Interaction between water and polar groups of the helix backbone: an important determinant of helix propensities - Test2 - elhamkhani - TriplyDB

Interaction between water and polar groups of the helix backbone: an important determinant of helix propensities

Interaction between water and polar groups of the helix backbone: an important determinant of helix propensities

http://www.wikidata.org/entity/Q36333304

about

Structure of the c14 Rotor Ring of the Proton Translocating Chloroplast ATP Synthase Effects of charged amino acids at b and c heptad positions on specificity and stability of four-chain coiled coils Thermodynamic analysis of helix-engineered forms of the activation domain of human procarboxypeptidase A2.The hydration of amides in helices; a comprehensive picture from molecular dynamics, IR, and NMR.Helix formation via conformation diffusion search A molecular dynamics study of acylphosphatase in aggregation-promoting conditions: the influence of trifluoroethanol/water solvent.A novel method reveals that solvent water favors polyproline II over beta-strand conformation in peptides and unfolded proteins: conditional hydrophobic accessible surface area (CHASA).Molecular dynamics of the structural changes of helical peptides induced by pressure.Context-independent, temperature-dependent helical propensities for amino acid residues.Enthalpy of helix-coil transition: missing link in rationalizing the thermodynamics of helix-forming propensities of the amino acid residues Relationship between side chain structure and 14-helix stability of beta3-peptides in water Hydration of the peptide backbone largely defines the thermodynamic propensity scale of residues at the C' position of the C-capping box of alpha-helices.The enthalpy of the alanine peptide helix measured by isothermal titration calorimetry using metal-binding to induce helix formation Role of backbone solvation in determining thermodynamic beta propensities of the amino acids.Alpha-helical stabilization by side chain shielding of backbone hydrogen bonds.alpha-helix formation: discontinuous molecular dynamics on an intermediate-resolution protein model.In search of the energetic role of peptide hydrogen bonds.Lysine and arginine residues do not increase the helicity of alanine-rich peptide helices.Conformational entropy of alanine versus glycine in protein denatured states The Flory isolated-pair hypothesis is not valid for polypeptide chains: implications for protein folding.Dehydration of main-chain amides in the final folding step of single-chain monellin revealed by time-resolved infrared spectroscopy.Energetics of the interaction between water and the helical peptide group and its role in determining helix propensities.Structural insights for designed alanine-rich helices: comparing NMR helicity measures and conformational ensembles from molecular dynamics simulation Transition state and ground state properties of the helix-coil transition in peptides deduced from high-pressure studies BiPPred: Combined sequence- and structure-based prediction of peptide binding to the Hsp70 chaperone BiP.Effects of charge states, charge sites and side chain interactions on conformational preferences of a series of model peptide ions.The helical alanine controversy: an (Ala)6 insertion dramatically increases helicity.H-bonding mediates polarization of peptide groups in folded proteins 2,2,2-Trifluoroethanol changes the transition kinetics and subunit interactions in the small bacterial mechanosensitive channel MscS The role of the N-terminal tail for the oligomerization, folding and stability of human frataxin Noncharged amino acid residues at the solvent-exposed positions in the middle and at the C terminus of the alpha-helix have the same helical propensity.Direct visualization of interaction between calmodulin and connexin45.Comparison of lipid-dependent bilayer insertion of pHLIP and its P20G variant.Microscopic nucleation and propagation rates of an alanine-based α-helix.Determinants of Helix Formation for a Kv1.3 Transmembrane Segment inside the Ribosome Exit Tunnel.

P2860

Q27655414-AE754E09-37DC-4FA5-AB31-8A9A3B0076A9 Q28364612-3CF1EFFB-55C3-4846-9705-E8B9BA3999CA Q30613298-F4E7CCA3-6615-4981-91A0-531E661D0F59 Q30769903-45CB703D-7E17-4954-B7CB-9A3C4A88FBB1 Q30819952-98D0D409-B671-493E-B32B-E53C0852F359 Q30975440-973480FA-E0D6-401B-8D58-76965514BE76 Q31133660-3A101C6D-16C5-4DF6-8887-8EE6A4C7E8A3 Q33462407-34648F18-363A-49C7-ABA3-1ED3F73D3ACF Q33496223-AAD91593-8B4C-402C-A6F8-ADFD3E21153B Q33818377-94587CD6-541C-486A-8D0F-F9F107C8A9BB Q33862294-9E47DCB3-A205-4354-85E2-77C0D18FD95F Q33943720-D923B80E-82E3-46D0-A558-CA36D5A16BF0 Q34009028-9CFEC1ED-CE81-4E06-8810-67D02189301D Q34009075-E4CD02B1-71F9-4BEF-88AD-E73BB0E3B32E Q34014321-5F037EE1-02C4-4F3E-A49C-B3C6FA205CCB Q34084053-D09A6C89-7A8E-4121-A7D3-354DF2E332BC Q35064700-DCD6ED62-A791-4874-84EE-74D301C11764 Q35607904-06F2AF48-9ED2-4DAC-B5F6-3568B8085CE7 Q35669665-D97245C5-4F0F-4D76-ADF9-69FF0B8EE55B Q35817954-28201EBA-572E-4187-B8A6-87DF2E7E200C Q36869878-B41FE4D1-242A-4CF1-BED2-BE8CFEF61B8E Q37260438-B0142194-AFF4-47A2-B079-236D45668BE8 Q37275705-36992FB3-3E27-483B-A119-A9FBF91294BA Q37421224-FD57F1DD-5A18-4F2A-95CA-192AF87CB003 Q39692774-F5AC9A11-29BA-42FC-B2A6-AE1AFA9CADA9 Q40829679-7C5F1E1D-9078-42C2-85BE-EC81DEEB8E38 Q41863409-9F984736-62E1-46D5-8E2F-CAD33211F49B Q41992325-0A74229B-F661-4D86-A106-47511E50FE59 Q42155859-ABEF8660-FB07-4EBE-8721-0927D3D332FD Q42552259-C384EFCD-D4DF-418F-801A-C1AD25BB3377 Q43152693-4C281BB9-E4A0-4096-A93E-1397C32FF8E4 Q47723180-7A03F5DE-40BD-4771-867F-4D9ABE30542A Q47796543-A9B60D08-FA39-40E7-8C8C-924F37696679 Q48048113-215E7886-5572-4156-ABEF-A637B0BDA364 Q51016925-85DA0824-D3EE-4816-B7DE-E2316D22F2A3

P2860

Interaction between water and polar groups of the helix backbone: an important determinant of helix propensities

http://www.wikidata.org/entity/Q36333304

description

1999 nî lūn-bûn

@nan

1999年の論文

@ja

1999年学术文章

@wuu

1999年学术文章

@zh-cn

1999年学术文章

@zh-hans

1999年学术文章

@zh-my

1999年学术文章

@zh-sg

1999年學術文章

@yue

1999年學術文章

@zh

1999年學術文章

@zh-hant

name

Interaction between water and ...... erminant of helix propensities

@ast

Interaction between water and ...... erminant of helix propensities

@en

type

label

Interaction between water and ...... erminant of helix propensities

@ast

Interaction between water and ...... erminant of helix propensities

@en

prefLabel

Interaction between water and ...... erminant of helix propensities

@ast

Interaction between water and ...... erminant of helix propensities

@en

P1433

Q36333304-254F6042-9C09-498E-89A5-844999FD0923

P1476

Q36333304-64357F2A-237C-48DB-9A63-C39E9930BD82

P2093

Q36333304-7EEB9B46-7078-4FE2-A4D8-82D146A523FB

Q36333304-E19B9B77-7A9F-4AAD-8F33-BA4F87E5EB33

P2860

Q36333304-1ADAAB2A-C810-4681-9607-EF4F759CDF9E

Q36333304-25D0386B-76BA-430F-A80A-431A7768D9F5

Q36333304-2DCC9C31-DFDF-4A64-A7F2-EBFA348C5672

Q36333304-2FAAC92C-49CC-4F5A-BFD4-CC14DBE7F025

Q36333304-3CA77688-11B7-452D-BC05-FD8E9B9ED87C

Q36333304-4AB897D7-2395-4C6A-86F8-31D1DF92A681

Q36333304-6C1142E2-F78E-4973-B12F-E773AC88E9BF

Q36333304-6EC8B952-C5EB-4002-AC7D-8DA255653EE1

Q36333304-72A36FB9-4025-481A-9E54-61AFF1C1959C

Q36333304-771A8232-42CA-4160-934F-DF57142B67B7

P304

Q36333304-5B6F2075-6619-42C2-B1DE-75C1D87AD3F1

P31

Q36333304-62CB0444-6E9B-4675-B5F0-B58965B0C762

P356

Q36333304-6CD014A0-70E8-4F81-9532-7A7B22CD9758

P407

Q36333304-5C259696-208A-4D7F-957C-2A4FE57DF44E

P433

Q36333304-CBF421AE-E07A-49D0-A405-3A3B4B64FBDF

P478

Q36333304-F3A74F8D-5F03-4158-B177-6DC679B36B9C

P577

Q36333304-566116D3-47FB-42A3-961C-81027B5888BB

P5875

Q36333304-F4F59182-40C8-450D-9FF3-94E64EF55B87

P698

Q36333304-9908AEE9-96EE-4131-9C17-599E6D1DF0E1

P932

Q36333304-65B125FB-3702-4F40-87FD-4CD428A00CDB

P356

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

Interaction between water and ...... erminant of helix propensities

@en

P2093

P Luo

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

R L Baldwin

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

P2860

Alanine scanning mutagenesis of the alpha-helix 115-123 of phage T4 lysozyme: effects on structure, stability and the binding of solvent

Structural basis of amino acid alpha helix propensity

Stability of alpha-helices

Stability of α-Helices

Solvents, interfaces and protein structure.

Contribution of hydration to protein folding thermodynamics. I. The enthalpy of hydration.

Temperature, stability, and the hydrophobic interaction

Analysis of data from the analytical ultracentrifuge by nonlinear least-squares techniques.

Is protein folding hierarchic? I. Local structure and peptide folding.

Interaction of the peptide bond with solvent water: a vapor phase analysis.

P304

4930-4935

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

P31

scholarly article

P356

10.1073/PNAS.96.9.4930

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

P407

P433

9

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

P478

96

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

P577

1999-04-01T00:00:00Z

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

P5875

13078820

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

P698

10220396

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

P932

21794

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