Water dynamics and stability of major blood proteins  at pre-denaturation stage

Natalia Atamas; Vitalii Y. Bardik; Serhiy Komisarenko; Yevgen M. Makogonenko; Edward V. Lugovskoi; Nikolai P. Malomuzh; Dmitry A. Nerukh; Pavlo K. Solonin

doi:10.1478/AAPP.97S2A16

Water dynamics and stability of major blood proteins at pre-denaturation stage

Authors

Natalia Atamas Kiev Taras Shevchenko National University, Pr. Gluskova 4, Kiev 03127
Vitalii Y. Bardik Kiev Taras Shevchenko National University, Pr. Gluskova 4, Kiev 03127
Serhiy Komisarenko Palladin Institute of Biochemistry, Leontovicha 9, Kyiv 01601
Yevgen M. Makogonenko Palladin Institute of Biochemistry, Leontovicha 9, Kyiv 01601
Edward V. Lugovskoi Palladin Institute of Biochemistry, Leontovicha 9, Kyiv 01601
Nikolai P. Malomuzh Odessa Mechnikov National University, Dvoryanskaya str. 2, Odessa 65026
Dmitry A. Nerukh Systems Analytics Research Institute Department of Mathematics, Aston University, Birmingham B4 7ET
Pavlo K. Solonin National University of Life and Environmental Sciences of Ukraine, Heroiv Oborony Str. 16 16, Kiev 03014

DOI:

https://doi.org/10.1478/AAPP.97S2A16

Keywords:

photon correlation spectroscopy, hydrogen bonds, molecular dynamics, albumin, fibrinogen

Abstract

We investigate the temperature effect on the size and stability of two major blood plasma proteins, human serum albumin and fibrinogen in aqueous NaCl solution. Dynamic Light Scattering measurements were carried out in the physiological temperature range up to 45^°C. The analysis of the results provided the temperature dependences of the macromolecular hydrodynamic radius and the ζ -potential. For albumin the hydrodynamic radius remained unchanged, while the ζ -potential increased sharply at approximately 40^°C. For fibrinogen the radius increased significantly above 45^°C and the ζ -potential increased similar to albumin at slightly below 40^°C. The dynamics of albumin macromolecule was simulated using classical Molecular Dynamics, which showed no change in the gyration radius, root mean square deviation, and the composition of disulfide and salt bridges, but substantial change in the secondary structure of the protein. We conclude that these changes in the structure and dynamics of the proteins are correlated with the qualitative change of water dynamics at 42^°C in the hydration shell of the proteins.

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Published

2019-12-20

Issue

Vol 97, SUPPL NO 2 (2019): NACS 2017

Section

NACS 2017 (Conference Proceedings)

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