Related ArticlesNMR spectroscopy of hydroxyl protons in aqueous solutions of peptides and proteins.
J Biomol NMR. 1992 Sep;2(5):447-65
Authors: Liepinsh E, Otting G, Wüthrich K
Hydroxyl groups of serine and threonine, and to some extent also tyrosine are usually located on or near the surface of proteins. NMR observations of the hydroxyl protons is therefore of interest to support investigations of the protein surface in solution, and knowledge of the hydroxyl NMR lines is indispensable as a reference for studies of protein hydration in solution. In this paper, solvent suppression schemes recently developed for observation of hydration water resonances were used to observe hydroxyl protons of serine, threonine and tyrosine in aqueous solutions of small model peptides and the protein basic pancreatic trypsin inhibitor (BPTI). The chemical shifts of the hydroxyl protons of serine and threonine were found to be between 5.4 and 6.2 ppm, with random-coil shifts at 4 degrees C of 5.92 ppm and 5.88 ppm, respectively, and those of tyrosine between 9.6 and 10.1 ppm, with a random-coil shift of 9.78 ppm. Since these spectral regions are virtually free of other polypeptide 1H NMR signals, cross peaks with the hydroxyl protons are usually well separated even in homonuclear two-dimensional 1H NMR spectra. To illustrate the practical use of hydroxyl proton NMR in polypeptides, the conformations of the side-chain hydroxyl groups in BPTI were characterized by measurements of nuclear Overhauser effects and scalar coupling constants involving the hydroxyl protons. In addition, hydroxyl proton exchange rates were measured as a function of pH, where simple first-order rate processes were observed for both acid- and base-catalysed exchange of all but one of the hydroxyl-bearing residues in BPTI. For the conformations of the individual Ser, Thr and Tyr side chains characterized in the solution structure with the use of hydroxyl proton NMR, both exact coincidence and significant differences relative to the corresponding BPTI crystal structure data were observed.
Assignment strategies for aliphatic protons in the solid-state in randomly protonated proteins
Assignment strategies for aliphatic protons in the solid-state in randomly protonated proteins
Abstract Biological solid-state nuclear magnetic resonance spectroscopy developed rapidly in the past two decades and emerged as an important tool for structural biology. Resonance assignment is an essential prerequisite for structure determination and the characterization of motional properties of a molecule. Experiments, which rely on carbon or nitrogen detection, suffer, however, from low sensitivity. Recently, we introduced the RAP (Reduced Adjoining Protonation) labeling scheme, which...
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12-06-2011 08:01 AM
Optimum levels of exchangeable protons in perdeuterated proteins for proton detection in MAS solid-state NMR spectroscopy
Optimum levels of exchangeable protons in perdeuterated proteins for proton detection in MAS solid-state NMR spectroscopy
Abstract We present a systematic study of the effect of the level of exchangeable protons on the observed amide proton linewidth obtained in perdeuterated proteins. Decreasing the amount of D2O employed in the crystallization buffer from 90 to 0%, we observe a fourfold increase in linewidth for both 1H and 15N resonances. At the same time, we find a gradual increase in the signal-to-noise ratio (SNR) for 1Hâ??15N correlations in dipolar coupling based experiments for...
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01-09-2011 12:46 PM
[NMR paper] Relaxation of water protons in highly concentrated aqueous protein systems studied by
Relaxation of water protons in highly concentrated aqueous protein systems studied by 1H NMR spectroscopy.
Related Articles Relaxation of water protons in highly concentrated aqueous protein systems studied by 1H NMR spectroscopy.
Z Naturforsch C. 2001 Nov-Dec;56(11-12):1075-81
Authors: Szuminska K, Gutsze A, Kowalczyk A
Concentrated Aqueous Protein Systems, Proton Relaxation Times, Slow Chemical Exchange In this paper we present proton spin-lattice (T1) and spin-spin (T2) relaxation times measured vs. concentration, temperature, pulse...
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11-19-2010 08:44 PM
[NMR paper] Capillary array electrophoretic NMR of proteins in biological buffer solutions.
Capillary array electrophoretic NMR of proteins in biological buffer solutions.
Related Articles Capillary array electrophoretic NMR of proteins in biological buffer solutions.
J Magn Reson. 1999 Dec;141(2):355-9
Authors: He Q, Liu Y, Sun H, Li E
The capillary array electrophoretic NMR (CA-ENMR) was developed to study protein mixtures in biological buffer solutions of high ionic strength. By enhancing the strength of the effective electric field across the sample, the technique permits the detection of the electrophoretic motion of 1 mM...
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11-18-2010 08:31 PM
[NMR paper] The hydration of proteins in solutions by self-diffusion coefficients. NMR study.
The hydration of proteins in solutions by self-diffusion coefficients. NMR study.
Related Articles The hydration of proteins in solutions by self-diffusion coefficients. NMR study.
Biochim Biophys Acta. 1996 Apr 17;1289(3):312-4
Authors: Baranowska HM, Olszewski KJ
The hydration of the globular (lysozyme, albumin) and fibrillar (fibrinogen) proteins in solution has been determined from the measurements of the self-diffusion coefficient by NMR pulsed gradient method. It has been concluded that the concentration dependencies of the...
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08-22-2010 02:27 PM
[Question from NMRWiki Q&A forum] Please suggest model proteins and peptides for NMR
Please suggest model proteins and peptides for NMR
do you know any model proteins except lysozyme suitable for nmr experiments?
Check if somebody has answered this question on NMRWiki QA forum
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08-22-2010 02:30 AM
[Question from NMRWiki Q&A forum] When to label peptides and proteins and when not?
When to label peptides and proteins and when not?
When pursuing an NMR structure project - at what size of oligopeptide you would decide to label it with:
15N
13C
both
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08-22-2010 02:30 AM
NMR of Naphthalene: why are the alpha-protons more downfield than the beta- protons?
Hi, can you please help me explain why the alpha-protons of naphthalene are further downfield? I know that the protons at the alpha position must be more deshielded, but I don't know how to explain why they have less electron density compared to the beta protons. Does this have to do with the number of double bonds that can be drawn in different resonance structures? Thanks for your help!Thanks so much!
NMR spectroscopy of hydroxyl protons in aqueous solutions of peptides and proteins.
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