scholarly article | Q13442814 |
P2093 | author name string | Ronald E Yasbin | |
Huang-Mo Sung | |||
P2860 | cites work | THINKING ABOUT BACTERIAL POPULATIONS AS MULTICELLULAR ORGANISMS | Q22255622 |
Spontaneous point mutations that occur more often when advantageous than when neutral | Q24532456 | ||
The origin of mutants | Q28288915 | ||
The distribution of the numbers of mutants in bacterial populations | Q29620123 | ||
Control of sigma factor activity during Bacillus subtilis sporulation | Q33592573 | ||
Mechanisms of genome-wide hypermutation in stationary phase | Q33692333 | ||
General stress transcription factor sigmaB and sporulation transcription factor sigmaH each contribute to survival of Bacillus subtilis under extreme growth conditions | Q33734109 | ||
Transformation and Transfection in Lysogenic Strains of Bacillus subtilis 168 | Q33781373 | ||
Determining mutation rates in bacterial populations | Q33803752 | ||
Mechanisms of stationary phase mutation: a decade of adaptive mutation | Q33847662 | ||
Two-component and phosphorelay signal transduction | Q33879844 | ||
Genome-wide hypermutation in a subpopulation of stationary-phase cells underlies recombination-dependent adaptive mutation | Q33886793 | ||
The SOS response regulates adaptive mutation | Q33903483 | ||
A biochemical mechanism for nonrandom mutations and evolution | Q33917768 | ||
SOS mutator DNA polymerase IV functions in adaptive mutation and not adaptive amplification | Q33953638 | ||
Adaptive reversion of a frameshift mutation in Escherichia coli | Q33958142 | ||
An examination of adaptive reversion in Saccharomyces cerevisiae | Q33959891 | ||
Two enzymes, both of which process recombination intermediates, have opposite effects on adaptive mutation in Escherichia coli. | Q33966542 | ||
Opposing roles of the holliday junction processing systems of Escherichia coli in recombination-dependent adaptive mutation | Q33966750 | ||
Amplification-mutagenesis: evidence that "directed" adaptive mutation and general hypermutability result from growth with a selected gene amplification | Q34012598 | ||
Proofreading-defective DNA polymerase II increases adaptive mutation in Escherichia coli. | Q34019746 | ||
Adaptive reversion of an episomal frameshift mutation in Escherichia coli requires conjugal functions but not actual conjugation | Q34229499 | ||
Adaptive mutations, mutator DNA polymerases and genetic change strategies of pathogens | Q34392595 | ||
Genetic networks controlling the initiation of sporulation and the development of genetic competence in Bacillus subtilis | Q34399194 | ||
Transient and heritable mutators in adaptive evolution in the lab and in nature | Q34603730 | ||
Adaptive mutation: has the unicorn landed? | Q34603905 | ||
Genetics of selection-induced mutations: I. uvrA, uvrB, uvrC, and uvrD are selection-induced specific mutator loci | Q72151726 | ||
comK encodes the competence transcription factor, the key regulatory protein for competence development in Bacillus subtilis | Q72318915 | ||
New shuttle vectors for Bacillus subtilis and Escherichia coli which allow rapid detection of inserted fragments | Q72397524 | ||
Observations on the formation of clones containing araB-lacZ cistron fusions | Q72815889 | ||
The role of DNA damage in stationary phase ('adaptive') mutation | Q74808472 | ||
When the going gets tough: survival strategies and environmental signaling networks in Bacillus subtilis | Q77830305 | ||
Is there a link between mutation rates and the stringent response in Bacillus subtilis? | Q78026711 | ||
Fractionation of Escherichia coli cell populations at different stages during growth transition to stationary phase | Q78032273 | ||
Evidence that stationary-phase hypermutation in the Escherichia coli chromosome is promoted by recombination | Q34609122 | ||
The pleiotropic response regulator DegU functions as a priming protein in competence development in Bacillus subtilis | Q35202131 | ||
Phenotypic differentiation of "smart" versus "naive" bacteriophages of Bacillus subtilis | Q35608329 | ||
Nonadaptive mutations occur on the F' episome during adaptive mutation conditions in Escherichia coli | Q35620439 | ||
Promoter-creating mutations in Pseudomonas putida: a model system for the study of mutation in starving bacteria | Q36079713 | ||
Cloning and characterization of DNA damage-inducible promoter regions from Bacillus subtilis | Q36131497 | ||
Characterization of an inducible oxidative stress system in Bacillus subtilis | Q36165546 | ||
Cloning and characterization of the regulatory Bacillus subtilis competence genes comA and comB | Q36182552 | ||
Genetic method to identify regulons controlled by nonessential elements: isolation of a gene dependent on alternate transcription factor sigma B of Bacillus subtilis | Q36242581 | ||
Inducible DNA repair and differentiation in Bacillus subtilis: interactions between global regulons | Q36366603 | ||
Purification of competent cells in the Bacillus subtilis transformation system | Q36847724 | ||
Genetic competence in Bacillus subtilis | Q37057278 | ||
DNA-damage-inducible (din) loci are transcriptionally activated in competent Bacillus subtilis | Q37542338 | ||
TRANSFORMATION OF BIOCHEMICALLY DEFICIENT STRAINS OF BACILLUS SUBTILIS BY DEOXYRIBONUCLEATE. | Q37618850 | ||
DNA microarray analysis of Bacillus subtilis DegU, ComA and PhoP regulons: an approach to comprehensive analysis of B.subtilis two-component regulatory systems. | Q38296966 | ||
H-NS and RpoS regulate emergence of Lac Ara+ mutants of Escherichia coli MCS2. | Q38344584 | ||
Transient growth requirement in Bacillus subtilis following the cessation of exponential growth | Q39485533 | ||
Expression of the sigmaB-dependent general stress regulon confers multiple stress resistance in Bacillus subtilis. | Q39496307 | ||
Genetic exchange in Bacillus subtilis in soil | Q39646119 | ||
Whole-genome analysis of genes regulated by the Bacillus subtilis competence transcription factor ComK. | Q39678911 | ||
Genetic characterization of the inducible SOS-like system of Bacillus subtilis. | Q39969661 | ||
Pleiotropic effects of suppressor mutations in Bacillus subtilis. | Q40089785 | ||
Survival of hunger and stress: the role of rpoS in early stationary phase gene regulation in E. coli | Q40871460 | ||
Chapter 1 Measuring Spontaneous Mutation Rates in Yeast | Q40936432 | ||
Molecular handles on adaptive mutation | Q41034482 | ||
Adaptive reversion of a frameshift mutation in Escherichia coli by simple base deletions in homopolymeric runs | Q41572901 | ||
Mutation for survival | Q41703503 | ||
On the specificity of adaptive mutations. | Q41819829 | ||
The contribution of bacterial hypermutators to mutation in stationary phase | Q42551098 | ||
Microarray analysis of the Bacillus subtilis K-state: genome-wide expression changes dependent on ComK. | Q42673179 | ||
Adaptive mutation and slow-growing revertants of an Escherichia coli lacZ amber mutant | Q42967224 | ||
Antibiotic-resistance cassettes for Bacillus subtilis. | Q48068163 | ||
Adaptive amplification: an inducible chromosomal instability mechanism | Q50117945 | ||
Microbial genetics. Hypermutation under stress. | Q54564293 | ||
A direct role for DNA polymerase III in adaptive reversion of a frameshift mutation in Escherichia coli. | Q54567733 | ||
Evidence that F plasmid transfer replication underlies apparent adaptive mutation. | Q54613748 | ||
Adaptive mutation by deletions in small mononucleotide repeats. | Q54630365 | ||
Recombination in adaptive mutation. | Q54635736 | ||
Spontaneous mutation in stationary-phase Escherichia coli WP2 carrying various DNA repair alleles | Q54655623 | ||
Recombination-dependent mutation in non-dividing cells | Q56903492 | ||
The recE(A)+ gene of B subtilis and its gene product: further characterization of this universal protein | Q67996975 | ||
Properties of Bacillus subtilis 168 derivatives freed of their natural prophages | Q71542009 | ||
Regulatory inputs for the synthesis of ComK, the competence transcription factor of Bacillus subtilis | Q71699782 | ||
P433 | issue | 20 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | Bacillus subtilis | Q131238 |
P304 | page(s) | 5641-5653 | |
P577 | publication date | 2002-10-01 | |
P1433 | published in | Journal of Bacteriology | Q478419 |
P1476 | title | Adaptive, or stationary-phase, mutagenesis, a component of bacterial differentiation in Bacillus subtilis | |
P478 | volume | 184 |
Q42599294 | A high-frequency mutation in Bacillus subtilis: requirements for the decryptification of the gudB glutamate dehydrogenase gene |
Q93084901 | Aging of a Bacterial Colony Enforces the Evolvement of Nondifferentiating Mutants |
Q38386789 | An Environmental Shiga Toxin-Producing Escherichia coli O145 Clonal Population Exhibits High-Level Phenotypic Variation That Includes Virulence Traits |
Q36499774 | Bacterial stationary-state mutagenesis and Mammalian tumorigenesis as stress-induced cellular adaptations and the role of epigenetics |
Q46076444 | Conditional Function of Autoaggregative Protein Cah and Common cah Mutations in Shiga Toxin-Producing Escherichia coli |
Q37513635 | Contribution of the mismatch DNA repair system to the generation of stationary-phase-induced mutants of Bacillus subtilis |
Q36961674 | Controlling mutation: intervening in evolution as a therapeutic strategy |
Q36194928 | DNA repair and genome maintenance in Bacillus subtilis |
Q42041568 | Defects in the error prevention oxidized guanine system potentiate stationary-phase mutagenesis in Bacillus subtilis |
Q37173424 | DinB upregulation is the sole role of the SOS response in stress-induced mutagenesis in Escherichia coli |
Q34925901 | Emergence of antibiotic resistance from multinucleated bacterial filaments |
Q42796673 | Error-prone processing of apurinic/apyrimidinic (AP) sites by PolX underlies a novel mechanism that promotes adaptive mutagenesis in Bacillus subtilis |
Q47098951 | Errors in mutagenesis and the benefit of cell-to-cell signalling in the evolution of stress-induced mutagenesis |
Q34986917 | Extent of genetic lesions of the arginine and pyrimidine biosynthetic pathways in Lactobacillus plantarum, L. paraplantarum, L. pentosus, and L. casei: prevalence of CO(2)-dependent auxotrophs and characterization of deficient arg genes in L. planta |
Q40995271 | Implementation of a loss-of-function system to determine growth and stress-associated mutagenesis in Bacillus subtilis |
Q40763644 | Involvement of error-prone DNA polymerase IV in stationary-phase mutagenesis in Pseudomonas putida |
Q38669825 | LC-MS/MS proteomic analysis of starved Bacillus subtilis cells overexpressing ribonucleotide reductase (nrdEF): implications in stress-associated mutagenesis |
Q33417637 | Life, death, differentiation, and the multicellularity of bacteria |
Q25255347 | Making ends meet: repairing breaks in bacterial DNA by non-homologous end-joining |
Q61807790 | Mfd protects against oxidative stress in Bacillus subtilis independently of its canonical function in DNA repair |
Q42166009 | Mismatch Repair Modulation of MutY Activity Drives Bacillus subtilis Stationary-Phase Mutagenesis |
Q37512348 | Multiple strategies for translesion synthesis in bacteria |
Q33373675 | Mutability and importance of a hypermutable cell subpopulation that produces stress-induced mutants in Escherichia coli |
Q35869358 | Mutation as a stress response and the regulation of evolvability |
Q35063174 | Non-homologous end-joining: bacteria join the chromosome breakdance |
Q35130221 | Novel role of mfd: effects on stationary-phase mutagenesis in Bacillus subtilis |
Q38303861 | Nutritional control of elongation of DNA replication by (p)ppGpp |
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Q37713187 | RecD2 helicase limits replication fork stress in Bacillus subtilis. |
Q40310297 | Role of Bacillus subtilis DNA Glycosylase MutM in Counteracting Oxidatively Induced DNA Damage and in Stationary-Phase-Associated Mutagenesis |
Q42711973 | Role of Base Excision Repair (BER) in Transcription-associated Mutagenesis of Nutritionally Stressed Nongrowing Bacillus subtilis Cell Subpopulations |
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Q42324867 | Role of Ribonucleotide Reductase in Bacillus subtilis Stress-Associated Mutagenesis |
Q43064330 | Role of the Nfo and ExoA apurinic/apyrimidinic endonucleases in repair of DNA damage during outgrowth of Bacillus subtilis spores |
Q34470485 | Roles of E. coli double-strand-break-repair proteins in stress-induced mutation |
Q34810207 | Roles of YqjH and YqjW, homologs of the Escherichia coli UmuC/DinB or Y superfamily of DNA polymerases, in stationary-phase mutagenesis and UV-induced mutagenesis of Bacillus subtilis |
Q40346968 | Roles of endonuclease V, uracil-DNA glycosylase, and mismatch repair in Bacillus subtilis DNA base-deamination-induced mutagenesis |
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Q36961669 | Stationary phase mutagenesis in B. subtilis: a paradigm to study genetic diversity programs in cells under stress |
Q35544150 | Stationary phase mutagenesis: mechanisms that accelerate adaptation of microbial populations under environmental stress |
Q41842482 | Stationary-Phase Mutagenesis in Stressed Bacillus subtilis Cells Operates by Mfd-Dependent Mutagenic Pathways. |
Q37096548 | Stochastic processes influence stationary-phase decisions in Bacillus subtilis |
Q40459862 | Stress-Induced Mutagenesis. |
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Q37355812 | Stress-induced beta-lactam antibiotic resistance mutation and sequences of stationary-phase mutations in the Escherichia coli chromosome. |
Q36961683 | Stress-induced mutagenesis in bacteria. |
Q89697204 | The Bacillus Subtilis K-State Promotes Stationary-Phase Mutagenesis via Oxidative Damage |
Q38541782 | The Origin of Mutants Under Selection: How Natural Selection Mimics Mutagenesis (Adaptive Mutation) |
Q35941132 | The RecA-Dependent SOS Response Is Active and Required for Processing of DNA Damage during Bacillus subtilis Sporulation |
Q34285727 | The evolution of stress-induced hypermutation in asexual populations |
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Q41991047 | Transcription-associated mutation in Bacillus subtilis cells under stress |
Q46958037 | Transcriptional coupling of DNA repair in sporulating Bacillus subtilis cells. |
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Q33892432 | Transcriptome profiling analysis reveals metabolic changes across various growth phases in Bacillus pumilus BA06 |
Q64096919 | What is mutation? A chapter in the series: How microbes "jeopardize" the modern synthesis |
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