about
Bacterial persistence: a model of survival in changing environmentsNature, nurture, or chance: stochastic gene expression and its consequencesSwitching cell fate: the remarkable rise of induced pluripotent stem cells and lineage reprogramming technologiesThe evolution of bet-hedging adaptations to rare scenariosDifferent levels of catabolite repression optimize growth in stable and variable environmentsNatural biased coin encoded in the genome determines cell strategyBet hedging in yeast by heterogeneous, age-correlated expression of a stress protectantMapping the environmental fitness landscape of a synthetic gene circuitNoise contributions in an inducible genetic switch: a whole-cell simulation studyHeritable stochastic switching revealed by single-cell genealogyMolecular and cellular bases of adaptation to a changing environment in microorganismsMicrobial cell individuality and the underlying sources of heterogeneityIs transcriptional regulation of metabolic pathways an optimal strategy for fitness?Operating regimes of signaling cycles: statics, dynamics, and noise filteringRegulatory control and the costs and benefits of biochemical noiseBiological switches and clocksInfluence of stochastic gene expression on the cell survival rheostat after traumatic brain injuryInfluence of molecular noise on the growth of single cells and bacterial populationsA design principle of group-level decision making in cell populationsStochastic responses may allow genetically diverse cell populations to optimize performance with simpler signaling networksEnvironmental statistics and optimal regulationNoise in biologyA genome-wide analysis of promoter-mediated phenotypic noise in Escherichia coliStochasticity in the Genotype-Phenotype Map: Implications for the Robustness and Persistence of Bet-HedgingFunctional roles for noise in genetic circuitsCellular heterogeneity and live cell arrays.Evolutionary pressures on simple sequence repeats in prokaryotic coding regions.Bet-hedging and epigenetic inheritance in bacterial cell development.Pre-dispositions and epigenetic inheritance in the Escherichia coli lactose operon bistable switchIncreasing population growth by asymmetric segregation of a limiting resource during cell division.Discussion on research methods of bacterial resistant mutation mechanisms under selective culture--uncertainty analysis of data from the Luria-Delbrück fluctuation experiment.Bet-hedging during bacterial diauxic shift.Mechanism of transcriptional bursting in bacteria.The asymmetry of telomere replication contributes to replicative senescence heterogeneity.Complex dynamics of transcription regulation.The effect of stochasticity on the lac operon: an evolutionary perspectiveMemory in microbes: quantifying history-dependent behavior in a bacterium.Stochastic and regulatory role of chromatin silencing in genomic response to environmental changesGenetic noise control via protein oligomerizationFlipping DNA to generate and regulate microbial consortia.
P2860
Q24544968-9EDD2C0B-23AD-4420-BCE6-405AF0704045Q24610764-1C08D183-EADC-4BB5-A3AD-2B0EBD5729EFQ24617141-3114CCD9-EC3C-4D27-AF2E-696D897E9980Q24678043-4A403BCE-1F93-4748-9861-E995ECE3618AQ27316108-83D8BCB4-0F9C-49F7-B357-67EAC5CB3167Q27316979-00AEF387-BFBB-46B8-A818-622C7A066D9FQ27319462-2533A266-2EC8-4508-AB20-BBFE44F74356Q27331437-BA0F88C9-026C-429D-A7E1-BEB5450FC0F9Q27333733-B86F627E-599E-4B72-967D-0C034BC77B90Q27334245-D12AF173-8559-49F7-B683-8CE5BDC13892Q28079255-2CED419E-4AA1-49D9-B9B4-B303D892D745Q28252446-DA63FB51-E8B2-4326-AEA3-6BF6293C3FDDQ28469291-0DD22BEA-F820-4D19-B9CB-FD602AAE923CQ28472165-C5CBB1E5-FDC2-4E68-A4D1-D14E45AB6FF1Q28473536-4CC69ED9-CB4F-48E0-BCE3-59EC0077DD5CQ28475758-750917A7-FF6D-496B-87C1-6309A0FE795EQ28476525-2C763399-69A4-4BF4-B9F7-98FE6CB6AB94Q28478737-E5A9B6B5-60FC-46EA-A9CD-FAF2649EAA79Q28534350-31DD738A-64D7-4BE3-8DDB-DD7DC67CB78DQ28535190-841DE0DD-3CE1-4480-B955-9412F8A5DAFEQ28543209-B59CB8C0-353F-4E58-9703-A0DD4F060DF9Q28659275-545DBA94-869E-4ED6-A37A-54D2A395728DQ28732701-8B639318-31FA-4076-B405-699D605AFD78Q28817218-76B2B18B-BC4E-48AC-9A3A-4F058ED35021Q29616625-82BC0512-F0B8-4622-9A78-F140468F7E4CQ30401785-D43596A7-44F8-4F43-A39F-C2001ED762F4Q30410058-FD84CF13-FAAF-41CC-99FC-F8B0561D3FECQ30482011-62FF4F0D-31E9-4052-962E-C6B962FF8523Q30494565-98E4E36B-28F9-4978-A59A-FB78595D06BCQ30539967-A2B7968B-2F0D-4497-8312-175833146FD6Q30577815-01FB0737-F161-4797-9D90-B6F9BC6E5870Q30578887-F68282E1-7AC7-4F3D-85E6-8912436D7523Q30584486-4FE8E7ED-64C4-4F44-A66C-155518FF4FA4Q30668642-F140251C-3593-4553-B4AA-510CD2985265Q31053995-6B080F58-37A4-49B7-8179-AEEBA4FF7844Q33288725-AC4571B1-09A2-4825-AC15-A029CB0C3494Q33322890-A35C8476-C1BE-4CCA-9FFA-CF73AE69C971Q33361585-F26B257C-1BCF-464C-9B0D-96B24F673CA0Q33382294-721A5CBD-8076-43BC-A02B-24606931B14CQ33565680-3C092CAB-8686-4C7E-B371-4A0A535B29C6
P2860
description
2004 nî lūn-bûn
@nan
2004 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2004 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
name
Stochastic gene expression in fluctuating environments.
@ast
Stochastic gene expression in fluctuating environments.
@en
Stochastic gene expression in fluctuating environments.
@nl
type
label
Stochastic gene expression in fluctuating environments.
@ast
Stochastic gene expression in fluctuating environments.
@en
Stochastic gene expression in fluctuating environments.
@nl
prefLabel
Stochastic gene expression in fluctuating environments.
@ast
Stochastic gene expression in fluctuating environments.
@en
Stochastic gene expression in fluctuating environments.
@nl
P2860
P1433
P1476
Stochastic gene expression in fluctuating environments.
@en
P2093
Mukund Thattai
P2860
P304
P356
10.1534/GENETICS.167.1.523
P407
P577
2004-05-01T00:00:00Z