Hunger artists: yeast adapted to carbon limitation show trade-offs under carbon sufficiency - Wikidata - wikimedia - TriplyDB

Hunger artists: yeast adapted to carbon limitation show trade-offs under carbon sufficiency

Hunger artists: yeast adapted to carbon limitation show trade-offs under carbon sufficiency

http://www.wikidata.org/entity/Q33987589

about

Elucidating the molecular architecture of adaptation via evolve and resequence experiments Defectors Can Create Conditions That Rescue Cooperation Molecular and cellular bases of adaptation to a changing environment in microorganisms The Valley-of-Death: reciprocal sign epistasis constrains adaptive trajectories in a constant, nutrient limiting environment Saccharomyces cerevisiae: a nomadic yeast with no niche?The functional basis of adaptive evolution in chemostats The use of chemostats in microbial systems biology Improved use of a public good selects for the evolution of undifferentiated multicellularity Epistasis for growth rate and total metabolic flux in yeast.Adaptive Roles of SSY1 and SIR3 During Cycles of Growth and Starvation in Saccharomyces cerevisiae Populations Enriched for Quiescent or Nonquiescent Cells.Ex uno plures: clonal reinforcement drives evolution of a simple microbial community Different selective pressures lead to different genomic outcomes as newly-formed hybrid yeasts evolve.Whole genome, whole population sequencing reveals that loss of signaling networks is the major adaptive strategy in a constant environment.Recurrent rearrangement during adaptive evolution in an interspecific yeast hybrid suggests a model for rapid introgression.Too much of a good thing: the unique and repeated paths toward copper adaptation.Payoffs, not tradeoffs, in the adaptation of a virus to ostensibly conflicting selective pressures.The fitness consequences of aneuploidy are driven by condition-dependent gene effects.Evolutionary engineering of a wine yeast strain revealed a key role of inositol and mannoprotein metabolism during low-temperature fermentation Adaptation to High Ethanol Reveals Complex Evolutionary Pathways Polyploidy can drive rapid adaptation in yeast.Real-Time Evolution of a Subtelomeric Gene Family in Candida albicans Analysis of the Saccharomyces cerevisiae pan-genome reveals a pool of copy number variants distributed in diverse yeast strains from differing industrial environments.High-Throughput Identification of Adaptive Mutations in Experimentally Evolved Yeast Populations.Seeking Goldilocks During Evolution of Drug Resistance.A method for high-throughput production of sequence-verified DNA libraries and strain collections.Synergistic Pleiotropy Overrides the Costs of Complexity in Viral Adaptation.The genomic landscape and evolutionary resolution of antagonistic pleiotropy in yeast.Decoupling nutrient signaling from growth rate causes aerobic glycolysis and deregulation of cell size and gene expression.The fates of mutant lineages and the distribution of fitness effects of beneficial mutations in laboratory budding yeast populations Evolutionary engineering of Saccharomyces cerevisiae for improved industrially important properties.Adaptive laboratory evolution -- principles and applications for biotechnology.The Genomic Architecture of Interactions Between Natural Genetic Polymorphisms and Environments in Yeast Growth.The adaptive landscape of wildtype and glycosylation-deficient populations of the industrial yeast Pichia pastoris.The emergence of performance trade-offs during local adaptation: insights from experimental evolution.Yeast-bacteria competition induced new metabolic traits through large-scale genomic rearrangements in Lachancea kluyveri.Phenotypic and genotypic convergences are influenced by historical contingency and environment in yeast.How biochemical constraints of cellular growth shape evolutionary adaptations in metabolism.Development of a Comprehensive Genotype-to-Fitness Map of Adaptation-Driving Mutations in Yeast.De novo sequencing, assembly and analysis of the genome of the laboratory strain Saccharomyces cerevisiae CEN.PK113-7D, a model for modern industrial biotechnology.Molecular specificity, convergence and constraint shape adaptive evolution in nutrient-poor environments.

P2860

Q26783005-C6AC5DDD-409D-45F3-970E-81E9B458C8EE Q27317021-1CAC9B0C-FD35-4B33-8029-3C69B34BA433 Q28079255-FEF6CF5A-38A5-402A-A4E4-FCA639E76E4B Q28646039-E86F5668-59EF-4079-A805-013CBA0D13D0 Q28647013-42C86E43-AFEB-4C8B-B9A5-87D7594817C5 Q28649903-D7DC0DCB-F322-41FC-B99E-7E493E63A22E Q28658297-90A623F9-E1E6-4804-B822-F9EEA98B3188 Q28709417-8A811564-1773-47ED-B7A6-F38A247B9E32 Q31050806-95A9CF26-3187-432E-A931-5C67A7764169 Q33807670-71DC4BFD-FFC6-43B2-B7AD-CCB2B7143E45 Q33811779-E48974E7-58C7-4DC8-A5C0-BDF34E58A6D7 Q34218421-F25D6A24-FDAB-4703-80EC-40759F73F3D6 Q34387997-4011AF43-F2F1-40AD-B541-3A391A5E276E Q34649820-8AAFDB5A-56C3-4AAC-98DD-794EC07E9CAA Q35050923-7A70C9FA-3E9F-49E2-B330-EC5684885261 Q35294643-B979064B-1D6C-4402-8453-629DFEA95577 Q35642077-FC792EEB-0091-427B-8A09-4C7FE4526CB0 Q35700941-D0A9083A-6909-4F65-8632-2C6B29C5C7A9 Q35834410-22F0C69A-C705-4BF3-B385-E8E5E3B11432 Q35835073-9097D50B-D80E-4D60-B0B8-A5FACDDCBB74 Q35882372-4DC1F7CA-BC30-47F7-B71D-087DE0FE71EF Q35914861-73D1B5ED-46A6-4036-ACB6-01C41B50B2F4 Q36160359-1260DF52-4B44-4821-BA16-3A3C9DF48B54 Q36269559-BA891F27-5B47-44B9-AE23-FC0DB6433A82 Q36279402-7CB0EF87-B53D-41CF-86BC-445BDCA9E26A Q36429821-B198B6C1-BA8C-46A4-A7A5-7478BB30BD47 Q36442608-26C59999-EDF2-4576-AF7F-C66734CE5B08 Q36523600-4BF13C17-3A12-4ED3-AFC8-AFB11BA9D5DC Q37696346-8AE87372-9D65-489E-B4E3-98ECC666C6B7 Q37963938-BA2E0B8A-6BA8-48D5-8651-7CD30BFAF821 Q38118393-A619851A-4A99-465C-8994-126D631D5871 Q38439657-ADCACD35-BB92-48CE-975B-BE5935292721 Q38630215-E80D57C2-9682-4D26-9986-676756D9EF07 Q39060561-1943A9DE-9448-4774-81A9-68627407B294 Q40487771-0C50CF1C-450F-4A81-B032-27BB6C06FCB2 Q40898690-4B85EBD8-128D-44E7-8761-BF49A977E253 Q41077094-B1D6922E-2E61-4AC3-994A-1939A04D5549 Q41507951-3A1C5B67-47C8-453A-9992-AAFB97C3F5FA Q41821972-2D9BE783-AE10-4B79-B85B-37D5F40223E2 Q41862781-86EE9FE7-F36E-4489-B620-4E5D5B5376E4

P2860

Hunger artists: yeast adapted to carbon limitation show trade-offs under carbon sufficiency

http://www.wikidata.org/entity/Q33987589

description

2011 nî lūn-bûn

@nan

2011 թուականի Օգոստոսին հրատարակուած գիտական յօդուած

@hyw

2011 թվականի օգոստոսին հրատարակված գիտական հոդված

@hy

2011年の論文

@ja

2011年論文

@yue

2011年論文

@zh-hant

2011年論文

@zh-hk

2011年論文

@zh-mo

2011年論文

@zh-tw

2011年论文

@wuu

name

Hunger artists: yeast adapted ...... -offs under carbon sufficiency

@ast

Hunger artists: yeast adapted ...... -offs under carbon sufficiency

@en

type

label

Hunger artists: yeast adapted ...... -offs under carbon sufficiency

@ast

Hunger artists: yeast adapted ...... -offs under carbon sufficiency

@en

prefLabel

Hunger artists: yeast adapted ...... -offs under carbon sufficiency

@ast

Hunger artists: yeast adapted ...... -offs under carbon sufficiency

@en

P1433

Q33987589-5E42A125-A935-4696-8252-A537A711FC76

P1476

Q33987589-AF04159F-AB47-4B82-B93E-9026BEC48C2F

P2093

Q33987589-72B9577D-C38A-4A3D-8AB8-92141FC69AE9

Q33987589-9F323E2D-6098-4B94-93B7-DE4B5CCDBEC1

Q33987589-B7FFFED7-76D1-454C-8D0A-E37E58EC3A98

Q33987589-D5BCDEE9-034D-45DA-89BC-026932554432

P2860

Q33987589-02F46CFC-ABBD-44E0-A6BC-0AFF2FE559E4

Q33987589-0ABD2AA3-4BF2-4A57-82D1-B4CCC7C65676

Q33987589-0EBB2C56-7311-4D86-A8D2-719A3FD1A68D

Q33987589-210E1D6E-F22A-43A6-98B8-69D55B51C084

Q33987589-232EDE65-AB98-4238-A21F-7D41C477B923

Q33987589-254A4B6B-85DD-467E-973B-5DC7DA888896

Q33987589-3876A6E7-2BF1-4BA7-BEC4-B9821A8007B3

Q33987589-427C55AD-6650-4844-B7B5-B551ED48B335

Q33987589-4A833B81-0F3C-4833-8ECC-316DEDD46423

Q33987589-555290F8-7C06-45D1-BFEF-CAB2E63674F1

P304

Q33987589-1F364EE5-49C1-4B84-B2CD-18D8B816E15E

P31

Q33987589-0018754D-77B7-4063-A456-73C188D7C6CB

P356

Q33987589-815A8011-2C4A-4A79-A0B0-F563B54B4379

P433

Q33987589-DC5A2598-0F1A-4102-84D2-6FB592628B7B

P478

Q33987589-34654CDF-5435-40FA-972E-54B095D613F8

P50

Q33987589-536D48E8-ADC1-451F-B7AD-FEFCCE838044

Q33987589-F6A53271-78B3-42A9-97B2-3F50E94815E8

P577

Q33987589-766DA919-15E2-4050-8609-6BD878DB206D

P5875

Q33987589-1784E82E-3CF2-48F2-915F-AF2F1BD0F7E5

P698

Q33987589-C97F1148-33EB-42AD-B41A-38EDAC246C84

P932

Q33987589-3AACF392-79BF-4C1F-BC1D-F1B91631441A

P356

JOURNAL.PGEN.1002202

P1433

P1476

Hunger artists: yeast adapted ...... -offs under carbon sufficiency

@en

P2093

Frank Rosenzweig

http://www.w3.org/2001/XMLSchema#string

Jared W Wenger

http://www.w3.org/2001/XMLSchema#string

Jeffrey Piotrowski

http://www.w3.org/2001/XMLSchema#string

Kami Chiotti

http://www.w3.org/2001/XMLSchema#string

P2860

Microbial genetics: Evolution experiments with microorganisms: the dynamics and genetic bases of adaptation

Genome-wide analysis of a long-term evolution experiment with Drosophila

Two TOR complexes, only one of which is rapamycin sensitive, have distinct roles in cell growth control

Evolutionary genomics of ecological specialization

Significance analysis of microarrays applied to the ionizing radiation response

Glucose deprivation contributes to the development of KRAS pathway mutations in tumor cells

Fast and accurate short read alignment with Burrows-Wheeler transform

Ras and Gpa2 mediate one branch of a redundant glucose signaling pathway in yeast

Tpk3 and Snf1 protein kinases regulate Rgt1 association with Saccharomyces cerevisiae HXK2 promoter

The Evolution of Viruses in Multi-Host Fitness Landscapes

P304

e1002202

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1371/JOURNAL.PGEN.1002202

http://www.w3.org/2001/XMLSchema#string

P433

8

http://www.w3.org/2001/XMLSchema#string

P478

7

http://www.w3.org/2001/XMLSchema#string

P50

Saisubramanian Nagarajan

P577

2011-08-04T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

51559704

http://www.w3.org/2001/XMLSchema#string

P698

21829391

http://www.w3.org/2001/XMLSchema#string

P932

3150441

http://www.w3.org/2001/XMLSchema#string