A modified Stokes-Einstein equation for A<it>β</it> aggregation

<p>Abstract</p> <p>Background</p> <p>In all amyloid diseases, protein aggregates have been implicated fully or partly, in the etiology of the disease. Due to their significance in human pathologies, there have been unprecedented efforts towards physiochemical understand...

Full description

Bibliographic Details
Main Authors: Rangachari Vijayaraghavan, Ghosh Preetam, Chung Bong, Achuthan Srisairam, Vaidya Ashwin
Format: Article
Language:English
Published: BMC 2011-10-01
Series:BMC Bioinformatics
id doaj-f37d16c0651f4285bc3ba311ffa3d51a
record_format Article
spelling doaj-f37d16c0651f4285bc3ba311ffa3d51a2020-11-25T02:13:58ZengBMCBMC Bioinformatics1471-21052011-10-0112Suppl 10S1310.1186/1471-2105-12-S10-S13A modified Stokes-Einstein equation for A<it>β</it> aggregationRangachari VijayaraghavanGhosh PreetamChung BongAchuthan SrisairamVaidya Ashwin<p>Abstract</p> <p>Background</p> <p>In all amyloid diseases, protein aggregates have been implicated fully or partly, in the etiology of the disease. Due to their significance in human pathologies, there have been unprecedented efforts towards physiochemical understanding of aggregation and amyloid formation over the last two decades. An important relation from which hydrodynamic radii of the aggregate is routinely measured is the classic Stokes-Einstein equation. Here, we report a modification in the classical Stokes-Einstein equation using a mixture theory approach, in order to accommodate the changes in viscosity of the solvent due to the changes in solute size and shape, to implement a more realistic model for A<it>β</it> aggregation involved in Alzheimer’s disease. Specifically, we have focused on validating this model in protofibrill lateral association reactions along the aggregation pathway, which has been experimentally well characterized.</p> <p>Results</p> <p>The modified Stokes-Einstein equation incorporates an effective viscosity for the mixture consisting of the macromolecules and solvent where the lateral association reaction occurs. This effective viscosity is modeled as a function of the volume fractions of the different species of molecules. The novelty of our model is that in addition to the volume fractions, it incorporates previously published reports on the dimensions of the protofibrils and their aggregates to formulate a more appropriate shape rather than mere spheres. The net result is that the diffusion coefficient which is inversely proportional to the viscosity of the system is now dependent on the concentration of the different molecules as well as their proper shapes. Comparison with experiments for variations in diffusion coefficients over time reveals very similar trends.</p> <p>Conclusions</p> <p>We argue that the standard Stokes-Einstein’s equation is insufficient to understand the temporal variations in diffusion when trying to understand the aggregation behavior of A<it>β</it>42 proteins. Our modifications also involve inclusion of improved shape factors of molecules and more appropriate viscosities. The modification we are reporting is not only useful in A<it>β</it> aggregation but also will be important for accurate measurements in all protein aggregation systems.</p>
collection DOAJ
language English
format Article
sources DOAJ
author Rangachari Vijayaraghavan
Ghosh Preetam
Chung Bong
Achuthan Srisairam
Vaidya Ashwin
spellingShingle Rangachari Vijayaraghavan
Ghosh Preetam
Chung Bong
Achuthan Srisairam
Vaidya Ashwin
A modified Stokes-Einstein equation for A<it>β</it> aggregation
BMC Bioinformatics
author_facet Rangachari Vijayaraghavan
Ghosh Preetam
Chung Bong
Achuthan Srisairam
Vaidya Ashwin
author_sort Rangachari Vijayaraghavan
title A modified Stokes-Einstein equation for A<it>β</it> aggregation
title_short A modified Stokes-Einstein equation for A<it>β</it> aggregation
title_full A modified Stokes-Einstein equation for A<it>β</it> aggregation
title_fullStr A modified Stokes-Einstein equation for A<it>β</it> aggregation
title_full_unstemmed A modified Stokes-Einstein equation for A<it>β</it> aggregation
title_sort modified stokes-einstein equation for a<it>β</it> aggregation
publisher BMC
series BMC Bioinformatics
issn 1471-2105
publishDate 2011-10-01
description <p>Abstract</p> <p>Background</p> <p>In all amyloid diseases, protein aggregates have been implicated fully or partly, in the etiology of the disease. Due to their significance in human pathologies, there have been unprecedented efforts towards physiochemical understanding of aggregation and amyloid formation over the last two decades. An important relation from which hydrodynamic radii of the aggregate is routinely measured is the classic Stokes-Einstein equation. Here, we report a modification in the classical Stokes-Einstein equation using a mixture theory approach, in order to accommodate the changes in viscosity of the solvent due to the changes in solute size and shape, to implement a more realistic model for A<it>β</it> aggregation involved in Alzheimer’s disease. Specifically, we have focused on validating this model in protofibrill lateral association reactions along the aggregation pathway, which has been experimentally well characterized.</p> <p>Results</p> <p>The modified Stokes-Einstein equation incorporates an effective viscosity for the mixture consisting of the macromolecules and solvent where the lateral association reaction occurs. This effective viscosity is modeled as a function of the volume fractions of the different species of molecules. The novelty of our model is that in addition to the volume fractions, it incorporates previously published reports on the dimensions of the protofibrils and their aggregates to formulate a more appropriate shape rather than mere spheres. The net result is that the diffusion coefficient which is inversely proportional to the viscosity of the system is now dependent on the concentration of the different molecules as well as their proper shapes. Comparison with experiments for variations in diffusion coefficients over time reveals very similar trends.</p> <p>Conclusions</p> <p>We argue that the standard Stokes-Einstein’s equation is insufficient to understand the temporal variations in diffusion when trying to understand the aggregation behavior of A<it>β</it>42 proteins. Our modifications also involve inclusion of improved shape factors of molecules and more appropriate viscosities. The modification we are reporting is not only useful in A<it>β</it> aggregation but also will be important for accurate measurements in all protein aggregation systems.</p>
work_keys_str_mv AT rangacharivijayaraghavan amodifiedstokeseinsteinequationforaitbitaggregation
AT ghoshpreetam amodifiedstokeseinsteinequationforaitbitaggregation
AT chungbong amodifiedstokeseinsteinequationforaitbitaggregation
AT achuthansrisairam amodifiedstokeseinsteinequationforaitbitaggregation
AT vaidyaashwin amodifiedstokeseinsteinequationforaitbitaggregation
AT rangacharivijayaraghavan modifiedstokeseinsteinequationforaitbitaggregation
AT ghoshpreetam modifiedstokeseinsteinequationforaitbitaggregation
AT chungbong modifiedstokeseinsteinequationforaitbitaggregation
AT achuthansrisairam modifiedstokeseinsteinequationforaitbitaggregation
AT vaidyaashwin modifiedstokeseinsteinequationforaitbitaggregation
_version_ 1724902893087096832