%D8%AA%D8%B7%D9%88%D8%B1_%D9%85%D9%88%D8%AC%D9%87Evoluci%C3%B3n_empobinadaEvoluci%C3%B3_dirigidaCategory:Directed_evolutionGerichtete_EvolutionDirected_evolutionEvoluci%C3%B3n_dirigida%C3%89volution_dirig%C3%A9eEvoluci%C3%B3n_dirixidaEvolusi_terarahWerara_r%C3%AAber%C3%AEkir%C3%AEDirected_evolutionQ440681
about
sameAs
P2283
P279
Directed evolution drives the next generation of biocatalystsDirected evolution of a model primordial enzyme provides insights into the development of the genetic codeDirected evolution of bright mutants of an oxygen-independent flavin-binding fluorescent protein from Pseudomonas putidaProtein Design by Directed EvolutionIn the light of directed evolution: pathways of adaptive protein evolutionDirected evolution of protein enzymes using nonhomologous random recombinationDirected evolution of mammalian paraoxonases PON1 and PON3 for bacterial expression and catalytic specializationBeyond directed evolution--semi-rational protein engineering and designUltrahigh-throughput screening in drop-based microfluidics for directed evolution.Exploring protein fitness landscapes by directed evolutionSimultaneous optimization of enzyme activity and quaternary structure by directed evolutionDirected evolution of adeno-associated virus to an infectious respiratory virusDirected evolution of a filamentous fungus for thermotoleranceDirected evolution of single-chain Fv for cytoplasmic expression using the beta-galactosidase complementation assay results in proteins highly susceptible to protease degradation and aggregationA highly sensitive selection method for directed evolution of homing endonucleases.Directed evolution strategies for improved enzymatic performanceNucleotide exchange and excision technology (NExT) DNA shuffling: a robust method for DNA fragmentation and directed evolutionFusoselect: cell-cell fusion activity engineered by directed evolution of a retroviral glycoprotein.Selection platforms for directed evolution in synthetic biologyDirected evolution: an evolving and enabling synthetic biology toolDirected evolution combined with synthetic biology strategies expedite semi-rational engineering of genes and genomesPolishing the craft of genetic diversity creation in directed evolutionPredicting the emergence of antibiotic resistance by directed evolution and structural analysisDirected evolution of a new catalytic site in 2-keto-3-deoxy-6-phosphogluconate aldolase from Escherichia coliDirected evolution approach to a structural genomics project: Rv2002 from Mycobacterium tuberculosisConversion of cyclodextrin glycosyltransferase into a starch hydrolase by directed evolution: the role of alanine 230 in acceptor subsite +1Elimination of competing hydrolysis and coupling side reactions of a cyclodextrin glucanotransferase by directed evolutionThe structure of monoamine oxidase from Aspergillus niger provides a molecular context for improvements in activity obtained by directed evolutionDirected evolution of an enantioselective epoxide hydrolase: uncovering the source of enantioselectivity at each evolutionary stageStructure-guided directed evolution of alkenyl and arylmalonate decarboxylasesDirected Evolution and Structural Characterization of a Simvastatin SynthaseDirected evolution of copper nitrite reductase to a chromogenic reductantStructural Evidence for Enhancement of Sequential Vitamin D3 Hydroxylation Activities by Directed Evolution of Cytochrome P450 Vitamin D3 HydroxylaseEnhancement of the latent 3-isopropylmalate dehydrogenase activity of promiscuous homoisocitrate dehydrogenase by directed evolutionStructural Insights into Substrate Specificity in Variants of N-Acetylneuraminic Acid Lyase Produced by Directed EvolutionDirected Evolution of a Thermostable Quorum-quenching Lactonase from the Amidohydrolase SuperfamilyFocused directed evolution of pentaerythritol tetranitrate reductase by using automated anaerobic kinetic screening of site-saturated librariesStructural Insight into the Expanded PCB-Degrading Abilities of a Biphenyl Dioxygenase Obtained by Directed EvolutionResurrection of a functional phosphatidylinositol transfer protein from a pseudo-Sec14 scaffold by directed evolutionOptimization of the In-Silico-Designed Kemp Eliminase KE70 by Computational Design and Directed Evolution
P921
Q21045409-A795D92A-5992-455A-BE79-7CBE961BDFC0Q21092411-39174D90-6F17-4A6C-9660-832EF5167092Q21202060-892F47CF-B08F-427D-AF88-BC62871849D1Q22065412-D91DF8DF-6906-48FE-86EE-4BD0B2FF3C9BQ22066327-1B87A61C-8EDC-484C-964D-0DAD1990694CQ24563994-CCC425D5-908A-47C7-8EBA-74F4AA5E2AB0Q24598027-62422540-A89C-4EB3-834B-A2393AFB04B5Q24604225-2670C08E-B130-4723-90AB-31449DCD6DEBQ24626072-91C72F41-0FE4-4559-8B11-922EACCA31CDQ24630945-9B9B3B01-0F9A-41EC-8698-CC3CD6A7667AQ24646681-CBAE404C-E396-4A69-9DBA-7DECD4EC379FQ24649385-515DB1BB-5565-47DE-956D-B374E9DC9E12Q24657089-0A5E0AC5-B170-400E-B667-90856D8A4942Q24803075-7FA2B3B9-869F-4796-8522-F598DF1A55A7Q24811912-C2005134-E03C-4F93-B882-46EF9FFC1C80Q24815563-FBAB3B40-A8A4-4008-BA99-48CC86279BE7Q24816006-9AB8C4D4-3ADF-48D4-BD3F-BCB95BB14D82Q25256213-2A25BA6E-CF77-47B4-95B4-DBD7FFB71DE6Q26741325-67898C59-20FA-4385-AC00-148813146A07Q26823011-8486786B-0D4C-42F7-B9D5-F4FC56419A37Q26823491-A9423D1D-EC1F-476E-B777-7EB92A7F25CDQ27001198-DA224112-245B-4456-BB0B-A31019559411Q27630116-81EE3336-008F-42C9-8593-8ADD0112F4E4Q27631640-4FEF662A-4AAE-46A4-BC07-EF945EEBC427Q27640298-6AD80D22-A001-4222-86F5-1EA4F7DE625EQ27641441-EB337B12-8ED0-417A-971E-77EB04E89A46Q27650390-B94A7A02-A51B-4ACD-B2AD-9AF9BC6C7F84Q27652653-AE7EDEAA-D76A-4050-83DA-8389F48191F0Q27655613-024808E4-D89C-47A0-A928-830A5F853B28Q27657367-B30C9039-DA0C-4757-AC7E-4AB650F5804EQ27658016-AC002926-39FB-4019-A585-C91F11FBE524Q27659029-F802E741-3C01-4683-89EF-F7B3A0E902DCQ27663638-75E5FC76-9BAB-40FC-A4CA-BF5B8AEF179CQ27664150-F75DE310-01D7-44D5-846C-7FE17363EA0BQ27664358-523534AA-992F-499F-9BD6-64A8063AF230Q27665391-A38AC5FC-BE87-457D-8D9F-8926AC9613EFQ27665727-A5C67CFC-28A6-4947-9F16-8A8272E6E749Q27665863-2CB2C14E-5F0F-417F-8FC1-AC1C4E481E57Q27666652-9FA4C21E-5248-4FFB-8C9E-70960C7EF83DQ27666766-846D7BE8-D12E-46CD-9B39-0ED68024D662
P921
description
protein engineering method
@en
метод біоінженерії
@uk
name
Evolución dirigida
@es
Evolución dirixida
@gl
Evolución empobinada
@ast
Evolusi terarah
@id
Werara rêberîkirî
@ku
directed evolution
@en
evolució dirigida
@ca
gerichtete Evolution
@de
Évolution dirigée
@fr
керована еволюція
@uk
type
label
Evolución dirigida
@es
Evolución dirixida
@gl
Evolución empobinada
@ast
Evolusi terarah
@id
Werara rêberîkirî
@ku
directed evolution
@en
evolució dirigida
@ca
gerichtete Evolution
@de
Évolution dirigée
@fr
керована еволюція
@uk
altLabel
Evolucion dirigida
@es
Evolució in vitro
@ca
Evolució in vivo
@ca
Evolution dirigee
@fr
directed molecular evolution
@en
in vitro evolution
@en
laboratory protein evolution
@en
керована молекулярна еволюція
@uk
направлена еволюція
@uk
人工定向演化
@zh
prefLabel
Evolución dirigida
@es
Evolución dirixida
@gl
Evolución empobinada
@ast
Evolusi terarah
@id
Werara rêberîkirî
@ku
directed evolution
@en
evolució dirigida
@ca
gerichtete Evolution
@de
Évolution dirigée
@fr
керована еволюція
@uk
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P3417
Directed-Evolution
P373
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P3827
directed-molecular-evolution