De novo design and molecular assembly of a transmembrane diporphyrin-binding protein complex.
about
Protein design: toward functional metalloenzymesDesign of a switchable eliminaseMetal-Mediated Affinity and Orientation Specificity in a Computationally Designed Protein HomodimerA Designed Functional Metalloenzyme that Reduces O2 to H2O with Over One Thousand TurnoversComputational redesign of the lipid-facing surface of the outer membrane protein OmpA.Achievements and Challenges in Computational Protein Design.Creating novel protein scripts beyond natural alphabetsNaturally evolved G protein-coupled receptors adopt metastable conformations.Protein engineering methods applied to membrane protein targets.Computational protein design: engineering molecular diversity, nonnatural enzymes, nonbiological cofactor complexes, and membrane proteins.Computational design of membrane proteins.Structural informatics, modeling, and design with an open-source Molecular Software Library (MSL).Strategies to control the binding mode of de novo designed protein interactions.Conditional trimerization and lytic activity of HIV-1 gp41 variants containing the membrane-associated segments.Covalent Anchor Positions Play an Important Role in Tuning Catalytic Properties of a Rationally Designed MnSalen-containing MetalloenzymeDe novo design of a transmembrane Zn²⁺-transporting four-helix bundle.Structural and Functional Studies on the Marburg Virus GP2 Fusion LoopFirst principles design of a core bioenergetic transmembrane electron-transfer protein.Toward high-resolution computational design of the structure and function of helical membrane proteinsMetalloproteins containing cytochrome, iron-sulfur, or copper redox centersComputational studies of membrane proteins: models and predictions for biological understanding.De Novo Design of Xeno-Metallo Coiled Coils.Design of self-assembling transmembrane helical bundles to elucidate principles required for membrane protein folding and ion transport.Designed multi-stranded heme binding β-sheet peptides in membrane.Computational design of a β-peptide that targets transmembrane helicesDe Novo Construction of Redox Active Proteins.β-Hairpin peptides: heme binding, catalysis, and structure in detergent micelles.DNA targeting and cleavage by an engineered metalloprotein dimer.The soluble loop BC region guides, but not dictates, the assembly of the transmembrane cytochrome b6.Structures of the Heme Acquisition Protein HasA with Iron(III)-5,15-Diphenylporphyrin and Derivatives Thereof as an Artificial Prosthetic Group.Designed Heme-Cage β-Sheet Miniproteins.Design of Redox-Active Peptides: Towards Functional Materials.Production of Computationally Designed Small Soluble- and Membrane-Proteins: Cloning, Expression, and Purification.Design of a heme-binding peptide motif adopting a β-hairpin conformation.Computational Protein Design with Deep Learning Neural Networks.Catalytic peptide assemblies.An Artificial Heme Enzyme for Cyclopropanation Reactions.Fe- but not Mg-protophorphyrin IX binds to a transmembrane b-type cytochrome.The de novo design of a biocompatible and functional integral membrane protein using minimal sequence complexityDesigned for life: biocompatible de novo designed proteins and components
P2860
Q26866201-59F63EBA-B5FD-48CF-B563-4F15DC61D647Q27667492-6F8F5B57-1172-44EA-B639-C6EDB65CEE2CQ27675621-820B0CCC-1BB3-4DFD-A995-7E6E54B0CE7CQ27678766-FBCE1569-42E2-4983-A3F8-D06A582E8213Q30152888-AC300A8F-70FE-46F8-8C87-0B3DA54EEED3Q30395939-7AFCCDCB-9F7B-4D2A-92EF-756B84AF40D1Q30410150-BA360CD3-9C6E-4D07-B2B7-38E51669EE57Q30419814-EAC0DD32-06AE-4FB2-A7A0-DA430130F459Q30423115-964357BA-E9DB-4E94-95B2-8B686DA8D998Q33830526-BC08BF56-CD43-40CA-AAA1-D7F91E142085Q33942265-E35CE8E7-C1AD-4135-9C6E-265151DFF5F5Q34260787-AE12B6A5-6ED2-457A-BE5D-504A06468A4EQ34348335-066C206B-FBD5-404D-B69D-45E696A73920Q35142768-7E13C3FB-F911-4DAB-91D4-B5629BBD8AC6Q35355678-A135A953-C127-4D9B-9D61-5610F573CB6FQ35456726-6B3C98F4-6657-4BB0-AAF8-451305D92931Q36043176-6E608A7F-BCD3-465D-AAAA-C2C3C3D57175Q36840077-1F20D109-2577-4A5C-B33E-F2565AC418F4Q37128527-BD0A707F-B9DD-48CB-B98E-29098BED332EQ37727718-56FD7E6C-D5EC-4016-8114-10BFCB68660DQ37952425-EA031505-1E4B-49E3-BEDB-4E3FE4EAED30Q38642260-0AE15A67-D281-40CB-AAED-30BBE5C23582Q38718401-7E769609-EB33-4636-8E4C-4BC3DA92B067Q41092138-8163EDC7-E55F-426F-90D9-CE5C5DE9E86CQ41785529-4D8C1075-2BDC-46A6-9CC7-E3875FC3A6DBQ42363320-4398FC55-B086-4AFD-9804-0EF8702CE6AAQ43484305-440DBB80-BE16-4257-AE40-B1D37BB7FDD3Q45929052-47E7E9EE-96BA-418C-A101-5906B8F8DE58Q47149209-9B6E25DE-CF38-4C03-ABE8-388B5176B2D2Q47663874-655A10C1-6AFB-4318-B480-C146515525F0Q47872858-6A013A50-17B5-45DA-9DEE-81FA2F188570Q51152149-030CCFED-71C8-478F-80D4-C80A71FE0CB9Q51287768-2B34B88D-F92E-4337-A87B-516DAF9D9044Q52562966-5685C564-FE15-4BF8-B584-B14CF2DC2D4CQ52573365-18A0D8CC-61FB-4C18-A299-3E4E8CA88321Q52624037-C5A0E5F9-475F-43F0-A530-622676504583Q53689020-4295FB70-DEE5-48CE-80F4-C3CAA1793A3CQ54455314-E9B42AAA-977C-487C-8A55-A04562FBD92CQ57062484-9174A833-1BF8-483B-9C3E-226AFA023E2CQ58693720-FC465DB7-5BF6-4FA6-8DE4-C0136630AC13
P2860
De novo design and molecular assembly of a transmembrane diporphyrin-binding protein complex.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
2010年论文
@zh
2010年论文
@zh-cn
name
De novo design and molecular a ...... hyrin-binding protein complex.
@en
type
label
De novo design and molecular a ...... hyrin-binding protein complex.
@en
prefLabel
De novo design and molecular a ...... hyrin-binding protein complex.
@en
P2093
P2860
P921
P356
P1476
De novo design and molecular a ...... phyrin-binding protein complex
@en
P2093
F Ann Walker
H Christopher Fry
Ivan V Korendovych
J Kent Blasie
James D Lear
Michael J Therien
William F Degrado
Yong Ho Kim
P2860
P304
15516-15518
P356
10.1021/JA107487B
P407
P577
2010-11-01T00:00:00Z