AbstractProteins can aggregate in a wide variety of structures, both compact and extended. We present simulations of a coarse-grained anisotropic model that reproduce many of the experimentally observed aggregate structures. Conversely, all structures predicted by our model have experimental counterparts (ribbons, multistranded fibrils, and vesicles). The model we use is that of a rodlike particle with an attractive (hydrophobic) stripe on its side. Our Monte Carlo simulations show that aggregate morphologies crucially depend on two parameters. The first one is the width of the attractive stripe and the second one is a presence or absence of attractive interactions at the particle ends. These results provide us with a generic insight into t...
This work describes the development and application of computational models for the investigation of...
We have simulated the structure of kinetically irreversible protein aggregates in two-dimensional sp...
In nature, self-assembly occurs on all scales. We try to understand such processes so that we can, f...
AbstractProteins can aggregate in a wide variety of structures, both compact and extended. We presen...
Self-assembly of proteins into ordered, fibrilar structures is a commonly observed theme in biology....
Effectively coarse-graining particle shape is crucial to extending the time and length scales access...
We simulated the structure of reversible protein aggregates as a function of protein surface charact...
We explore the applicability of a single-bead coarse-grained molecular model to describe the competi...
Protein aggregation is often studied in the context of neurodegenerative diseases. Deposits of supra...
Self-assembly of proteins into ordered, fibrillar structures is a commonly observed theme in biology...
The huge computational expense of atomistic simulations of protein-protein interactions and the lack...
[Figurre: see text]. Protein aggregation can be defined as the sacrifice of stabilizing intrachain c...
Multi-scale aggregation to network formation of interacting proteins (H3.1) are examined by a knowle...
Protein aggregation involves self-assembly of normally soluble proteins or peptides into supramolecu...
AbstractDepending on external conditions, native proteins may change their structure and undergo dif...
This work describes the development and application of computational models for the investigation of...
We have simulated the structure of kinetically irreversible protein aggregates in two-dimensional sp...
In nature, self-assembly occurs on all scales. We try to understand such processes so that we can, f...
AbstractProteins can aggregate in a wide variety of structures, both compact and extended. We presen...
Self-assembly of proteins into ordered, fibrilar structures is a commonly observed theme in biology....
Effectively coarse-graining particle shape is crucial to extending the time and length scales access...
We simulated the structure of reversible protein aggregates as a function of protein surface charact...
We explore the applicability of a single-bead coarse-grained molecular model to describe the competi...
Protein aggregation is often studied in the context of neurodegenerative diseases. Deposits of supra...
Self-assembly of proteins into ordered, fibrillar structures is a commonly observed theme in biology...
The huge computational expense of atomistic simulations of protein-protein interactions and the lack...
[Figurre: see text]. Protein aggregation can be defined as the sacrifice of stabilizing intrachain c...
Multi-scale aggregation to network formation of interacting proteins (H3.1) are examined by a knowle...
Protein aggregation involves self-assembly of normally soluble proteins or peptides into supramolecu...
AbstractDepending on external conditions, native proteins may change their structure and undergo dif...
This work describes the development and application of computational models for the investigation of...
We have simulated the structure of kinetically irreversible protein aggregates in two-dimensional sp...
In nature, self-assembly occurs on all scales. We try to understand such processes so that we can, f...