Disentangling Crystallographic Inequivalence and Crystallographic Forms of <scp>l</scp>-Arginine by One- and Two-Dimensional Solid-State NMR Spectroscopy

Herbert‐Pucheta, José Enrique; Colaux, Henri; Bodenhausen, Geoffrey; Tékély, Piotr

doi:10.1021/jp209644k

Cited by 10 publications

(7 citation statements)

References 27 publications

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“…An interesting adapted spectroscopic tool used to disentangle different conformations and coordinationm odes in ag iven media is the proton spin-lattice relaxation time, T 1 . [25] As shown in Figure S5, measurements of T 1 1 Hr elaxation times (at T = 214 K) in the inversionr ecovery experiment imply the computing of series of 1D 1 Hs pectra with ap re-filter block (1808Àt). Evolution of signal intensity of each proton as af unction of t can be fitted according to Bloch equations in ordert oo btain T 1 1 Hv alues (FigureS5).…”

Section: Hnmr Schemesmentioning

confidence: 95%

Deciphering the Conformational Choreography of Zinc Coordination Complexes with Standard and Novel Proton NMR Techniques Combined with DFT Methods

et al. 2016

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The presence of water has been shown to deeply impact the stability and geometry of Zn complexes in solution. Evidence for tetra- and penta-coordinated species in a pyridylmethylamine-Zn(II) model complex is presented. Novel (1) H NMR tools such as T1 -filtered selective exchange spectroscopy and pure shifted gradient-encoded selective refocusing as well as classical 2D ((1) H-(1) H) exchange spectroscopy, diffusion-ordered spectroscopy and T1 ((1) H) measurements, in combination with density functional theory methods allow the full conformational dynamics of a pyridylmethylamine-Zn(II) complex to be revealed. Four conformers and two families of complexes depending on the hydration states are elucidated.

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Section: Hnmr Schemesmentioning

confidence: 95%

Deciphering the Conformational Choreography of Zinc Coordination Complexes with Standard and Novel Proton NMR Techniques Combined with DFT Methods

et al. 2016

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“…PARISxy consists of a block of m pairs (m = 1 or 2) of phase-alternated pulses [(x)(Àx)] m , followed by a phase-shifted block [(y)(Ày)] m [3]. Each version creates different sets of recoupling bands which allows their complementary use and flexible exploitation over a very broad range of spinning frequencies and static magnetic fields [3][4][5][6]. In the present work, with moderate spinning frequencies 20 < m rot < 30 kHz and a medium static magnetic field of 9.4 T, PARISxy (m = 1) naturally appears to be the method of choice [3].…”

Section: Methodsmentioning

confidence: 99%

“…Magnetization transfer can be brought about either via through-bond scalar couplings or via through-space dipolar interactions, provided the latter are 'recoupled' to cancel their elimination by magic angle spinning (MAS). To promote dipolar recoupling, we developed PARIS [2] and PARISxy [3] methods which permit one to achieve an efficient exchange of magnetization over a wide range of spinning frequencies and static magnetic fields and to record sensitive 2D correlation spectra of microcrystalline proteins [4], amyloid fibrils [5] and mixtures of crystallographic forms [6].…”

Section: Introductionmentioning

confidence: 99%

Restoring symmetry in two-dimensional solid-state NMR correlation spectra

Herbert‐Pucheta

Pelupessy

Bodenhausen

et al. 2012

Chemical Physics Letters

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a b s t r a c tThe intrinsic asymmetry of 2D solid-state homonuclear NMR correlation spectra that arises from a nonuniform preparation of the magnetization can be removed by equilibrating the magnetization in the initial stage of the experiments through dipolar recoupling induced by PARIS or PARISxy schemes. Both methods ensure magnetization exchange with modest radio-frequency amplitudes and permit one to create an initial state that restores the symmetry about the main diagonal of 2D spectra of uniformly labeled biomolecules. This improves the determination of structural and kinetic information. Both recoupling schemes may also be used to record nearly quantitative peak amplitudes in 1D cross-polarization magic-angle-spinning spectra.

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“…PARIS is also largely immune to the inhomogeneity of the rf field, 19 so that the full sample volume effectively contributes to the signal whatever the spinning frequency. Very recently, we used the PARIS approach to record sensitive 2D correlation spectra of a microcrystalline protein, 32 amyloid fibrils, 33 and mixtures of crystallographic forms 34 and to restore the symmetry in 2D correlation experiments. 35 All experiments presented in this part were C correlation spectra of sample A (left) and sample B (right) recorded on a 400 MHz spectrometer by using PARIS recoupling with a proton rf amplitude ν 1H = 15 kHz during a mixing time of 50 ms.…”

Section: Nmr Experiments and Numerical Simulationsmentioning

confidence: 99%

Probing Structural and Motional Features of the C-Terminal Part of the Human Centrin 2/P17-XPC Microcrystalline Complex by Solid-State NMR Spectroscopy

et al. 2012

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Insight into structural and motional features of the Cterminal part of the Human Centrin 2 in complex with the peptide P17-XPC was obtained by using complementary solid-state NMR methods. We demonstrate that the experimental conditions and procedures of sample crystallization determine the quality of solid-state NMR spectra and the internal mobility of the protein. 13 C− 13 C and 15 N− 15 N correlation spectra reveal intra-and inter-residue dipolar connectivities and provide partial, site-specific assignments of 13 C and 15 N resonance signals. The secondary structure of the C-ter HsCen2/P17-XPC complex in a microcrystalline state appears similar to that found in solution. Conformational flexibility is probed through relaxation-compensated measurements of dipolar order parameters that exploit the dynamics of cross-polarization in multidimensional experiments. The extracted dipolar coupling constants and relevant order parameters reveal increased backbone flexibility of the loops except for residues involved in coordination with the Ca 2+ cation that stabilizes the hydrophobic pocket containing the peptide P17-XPC.

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Disentangling Crystallographic Inequivalence and Crystallographic Forms of l-Arginine by One- and Two-Dimensional Solid-State NMR Spectroscopy

Cited by 10 publications

References 27 publications

Deciphering the Conformational Choreography of Zinc Coordination Complexes with Standard and Novel Proton NMR Techniques Combined with DFT Methods

Deciphering the Conformational Choreography of Zinc Coordination Complexes with Standard and Novel Proton NMR Techniques Combined with DFT Methods

Restoring symmetry in two-dimensional solid-state NMR correlation spectra

Probing Structural and Motional Features of the C-Terminal Part of the Human Centrin 2/P17-XPC Microcrystalline Complex by Solid-State NMR Spectroscopy

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