Quantitative analysis of the self-assembly strategies of intermediate filaments from tetrameric vimentin

A1 Journal article (refereed)


Internal Authors/Editors


Publication Details

List of Authors: Czeizler E, Mizera A, Czeizler E, Back RJ, Eriksson JE, Petre I
Publisher: Institute of Electrical and Electronics Engineers
Publication year: 2000
Journal: IEEE/ACM Transactions on Computational Biology and Bioinformatics
Journal acronym: IEEE/ACM Trans Comput Biol Bioinform
Volume number: 9
Issue number: 3
Start page: 885
End page: 898
ISSN: 1557-9964


Abstract

In vitro assembly of intermediate filaments from tetrameric vimentin consists of a very rapid phase of tetramers laterally associating into unit-length filaments and a slow phase of filament elongation. We focus in this paper on a systematic quantitative investigation of two molecular models for filament assembly, recently proposed in (Kirmse et al. J. Biol. Chem. 282, 52 (2007), 18563-18572), through mathematical modeling, model fitting, and model validation. We analyze the quantitative contribution of each filament elongation strategy: with tetramers, with unit-length filaments, with longer filaments, or combinations thereof. In each case, we discuss the numerical fitting of the model with respect to one set of data, and its separate validation with respect to a second, different set of data. We introduce a high-resolution model for vimentin filament self-assembly, able to capture the detailed dynamics of filaments of arbitrary length. This provides much more predictive power for the model, in comparison to previous models where only the mean length of all filaments in the solution could be analyzed. We show how kinetic observations on low-resolution models can be extrapolated to the high-resolution model and used for lowering its complexity.

Last updated on 2019-19-10 at 02:19