Abstract
The ability to control the morphologies of biomolecular aggregates is a central objective in the study of self-assembly processes. The development of predictive models offers the surest route for gaining such control. Under the right conditions, proteins will self-assemble into fibers that may rearrange themselves even further to form diverse structures, including the formation of closed loops. In this study, chicken egg white ovalbumin is used as a model for the study of fibril loops. By monitoring the kinetics of self-assembly, we demonstrate that loop formation is a consequence of end-to-end association between protein fibrils. A model of fibril formation kinetics, including end-joining, is developed and solved, showing that end-joining has a distinct effect on the growth of fibrillar mass density (which can be measured experimentally), establishing a link between self-assembly kinetics and the underlying growth mechanism. These results will enable experimentalists to infer fibrillar morphologies from an appropriate analysis of self-assembly kinetic data.
Original language | English |
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Pages (from-to) | 2300-2311 |
Number of pages | 12 |
Journal | BIOPHYSICAL JOURNAL |
Volume | 108 |
Issue number | 9 |
DOIs | |
Publication status | Published - 2015 |
Keywords
- apolipoprotein-c-ii
- amyloid fibril
- alpha-synuclein
- in-vitro
- proteins
- disease
- pathway
- ribbons
- fibrillization
- crystallin