Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery

[Image: see text] High hit rates from initial ligand-observed NMR screening can make it challenging to prioritize which hits to follow up, especially in cases where there are no available crystal structures of these hits bound to the target proteins or other strategies to provide affinity ranking. H...

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Autores principales: Liu, Manjuan, Mirza, Amin, McAndrew, P. Craig, Thapaliya, Arjun, Pierrat, Olivier A., Stubbs, Mark, Hahner, Tamas, Chessum, Nicola E. A., Innocenti, Paolo, Caldwell, John, Cheeseman, Matthew D., Bellenie, Benjamin R., van Montfort, Rob L. M., Newton, Gary K., Burke, Rosemary, Collins, Ian, Hoelder, Swen
Formato: Online Artículo Texto
Lenguaje:English
Publicado: American Chemical Society 2023
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10424183/
https://www.ncbi.nlm.nih.gov/pubmed/37467168
http://dx.doi.org/10.1021/acs.jmedchem.3c00758
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author Liu, Manjuan
Mirza, Amin
McAndrew, P. Craig
Thapaliya, Arjun
Pierrat, Olivier A.
Stubbs, Mark
Hahner, Tamas
Chessum, Nicola E. A.
Innocenti, Paolo
Caldwell, John
Cheeseman, Matthew D.
Bellenie, Benjamin R.
van Montfort, Rob L. M.
Newton, Gary K.
Burke, Rosemary
Collins, Ian
Hoelder, Swen
author_facet Liu, Manjuan
Mirza, Amin
McAndrew, P. Craig
Thapaliya, Arjun
Pierrat, Olivier A.
Stubbs, Mark
Hahner, Tamas
Chessum, Nicola E. A.
Innocenti, Paolo
Caldwell, John
Cheeseman, Matthew D.
Bellenie, Benjamin R.
van Montfort, Rob L. M.
Newton, Gary K.
Burke, Rosemary
Collins, Ian
Hoelder, Swen
author_sort Liu, Manjuan
collection PubMed
description [Image: see text] High hit rates from initial ligand-observed NMR screening can make it challenging to prioritize which hits to follow up, especially in cases where there are no available crystal structures of these hits bound to the target proteins or other strategies to provide affinity ranking. Here, we report a reproducible, accurate, and versatile quantitative ligand-observed NMR assay, which can determine K(d) values of fragments in the affinity range of low μM to low mM using transverse relaxation rate R(2) as the observable parameter. In this study, we examined the theory and proposed a mathematical formulation to obtain K(d) values using non-linear regression analysis. We designed an assay format with automated sample preparation and simplified data analysis. Using tool compounds, we explored the assay reproducibility, accuracy, and detection limits. Finally, we used this assay to triage fragment hits, yielded from fragment screening against the CRBN/DDB1 complex.
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spelling pubmed-104241832023-08-15 Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery Liu, Manjuan Mirza, Amin McAndrew, P. Craig Thapaliya, Arjun Pierrat, Olivier A. Stubbs, Mark Hahner, Tamas Chessum, Nicola E. A. Innocenti, Paolo Caldwell, John Cheeseman, Matthew D. Bellenie, Benjamin R. van Montfort, Rob L. M. Newton, Gary K. Burke, Rosemary Collins, Ian Hoelder, Swen J Med Chem [Image: see text] High hit rates from initial ligand-observed NMR screening can make it challenging to prioritize which hits to follow up, especially in cases where there are no available crystal structures of these hits bound to the target proteins or other strategies to provide affinity ranking. Here, we report a reproducible, accurate, and versatile quantitative ligand-observed NMR assay, which can determine K(d) values of fragments in the affinity range of low μM to low mM using transverse relaxation rate R(2) as the observable parameter. In this study, we examined the theory and proposed a mathematical formulation to obtain K(d) values using non-linear regression analysis. We designed an assay format with automated sample preparation and simplified data analysis. Using tool compounds, we explored the assay reproducibility, accuracy, and detection limits. Finally, we used this assay to triage fragment hits, yielded from fragment screening against the CRBN/DDB1 complex. American Chemical Society 2023-07-19 /pmc/articles/PMC10424183/ /pubmed/37467168 http://dx.doi.org/10.1021/acs.jmedchem.3c00758 Text en © 2023 The Authors. Published by American Chemical Society https://creativecommons.org/licenses/by/4.0/Permits the broadest form of re-use including for commercial purposes, provided that author attribution and integrity are maintained (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Liu, Manjuan
Mirza, Amin
McAndrew, P. Craig
Thapaliya, Arjun
Pierrat, Olivier A.
Stubbs, Mark
Hahner, Tamas
Chessum, Nicola E. A.
Innocenti, Paolo
Caldwell, John
Cheeseman, Matthew D.
Bellenie, Benjamin R.
van Montfort, Rob L. M.
Newton, Gary K.
Burke, Rosemary
Collins, Ian
Hoelder, Swen
Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery
title Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery
title_full Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery
title_fullStr Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery
title_full_unstemmed Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery
title_short Determination of Ligand-Binding Affinity (K(d)) Using Transverse Relaxation Rate (R(2)) in the Ligand-Observed (1)H NMR Experiment and Applications to Fragment-Based Drug Discovery
title_sort determination of ligand-binding affinity (k(d)) using transverse relaxation rate (r(2)) in the ligand-observed (1)h nmr experiment and applications to fragment-based drug discovery
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10424183/
https://www.ncbi.nlm.nih.gov/pubmed/37467168
http://dx.doi.org/10.1021/acs.jmedchem.3c00758
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