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Quantitative analysis of 2D EXSY NMR spectra of strongly coupled spin systems in transmembrane exchange

Quantitative analysis of 2D EXSY NMR spectra of strongly coupled spin systems in transmembrane exchange
Quantitative analysis of 2D EXSY NMR spectra of strongly coupled spin systems in transmembrane exchange

Solute translocation by membrane transport proteins is a vital biological process that can be tracked, on the sub-second timescale, using nuclear magnetic resonance (NMR). Fluorinated substrate analogues facilitate such studies because of high sensitivity of 19F NMR and absence of background signals. Accurate extraction of translocation rate constants requires precise quantification of NMR signal intensities. This becomes complicated in the presence of J-couplings, cross-correlations, and nuclear Overhauser effects (NOE) that alter signal integrals through mechanisms unrelated to translocation. Geminal difluorinated motifs introduce strong and hard-to-quantify contributions from non-exchange effects, the nuanced nature of which makes them hard to integrate into data analysis methodologies. With analytical expressions not being available, numerical least squares fitting of theoretical models to 2D spectra emerges as the preferred quantification approach. For large spin systems with simultaneous coherent evolution, cross-relaxation, cross-correlation, conformational exchange, and membrane translocation between compartments with different viscosities, the only available simulation framework is Spinach. In this study, we demonstrate GLUT-1 dependent membrane transport of two model sugars featuring CF2 and CF2CF2 fluorination motifs, with precise determination of translocation rate constants enabled by numerical fitting of 2D EXSY spectra. For spin systems and kinetic networks of this complexity, this was not previously tractable.

exchange spectroscopy, GLUT-1, human erythrocyte, nuclear magnetic resonance, polyfluorinated sugar, Spinach
1439-4227
e202300597
Shishmarev, Dmitry
11bac3f9-42c3-42ba-b3d1-e5fc06365580
Fontenelle, Clement Q.
c746c5ea-96bc-46c2-849d-47215ab58c03
Linclau, Bruno
19b9cacd-b8e8-4c65-af36-6352cade84ba
Kuprov, Ilya
bb07f28a-5038-4524-8146-e3fc8344c065
Kuchel, Philip W.
62f434b1-d370-4552-85f4-05b76c625945
Shishmarev, Dmitry
11bac3f9-42c3-42ba-b3d1-e5fc06365580
Fontenelle, Clement Q.
c746c5ea-96bc-46c2-849d-47215ab58c03
Linclau, Bruno
19b9cacd-b8e8-4c65-af36-6352cade84ba
Kuprov, Ilya
bb07f28a-5038-4524-8146-e3fc8344c065
Kuchel, Philip W.
62f434b1-d370-4552-85f4-05b76c625945

Shishmarev, Dmitry, Fontenelle, Clement Q., Linclau, Bruno, Kuprov, Ilya and Kuchel, Philip W. (2023) Quantitative analysis of 2D EXSY NMR spectra of strongly coupled spin systems in transmembrane exchange. ChemBioChem, e202300597. (doi:10.1002/cbic.202300597).

Record type: Article

Abstract

Solute translocation by membrane transport proteins is a vital biological process that can be tracked, on the sub-second timescale, using nuclear magnetic resonance (NMR). Fluorinated substrate analogues facilitate such studies because of high sensitivity of 19F NMR and absence of background signals. Accurate extraction of translocation rate constants requires precise quantification of NMR signal intensities. This becomes complicated in the presence of J-couplings, cross-correlations, and nuclear Overhauser effects (NOE) that alter signal integrals through mechanisms unrelated to translocation. Geminal difluorinated motifs introduce strong and hard-to-quantify contributions from non-exchange effects, the nuanced nature of which makes them hard to integrate into data analysis methodologies. With analytical expressions not being available, numerical least squares fitting of theoretical models to 2D spectra emerges as the preferred quantification approach. For large spin systems with simultaneous coherent evolution, cross-relaxation, cross-correlation, conformational exchange, and membrane translocation between compartments with different viscosities, the only available simulation framework is Spinach. In this study, we demonstrate GLUT-1 dependent membrane transport of two model sugars featuring CF2 and CF2CF2 fluorination motifs, with precise determination of translocation rate constants enabled by numerical fitting of 2D EXSY spectra. For spin systems and kinetic networks of this complexity, this was not previously tractable.

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Accepted/In Press date: 20 November 2023
e-pub ahead of print date: 20 November 2023
Additional Information: Funding Information: . The work was funded by a grant from the Leverhulme Trust (RPG‐2015‐211), from the National Health and Medical Research Council of Australia (GNT1173015), and from the Australian Research Council (DP140102596). B. L. thanks the EPSRC for core capability grant (EP/K039466/1) and the Research Foundation Flanders (FWO, Belgium) for an Odysseus Type I grant (G0F5621 N). P. W. K. and D. S. thank Drs Ian Luck, Ann Kwan, and Biswaranjan Mohanty for the maintenance of the 400 MHz NMR spectrometer that is part of the resources of Sydney Analytical. This work was supported by EPSRC (EP/W020343/1) and MathWorks, and used NVIDIA Tesla A100 GPUs through NVIDIA Academic Grants Programme. The authors acknowledge the use of the IRIDIS High Performance Computing Facility, and associated support services at the University of Southampton, in the completion of this work. Open Access publishing facilitated by The University of Sydney, as part of the Wiley ‐ The University of Sydney agreement via the Council of Australian University Librarians Publisher Copyright: © 2023 The Authors. ChemBioChem published by Wiley-VCH GmbH.
Keywords: exchange spectroscopy, GLUT-1, human erythrocyte, nuclear magnetic resonance, polyfluorinated sugar, Spinach

Identifiers

Local EPrints ID: 486042
URI: http://eprints.soton.ac.uk/id/eprint/486042
ISSN: 1439-4227
PURE UUID: 367147aa-7c1b-4f85-a435-47f0de064f97
ORCID for Clement Q. Fontenelle: ORCID iD orcid.org/0000-0002-1630-3407
ORCID for Bruno Linclau: ORCID iD orcid.org/0000-0001-8762-0170
ORCID for Ilya Kuprov: ORCID iD orcid.org/0000-0003-0430-2682

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Date deposited: 08 Jan 2024 17:32
Last modified: 18 Mar 2024 03:22

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Contributors

Author: Dmitry Shishmarev
Author: Clement Q. Fontenelle ORCID iD
Author: Bruno Linclau ORCID iD
Author: Ilya Kuprov ORCID iD
Author: Philip W. Kuchel

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