about
Evolution of vacuolar proton pyrophosphatase domains and volutin granules: clues into the early evolutionary origin of the acidocalcisomeOMPdb: a database of {beta}-barrel outer membrane proteins from Gram-negative bacteriaTopological mapping methods for α-helical bacterial membrane proteins--an update and a guideStructural analysis of a peptide fragment of transmembrane transporter protein bilitranslocaseMembrane-Bound Catechol-O-Methyl Transferase in Cortical Neurons and Glial Cells is Intracellularly OrientedPlanar substrate-binding site dictates the specificity of ECF-type nickel/cobalt transportersBuilding and analyzing protein interactome networks by cross-species comparisonsLipids in the assembly of membrane proteins and organization of protein supercomplexes: implications for lipid-linked disordersEmerging methodologies to investigate lipid-protein interactionsTransmembrane topology and signal peptide prediction using dynamic bayesian networksMeMotif: a database of linear motifs in alpha-helical transmembrane proteinsA sequence-based computational model for the prediction of the solvent accessible surface area for α-helix and β-barrel transmembrane residues.Membrane thickness varies around the circumference of the transmembrane protein BtuB.Porins in prokaryotes and eukaryotes: common themes and variations.Predicting weakly stable regions, oligomerization state, and protein-protein interfaces in transmembrane domains of outer membrane proteins.Analysis of structured and intrinsically disordered regions of transmembrane proteinsProtein secretion and outer membrane assembly in AlphaproteobacteriaClassification of α-helical membrane proteins using predicted helix architecturesWhy is the biological hydrophobicity scale more accurate than earlier experimental hydrophobicity scales?Low complexity and disordered regions of proteins have different structural and amino acid preferences.Complete atomistic model of a bacterial cytoplasm for integrating physics, biochemistry, and systems biology.Prediction of membrane protein structures with complex topologies using limited constraintsSequence-structure relationship study in all-α transmembrane proteins using an unsupervised learning approach.Predicting protein-protein binding sites in membrane proteins.Computational Approaches for Revealing the Structure of Membrane Transporters: Case Study on Bilitranslocase.A photon-free approach to transmembrane protein structure determination.Bihelix: Towards de novo structure prediction of an ensemble of G-protein coupled receptor conformations.Retrieving backbone string neighbors provides insights into structural modeling of membrane proteins.Membrane protein native state discrimination by implicit membrane models.Modular prediction of protein structural classes from sequences of twilight-zone identity with predicting sequences.Data-driven model for the prediction of protein transmembrane regions.Predicting transmembrane helix packing arrangements using residue contacts and a force-directed algorithmStructural fragment clustering reveals novel structural and functional motifs in alpha-helical transmembrane proteins.Characterization of an endoplasmic reticulum-associated silaffin kinase from the diatom Thalassiosira pseudonanaThe EXIT Strategy: an Approach for Identifying Bacterial Proteins Exported during Host Infection.MPRAP: an accessibility predictor for a-helical transmembrane proteins that performs well inside and outside the membraneModel-guided mutagenesis drives functional studies of human NHA2, implicated in hypertension.MEDELLER: homology-based coordinate generation for membrane proteinsMolecular modeling and ligand docking for solute carrier (SLC) transportersNClassG+: A classifier for non-classically secreted Gram-positive bacterial proteins.
P2860
Q21203752-C4DF1AEA-60D1-4E43-ACBB-2838E097667CQ24609418-7D209D28-34EF-47B2-841C-04BD07CE8135Q26863116-3ED31DD1-6962-4316-828D-4A5239E6FCFEQ27301091-ECB07CCA-479D-4CD4-A43D-3431FF68CA79Q27500447-2C9B6BA3-BB13-4AD4-9C99-279A2FE997B6Q27681058-EF1F9EC8-985D-46F2-978A-659E178DE02BQ28278221-37BDC0E4-FC76-46B3-B056-A536F445A3D0Q28386214-E4439001-5E02-4082-908A-C5F2ED6E8B46Q28386247-9AF3F716-8137-4364-A4D5-34EA8EF3FD3AQ28473900-4EE3936B-65C1-4BDB-8F4D-0E763CF16A78Q28749242-84A111DD-9C14-4781-A61A-689D5F8537F4Q30155468-82CF0F87-D28B-4AAD-81D9-1F9E035BBBA2Q30155833-41C1B256-A431-4F23-9A8E-11894FF95AC9Q30156035-FFA9A72B-7F0D-4305-BA12-324A930B4FD2Q30157187-78CADB8E-CA45-4DC8-8F08-EDCABC0E1D23Q30157208-52202EC3-5668-4D42-84CC-86B63DD63F72Q30157537-DC252087-EACE-47C3-BDAD-FF3367EA1DF7Q30355362-DEDA1450-4146-48DC-863F-34EBAC1AF773Q30361608-FD31CF00-C86E-45A7-8F2B-016C001FE498Q30369339-6063BB89-9E20-4F79-B413-A1CE125FE153Q30372639-0BF08244-8327-43D6-975E-F8AB37EEF16BQ30374712-153B57FD-F243-4273-AEFE-DDBE46384C0AQ30375311-9F9DE0F8-F41A-4B3D-A717-81CD7B71D78CQ30381038-2F21781F-1752-4270-9A35-DF0CA8C8C9F5Q30398993-6E7A3E80-8672-4257-8E1D-61EC840BDAFAQ30408575-FD18F605-7FEB-4E0C-B163-CAC7B28ACEEFQ30410723-B23BF464-68B6-4D3B-907E-0577B30DD553Q30414262-5EF8E605-767A-47AE-A24F-DCD7758BB97FQ30424545-92951BCB-6CC5-45F6-B3FD-77B54E06358DQ33517965-704E78C9-84AF-4704-BAFF-1955B718F427Q33520010-5413BB16-C967-4A30-96EC-173F53B2ACCAQ33545205-B928F782-8B0F-4BFE-886F-EAD590E242ABQ33564924-7AFAAD2D-6945-41E2-B950-73F92BC759ABQ33569653-2B364212-EA37-4CE5-8A02-C8B01DBA16E1Q33603832-FE5FE354-1C34-468F-A213-FD036003676EQ33611134-15F72981-4EDD-476B-93B9-D496EB19B624Q33665631-1BABC033-1AD6-4EA8-BEBB-F6FD42A2FB52Q33711713-3298A9D5-3B75-4E58-945E-DDD843F54071Q33751096-DD72234E-AF56-4E68-B546-266B2E188508Q33793575-B801CDB3-D53F-45C0-80D0-642B6CEC2661
P2860
description
2007 nî lūn-bûn
@nan
2007 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2007 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
name
Membrane protein structure: prediction versus reality.
@ast
Membrane protein structure: prediction versus reality.
@en
type
label
Membrane protein structure: prediction versus reality.
@ast
Membrane protein structure: prediction versus reality.
@en
prefLabel
Membrane protein structure: prediction versus reality.
@ast
Membrane protein structure: prediction versus reality.
@en
P1476
Membrane protein structure: prediction versus reality.
@en
P304
P356
10.1146/ANNUREV.BIOCHEM.76.052705.163539
P577
2007-01-01T00:00:00Z