | Spiral architecture of the nucleoid in Bdellovibrio bacteriovorus |
Q92990682 | Spo0J and SMC are required for normal chromosome segregation in Staphylococcus aureus |
Q38241192 | Systems and synthetic biology approaches to cell division |
Q39431299 | Taking chances and making mistakes: non-genetic phenotypic heterogeneity and its consequences for surviving in dynamic environments |
Q37901364 | Temporal and spatial oscillations in bacteria |
Q42268886 | The Escherichia coli SMC complex, MukBEF, shapes nucleoid organization independently of DNA replication |
Q52659560 | The Origin of Chromosomal Replication Is Asymmetrically Positioned on the Mycobacterial Nucleoid, and the Timing of Its Firing Depends on HupB. |
Q37695599 | The Proximity of Ribosomal Protein Genes to oriC Enhances Vibrio cholerae Fitness in the Absence of Multifork Replication. |
Q38124749 | The cell cycle of archaea |
Q26859022 | The chromosome cycle of prokaryotes |
Q42760682 | The compartmentalized vessel: The bacterial cell as a model for subcellular organization (a tale of two studies). |
Q33360184 | The dynamics of the RNA world: insights and challenges |
Q34161178 | The fractal globule as a model of chromatin architecture in the cell |
Q42928479 | The general phosphotransferase system proteins localize to sites of strong negative curvature in bacterial cells |
Q34863144 | The ghost in the machine: is the bacterial chromosome a phantom chain? |
Q38913286 | The glucosaminidase domain of Atl - the major Staphylococcus aureus autolysin - has DNA-binding activity |
Q26852759 | The precarious prokaryotic chromosome |
Q36588923 | The role of MatP, ZapA and ZapB in chromosomal organization and dynamics in Escherichia coli |
Q33810618 | The terminal region of the E. coli chromosome localises at the periphery of the nucleoid. |
Q38235674 | Toxicology-based cancer causation analysis of CoCr-containing hip implants: a quantitative assessment of genotoxicity and tumorigenicity studies |
Q50624761 | Tracking of chromosome dynamics in live Streptococcus pneumoniae reveals that transcription promotes chromosome segregation. |
Q42272339 | Universal internucleotide statistics in full genomes: a footprint of the DNA structure and packaging? |
Q41774790 | Variation of the folding and dynamics of the Escherichia coli chromosome with growth conditions |
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