Evolution of protein fold in the presence of functional constraints
A Andreeva, AG Murzin - Current opinion in structural biology, 2006 - Elsevier
A Andreeva, AG Murzin
Current opinion in structural biology, 2006•ElsevierThe functional requirement to form and maintain the active site structure probably exerts a
strong selective pressure on a protein to adopt just one stable and evolutionarily conserved
fold. Nonetheless, new evidence suggests the likelihood of protein fold being neither
physically nor biologically invariant. Alternative folds discovered in several proteins are
composed of constant and variable parts. The latter display context-dependent
conformations and a tendency to form new oligomeric interfaces. In turn, oligomerisation …
strong selective pressure on a protein to adopt just one stable and evolutionarily conserved
fold. Nonetheless, new evidence suggests the likelihood of protein fold being neither
physically nor biologically invariant. Alternative folds discovered in several proteins are
composed of constant and variable parts. The latter display context-dependent
conformations and a tendency to form new oligomeric interfaces. In turn, oligomerisation …
The functional requirement to form and maintain the active site structure probably exerts a strong selective pressure on a protein to adopt just one stable and evolutionarily conserved fold. Nonetheless, new evidence suggests the likelihood of protein fold being neither physically nor biologically invariant. Alternative folds discovered in several proteins are composed of constant and variable parts. The latter display context-dependent conformations and a tendency to form new oligomeric interfaces. In turn, oligomerisation mediates fold evolution without loss of protein function. Gene duplication breaks down homo-oligomeric symmetry and relieves the pressure to maintain the local architecture of redundant active sites; this can lead to further structural changes.
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