Abstract
Split-protein systems have emerged as a powerful tool for detecting biomolecular interactions and reporting biological reactions. However, reliable methods for identifying viable split sites are still unavailable. In this study, we demonstrated the feasibility that valid circular permutation (CP) sites in proteins have the potential to act as split sites and that CP prediction can be used to search for internal permissive sites for creating new split proteins. Using a protein ligase, intein, as a model, CP predictor facilitated the creation of circular permutants in which backbone opening imposes the least detrimental effects on intein folding. We screened a series of predicted intein CPs and identified stable and native-fold CPs. When the valid CP sites were introduced as split sites, there was a reduction in folding enthalpy caused by the new backbone opening; however, the coincident loss in entropy was sufficient to be compensated, yielding a favorable free energy for self-association. Since split intein is exploited in protein semi-synthesis, we tested the related protein trans-splicing (PTS) activities of the corresponding split inteins. Notably, a novel functional split intein composed of the N-terminal 36 residues combined with the remaining C-terminal fragment was identified. Its PTS activity was shown to be better than current reported two-piece intein with a short N-terminal segment. Thus, the incorporation of in silico CP prediction facilitated the design of split intein as well as circular permutants.
Highlights
In the protein-engineering field, it is well known that manipulating individual residues can change the non-covalent interactions within a protein structural scaffold
The only uncertainty is for the natural occurring split site 105 (Q105-L106) and engineered site 100 (E100-S101) in Ssp DnaB mini-intein; for this protein, the coordinates for residues 98–116 are missing in the Xray structure (PDB code: 1MI8) [24]
If we consider a threshold of CPred score = 0.7, the five functional split sites are all with CPred scores higher than the value
Summary
In the protein-engineering field, it is well known that manipulating individual residues can change the non-covalent interactions within a protein structural scaffold. The covalent connectivity provided by peptide bonds restricts protein conformation because of steric hindrance and limited energy loss [1,2]. CP is a backbone rearrangement in which the original amino- and carboxyl-termini in a protein sequence are connected and new termini internally relocated [1,4]. Despite this rearrangement, many CPs retain their native structure and conserved function or enzymatic activity [1,2]. Examining the influences of CP on the structures and functions, the outcomes have indicated that if the proper CP site is used, the overall protein structure and biological function can be maintained [2,10]
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