about
Multiple chaperonins in bacteria--novel functions and non-canonical behaviorsRNA thermometersImportant role of class I heat shock genes hrcA and dnaK in the heat shock response and the response to pH and NaCl stress of group I Clostridium botulinum strain ATCC 3502Enhancing isoprene production by genetic modification of the 1-deoxy-d-xylulose-5-phosphate pathway in Bacillus subtilisArchitecture of thermal adaptation in an Exiguobacterium sibiricum strain isolated from 3 million year old permafrost: a genome and transcriptome approachCharacterization of the CtsR stress response regulon in Lactobacillus plantarumStress under the dam: meeting report of the Fourth International Workshop on the Molecular Biology of Stress Responses.Transcriptional profiles of Treponema denticola in response to environmental conditions.Discovering the mechanism of action of novel antibacterial agents through transcriptional profiling of conditional mutants.Functional consequences of genome evolution in Listeria monocytogenes: the lmo0423 and lmo0422 genes encode sigmaC and LstR, a lineage II-specific heat shock system.RscA, a member of the MDR1 family of transporters, is repressed by CovR and required for growth of Streptococcus pyogenes under heat stress.Comparative transcriptional analysis of clinically relevant heat stress response in Clostridium difficile strain 630.Blue LED inhibits the growth of Porphyromonas gingivalis by suppressing the expression of genes associated with DNA replication and cell division.Global analysis of heat shock response in Desulfovibrio vulgaris HildenboroughTranscription factors and genetic circuits orchestrating the complex, multilayered response of Clostridium acetobutylicum to butanol and butyrate stress.Lessons from the modular organization of the transcriptional regulatory network of Bacillus subtilis.Analysis of Clostridium beijerinckii NCIMB 8052's transcriptional response to ferulic acid and its application to enhance the strain tolerance.Survival of Bacillus spp. SUBB01 at high temperatures and a preliminary assessment of its ability to protect heat-stressed Escherichia coli cells.Bacillus subtilis as a tool for vaccine development: from antigen factories to delivery vectors.Promoter Screening from Bacillus subtilis in Various Conditions Hunting for Synthetic Biology and Industrial Applications.Heat shock and prolonged heat stress attenuate neurotoxin and sporulation gene expression in group I Clostridium botulinum strain ATCC 3502.Reexamining transcriptional regulation of the Bacillus subtilis htpX gene and the ykrK gene, encoding a novel type of transcriptional regulator, and redefining the YkrK operator.Genetic evidence for the actin homolog gene mreBH and the bacitracin resistance gene bcrC as targets of the alternative sigma factor SigI of Bacillus subtilis.Global Association between Thermophilicity and Vancomycin Susceptibility in Bacteria.Clostridium thermocellum transcriptomic profiles after exposure to furfural or heat stress.Bioprocess monitoring by marker gene analysis.Regulation of bacterial heat shock stimulonsNon-housekeeping, non-essential GroEL (chaperonin) has acquired novel structure and function beneficial under stress in cyanobacteria.CcpA affects expression of the groESL and dnaK operons in Lactobacillus plantarum.Short- and long-term adaptation to ethanol stress and its cross-protective consequences in Lactobacillus plantarum.Transcriptome signatures of class I and III stress response deregulation in Lactobacillus plantarum reveal pleiotropic adaptation.Highly precise quantification of protein molecules per cell during stress and starvation responses in Bacillus subtilis.Quantitative phosphoproteomics reveals the role of protein arginine phosphorylation in the bacterial stress response.The global transcriptional responses of Bacillus anthracis Sterne (34F2) and a Delta sodA1 mutant to paraquat reveal metal ion homeostasis imbalances during endogenous superoxide stressPost-transcriptional regulation by distal Shine-Dalgarno sequences in the grpE-dnaK intergenic region of Streptococcus mutans.Role of Ribonucleotide Reductase in Bacillus subtilis Stress-Associated Mutagenesis.Comparative proteomic analysis of Lactobacillus plantarum WCFS1 and ΔctsR mutant strains under physiological and heat stress conditions.COMODO: an adaptive coclustering strategy to identify conserved coexpression modules between organisms.Expression and function of a groEL paralog in the thermophilic cyanobacterium Thermosynechococcus elongatus under heat and cold stress.Bacterial metabolites from intra- and inter-species influencing thermotolerance: the case of Bacillus cereus and Geobacillus stearothermophilus.
P2860
Q28084087-6FB77F2D-3116-4635-95E3-2DDD85C8C799Q28293883-B9F258E7-933A-440F-A2BB-40DDEF6CFB8DQ28485610-BAE61EB0-ED65-4E76-BDFF-5E97681FBEC9Q28741533-A017062E-4D54-4773-AE68-909A6B5C7C2BQ33385517-716501AA-3E5C-432E-BB43-7F6A6BA0412AQ33614901-4EF36EBD-8B25-4BC1-BFCD-DEF38DCF29DDQ33716826-E3772626-0CD9-4130-8FD9-9AA554E5FC86Q33737406-B888AAA6-BB8D-43C3-8EBF-940EC2F56C7EQ33803840-E0BD0A3E-4123-403C-B630-31D74379E4D4Q34110044-68265F97-64D0-402E-B45E-AA1B3DE0C47CQ34233237-0BFD4855-3DC4-4D52-8F62-AE6AE2308A66Q34364874-750127F5-0E71-4368-A6CF-C54E5EEACC95Q34467938-D0338502-C0C0-436C-B6C4-AA64A83B486DQ34509935-3706F91F-F9F1-4BC4-8DF8-B3272257EC60Q35033035-19896EB6-B9BD-4ED6-8763-5D957966BF24Q35044290-EB50E9B1-1BB3-45D4-B31B-EF4554032735Q35523171-84D7173C-A132-4AA4-AB28-F3C72EF425B6Q35829826-41591066-D005-48A4-99E9-51261010D3B6Q36030835-B855BCE3-A9FA-4B2B-8D9F-9C7E6A0445CBQ36068329-4623B1A2-1F63-4247-9012-2A9996FFAB6BQ36360827-AAFC07AD-5054-44BB-B790-0510EB13D981Q36435358-A39843CD-B83D-4008-8BF6-13C1406D0978Q36483255-D7D4C169-427B-4325-98D7-3AA82D3AFB3FQ36747106-083B7C0E-3410-422B-97CE-940F1E0BE137Q37359961-E4A5993A-65CA-4271-B570-0B21541927F3Q37904940-7A4837D3-E579-40C1-A947-F6AE37D00324Q38925897-303DA30E-C781-43D3-8CFB-E7FD7E821618Q39361817-4FAB15D3-7B13-481F-9A5F-67FBD0221059Q40324335-98C7056A-AC7D-4BED-9F1F-D68F3B0BED44Q41768463-9107B43F-F079-4C3D-8A15-4879A82F01EDQ41775744-459E4130-CF63-43E8-A914-293B94FB54B2Q41822468-61B0E141-7B68-424C-9A99-B4D4D24FF846Q41926331-659602CB-86C5-457F-B26D-C166E7209A2FQ41979741-44F6B1B8-B13A-4769-8B5C-7E27A401A7D7Q42080126-44A7B3FA-DB79-4475-8F29-A36D58C18DCCQ42324867-68BD0CF7-855F-4328-B1A6-9FE4C379A288Q42423810-20910625-D39F-4576-8ED3-0E2A3C43D407Q42714257-2E7B9532-313A-44B3-9D53-6C9DC75CD174Q43025329-40861215-3727-4D55-AA33-F398C97292C0Q46453546-426F16BE-A3ED-4979-94D5-EC3DFFA839C2
P2860
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
2003年论文
@zh
2003年论文
@zh-cn
name
The Bacillus subtilis heat shock stimulon
@ast
The Bacillus subtilis heat shock stimulon
@en
type
label
The Bacillus subtilis heat shock stimulon
@ast
The Bacillus subtilis heat shock stimulon
@en
prefLabel
The Bacillus subtilis heat shock stimulon
@ast
The Bacillus subtilis heat shock stimulon
@en
P2860
P1476
The Bacillus subtilis heat shock stimulon
@en
P2093
Wolfgang Schumann
P2860
P304
P356
10.1379/1466-1268(2003)008<0207:TBSHSS>2.0.CO;2
P577
2003-01-01T00:00:00Z