Measurement of bond vector orientations in invisible excited states of proteins

Vallurupalli, Pramodh; Hansen, D. Flemming; Stollar, Elliott J.; Meirovitch, Eva; Kay, Lewis E.

doi:10.1073/pnas.0708296104

Cited by 174 publications

(291 citation statements)

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“…Relaxation dispersion profiles have been recorded that focus on 15 N, 1 HN, 13 C ␣ , and 13 CO nuclei using previously published experiments (6,(19)(20)(21). Data from a given nucleus-type is fitted together to extract absolute values of chemical shift differences between ground (P) and excited (PL) states, ͉⌬ ͉ (ppm) or ͉⌬ ͉ (rad/sec), along with the global parameters, k ex ϭ k on [L] ϩ k off and p PL , the population of the excited state (3,7). For each of the four nuclei indicated above, the sign of ⌬ can be obtained in many cases and hence the chemical shifts of the excited state, following the approach of Skrynnikov et al (5).…”

Section: Resultsmentioning

confidence: 99%

“…Thus, with the development of robust methods for the measurement of both chemical shifts and anisotropic interactions in invisible protein states, it is now possible to contemplate structural studies of these ''elusive'' conformers. Here we study the invisible bound state that is formed on the addition of a small mole fraction (Ϸ5%) of a 17-residue Ark1p peptide (17) to a solution of the Abp1p SH3 domain (18), an exchanging system that we have investigated by CPMG relaxation dispersion methods and for which large amounts of chemical shift (6) and RDC/RCSA data have been recorded (7,9,10). We show that restraints available from relaxation dispersion data alone permit the calculation of a well defined ensemble of structures of the invisible bound state, with a pairwise root mean square deviation of backbone atoms of 0.33 Ϯ 0.08 Å. Cross-validation using 1 H- 15 N RDC values measured in a second ''orthogonal'' alignment frame establishes the accuracy of the structure.…”

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“…It has also recently been shown that variants of the standard CPMG-based relaxation dispersion experiments can be designed for samples dissolved in small amounts of alignment media (7,8) so that anisotropic interactions, including residual dipolar couplings (RDCs) and residual chemical shift anisotropies (RCSAs) of the invisible state, can be measured. Based on these approaches, accurate values of 1 HN-15 N, 1 H ␣ -13 C ␣ , and 1 HN-13 CO RDCs and 13 CO RCSAs have been reported in an exchanging protein system (7,9,10).…”

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Structures of invisible, excited protein states by relaxation dispersion NMR spectroscopy

Vallurupalli

Hansen

Kay

2008

Proc. Natl. Acad. Sci. U.S.A.

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Molecular function is often predicated on excursions between ground states and higher energy conformers that can play important roles in ligand binding, molecular recognition, enzyme catalysis, and protein folding. The tools of structural biology enable a detailed characterization of ground state structure and dynamics; however, studies of excited state conformations are more difficult because they are of low population and may exist only transiently. Here we describe an approach based on relaxation dispersion NMR spectroscopy in which structures of invisible, excited states are obtained from chemical shifts and residual anisotropic magnetic interactions. To establish the utility of the approach, we studied an exchanging protein (Abp1p SH3 domain)-ligand (Ark1p peptide) system, in which the peptide is added in only small amounts so that the ligand-bound form is invisible. From a collection of 15 N, 1 HN, 13 C ␣ , and 13 CO chemical shifts, along with 1 HN-15 N, 1 H ␣ -13 C ␣ , and 1 HN-13 CO residual dipolar couplings and 13 CO residual chemical shift anisotropies, all pertaining to the invisible, bound conformer, the structure of the bound state is determined. The structure so obtained is cross-validated by comparison with 1 HN-15 N residual dipolar couplings recorded in a second alignment medium. The methodology described opens up the possibility for detailed structural studies of invisible protein conformers at a level of detail that has heretofore been restricted to applications involving visible ground states of proteins.Carr-Purcell-Meiboom-Gill (CPMG) ͉ dynamics ͉ excited state structure ͉ residual dipolar couplings ͉ chemical exchange M uch of structural biology focuses on the generation of static structures of biomolecules, with less consideration of how such structures change in time. This, in part, reflects the sample requirements that are imposed by the different structural methods. In the case of studies using x-ray diffraction, for example, molecular dynamics are minimized due to the crystalline nature of the sample itself, which traps the molecule in a single conformation, and by the liquid nitrogen temperatures that are used in most experiments. In the case of solution NMR spectroscopy, sample conditions are sought that give rise to the ''highest quality spectra'' that often derive from the most stable form of the protein, and conformational heterogeneity that reflects excursions between different states is thus minimized. Certainly, initial focus on a single static representation is a wise choice, as much can be learned from these high-resolution pictures. However, function is often predicated on excursions between different conformers (1, 2), and it is therefore of interest to obtain detailed structural information about the many different states of a biomolecule that populate its energy landscape.Of the different conformers that one wishes to study, it is clear that those belonging to the low energy ground state are the most easily probed, because they are populated to the greatest extent. Hig...

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Section: Resultsmentioning

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Structures of invisible, excited protein states by relaxation dispersion NMR spectroscopy

Vallurupalli

Hansen

Kay

2008

Proc. Natl. Acad. Sci. U.S.A.

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193

170

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“…The combination of nuclear magnetic resonance (NMR) spectroscopy and isothermal titration calorimetry (32) can characterize binding kinetics that are too rapid for standard stopped-flow techniques, on the order of 10 4 s Ϫ1 (33). In this approach, a substoichiometric amount of ligand is added to a protein sample whose signals are monitored by NMR spectros- copy.…”

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Electrostatic Interactions in the Binding Pathway of a Transient Protein Complex Studied by NMR and Isothermal Titration Calorimetry

Meneses

Mittermaier

2014

Journal of Biological Chemistry

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Background: Electrostatic interactions are known accelerate binding in protein complexes with long lifetimes (minutes to hours). Results: NMR and calorimetry were used to characterize binding kinetics in short lived (ϳ1 ms) protein-peptide complexes. Conclusion: Electrostatic enhancement is much less and basal (electrostatic-free) association rates are greater than previously observed. Significance: Electrostatics may play different roles in short lived and long lived protein complexes.

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“…40,53,82,83,87 Incorporation of chemical shifts in NMR structure refinement and the development of new NMR experiments that can report on internuclear vector orientations in excited conformational states provide valuable structural constraints that may enable direct structural characterization of higher energy protein conformations. [88][89][90] Kay and coworkers recently reported the structure of an ''invisible'' protein folding intermediate, a remarkable achievement convincingly showing that structure determination of weakly populated conformational states are within reach. 91 Under favorable conditions, NMRdetected paramagnetic relaxation enhancement (PRE) can be used to determine the structure of weakly populated conformational states.…”

Section: Protein Activation Via Energetically Excited Statesmentioning

confidence: 99%

NMR reveals novel mechanisms of protein activity regulation

Kalodimos

2011

Protein Science

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NMR spectroscopy is one of the most powerful tools for the characterization of biomolecular systems. A unique aspect of NMR is its capacity to provide an integrated insight into both the structure and intrinsic dynamics of biomolecules. In addition, NMR can provide siteresolved information about the conformation entropy of binding, as well as about energetically excited conformational states. Recent advances have enabled the application of NMR for the characterization of supramolecular systems. A summary of mechanisms underpinning protein activity regulation revealed by the application of NMR spectroscopy in a number of biological systems studied in the lab is provided.

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Measurement of bond vector orientations in invisible excited states of proteins

Cited by 174 publications

References 38 publications

Structures of invisible, excited protein states by relaxation dispersion NMR spectroscopy

Structures of invisible, excited protein states by relaxation dispersion NMR spectroscopy

Electrostatic Interactions in the Binding Pathway of a Transient Protein Complex Studied by NMR and Isothermal Titration Calorimetry

NMR reveals novel mechanisms of protein activity regulation

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