19F Dark-State Exchange Saturation Transfer NMR Reveals Reversible Formation of Protein-Specific Large Clusters in High-Concentration Protein Mixtures

Proteins frequently exist as high-concentration mixtures, both in biological environments and increasingly in biopharmaceutical co-formulations. Such crowded conditions promote protein–protein interactions, potentially leading to formation of protein clusters, aggregation, and phase separation. Char...

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Veröffentlicht in:	Analytical chemistry (Washington) 2019-04, Vol.91 (7), p.4702-4708
Hauptverfasser:	Edwards, John M, Bramham, Jack E, Podmore, Adrian, Bishop, Steven M, van der Walle, Christopher F, Golovanov, Alexander P
Format:	Artikel
Sprache:	eng
Schlagworte:	Additives Analytical chemistry Arginine Biopharmaceuticals Chemistry Clustering Exchanging Formulations Heterogeneity Monoclonal antibodies NMR Nuclear magnetic resonance Phase separation Populations Protein interaction Proteins Saturation Sodium chloride Temperature dependence
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container_title	Analytical chemistry (Washington)
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creator	Edwards, John M Bramham, Jack E Podmore, Adrian Bishop, Steven M van der Walle, Christopher F Golovanov, Alexander P
description	Proteins frequently exist as high-concentration mixtures, both in biological environments and increasingly in biopharmaceutical co-formulations. Such crowded conditions promote protein–protein interactions, potentially leading to formation of protein clusters, aggregation, and phase separation. Characterizing these interactions and processes in situ in high-concentration mixtures is challenging due to the complexity and heterogeneity of such systems. Here we demonstrate the application of the dark-state exchange saturation transfer (DEST) NMR technique to a mixture of two differentially 19F-labeled 145 kDa monoclonal antibodies (mAbs) to assess reversible temperature-dependent formation of small and large protein-specific clusters at concentrations up to 400 mg/mL. 19F DEST allowed quantitative protein-specific characterization of the cluster populations and sizes for both mAbs in the mixture under a range of conditions. Additives such as arginine glutamate and NaCl also had protein-specific effects on the dark-state populations and cluster characteristics. Notably, both mAbs appear to largely exist as separate self-associated clusters, which mechanistically respond differently to changes in solution conditions. We show that for mixtures of differentially 19F-labeled proteins DEST NMR can characterize clustering in a protein-specific manner, offering unique tracking of clustering pathways and a means to understand and control them.
doi_str_mv	10.1021/acs.analchem.9b00143
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subjects	Additives Analytical chemistry Arginine Biopharmaceuticals Chemistry Clustering Exchanging Formulations Heterogeneity Monoclonal antibodies NMR Nuclear magnetic resonance Phase separation Populations Protein interaction Proteins Saturation Sodium chloride Temperature dependence
title	19F Dark-State Exchange Saturation Transfer NMR Reveals Reversible Formation of Protein-Specific Large Clusters in High-Concentration Protein Mixtures
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