Insights on Alanine and Arginine Binding to Silica with Atomic Resolution

Stefan Rauwolf; Saientan Bag; Rodrigo Rouqueiro; Sebastian Patrick Schwaminger; Ana Cristina Dias-Cabral; Sonja Berensmeier; Wolfgang Wenzel

doi:10.1021/acs.jpclett.1c02398

Insights on Alanine and Arginine Binding to Silica with Atomic Resolution

Stefan Rauwolf, Saientan Bag, Rodrigo Rouqueiro, Sebastian Patrick Schwaminger, Ana Cristina Dias-Cabral, Sonja Berensmeier, Wolfgang Wenzel

Chair of Bioseparation Engineering

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

Interactions of biomolecules with inorganic oxide surfaces such as silica in aqueous solutions are of profound interest in various research fields, including chemistry, biotechnology, and medicine. While there is a general understanding of the dominating electrostatic interactions, the binding mechanism is still not fully understood. Here, chromatographic zonal elution and flow microcalorimetry experiments were combined with molecular dynamic simulations to describe the interaction of different capped amino acids with the silica surface. We demonstrate that ion pairing is the dominant electrostatic interaction. Surprisingly, the interaction strength is more dependent on the repulsive carboxy group than on the attracting amino group. These findings are essential for conducting experimental and simulative studies on amino acids when transferring the results to biomolecule-surface interactions.

Original language	English
Pages (from-to)	9384-9390
Number of pages	7
Journal	Journal of Physical Chemistry Letters
Volume	12
Issue number	38
DOIs	https://doi.org/10.1021/acs.jpclett.1c02398
State	Published - 30 Sep 2021

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abstract = "Interactions of biomolecules with inorganic oxide surfaces such as silica in aqueous solutions are of profound interest in various research fields, including chemistry, biotechnology, and medicine. While there is a general understanding of the dominating electrostatic interactions, the binding mechanism is still not fully understood. Here, chromatographic zonal elution and flow microcalorimetry experiments were combined with molecular dynamic simulations to describe the interaction of different capped amino acids with the silica surface. We demonstrate that ion pairing is the dominant electrostatic interaction. Surprisingly, the interaction strength is more dependent on the repulsive carboxy group than on the attracting amino group. These findings are essential for conducting experimental and simulative studies on amino acids when transferring the results to biomolecule-surface interactions.",

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AU - Rauwolf, Stefan

AU - Bag, Saientan

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AU - Dias-Cabral, Ana Cristina

AU - Berensmeier, Sonja

AU - Wenzel, Wolfgang

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AB - Interactions of biomolecules with inorganic oxide surfaces such as silica in aqueous solutions are of profound interest in various research fields, including chemistry, biotechnology, and medicine. While there is a general understanding of the dominating electrostatic interactions, the binding mechanism is still not fully understood. Here, chromatographic zonal elution and flow microcalorimetry experiments were combined with molecular dynamic simulations to describe the interaction of different capped amino acids with the silica surface. We demonstrate that ion pairing is the dominant electrostatic interaction. Surprisingly, the interaction strength is more dependent on the repulsive carboxy group than on the attracting amino group. These findings are essential for conducting experimental and simulative studies on amino acids when transferring the results to biomolecule-surface interactions.

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Insights on Alanine and Arginine Binding to Silica with Atomic Resolution

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