SCHEMA recombination of a fungal cellulase uncovers a single mutation that contributes markedly to stability
about
Beyond directed evolution--semi-rational protein engineering and designProtein stability: computation, sequence statistics, and new experimental methodsEngineered thermostable fungal Cel6A and Cel7A cellobiohydrolases hydrolyze cellulose efficiently at elevated temperaturesDirected evolution: tailoring biocatalysts for industrial applicationsEndoglucanases: insights into thermostability for biofuel applicationsModulating the thermostability of Endoglucanase I from Trichoderma reesei using computational approaches.Designing specific protein-protein interactions using computation, experimental library screening, or integrated methodsDirected evolution strategies for enantiocomplementary haloalkane dehalogenases: from chemical waste to enantiopure building blocks.Utilizing natural diversity to evolve protein function: applications towards thermostability.High throughput screening of fungal endoglucanase activity in Escherichia coliComplex recombination patterns arising during geminivirus coinfections preserve and demarcate biologically important intra-genome interaction networks.Hypocrea jecorina CEL6A protein engineering.Random field model reveals structure of the protein recombinational landscape.Chimeric β-lactamases: global conservation of parental function and fast time-scale dynamics with increased slow motionsComparison of family 9 cellulases from mesophilic and thermophilic bacteria.Cellulases from thermophilic fungi: recent insights and biotechnological potential.Discriminating between stabilizing and destabilizing protein design mutations via recombination and simulation.Computational investigation of glycosylation effects on a family 1 carbohydrate-binding module.Exploring the Mechanism Responsible for Cellulase Thermostability by Structure-Guided Recombination.Structure-guided SCHEMA recombination generates diverse chimeric channelrhodopsinsMolecular tools for chemical biotechnology.Processive and nonprocessive cellulases for biofuel production--lessons from bacterial genomes and structural analysis.Stabilizing biocatalysts.Recent advances in rational approaches for enzyme engineering.Synthetic biology for the directed evolution of protein biocatalysts: navigating sequence space intelligently.Improving the activity of Trichoderma reesei cel7B through stabilizing the transition state.Exploiting sequence and stability information for directing nanobody stability engineering.Efficient screening of fungal cellobiohydrolase class I enzymes for thermostabilizing sequence blocks by SCHEMA structure-guided recombination.Increasing protein stability: importance of DeltaC(p) and the denatured state.Crystal structure of a family 6 cellobiohydrolase from the basidiomycete Phanerochaete chrysosporiumA thermophilic cellulase complex from Phialophora sp. G5 showing high capacity in cellulose hydrolysis.Highly thermostable fungal cellobiohydrolase I (Cel7A) engineered using predictive methods.Engineered thermostable fungal cellulases exhibit efficient synergistic cellulose hydrolysis at elevated temperatures.Removal of the free cysteine residue reduces irreversible thermal inactivation of feruloyl esterase: evidence from circular dichroism and fluorescence spectra.Biochemie 2009
P2860
Q24604225-6999EBE8-AFB8-443F-A7A8-17860CC77AC1Q26779815-50B2EC97-834E-4173-9ED8-0A9A94D23755Q27683987-586DE989-8AD9-4ED2-9B54-4D0F4D300D4EQ28275218-FF8367F7-25EF-45C1-B21E-BE17E123650AQ28661239-B72024B6-5CD3-4AC1-9E52-22C5948DB01BQ30372807-954785A1-683E-4A19-91FF-8AABC930DBE5Q30416858-C6A57609-187D-4108-9C06-92D27BB4A86DQ31042124-A0A4346F-A360-4DEA-B0E0-FE00F2A18DBDQ33864392-9A469C8D-4D08-4ECD-89C9-5435C61CDB7EQ34000774-B2ABAEEE-5ADF-4FFC-89F1-69ACBF88E9A4Q34031182-D9D03BC2-3517-4BA8-998A-DAAF118B9B84Q34154286-97332FB2-B879-48FA-8FFA-668242439DC6Q34440613-FF13EFB1-D4EB-43F8-B4D6-1C01A3DF9432Q34533557-2BE70ABD-12DC-41E8-B1E5-7C5028B25901Q34738076-CD4A47F0-8EF6-417C-AE9A-A689B10844E6Q35579359-F6A60CF5-532A-4CCB-8022-19D0A83F38AEQ35665150-5973A9D8-9CB2-4552-8BA9-70E279DF017DQ35728158-4BA7513D-B0E4-4366-AB8E-9205DA0B49E6Q35961181-14175D5D-4A47-4F34-8B3D-21D3CA32B074Q36304921-6D34579C-4757-40D7-9FDD-545AE796A7A3Q37086813-2D9EF80F-0844-4138-98C3-79BBC759E536Q37960373-7BE26072-CDCF-4664-86E0-B14107C6918FQ38117536-25C8E99F-50C5-4664-9858-5644EB77DA9CQ38201023-81E20A54-0677-43A3-8B34-352ED1B3D507Q38287400-0BA75732-AB12-44F4-BAAA-979EEA408F89Q38295013-07AEB0D8-C576-41A8-89F4-762C1955CFD1Q38713206-0F262383-E28F-428F-97FD-AA2942FDA374Q39111595-1131FE50-3CF3-4AE4-ADEE-1646D66349D9Q40497348-65B21E6D-0768-4CFB-BE8D-10E5D0EFE80DQ40981534-FD70A45A-2984-4FB5-A4D9-FF85F790FF06Q43033973-1F465406-38B1-428D-ACAA-4FB06133B4DAQ45945338-8D4ACA16-9EAF-4481-BE17-5569EF0D8BC3Q46081387-09B549C8-8DB2-4CE6-A56A-C68FC916D6E0Q53797244-581D235F-380A-4560-A295-455AA9EA2B36Q57260233-5A457CA2-042D-4E7E-A766-6BA0973FA7A1
P2860
SCHEMA recombination of a fungal cellulase uncovers a single mutation that contributes markedly to stability
description
2009 nî lūn-bûn
@nan
2009 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
SCHEMA recombination of a fung ...... tributes markedly to stability
@ast
SCHEMA recombination of a fung ...... tributes markedly to stability
@en
SCHEMA recombination of a fung ...... tributes markedly to stability
@nl
type
label
SCHEMA recombination of a fung ...... tributes markedly to stability
@ast
SCHEMA recombination of a fung ...... tributes markedly to stability
@en
SCHEMA recombination of a fung ...... tributes markedly to stability
@nl
prefLabel
SCHEMA recombination of a fung ...... tributes markedly to stability
@ast
SCHEMA recombination of a fung ...... tributes markedly to stability
@en
SCHEMA recombination of a fung ...... tributes markedly to stability
@nl
P2093
P2860
P356
P1476
SCHEMA recombination of a fung ...... tributes markedly to stability
@en
P2093
Alan Villalobos
Arvind Kannan
Jeremy Minshull
Kevin Boulware
Matthew A Smith
Pete Heinzelman
Sridhar Govindarajan
P2860
P304
P356
10.1074/JBC.C109.034058
P407
P577
2009-09-25T00:00:00Z