Construction of a catalytically active iron superoxide dismutase by rational protein design.
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De novo proteins from designed combinatorial librariesProtein design: toward functional metalloenzymesUse of a non-rigid region in T4 lysozyme to design an adaptable metal-binding siteRetrostructural analysis of metalloproteins: application to the design of a minimal model for diiron proteinsDesign, synthesis, and characterization of a novel hemoproteinProton and metal ion-dependent assembly of a model diiron proteinComputational approaches for rational design of proteins with novel functionalitiesDesigning artificial enzymes by intuition and computationHistidine placement in de novo-designed heme proteins.TransCent: computational enzyme design by transferring active sites and considering constraints relevant for catalysis.Structure and dynamics of the influenza A M2 channel: a comparison of three structures.Motif-directed flexible backbone design of functional interactions.A matching algorithm for catalytic residue site selection in computational enzyme design.Enzyme-like proteins by computational designImproving computational protein design by using structure-derived sequence profile.Rational design of nascent metalloenzymesRational protein design: combining theory and experiment.Computational design of a Zn2+ receptor that controls bacterial gene expression.The rational design and construction of a cuboidal iron-sulfur protein.The de novo design of a rubredoxin-like Fe site.Protein fabrication automationCatalytic mechanism and performance of computationally designed enzymes for Kemp eliminationOrigin of the activity drop with the E50D variant of catalytic antibody 34E4 for Kemp eliminationEnergy functions in de novo protein design: current challenges and future prospects.Computational design approaches and tools for synthetic biology.Emerging themes in the computational design of novel enzymes and protein-protein interfaces.Computational design gains momentum in enzyme catalysis engineering.Metalloprotein and metallo-DNA/RNAzyme design: current approaches, success measures, and future challenges.Solution structure of HndAc: a thioredoxin-like domain involved in the NADP-reducing hydrogenase complexLocal encoding of computationally designed enzyme activity.Rational design of a novel calcium-binding site adjacent to the ligand-binding site on CD2 increases its CD48 affinity.Systematic optimization model and algorithm for binding sequence selection in computational enzyme design.The aglycone specificity-determining sites are different in 2, 4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA)-glucosidase (Maize beta -glucosidase) and dhurrinase (Sorghum beta -glucosidase).Computational protein engineering.Artificial Metalloenzymes with the Neocarzinostatin Scaffold: Toward a Biocatalyst for the Diels-Alder Reaction.From "hemoabzymes" to "hemozymes": towards new biocatalysts for selective oxidations.Proteins from scratch.7 Computational protein design and discoveryVarious strategies for obtaining oxidative artificial hemoproteins with a catalytic oxidative activity: from "Hemoabzymes" to "Hemozymes"?
P2860
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P2860
Construction of a catalytically active iron superoxide dismutase by rational protein design.
description
1997 nî lūn-bûn
@nan
1997年の論文
@ja
1997年論文
@yue
1997年論文
@zh-hant
1997年論文
@zh-hk
1997年論文
@zh-mo
1997年論文
@zh-tw
1997年论文
@wuu
1997年论文
@zh
1997年论文
@zh-cn
name
Construction of a catalyticall ...... se by rational protein design.
@ast
Construction of a catalyticall ...... se by rational protein design.
@en
type
label
Construction of a catalyticall ...... se by rational protein design.
@ast
Construction of a catalyticall ...... se by rational protein design.
@en
prefLabel
Construction of a catalyticall ...... se by rational protein design.
@ast
Construction of a catalyticall ...... se by rational protein design.
@en
P2093
P2860
P356
P1476
Construction of a catalyticall ...... se by rational protein design.
@en
P2093
H W Hellinga
J P Caradonna
P2860
P304
P356
10.1073/PNAS.94.11.5562
P407
P577
1997-05-01T00:00:00Z