about
Structural evidence for entropic contribution of salt bridge formation to a protein antigen-antibody interaction: the case of hen lysozyme-HyHEL-10 Fv complexβ-Strand Flipping and Slipping Triggered by Turn Replacement Reveal the Opportunistic Nature of β-Strand PairingNMR structures of two designed proteins with high sequence identity but different fold and functionMetamorphic proteins mediate evolutionary transitions of structureStructure and dynamics of a primordial catalytic fold generated by in vitro evolutionConservation of Protein Structure over Four Billion YearsHSEpred: predict half-sphere exposure from protein sequencesInsights from the architecture of the bacterial transcription apparatusMechanism of protein folding.Conserved key amino acid positions (CKAAPs) derived from the analysis of common substructures in proteins.Protein topology and stability define the space of allowed sequences.When monomers are preferred: a strategy for the identification and disruption of weakly oligomerized proteinsSequence determinants of a conformational switch in a protein structure.The network of sequence flow between protein structures.Protein reconstitution and three-dimensional domain swapping: benefits and constraints of covalency.The role of negative selection in protein evolution revealed through the energetics of the native state ensemble.A polymetamorphic protein.Application of the "codon-shuffling" method. Synthesis and selection of de novo proteins as antibacterials.Capturing protein sequence-structure specificity using computational sequence design.Re-engineering a beta-lactamase using prototype peptides from a library of local structural motifs.Recombinatoric exploration of novel folded structures: a heteropolymer-based model of protein evolutionary landscapesCombinatorial mutagenesis to restrict amino acid usage in an enzyme to a reduced setBreaking open a protein barrelBiophysics of protein evolution and evolutionary protein biophysicsA common evolutionary origin of two elementary enzyme folds.Altering dimerization specificity by changes in surface electrostatics.Retroevolution of lambda Cro toward a stable monomer.Scoring functions in protein folding and designA folding space odyssey.DNA recognition, strand selectivity, and cleavage mode during integrase family site-specific recombination.An energetic representation of protein architecture that is independent of primary and secondary structure.Directed evolution of a (beta alpha)8-barrel enzyme to catalyze related reactions in two different metabolic pathways.Geographic Distribution of Archaeal Ammonia Oxidizing Ecotypes in the Atlantic Ocean.On hydrophobicity and conformational specificity in proteins.Computational exploration of the network of sequence flow between protein structures.Linkage, mobility, and selfishness in the MazF family of bacterial toxins: a snapshot of bacterial evolutionIdentification of amino acids imparting acceptor substrate selectivity to human arylamine acetyltransferases NAT1 and NAT2.Mutagenic dissection of the sequence determinants of protein folding, recognition, and machine function.Protein design from in silico dynamic information: the emergence of the 'turn-dock-lock' motif.Generating artificial homologous proteins according to the representative family character in molecular mechanics properties--an attempt in validating an underlying rule of protein evolution.
P2860
Q27631152-8CC52509-EA17-4052-84FA-118738327557Q27648967-5D7317C4-8FE3-4E36-9AD9-B723F57D9733Q27652181-5F72EB44-6371-45F4-A051-4E0079FF2F17Q27660427-BAE180FB-ED7E-4EA1-8B44-A9BED00E4E0EQ27675417-94E6579F-D9C4-45B0-B110-AFF505CED5D2Q27679488-45A4E23F-678F-496B-9633-26E6F1B45E41Q28279499-29B2C5C9-A678-4551-BFCF-584C0E9C99BEQ28681074-50EE33F1-24D2-4856-BC48-C9CC5EE254C0Q30168709-5A219A39-23E7-4861-89A8-EA1943725E26Q30327615-56577390-10E0-449E-8737-CFAAEDA933FDQ30329464-321567A6-8F22-47F5-B2BE-0CB6DF72C485Q30349959-A574B7CA-F413-429C-BF33-0B01B55DF10BQ30352170-29B531E7-544D-405F-88FC-FC45702725BEQ30362615-ADBF9EE6-FE79-462B-87E0-3268016E0CE2Q30365413-BEC219ED-0074-47BB-8038-DA913CB47370Q30383783-8CE875B4-0936-4169-B2CB-7A804E3E8B11Q30428011-FA66806D-C697-4978-B8D8-A048F7B16607Q30850874-D62CA077-2A73-4208-AF69-A0881CEEACFCQ31115802-34C85EF9-BFB6-4BF5-AF28-ACC399C852B1Q33402504-163A57C8-BA94-474D-80E9-73380A6098B9Q33894500-82664AF2-1553-4528-8543-99D0BB9C810AQ34159962-4295DC4A-1ABE-44BE-ABE1-B357873032DBQ34180410-8F62993B-0F2E-49A8-8DFC-0A13E32E5E11Q34311852-4108C6C3-E2FF-4092-A2B1-CF4161F6A373Q34500674-4D216F8A-8AE5-408D-8131-38E22C4FA551Q34702006-3215B405-3819-4D28-8336-A2A70A133AF2Q34805296-4DB8D540-DDE4-4C0B-9A97-71A6C306A8C0Q36282002-28A41D58-CD95-4D15-84EC-EFC8357F40DAQ36498323-724A6756-79FE-4AEE-8272-F194430D430EQ36606442-E73641D4-9E67-4A29-A786-51872E4EF75AQ37359395-BDD40D06-87EC-4BFE-9DEF-CD0FF6F641AFQ37389262-DAC94134-69B6-40A5-9B16-8F8D0C87E2FFQ38293444-60A7C7F4-6912-41B9-9091-58B909F81922Q40267664-50AD97B9-19D2-4D51-9CDA-1421D8BA96B5Q41816394-4B6DCC45-4059-4DF3-B0D9-83EFFCFFF61AQ41849114-9969F2D9-E040-472F-9D75-55E6C95B3171Q41855440-5727D105-90D8-4DFB-8E76-34860DF9992DQ42881980-C15E54F3-1904-4DEB-9440-1AFCF10845ECQ48619311-CC801C02-CE6D-4968-8FED-AF34409E74CDQ51723393-0BECD8A2-FE70-46B0-A7D6-376F3885DC07
P2860
description
1999 nî lūn-bûn
@nan
1999 թուականի Ապրիլին հրատարակուած գիտական յօդուած
@hyw
1999 թվականի ապրիլին հրատարակված գիտական հոդված
@hy
1999年の論文
@ja
1999年論文
@yue
1999年論文
@zh-hant
1999年論文
@zh-hk
1999年論文
@zh-mo
1999年論文
@zh-tw
1999年论文
@wuu
name
Evolution of a protein fold in vitro
@ast
Evolution of a protein fold in vitro
@en
Evolution of a protein fold in vitro
@nl
type
label
Evolution of a protein fold in vitro
@ast
Evolution of a protein fold in vitro
@en
Evolution of a protein fold in vitro
@nl
prefLabel
Evolution of a protein fold in vitro
@ast
Evolution of a protein fold in vitro
@en
Evolution of a protein fold in vitro
@nl
P2093
P1433
P1476
Evolution of a protein fold in vitro
@en
P2093
P304
P356
10.1126/SCIENCE.284.5412.325
P407
P50
P577
1999-04-01T00:00:00Z