Use of a water flip-back pulse in the homonuclear NOESY experiment.
about
The extracellular human melanoma inhibitory activity (MIA) protein adopts an SH3 domain-like fold.A three-stemmed mRNA pseudoknot in the SARS coronavirus frameshift signalTemplate requirements for RNA synthesis by a recombinant hepatitis C virus RNA-dependent RNA polymeraseA 30-residue fragment of the carp granulin-1 protein folds into a stack of two beta-hairpins similar to that found in the native proteinNMR structure of the channel-former zervamicin IIB in isotropic solventsSolution structure of the main alpha-amylase inhibitor from amaranth seedsNMR spatial structure of alpha-conotoxin ImI reveals a common scaffold in snail and snake toxins recognizing neuronal nicotinic acetylcholine receptorsStructure dissection of human progranulin identifies well-folded granulin/epithelin modules with unique functional activitiesHigh-resolution NMR structure of the antimicrobial peptide protegrin-2 in the presence of DPC micellesResidues 21-30 within the extracellular N-terminal region of the C5a receptor represent a binding domain for the C5a anaphylatoxinAdvanced Solvent Signal Suppression for the Acquisition of 1D and 2D NMR Spectra of Scotch Whisky.Refined solution structure and backbone dynamics of HIV-1 Nef.Modulation of zinc- and cobalt-binding affinities through changes in the stability of the zinc ribbon protein L36.Biomolecular ligands screening using radiation damping difference WaterLOGSY spectroscopy.The chimeric peptide [Lys(-2)-Arg(-1)]-sarafotoxin-S6b, composed of the endothelin pro-sequence and sarafotoxin, retains the salt-bridge staple between Arg(-1) and Asp8 previously observed in [Lys(-2)-Arg(-1)]-endothelin. Implications of this salt-bConformation of N-terminal HIV-1 Tat (fragment 1-9) peptide by NMR and MD simulations.Proton-proton Overhauser NMR spectroscopy with polypeptide chains in large structures.Oligomerization of protegrin-1 in the presence of DPC micelles. A proton high-resolution NMR study.Homogeneous and heterogeneous tertiary structure ensembles of amyloid-β peptides.Structural energetics of the adenine tract from an intrinsic transcription terminator.Sequence-dependence of the energetics of opening of at basepairs in DNA.N-acylated peptides derived from human lactoferricin perturb organization of cardiolipin and phosphatidylethanolamine in cell membranes and induce defects in Escherichia coli cell division.Protein-Inhibitor Interaction Studies Using NMRRNA dimerization plays a role in ribosomal frameshifting of the SARS coronavirus.Folding trajectories of human dihydrofolate reductase inside the GroEL GroES chaperonin cavity and free in solution.Multivalent Amino Sugars to Recognize Different TAR RNA Conformations.Measurement of long-range 1H-19F scalar coupling constants and their glycosidic torsion dependence in 5-fluoropyrimidine-substituted RNAThe core microprocessor component DiGeorge syndrome critical region 8 (DGCR8) is a nonspecific RNA-binding protein.Dynamics and stability of individual base pairs in two homologous RNA-DNA hybrids.The Aspergillus nidulans transcription factor AlcR forms a stable complex with its half-site DNA: a NMR study.Direct NMR observation of the thioredoxin-mediated reduction of the chloroplast NADP-malate dehydrogenase provides a structural basis for the relief of autoinhibition.Radiation damping in modern NMR experiments: progress and challenges.Solution structure and backbone dynamics of Calsensin, an invertebrate neuronal calcium-binding protein.GroEL Recognizes an Amphipathic Helix and Binds to the Hydrophobic Side.Uncovering the thermodynamics of monomer binding for RNA replication.Unique C. elegans telomeric overhang structures reveal the evolutionarily conserved properties of telomeric DNASolution structure of substrate-based ligands when bound to hepatitis C virus NS3 protease domain.Micelle-bound conformation of a hairpin-forming peptide: combined NMR and molecular dynamics study.Opening dynamics of 8-oxoguanine in DNA.Impact of Azidohomoalanine Incorporation on Protein Structure and Ligand Binding.
P2860
Q24536791-7167E7AD-5331-460C-9510-37B1D1CE2157Q24803069-631C7CF0-776A-4F74-A451-F9E1F6635639Q27469758-69B2DE99-BE6F-4647-8E37-FFAAC94F0083Q27619158-3F33360F-8B81-4842-A3FD-F59ECDA3896DQ27621487-DC75A264-4801-4D2B-8012-C007762CE12FQ27631162-91E823F3-A79E-4021-952B-9A0A6CEFC61DQ27639865-DF9979DF-C11A-495F-B386-B5CC156D3793Q27650138-E6C806C4-7F22-4E9A-BD78-B6F202DDFCABQ27696221-69BD8147-AE36-4E30-8E89-5116FAA2B972Q28268382-F7D9E022-E92D-4105-9F23-0FD80CEFFAFDQ30101041-7DD60C89-4281-4C59-9D45-19C05FB7E7F0Q30176531-CADF77C6-D091-4DAB-ACDB-A510D4BB8DCFQ30350313-214EE473-D607-4DD4-9003-F9E6179CFD6AQ30641707-A2943006-262E-49D2-85F4-3141B196AB4DQ30650994-7FE39B74-B76E-44A4-A28A-23C44CB468E8Q30667781-F269979A-4AD2-40AB-8E17-A1F4889041F6Q31065744-FEFEEA6A-4C10-47A1-8114-C49D5E9ABD88Q32119117-10E268AB-E53F-48AC-806F-BEA6176C383BQ33973960-F82FCDAE-5452-404B-A558-2A614DC562EDQ34011482-2B0B11AE-80C8-4590-B798-B46686AB03A1Q34187349-2F844B9E-E9A1-4D11-A3C4-E2EA9D5ACC0DQ35111141-D3CF4995-7F44-42B6-B33D-8D582ED902A3Q36036813-E4283222-D6C1-4629-AC70-F26FF48A5FB8Q36619971-BCAA02AC-E20A-4FAC-8120-E145D65A095EQ36696358-D802D47D-EF87-43DC-8E52-BD68FB8036FCQ36788071-807F50B1-AF72-425A-AC21-238978131BB6Q36915968-9BD3DC21-EC1D-45BC-AD91-1D58BFD67806Q37168451-805D8A9C-2107-4D58-B83C-27789B6C40EDQ37378462-C6FC23F1-3B59-420A-945F-470616058F73Q38345802-34600BAD-F09A-4AFE-80D2-B323A5411EB6Q39434649-7883FBE7-41C8-4463-AFA0-60EE3BB66426Q40399095-5D307D40-B76D-4CD8-84EF-2A5FC2D53285Q42107446-79B1DF12-0021-455F-9E5D-22692F4698E3Q42123947-AB426859-EC79-4DEA-9596-836E1EDDCF43Q42154077-A591A280-ABA1-4450-8A61-2A77C726B3CEQ42400871-DA35EDFB-FFCF-4AD9-ABF6-9C684AEA59B7Q42993945-6DF39706-F41D-4CC2-91C1-C241B71C01CDQ44181627-05C3A5C4-09C8-4FDF-8B37-7400980DF13CQ46438848-B2317E69-B35A-431C-A316-E722805C14E0Q47741447-00A704B7-5E76-409C-AFD1-3A1E80A7632C
P2860
Use of a water flip-back pulse in the homonuclear NOESY experiment.
description
1995 nî lūn-bûn
@nan
1995 թուականի Ապրիլին հրատարակուած գիտական յօդուած
@hyw
1995 թվականի ապրիլին հրատարակված գիտական հոդված
@hy
1995年の論文
@ja
1995年論文
@yue
1995年論文
@zh-hant
1995年論文
@zh-hk
1995年論文
@zh-mo
1995年論文
@zh-tw
1995年论文
@wuu
name
Use of a water flip-back pulse in the homonuclear NOESY experiment.
@ast
Use of a water flip-back pulse in the homonuclear NOESY experiment.
@en
type
label
Use of a water flip-back pulse in the homonuclear NOESY experiment.
@ast
Use of a water flip-back pulse in the homonuclear NOESY experiment.
@en
prefLabel
Use of a water flip-back pulse in the homonuclear NOESY experiment.
@ast
Use of a water flip-back pulse in the homonuclear NOESY experiment.
@en
P356
P1476
Use of a water flip-back pulse in the homonuclear NOESY experiment.
@en
P2093
C Dhalluin
J M Wieruszeski
P2888
P304
P356
10.1007/BF00211762
P50
P577
1995-04-01T00:00:00Z