Different levels of catabolite repression optimize growth in stable and variable environments
about
Memory and fitness optimization of bacteria under fluctuating environmentsMolecular and cellular bases of adaptation to a changing environment in microorganismsComputing the functional proteome: recent progress and future prospects for genome-scale modelsExploiting Single-Cell Quantitative Data to Map Genetic Variants Having Probabilistic EffectsQuantification and Classification of E. coli Proteome Utilization and Unused Protein Costs across Environments.Flux-Enabled Exploration of the Role of Sip1 in Galactose Yeast MetabolismAdaptive Roles of SSY1 and SIR3 During Cycles of Growth and Starvation in Saccharomyces cerevisiae Populations Enriched for Quiescent or Nonquiescent Cells.Duplication of a promiscuous transcription factor drives the emergence of a new regulatory network.Hierarchy of non-glucose sugars in Escherichia coli.Natural variation in preparation for nutrient depletion reveals a cost-benefit tradeoff.Phenotypic heterogeneity in metabolic traits among single cells of a rare bacterial species in its natural environment quantified with a combination of flow cell sorting and NanoSIMS.Population diversification in a yeast metabolic program promotes anticipation of environmental shiftsShifting sugars and shifting paradigmsExperimental evolution in fluctuating environments: tolerance measurements at constant temperatures incorrectly predict the ability to tolerate fluctuating temperatures.Perception and regulatory principles of microbial growth controlTiming and Variability of Galactose Metabolic Gene Activation Depend on the Rate of Environmental Change.Glucose-Regulated Phosphorylation of the PUF Protein Puf3 Regulates the Translational Fate of Its Bound mRNAs and Association with RNA Granules.Populations adapt to fluctuating selection using derived and ancestral allelic diversity.In silico evolution of diauxic growth.Genomics and the making of yeast biodiversity.The Rewiring of Ubiquitination Targets in a Pathogenic Yeast Promotes Metabolic Flexibility, Host Colonization and Virulence.Polymorphisms in the yeast galactose sensor underlie a natural continuum of nutrient-decision phenotypes.Transcription, Signaling Receptor Activity, Oxidative Phosphorylation, and Fatty Acid Metabolism Mediate the Presence of Closely Related Species in Distinct Intertidal and Cold-Seep HabitatsThe lag-phase during diauxic growth is a trade-off between fast adaptation and high growth rate.Complex Interplay of Physiology and Selection in the Emergence of Antibiotic Resistance.Transcription factor levels enable metabolic diversification of single cells of environmental bacteria.Metabolism at evolutionary optimal States.Polygenic evolution of a sugar specialization trade-off in yeast.Experimental evolution and the adjustment of metabolic strategies in lactic acid bacteria.Laboratory Evolution to Alternating Substrate Environments Yields Distinct Phenotypic and Genetic Adaptive Strategies.Phenotypic heterogeneity driven by nutrient limitation promotes growth in fluctuating environments.Different food sources elicit fast changes to bacterial virulenceGenome-wide mapping of cellular traits using yeast.Taking chances and making mistakes: non-genetic phenotypic heterogeneity and its consequences for surviving in dynamic environmentsCosts of Clock-Environment Misalignment in Individual Cyanobacterial Cells.Stress-response balance drives the evolution of a network module and its host genome.Variable repeats in the eukaryotic polyubiquitin gene ubi4 modulate proteostasis and stress survival.The impact of bottlenecks on microbial survival, adaptation and phenotypic switching in host-pathogen interactions.Negative frequency-dependent interactions can underlie phenotypic heterogeneity in a clonal microbial population.Noise and Epigenetic Inheritance of Single-Cell Division Times Influence Population Fitness
P2860
Q27314372-DF4BE361-70C9-4FB2-BB82-26E3E93B28E1Q28079255-75EC1C11-174F-44CC-B298-7015D9187BC6Q28080776-FDE1B2C7-A3C3-427E-86D8-60771D0E56AFQ30000053-A412518D-A264-4A86-B6EC-7C442BBEC1D7Q30151952-0C731192-03AB-4656-97FB-EC2E30D0EB53Q33723661-63FCD82F-F125-484E-B55C-A615CD0927D7Q33807670-AD3064BA-B8D8-4B71-AEC6-51C6042C04D7Q34234550-FD853612-0783-4EA5-8339-10B65159FA8DQ35006510-E1EBA298-A434-465D-B60F-6D0F47B5ACE4Q35019289-68DC737A-EEF9-4C0B-A9B7-3D5382B626B0Q35442607-5FB9E070-DA22-4696-B56B-C22E6CD244FCQ35549977-44A0E90D-F23B-41C7-8DFF-0B0787F278B1Q35562477-750BF3CD-7020-438E-A3B5-48482E41ACE4Q35565310-C164DC13-6E6D-4B9D-BB4E-568D43222E7AQ35636333-EF5D8BB2-FEB7-449C-AE5E-892AD1508771Q35705681-3A2CD685-E28C-4FE7-8D8E-2944F2B58B17Q35756211-60B01CBE-48C8-4DB5-9221-43518B3D82E6Q35772729-AEDDF70F-0F3B-483B-BF5B-A3176D3B6AECQ35791099-5B558727-7810-4ED6-8826-0386CE938242Q35864089-5D80EAA9-DA8F-479D-836D-5202956F95EBQ35988118-E7AEAFE9-2808-4604-B433-33FEE750805CQ36380064-8DDBE689-7259-4682-9D89-3D701514EA8AQ36592445-8E56FB4D-8957-4C7D-9BE7-83AA52FB8899Q36850446-2E8F0195-F7EE-4704-A970-41F288F50120Q36984071-2268E34F-94BE-4EA0-B390-B4BEA0B86ADAQ37268254-CF5901F8-957C-4570-9CBC-380D0185EA26Q38515559-5B08B0D3-109D-44D5-8152-A80E998EB10AQ38570070-B7C4F631-F46B-414F-944E-2C304357A2E0Q38716851-FE3B3480-D9D7-4267-8CD5-E35D340B1A1AQ38813551-E4B7B11E-D8DE-49E6-BAB4-40AA67C81648Q38826733-EB986EA4-7DC4-4D88-80DA-B2FAD716152BQ38902109-954DE929-EAB2-4435-A3A2-539802ADA9A5Q39216215-25EC1CEF-3D30-4F05-B5D8-C98D71857B12Q39431299-EC1EF2C5-1ADB-4B89-9231-9FBEE09F8137Q40960174-A19433BC-61B8-49B8-8C27-737220A98A84Q41023000-C32792C2-67DD-4044-969E-3ADDC8CC3E55Q41565047-E1ABA09B-AA98-4433-A275-34E41FE434F9Q41923111-6489FB4E-D93C-4170-AF62-686A3AE06A09Q41982378-F9F1D98F-FBF1-4E31-A7DE-E2C83E0D3596Q42272721-73C1FAA7-8793-4E39-8A9F-1F5F61D10312
P2860
Different levels of catabolite repression optimize growth in stable and variable environments
description
2014 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2014 թվականի հունվարին հրատարակված գիտական հոդված
@hy
article scientifique (publié 2014-01)
@fr
articolo scientifico (pubblicato il 2014-01)
@it
artigo científico (publicado na 2014-01)
@pt
artículu científicu espublizáu en 2014
@ast
im Januar 2014 veröffentlichter wissenschaftlicher Artikel
@de
scientific article (publication date: 2014)
@en
vedecký článok (publikovaný 2014-01)
@sk
videnskabelig artikel (udgivet 2014-01)
@da
name
Different levels of catabolite ...... able and variable environments
@ast
Different levels of catabolite ...... able and variable environments
@en
Different levels of catabolite ...... able and variable environments
@nl
type
label
Different levels of catabolite ...... able and variable environments
@ast
Different levels of catabolite ...... able and variable environments
@en
Different levels of catabolite ...... able and variable environments
@nl
prefLabel
Different levels of catabolite ...... able and variable environments
@ast
Different levels of catabolite ...... able and variable environments
@en
Different levels of catabolite ...... able and variable environments
@nl
P2093
P2860
P50
P3181
P1433
P1476
Different levels of catabolite ...... able and variable environments
@en
P2093
Bram Cerulus
Gemma Perez-Samper
Joao B Xavier
Sarah Boogmans
P2860
P304
P3181
P356
10.1371/JOURNAL.PBIO.1001764
P407
P577
2014-01-14T00:00:00Z