XANES Measurements for Studies of Adsorbed Protein Layers at Liquid Interfaces.

Oleg V Konovalov,Daniil D Vakhrameev,Olga V Kosmachevskaya,Valentin I Borshchevskiy,Sergey N Yakunin,Eleonora A Yurieva,Galina E Yalovega,Mikhail V Kovalchuk,Alexander V Rogachev,Natalia N Novikova,Alexey F Topunov,Maria A Kremennaya,Alexander L Trigub

doi:10.3390/ma13204635

Abstract

X-ray absorption near edge structure (XANES) spectra for protein layers adsorbed at liquid interfaces in a Langmuir trough have been recorded for the first time. We studied the parkin protein (so-called E3 ubiquitin ligase), which plays an important role in pathogenesis of Parkinson disease. Parkin contains eight Zn binding sites, consisting of cysteine and histidine residues in a tetracoordinated geometry. Zn K-edge XANES spectra were collected in the following two series: under mild radiation condition of measurements (short exposition time) and with high X-ray radiation load. XANES fingerprint analysis was applied to obtain information on ligand environments around zinc ions. Two types of zinc coordination geometry were identified depending on X-ray radiation load. We found that, under mild conditions, local zinc environment in our parkin preparations was very similar to that identified in hemoglobin, treated with a solution of ZnCl2 salt. Under high X-ray radiation load, considerable changes in the zinc site structure were observed; local zinc environment appeared to be almost identical to that defined in Zn-containing enzyme alkaline phosphatase. The formation of a similar metal site in unrelated protein molecules, observed in our experiments, highlights the significance of metal binding templates as essential structural modules in protein macromolecules.

Highlights

Two-dimensional arrays of proteins adsorbed at lipid membranes in living organisms have attracted exceptional interest in biomedical studies
All X-ray absorption near edge structure (XANES) data were collected at room temperature (T = 23 °C)
Sealed Langmuir trough was filed with water vapor saturated helium to the air/liquid interface in technique is based on the analysis of angular decrease X-ray scattering on the nitrogen and oxygen contained in the air, and to reduce evaporation

Summary

Introduction

Two-dimensional arrays of proteins adsorbed at lipid membranes in living organisms have attracted exceptional interest in biomedical studies. Various micro- and nanostructures in the cell are organized in such a way that proteins and other biomolecules are either permanently bound to their surfaces, Materials 2020, 13, 4635; doi:10.3390/ma13204635 www.mdpi.com/journal/materials. High precision X-ray techniques have been recognized to be very promising for investigations of two-dimensional bioorganic nanostructures. Are extensively used to study adsorbed protein layers at fluid interfaces [1,2,3]. These techniques do not provide atomically resolved structural information about protein macromolecules

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