Recognition and architecture of the framework structure of protein

We examine a simple kinetic model for association that incorporates the basic features of protein-protein recognition within the rigid body approximation, that is, when no large conformation change occurs. Association starts with random collision at the rate k coll predicted by the Einstein-Smolucho

An alpha/beta barrel is predicted for the three-dimensional (3D) structure of Bacillus subtilis ferrochelatase. To arrive at this structure, the THREADER program was used to find possible homologous 3D structures and to predict the secondary structure for the ferrochelatase sequence. The secondary s

Protein structure prediction is arguably the biggest unsolved problem of structural biology. The notion of the number of naturally occurring different protein folds being limited allows partial solution of this problem by the use of fold recognition methods, which ''thread'' the sequence in question

## Abstract α‐Helical membrane proteins exist in an anisotropic environment which strongly influences their folding, stability, and architecture, which is far more complex than a simple bundle of transmembrane helices, notably due to helix deformations, prosthetic groups and extramembrane structure

## Abstract Classical descriptions of the three‐dimensional shapes of proteins usually invoke three main structures: α‐helix, β‐sheet, and β‐turn. More recently, the polyproline II (PPII) structure has been implicated in diverse biological activities including signal transduction, transcription, ce