Oligomerization of a symmetric β‐trefoil protein in response to folding nucleus perturbation

Gene duplication and fusion events in protein evolution are postulated to be responsible for the common protein folds exhibiting internal rotational symmetry. Such evolutionary processes can also potentially yield regions of repetitive primary structure. Repetitive primary structure offers the poten...

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Bibliographic Details
Published in:Protein science 2020-07, Vol.29 (7), p.1629-1640
Main Authors: Tenorio, Connie A., Parker, Joseph B., Blaber, Michael
Format: Article
Language:English
Subjects:
Amino acid sequence
Crystallography, X-Ray
domain‐swapping
Evolution, Molecular
Folding
folding pathway
Full‐length Papers
Fusion protein
Gene Duplication
Models, Molecular
Mutation
Oligomerization
Perturbation
protein evolution
Protein Folding
Protein Multimerization
Protein Structure, Quaternary
protein symmetry
Proteins
Symmetry
Trefoil Factors - chemistry
Trefoil Factors - genetics
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Summary:Gene duplication and fusion events in protein evolution are postulated to be responsible for the common protein folds exhibiting internal rotational symmetry. Such evolutionary processes can also potentially yield regions of repetitive primary structure. Repetitive primary structure offers the potential for alternative definitions of critical regions, such as the folding nucleus (FN). In principle, more than one instance of the FN potentially enables an alternative folding pathway in the face of a subsequent deleterious mutation. We describe the targeted mutation of the carboxyl‐terminal region of the (internally located) FN of the de novo designed purely‐symmetric β‐trefoil protein Symfoil‐4P. This mutation involves wholesale replacement of a repeating trefoil‐fold motif with a “blade” motif from a β‐propeller protein, and postulated to trap that region of the Symfoil‐4P FN in a nonproductive folding intermediate. The resulting protein (termed “Bladefoil”) is shown to be cooperatively folding, but as a trimeric oligomer. The results illustrate how symmetric protein architectures have potentially diverse folding alternatives available to them, including oligomerization, when preferred pathways are perturbed.
ISSN:0961-8368
1469-896X
DOI:10.1002/pro.3877