The unexpected structure of the designed protein Octarellin V.1 forms a challenge for protein structure prediction tools

Maximiliano Figueroa, Mike Sleutel, Marylene Vandevenne, Gregory Parvizi, Sophie Attout, Olivier Jacquin, Julie Vandenameele, Axel W. Fischer, Christian Damblon, Erik Goormaghtigh, Marie Valerio-Lepiniec, Agathe Urvoas, Dominique Durand, Els Pardon, Jan Steyaert, Philippe Minard, Dominique Maes, Jens Meiler, Andre Matagne, Joseph A. MartialCecile Van de Weerdt

Research output: Contribution to journalArticlepeer-review

13 Citations (Scopus)
443 Downloads (Pure)

Abstract

Despite impressive successes in protein design, designing a well-folded protein of more 100 amino acids de novo remains a formidable challenge. Exploiting the promising biophysical features of the artificial protein Octarellin V, we improved this protein by directed evolution, thus creating a more stable and soluble protein: Octarellin V.1. Next, we obtained crystals of Octarellin V.1 in complex with crystallization chaperons and determined the tertiary structure. The experimental structure of Octarellin V.1 differs from its in silico design: the (αβα) sandwich architecture bears some resemblance to a Rossman-like fold instead of the intended TIM-barrel fold. This surprising result gave us a unique and attractive opportunity to test the state of the art in protein structure prediction, using this artificial protein free of any natural selection. We tested 13 automated webservers for protein structure prediction and found none of them to predict the actual structure. More than 50% of them predicted a TIM-barrel fold, i.e. the structure we set out to design more than 10 years ago. In addition, local software runs that are human operated can sample a structure similar to the experimental one but fail in selecting it, suggesting that the scoring and ranking functions should be improved. We propose that artificial proteins could be used as tools to test the accuracy of protein structure prediction algorithms, because their lack of evolutionary pressure and unique sequences features.
Original languageEnglish
Pages (from-to)19-30
JournalJournal of Structural Biology
Volume195
Issue number1
DOIs
Publication statusPublished - Jul 2016

Keywords

  • De novo design
  • Artificial proteins
  • Protein design
  • Molecular modeling

Fingerprint

Dive into the research topics of 'The unexpected structure of the designed protein Octarellin V.1 forms a challenge for protein structure prediction tools'. Together they form a unique fingerprint.

Cite this