Litcius/Paper detail

Physics-based approach to extend a <i>de novo</i> TIM barrel with rationally designed helix-loop-helix motifs

Sina Kordes, Julian Beck, S. Shanmugaratnam, Merle Flecks, Birte Höcker

2023Protein Engineering Design and Selection10 citationsDOI

Abstract

Computational protein design promises the ability to build tailor-made proteins de novo. While a range of de novo proteins have been constructed so far, the majority of these designs have idealized topologies that lack larger cavities which are necessary for the incorporation of small molecule binding sites or enzymatic functions. One attractive target for enzyme design is the TIM-barrel fold, due to its ubiquity in nature and capability to host versatile functions. With the successful de novo design of a 4-fold symmetric TIM barrel, sTIM11, an idealized, minimalistic scaffold was created. In this work, we attempted to extend this de novo TIM barrel by incorporating a helix-loop-helix motif into its βα-loops by applying a physics-based modular design approach using Rosetta. Further diversification was performed by exploiting the symmetry of the scaffold to integrate two helix-loop-helix motifs into the scaffold. Analysis with AlphaFold2 and biochemical characterization demonstrate the formation of additional α-helical secondary structure elements supporting the successful extension as intended.

Topics & Concepts

Helix (gastropod)Barrel (horology)PhysicsLoop (graph theory)Basic helix-loop-helixBiologyGeneticsCombinatoricsEngineeringMathematicsMechanical engineeringDNA-binding proteinGeneTranscription factorSnailEcologyPeptidase Inhibition and AnalysisToxin Mechanisms and ImmunotoxinsMonoclonal and Polyclonal Antibodies Research