Protein quality control acts on folding intermediates to shape the effects of mutations on organismal fitness. - Wikidata - wikimedia - TriplyDB

Protein quality control acts on folding intermediates to shape the effects of mutations on organismal fitness.

Protein quality control acts on folding intermediates to shape the effects of mutations on organismal fitness.

http://www.wikidata.org/entity/Q36532990

about

Merging molecular mechanism and evolution: theory and computation at the interface of biophysics and evolutionary population genetics Comparing protein folding in vitro and in vivo: foldability meets the fitness challenge Recent developments in the use of differential scanning fluorometry in protein and small molecule discovery and characterization Individual and collective contributions of chaperoning and degradation to protein homeostasis in E. coli.A model of proteostatic energy cost and its use in analysis of proteome trends and sequence evolution Fitness Trade-Offs Determine the Role of the Molecular Chaperonin GroEL in Buffering Mutations Viewing protein fitness landscapes through a next-gen lens.The molecular chaperone DnaK is a source of mutational robustness The Role of Evolutionary Selection in the Dynamics of Protein Structure Evolution.Molecular Determinants of Mutant Phenotypes, Inferred from Saturation Mutagenesis Data A comprehensive, high-resolution map of a gene's fitness landscape The binary protein-protein interaction landscape of Escherichia coli Opposing effects of folding and assembly chaperones on evolvability of Rubisco.Reconstructed Ancestral Enzymes Impose a Fitness Cost upon Modern Bacteria Despite Exhibiting Favourable Biochemical Properties.Latent effects of Hsp90 mutants revealed at reduced expression levels.Variation in the fitness effects of mutations with population density and size in Escherichia coli Thermal stabilization of dihydrofolate reductase using monte carlo unfolding simulations and its functional consequences.Protein Homeostasis Imposes a Barrier on Functional Integration of Horizontally Transferred Genes in Bacteria Biophysical principles predict fitness landscapes of drug resistance.BRG1 and BRM SWI/SNF ATPases redundantly maintain cardiomyocyte homeostasis by regulating cardiomyocyte mitophagy and mitochondrial dynamics in vivo.Transient protein-protein interactions perturb E. coli metabolome and cause gene dosage toxicity.Alanine scan of core positions in ubiquitin reveals links between dynamics, stability, and function.Modulating protein stability - directed evolution strategies for improved protein function.Quantifying and understanding the fitness effects of protein mutations: Laboratory versus nature Role of auxiliary proteins in Rubisco biogenesis and function.Bridging the physical scales in evolutionary biology: from protein sequence space to fitness of organisms and populations.De Novo Evolutionary Emergence of a Symmetrical Protein Is Shaped by Folding Constraints.Systems-level response to point mutations in a core metabolic enzyme modulates genotype-phenotype relationship.Selection on metabolic pathway function in the presence of mutation-selection-drift balance leads to rate-limiting steps that are not evolutionarily stable.Is catalytic activity of chaperones a selectable trait for the emergence of heat shock response?A "fuzzy"-logic language for encoding multiple physical traits in biomolecules.Catalysis of protein folding by chaperones accelerates evolutionary dynamics in adapting cell populations A Simple Model of Protein Domain Swapping in Crowded Cellular Environments.Thermosensitivity of growth is determined by chaperone-mediated proteome reallocation.The burst-phase folding intermediate of ribonuclease H changes conformation over evolutionary history.Stability of the Influenza Virus Hemagglutinin Protein Correlates with Evolutionary Dynamics.Low cost, microcontroller based heating device for multi-wavelength differential scanning fluorimetry.Optimization of lag phase shapes the evolution of a bacterial enzyme.Phylogenetic divergence of cell biological features.TRIM16 controls assembly and degradation of protein aggregates by modulating the p62-NRF2 axis and autophagy

P2860

Q26861515-BBB51DF8-26E7-4D7A-8E6A-5571404B4087 Q26991933-D3B6AF83-6F39-4F67-BF76-B97ADF49EF9A Q26996528-1DCFC21C-4BEE-49D6-91CE-6211F92AD6B4 Q27320857-C659C5B5-D95E-4D9B-B02A-91709B66E2DA Q28540274-FA8397FF-1035-4E1E-8FEB-DB6130F0AEE8 Q28607448-C3A5FE73-8A90-47AB-AA1D-B6A1D8A855E6 Q30367833-0CF659AE-87EA-4DD0-B412-7DD389FBDF08 Q30391567-1B8C23F1-D8D7-4514-8740-6ACC1D2C958D Q30401012-DB202BB0-4306-40A4-AA1D-E39C98A2487B Q31123704-54E38EFB-4B0E-4C5C-9C27-4C0B0A7795C9 Q33654337-3BDC77BD-ABF8-47ED-922E-282F9F229FB0 Q34010755-07E7AD4E-794D-4684-BCE3-7B691A8A88F2 Q34456547-C4D8917C-AC4B-4BAE-AD53-D67AF2365F6F Q34493140-313CE6E9-05AE-4CFB-A5E0-7090246CAC04 Q34795559-56DEA795-5BC3-43F9-B02A-604BA5457996 Q35224374-46B3E47D-85A8-4541-9909-CD7ED3D623DD Q35612683-9980CDBF-2308-4DFF-B7C8-74689B6C8E36 Q35814404-51B6FE77-A673-4866-9B2E-B8B97FDEECEF Q36710493-C9D728D6-4DB5-429F-B86B-1AFB3472EEDC Q36880214-A4E2AE83-C65A-4B32-84C4-4B0A1DA17B6A Q37524872-74588B20-2563-45EE-BC56-07D77BEA0BBE Q37633562-5FFDB1E1-4F6A-4474-B319-25FF00987C47 Q38109676-AA2DCC41-4893-4CBC-AB3A-2C57EFC0F448 Q38787151-92D14DA6-BD20-40B9-BDC3-FC2DA5AF6F53 Q38850428-1E69DCF4-887A-4777-967B-C1CC851F3B7B Q38997863-D256A504-A092-43F5-9CA1-1F361A57E14F Q40066647-A49C3A40-25D9-4926-B3F3-D3290B933BA3 Q40170200-377ED9FA-E281-4843-9B4C-5B336D7D7F2F Q41841882-39A63F53-A78A-4154-B0F4-54655C4715F1 Q41853435-A3E56F4D-A08F-48F9-9B11-878D2D86CA43 Q41973906-FAF2F0B6-4D3D-4B4A-9B2D-8D5F89CF988E Q42050933-155578C5-BCCB-4177-890C-177BFC81A0EE Q42576606-2A9B8416-65E6-42B9-8175-1A671569BCB7 Q46138830-94D6D7B5-FB48-4DC3-A100-C2965541C4C7 Q46160796-8376447E-67B0-4EC1-BC27-77455E5EA964 Q47135067-C108CE72-77A2-4789-A805-395995F826A7 Q48181112-4A59BC3B-9084-406A-B213-643A79A3A129 Q54150482-118DBD24-C492-4996-A70F-5A2E18AF3CC1 Q55438253-DA1318A2-2D2F-448D-AB24-E8A639F22035 Q58704576-E37D7CBA-6026-4348-A755-CD7BD8DB4326

P2860

Protein quality control acts on folding intermediates to shape the effects of mutations on organismal fitness.

http://www.wikidata.org/entity/Q36532990

description

2012 nî lūn-bûn

@nan

2012年の論文

@ja

2012年論文

@yue

2012年論文

@zh-hant

2012年論文

@zh-hk

2012年論文

@zh-mo

2012年論文

@zh-tw

2012年论文

@wuu

2012年论文

@zh

2012年论文

@zh-cn

name

Protein quality control acts o ...... tations on organismal fitness.

@ast

Protein quality control acts o ...... tations on organismal fitness.

@en

type

label

Protein quality control acts o ...... tations on organismal fitness.

@ast

Protein quality control acts o ...... tations on organismal fitness.

@en

prefLabel

Protein quality control acts o ...... tations on organismal fitness.

@ast

Protein quality control acts o ...... tations on organismal fitness.

@en

P1433

Q36532990-14844994-150B-4ED5-A708-4E9FC29154FD

P1476

Q36532990-5AEC3269-91C1-4266-A3D4-FDFC04A066EF

P2093

Q36532990-C00A2C4E-1BEE-4A8C-A7F5-E3511EB6E980

Q36532990-E798BFCB-D86D-4B16-B5FE-F2302189E920

P2860

Q36532990-0141B9DE-2593-4C0B-8599-8EC17179535B

Q36532990-06CA1F07-1EA1-4E6B-AC06-4F5AF5F31001

Q36532990-09250ED7-BAE8-4364-B31B-F3A830A8F672

Q36532990-0F9E3481-BD37-4A5C-B8AA-DB4CFE33564C

Q36532990-17D108BA-5728-45A2-A6A1-970ABD6617B9

Q36532990-205EA2E1-4E1D-4023-BA99-CFA509743425

Q36532990-26F8C883-8C95-4B1D-A89C-9EC517CEFD8B

Q36532990-2AA215EA-C51D-4CE1-8258-F32DCA124FC5

Q36532990-2AAF2906-338D-4F00-916A-9A427D05A785

Q36532990-33753F69-0C14-46D7-983D-E39D6602A946

P304

Q36532990-BD9029F0-2FDD-4F27-B5EB-7E17069E2A69

P31

Q36532990-6E456BE8-6B2E-42BE-A3FC-56F8A93FFB32

P356

Q36532990-85F63B65-5092-445A-9EEC-7578731545F3

P433

Q36532990-A45C280E-87B6-49CE-B326-DBCD18957541

P478

Q36532990-18FF7BD7-838F-4AA5-9298-6DA7FC64DC8C

P50

Q36532990-9804637A-2C21-426B-A633-4E586630541A

Q36532990-9FE760BF-E904-4DB1-96FF-304516C8A735

Q36532990-F2233F2F-A968-4547-8210-FC79CC21952D

P577

Q36532990-58D8F0F2-FF60-422C-870C-A8A03E9A3F7E

P5875

Q36532990-6F43AB44-0105-463A-BEB5-7B67B78D18CF

P698

Q36532990-5E4236D6-33F5-4601-8B51-CE1F6054FF80

P921

Q36532990-2953D9A1-DDBF-4C15-8C57-255263F04614

Q36532990-2D5A5463-EC54-4503-8600-B8775308C7A7

P932

Q36532990-7F616ACF-117A-4F60-AE76-ACF4B7DEC538

P356

J.MOLCEL.2012.11.004

P1433

P1476

Protein quality control acts o ...... tations on organismal fitness.

@en

P2093

Jingwen Zhou

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

Wanmeng Mu

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

P2860

Quasispecies theory in the context of population genetics

Modeling of the bacterial growth curve

Comparison of theoretical proteomes: identification of COGs with conserved and variable pI within the multimodal pI distribution.

Instability, unfolding and aggregation of human lysozyme variants underlying amyloid fibrillogenesis

One-step inactivation of chromosomal genes in Escherichia coli K-12 using PCR products

Protein disaggregation mediated by heat-shock protein Hsp104.

Endosymbiotic bacteria: groEL buffers against deleterious mutations

Chaperonin overexpression promotes genetic variation and enzyme evolution

Quantifying E. coli Proteome and Transcriptome with Single-Molecule Sensitivity in Single Cells

Molecular chaperones in protein folding and proteostasis

P304

133-144

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

P31

scholarly article

P356

10.1016/J.MOLCEL.2012.11.004

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

P433

1

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

P478

49

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

P50

Shimon Bershtein

Adrian Serohijos

Eugene I. Shakhnovich

P577

2012-12-06T00:00:00Z

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

P5875

233877650

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

P698

23219534

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

P921

quality control

protein folding

P932

3545112

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