Connection between the taxonomic substates and protonation of histidines 64 and 97 in carbonmonoxy myoglobin. - Wikidata - wikimedia - TriplyDB

Connection between the taxonomic substates and protonation of histidines 64 and 97 in carbonmonoxy myoglobin.

Connection between the taxonomic substates and protonation of histidines 64 and 97 in carbonmonoxy myoglobin.

http://www.wikidata.org/entity/Q34171122

about

Ligand migration and binding in the dimeric hemoglobin of Scapharca inaequivalvis.Influence of static and dynamic disorder on the visible and infrared absorption spectra of carbonmonoxy horseradish peroxidase.Straight-chain alkyl isocyanides open the distal histidine gate in crystal structures of myoglobin Influence of distal residue B10 on CO dynamics in myoglobin and neuroglobin Chromophore-protein interactions in the anthozoan green fluorescent protein asFP499.Insight into protein structure and protein-ligand recognition by Fourier transform infrared spectroscopy.Dynamics of a myoglobin mutant enzyme: 2D IR vibrational echo experiments and simulations.Protein dynamics studied with ultrafast two-dimensional infrared vibrational echo spectroscopy.Direct observation of fast protein conformational switching Time-resolved hole-burning study on myoglobin: fluctuation of restricted water within distal pocket.Protein relaxation in the photodissociation of myoglobin-CO complexes.Protein ligand migration mapped by nonequilibrium 2D-IR exchange spectroscopy.The pH dependence of heme pocket hydration and ligand rebinding kinetics in photodissociated carbonmonoxymyoglobin.Binding and docking interactions of NO, CO and O₂in heme proteins as probed by density functional theory Ligand binding and protein dynamics in neuroglobin Dynamics of ANS binding to tuna apomyoglobin measured with fluorescence correlation spectroscopy Myoglobin-CO conformational substate dynamics: 2D vibrational echoes and MD simulations The role of structure, energy landscape, dynamics, and allostery in the enzymatic function of myoglobin.Infrared absorption study of the heme pocket dynamics of carbonmonoxyheme proteins Viscosity-dependent protein dynamics Transient ligand docking sites in Cerebratulus lacteus mini-hemoglobin.A spectroscopic study of structural heterogeneity and carbon monoxide binding in neuroglobin.Observation of the Fe-CN and Fe-CO vibrations in the active site of [NiFe] hydrogenase by nuclear resonance vibrational spectroscopy Myoglobin-CO substate structures and dynamics: multidimensional vibrational echoes and molecular dynamics simulations.An engineered heme-copper center in myoglobin: CO migration and binding.Probing the role of hydration in the unfolding transitions of carbonmonoxy myoglobin and apomyoglobin Photolysis of Hi-CO Nitrogenase - Observation of a Plethora of Distinct CO Species using Infrared Spectroscopy.Structural assignment of spectra by characterization of conformational substates in bound MbCO.The structure of carbonmonoxy neuroglobin reveals a heme-sliding mechanism for control of ligand affinity.Calculated pH-dependent population and protonation of carbon-monoxy-myoglobin conformers.Kinetic evidence for three photolyzable taxonomic conformational substates in oxymyoglobin.Mechanistic insights into reversible photoactivation in proteins of the GFP family.The pH dependence of naturally occurring low-spin forms of methaemoglobin and metmyoglobin: an EPR study Dynamic fluctuation of proteins watched in real time.Structural dynamics of myoglobin: ligand migration among protein cavities studied by Fourier transform infrared/temperature derivative spectroscopy.Structural dynamics of myoglobin: ligand migration and binding in valine 68 mutants.Structural dynamics in the active site of murine neuroglobin and its effects on ligand binding.

P2860

Q27649034-3A95C705-275E-4860-92AF-F9CA0588BB3D Q28365192-0E370C8F-E6FF-43EA-A9CF-4B1A9E153572 Q28656517-85D2406E-8D29-444E-9C5D-1EDE0F9F5E27 Q28756881-05E82933-A318-4EDA-AF4F-73BE5CDD25EB Q30159644-4D5BFF82-6B2C-4EC9-B7F9-2A6133992227 Q30327608-988E5F03-7761-4B0D-BDFD-6418EF48D115 Q30397158-E7F798DC-7167-4886-A601-A2551BDDFBD1 Q30414457-B21798B4-8960-4D48-AD31-AA3C6F8A2EA2 Q30492072-F60D3514-10D3-44F8-897E-BADFCFF45C68 Q30650120-430D9CA0-2EF5-43DC-95D3-053F4C7F79D2 Q31153584-970FEE18-4810-44F4-B920-97311635D05B Q33270807-E09270B7-187A-47CA-8858-3EB5B1DDF850 Q33325118-A537EEF6-39D7-4587-9B3E-3DDC337541F5 Q33513486-4D0CA8C8-BF78-4B8A-9CB0-CDC9C5FABE4C Q34030780-20500924-1870-4A2E-BBBA-65F0FF74EEB8 Q34177092-58A36AF8-FC25-474B-87A2-79BE2EC74430 Q34178161-CBF6B1E3-1083-48C9-B473-B4807679AB76 Q34459642-28D26CD4-8C54-4DEB-A0F8-73DE3F079E86 Q35128904-C15E45D5-C3FC-43CC-907B-3F1B6E8421D1 Q35753790-57A634CC-D6BA-4A3C-BB6E-7BC7ABC92DF6 Q36003373-78A9ED1E-0295-432E-A051-52F7CCFA0ED3 Q36273772-9BD715E4-936A-4061-9CAA-F8256CF12599 Q36504095-E467E197-3B72-444E-8FF2-4FFF33A64039 Q36732379-33D226D8-3222-4BD5-A34A-71DFD065A9D5 Q36941541-4C2D2AE7-2D43-418E-BE77-F76DB3808B72 Q37171949-57CA0280-4E65-4387-9379-CED4AD68C0CB Q37249361-A72EE0DA-5B47-4EE9-88B9-2EB47586B491 Q37263658-1F4CD611-11CD-4B6D-90FD-2AD98D96629D Q37713894-07262561-8364-44B5-9E53-39D7C45FC301 Q40179492-84E0D26A-0DE8-4A34-ADFB-AE868DC4A33A Q40205055-63F90FC9-C9AB-48EF-B3FA-F0E21256E67E Q41979085-96B6F1F1-374E-494A-A982-9636C482C1E2 Q42037950-F5A07C25-B326-4523-B87E-2C07456CBCA0 Q43177849-8FC98440-B58A-4C35-9F9B-10387DF36E25 Q43855735-20A797F9-25C7-40A9-8571-D30F24FFB35D Q44542402-1B13FF4A-1A7E-4554-8362-53A9EBD24DFD Q47962955-700BF7B3-B575-47AF-9B47-3FB058735712

P2860

Connection between the taxonomic substates and protonation of histidines 64 and 97 in carbonmonoxy myoglobin.

http://www.wikidata.org/entity/Q34171122

description

1999 nî lūn-bûn

@nan

1999 թուականի Օգոստոսին հրատարակուած գիտական յօդուած

@hyw

1999 թվականի օգոստոսին 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

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@ast

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@en

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@nl

type

label

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@ast

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@en

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@nl

prefLabel

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@ast

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@en

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@nl

P1433

Q34171122-2D73CEA8-7C6F-4511-B587-9E22DCB34E84

P1476

Q34171122-D9CF61D1-45BD-4374-82D7-6C2C56A6B919

P2093

Q34171122-0139A5D2-F608-4CC2-98AA-F0F560BAD5F8

Q34171122-3D9D9010-3298-4AF2-BD32-8FB12DC15F14

Q34171122-70AD5DA6-DB10-4B0F-9052-9B57160017ED

Q34171122-9FCDDA74-0C52-4FFE-AA9F-209581154058

Q34171122-ECB486C7-47D9-4DFA-AC18-25CFC4887D68

P2860

Q34171122-090B110E-7F89-425E-A420-0053B4545E59

Q34171122-0E10090E-4991-44AC-9A36-87E12B0D70FB

Q34171122-13DE9FD6-EA0F-4B9D-B11F-CAE7FB3071DF

Q34171122-228B1C7A-6D7E-4308-AAD3-EA48A8E78DEF

Q34171122-2A56F179-A67D-4FA2-BDDE-0F591679C7BA

Q34171122-51E53018-9771-43D1-984B-CBACACD877A1

Q34171122-5D923788-DDCD-49C5-B8D1-9EC534AFF6D6

Q34171122-60E65E1C-2EB8-48E5-A96A-2B776682E85E

Q34171122-684F2EAD-B539-409C-9A2B-EBFE42E3BABA

Q34171122-68B2D244-3B10-43CD-BB21-C74E73D4C233

P304

Q34171122-1AD239EB-49FE-4F46-98FC-73AD951AA370

P31

Q34171122-41E5E830-9185-49DB-98EA-67E7CFB3A607

P356

Q34171122-D95FD2E2-16B4-4B2F-A6F6-477BD5221AFE

P407

Q34171122-F570B7EA-89DF-414A-B2CC-2EDBD4A918B1

P433

Q34171122-EB1BFA3A-52CF-4F23-A43A-9CDC88F4CD66

P478

Q34171122-81524893-0C51-4674-9AA4-2AF7BD04B65D

P577

Q34171122-8D6F4A63-6D6E-47C4-B266-5603046C703C

P698

Q34171122-732AF40F-4B21-4EB0-B9CF-4F24DD52ED88

P932

Q34171122-DFC0DB14-149E-48A9-AB2A-37864FB6930C

P356

S0006-3495(99)76954-7

P1433

Biophysical Journal

P1476

Connection between the taxonom ...... 97 in carbonmonoxy myoglobin.

@en

P2093

B H McMahon

http://www.w3.org/2001/XMLSchema#string

E Y Chien

http://www.w3.org/2001/XMLSchema#string

G U Nienhaus

http://www.w3.org/2001/XMLSchema#string

J D Müller

http://www.w3.org/2001/XMLSchema#string

S G Sligar

http://www.w3.org/2001/XMLSchema#string

P2860

X-ray structure and refinement of carbon-monoxy (Fe II)-myoglobin at 1.5 A resolution

Solution structure of carbonmonoxy myoglobin determined from nuclear magnetic resonance distance and chemical shift constraints

High-resolution crystal structures of distal histidine mutants of sperm whale myoglobin

Structural determinants of the stretching frequency of CO bound to myoglobin

Crystal structures of CO-, deoxy- and met-myoglobins at various pH values

The energy landscapes and motions of proteins

Hydrogen exchange measurement of the free energy of structural and allosteric change in hemoglobin.

Conformational substates and motions in myoglobin. External influences on structure and dynamics.

Ligand binding to heme proteins. VI. Interconversion of taxonomic substates in carbonmonoxymyoglobin

Conformational interconversion in protein crystals.

P304

1036-1051

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1016/S0006-3495(99)76954-7

http://www.w3.org/2001/XMLSchema#string

P407

P433

2

http://www.w3.org/2001/XMLSchema#string

P478

77

http://www.w3.org/2001/XMLSchema#string

P577

1999-08-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

10423448

http://www.w3.org/2001/XMLSchema#string

P932

1300394

http://www.w3.org/2001/XMLSchema#string