Journal
STRUCTURE
Volume 20, Issue 1, Pages 161-171Publisher
CELL PRESS
DOI: 10.1016/j.str.2011.10.021
Keywords
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Funding
- National Science and Engineering Council (NSERC)
- Canadian Institutes of Health Research (CIHR) [43998]
- NSERC Canada
- Canada Research Chair
- National Institute of General Medical Sciences [GM62116]
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The high frequency of internal structural symmetry in common protein folds is presumed to reflect their evolutionary origins from the repetition and fusion of ancient peptide modules, but little is known about the primary sequence and physical determinants of this process. Unexpectedly, a sequence and structural analysis of symmetric subdomain modules within an abundant and ancient globular fold, the beta-trefoil, reveals that modular evolution is not simply a relic of the ancient past, but is an ongoing and recurring mechanism for regenerating symmetry, having occurred independently in numerous existing beta-trefoil proteins. We performed a computational reconstruction of a beta-trefoil subdomain module and repeated it to form a newly three-fold symmetric globular protein, Three Foil. In addition to its near perfect structural identity between symmetric modules, Three Foil is highly soluble, performs multivalent carbohydrate binding, and has remarkably high thermal stability. These findings have far-reaching implications for understanding the evolution and design of proteins via subdomain modules.
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