about
Metabolite-enabled eradication of bacterial persisters by aminoglycosidesExperimental phage therapy against Staphylococcus aureus in miceEvolutionary rescue: linking theory for conservation and medicinePhotodynamic inactivation of biofilm: taking a lightly colored approach to stubborn infectionStochastic expression of a multiple antibiotic resistance activator confers transient resistance in single cellsCecum lymph node dendritic cells harbor slow-growing bacteria phenotypically tolerant to antibiotic treatmentNongenetic individuality in the host-phage interactionTriazaspirodimethoxybenzoyls as Selective Inhibitors of Mycobacterial Lipoamide Dehydrogenase,Cytological and transcript analyses reveal fat and lazy persister-like bacilli in tuberculous sputum"One-size-fits-all"? Optimizing treatment duration for bacterial infectionsPepD participates in the mycobacterial stress response mediated through MprAB and SigEVapC20 of Mycobacterium tuberculosis cleaves the sarcin-ricin loop of 23S rRNAInvolvement of an ATP-dependent protease, PA0779/AsrA, in inducing heat shock in response to tobramycin in Pseudomonas aeruginosaBacterial temporal dynamics enable optimal design of antibiotic treatmentEvaluation of the characteristics of leucyl-tRNA synthetase (LeuRS) inhibitor AN3365 in combination with different antibiotic classesThe probability of evolutionary rescue: towards a quantitative comparison between theory and evolution experimentsPersister cells, dormancy and infectious diseaseAgent-based modeling of competence phenotype switching in Bacillus subtilisPersistence: a copacetic and parsimonious hypothesis for the existence of non-inherited resistance to antibioticsClassic reaction kinetics can explain complex patterns of antibiotic action.Why is long-term therapy required to cure tuberculosis?Is bacterial persistence a social trait?The neglected intrinsic resistome of bacterial pathogens.Cell division in Escherichia coli cultures monitored at single cell resolutionDistinct specificities of Mycobacterium tuberculosis and mammalian proteasomes for N-acetyl tripeptide substrates.The impact of different antibiotic regimens on the emergence of antimicrobial-resistant bacteriaIneffectiveness of tigecycline against persistent Borrelia burgdorferiRobustness analysis of culturing perturbations on Escherichia coli colony biofilm beta-lactam and aminoglycoside antibiotic tolerance.Activated ClpP kills persisters and eradicates a chronic biofilm infectionThe development of ciprofloxacin resistance in Pseudomonas aeruginosa involves multiple response stages and multiple proteins.Antibiotic control of antibiotic resistance in hospitals: a simulation studyCadaverine suppresses persistence to carboxypenicillins in Pseudomonas aeruginosa PAO1.Active starvation responses mediate antibiotic tolerance in biofilms and nutrient-limited bacteriaCharacterization of the contribution to virulence of three large plasmids of avian pathogenic Escherichia coli chi7122 (O78:K80:H9).Sheltering effect and indirect pathogenesis of carbapenem-resistant Acinetobacter baumannii in polymicrobial infection.The evolutionary advantage of heritable phenotypic heterogeneity.Collective dynamics of gene expression in cell populationsVapC toxins from Mycobacterium tuberculosis are ribonucleases that differentially inhibit growth and are neutralized by cognate VapB antitoxins.Spontaneous and evolutionary changes in the antibiotic resistance of Burkholderia cenocepacia observed by global gene expression analysis.Genetic variation for antibiotic persistence in Escherichia coli.
P2860
Q24628050-F1E70821-0E6E-47BB-B935-71AD21F53144Q24685170-E202557E-0093-4756-9DA4-1EB5902EFE46Q26862297-0B107BAA-ADAC-4E02-AFB2-89A7391F7B5CQ27027616-AFE5A69D-6CBC-4349-AB12-3450A9F6D266Q27301322-B2719697-7B42-4C27-BEDC-0355EEA1EA81Q27315926-375B8059-55B0-456C-9CDA-C5A93D592D3FQ27333449-5040F639-9F45-40A0-872F-7605139C7F14Q27658975-4A86052E-CC90-4A02-A819-B5AE130A0945Q28472502-6BF4735B-5D54-481A-93AF-88F613539DAFQ28478851-7BAC1049-32C0-4E70-A0CF-BF3B96E68555Q28486663-3420212E-C7F1-4B9E-B054-B5C295F37DCFQ28487499-1ECCC1D9-A73D-4BDE-86FF-B2D551EB0E51Q28492485-3499AE6A-9179-4026-844F-47D43D88BDFEQ28546654-3F438DE2-D4BB-4C26-B1CA-0D77B1052298Q28597744-1C4F4C23-926C-4FAE-9B6E-4E9FD7CB2140Q28710078-D86F7C34-62F1-4565-A7F3-F017EEB8C766Q29615655-6775B692-2B6F-46C0-BACC-8D64E1706D69Q30539650-D43DACFB-1F5D-4110-B0E0-BBF8A6FF8C02Q30604367-4D3309AB-B7DB-412E-97E2-5F706B43037EQ30662980-351EB04B-4D4C-48DB-8D68-1B80553C741EQ33280142-B9A709E9-0FD7-41C8-9354-FE097BBC73F4Q33294723-CA97820C-735A-4ED3-BAE1-7D509F173E8CQ33320525-B3611DBB-36BC-4929-B3F9-9CC576E0B95CQ33330202-77DBE453-5A49-4BF8-AD32-49A94C3215B3Q33373239-06726D90-5F29-4EBB-8921-984CF0ED703AQ33396218-E341AF38-DE0F-4F51-B8A6-50634AA24C39Q33613691-832E9D94-6E83-4993-8E6E-A7622F79E60BQ33626996-276084D3-1797-4EA7-A322-7CCB6190F383Q33653007-22A974FB-6BF8-41AB-9E59-2DE7C07A34ECQ33653162-CCB06BB0-338F-4C5A-9AC8-A15898D2A989Q33672358-2375AAD7-F4FB-48EF-9D4B-C50B172276F5Q33696945-8DBEB940-547E-4D31-B3FE-1959C934BA54Q33716417-300616A8-46C8-4D64-A830-DAF23EF1BD1FQ33769054-D871FEC4-6BC2-4223-8D86-717382390162Q33798228-B59FC54C-3524-4233-9487-F22B5E1038E3Q33894867-C28E3503-2480-4910-9ED4-9AA7E5135E9AQ33941246-241E216D-2470-47BD-9135-6A9F823B62EDQ33955336-F8E03AE2-824F-4032-BE37-EAF73CC924E8Q33968990-A94AE960-0D6A-4A36-8074-2077EAA8DE7BQ34180291-1B649B7C-D4D0-4A74-88AE-EE22E4227924
P2860
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
2006年论文
@zh
2006年论文
@zh-cn
name
Non-inherited antibiotic resistance.
@ast
Non-inherited antibiotic resistance.
@en
type
label
Non-inherited antibiotic resistance.
@ast
Non-inherited antibiotic resistance.
@en
prefLabel
Non-inherited antibiotic resistance.
@ast
Non-inherited antibiotic resistance.
@en
P2860
P356
P1476
Non-inherited antibiotic resistance
@en
P2093
Bruce R Levin
P2860
P2888
P304
P356
10.1038/NRMICRO1445
P407
P577
2006-07-01T00:00:00Z