Related ArticlesThe eigenmode perspective of NMR spin relaxation in proteins.
J Chem Phys. 2013 Dec 14;139(22):225104
Authors: Shapiro YE, Meirovitch E
Abstract
We developed in recent years the two-body (protein and probe) coupled-rotator slowly relaxing local structure (SRLS) approach for elucidating protein dynamics from NMR spin relaxation. So far we used as descriptors the set of physical parameters that enter the SRLS model. They include the global (protein-related) diffusion tensor, D1, the local (probe-related) diffusion tensor, D2, and the local coupling/ordering potential, u. As common in analyzes based on mesoscopic dynamic models, these parameters have been determined with data-fitting techniques. In this study, we describe structural dynamics in terms of the eigenmodes comprising the SRLS time correlation functions (TCFs) generated by using the best-fit parameters as input to the Smoluchowski equation. An eigenmode is a weighted exponential with decay constant given by an eigenvalue of the Smoluchowski operator, and weighting factor determined by the corresponding eigenvector. Obviously, both quantities depend on the SRLS parameters as determined by the SRLS model. Unlike the set of best-fit parameters, the eigenmodes represent patterns of motion of the probe-protein system. The following new information is obtained for the typical probe, the (15)N-(1)H bond. Two eigenmodes, associated with the protein and the probe, dominate when the time scale separation is large (i.e., D2 >> D1), the tensorial properties are simple, and the local potential is either very strong or very weak. When the potential exceeds these limits while the remaining conditions are preserved, new eigenmodes arise. The multi-exponentiality of the TCFs is associated in this case with the restricted nature of the local motion. When the time scale separation is no longer large, the rotational degrees of freedom of the protein and the probe become statistically dependent (coupled dynamically). The multi-exponentiality of the TCFs is associated in this case with the restricted nature of both the local and the global motion. The effects of local diffusion axiality, potential strength, and extent of mode-coupling on the eigenmode setup are investigated. We detect largely global motional or largely local motional eigenmodes. In addition, we detect mixed eigenmodes associated with correlated/prograde or anti-correlated/retrograde rotations of the global (D1) and local (D2) motional modes. The eigenmode paradigm is applied to N-H bond dynamics in the ?-sheet residue K19, and the ?-helix residue A34, of the third immunoglobulin-binding domain of streptococcal protein G. The largest contribution to the SRLS TCFs is made by mixed anti-correlated D1 and D2 eigenmodes. The next largest contribution is made by D1-dominated eigenmodes. Eigenmodes dominated by the local motion contribute appreciably to A34 and marginally to K19. Correlated D1 and D2 eigenmodes contribute exclusively to K19 and do not contribute above 1% to A34. The differences between K19 and A34 are delineated and rationalized in terms of the best-fit SRLS parameters and mode-mixing. It may be concluded that eigenmode analysis is complementary and supplementary to data-fitting-based analysis.
[NMR paper] The time correlation function perspective of NMR relaxation in proteins.
The time correlation function perspective of NMR relaxation in proteins.
The time correlation function perspective of NMR relaxation in proteins.
J Chem Phys. 2013 Aug 28;139(8):084107
Authors: Shapiro YE, Meirovitch E
Abstract
We applied over a decade ago the two-body coupled-rotator slowly relaxing local structure (SRLS) approach to NMR relaxation in proteins. One rotator is the globally moving protein and the other rotator is the locally moving probe (spin-bearing moiety, typically the (15)N-(1)H bond). So far we applied SRLS to...
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[NMR paper] Carbon Relaxation in (13)C(?)-H(?) and (13)C(?)-D(?) Spin Pairs as a Probe of Backbone Dynamics in Proteins.
Carbon Relaxation in (13)C(?)-H(?) and (13)C(?)-D(?) Spin Pairs as a Probe of Backbone Dynamics in Proteins.
http://www.ncbi.nlm.nih.gov/corehtml/query/egifs/http:--pubs.acs.org-images-pubmed-acspubs.jpg Related Articles Carbon Relaxation in (13)C(?)-H(?) and (13)C(?)-D(?) Spin Pairs as a Probe of Backbone Dynamics in Proteins.
J Phys Chem B. 2013 Jan 25;
Authors: Sun H, Long D, Brüschweiler R, Tugarinov V
Abstract
NMR methodology for the measurements of ?-carbon R(1) and R(1?) spin relaxation rates in (13)C(?)-H(?) and (13)C(?)-D(?) spin...
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02-03-2013 10:22 AM
Mathematical treatment of adiabatic fast passage pulses for the computation of nuclear spin relaxation rates in proteins with conformational exchange
Mathematical treatment of adiabatic fast passage pulses for the computation of nuclear spin relaxation rates in proteins with conformational exchange
Abstract Although originally designed for broadband inversion and decoupling in NMR spectroscopy, recent methodological developments have introduced adiabatic fast passage (AFP) pulses into the field of protein dynamics. AFP pulses employ a frequency sweep, and have not only superior inversion properties with respect to offset effects, but they are also easily implemented into a pulse sequence. As magnetization is dragged from the +z to...
[NMR paper] Thermodynamic insights into proteins from NMR spin relaxation studies.
Thermodynamic insights into proteins from NMR spin relaxation studies.
Related Articles Thermodynamic insights into proteins from NMR spin relaxation studies.
Curr Opin Struct Biol. 2001 Oct;11(5):555-9
Authors: Spyracopoulos L, Sykes BD
NMR spin relaxation measurements of picosecond to nanosecond timescale backbone and sidechain fluctuations of protein molecules, and subsequent entropic interpretation yield interesting, but sometimes counterintuitive, insights into proteins. The stabilities of proteins and protein interactions are achieved...
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11-19-2010 08:44 PM
[NMR paper] Reorientational eigenmode dynamics: a combined MD/NMR relaxation analysis method for
Reorientational eigenmode dynamics: a combined MD/NMR relaxation analysis method for flexible parts in globular proteins.
Related Articles Reorientational eigenmode dynamics: a combined MD/NMR relaxation analysis method for flexible parts in globular proteins.
J Am Chem Soc. 2001 Aug 1;123(30):7305-13
Authors: Prompers JJ, Brüschweiler R
An approach is presented for the interpretation of heteronuclear NMR spin relaxation data in mobile protein parts in terms of reorientational eigenmode dynamics. The method is based on the covariance matrix of...
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[NMR paper] NMR spin relaxation methods for characterization of disorder and folding in proteins.
NMR spin relaxation methods for characterization of disorder and folding in proteins.
Related Articles NMR spin relaxation methods for characterization of disorder and folding in proteins.
J Mol Graph Model. 2001;19(1):3-12
Authors: Bracken C
The flexibility and dynamics of proteins directly influence the processes of protein folding, recognition, and function. NMR spin relaxation methods are used to assess the dynamics and mobility of proteins, for fast ps and ns motions as well as slower microsecond and ms events. The degree of protein...
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[NMR paper] 19F-NMR spin-spin relaxation (T2) method for characterizing volatile anesthetic bindi
19F-NMR spin-spin relaxation (T2) method for characterizing volatile anesthetic binding to proteins. Analysis of isoflurane binding to serum albumin.
Related Articles 19F-NMR spin-spin relaxation (T2) method for characterizing volatile anesthetic binding to proteins. Analysis of isoflurane binding to serum albumin.
Biochemistry. 1992 Aug 11;31(31):7069-76
Authors: Dubois BW, Evers AS
This paper characterizes the low-affinity ligand binding interactions of a fluorinated volatile anesthetic, isoflurane (CHF2OCHClCF3), with bovine serum albumin...
The eigenmode perspective of NMR spin relaxation in proteins.
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