Abstract
Repeat proteins have recently attracted much attention as alternative scaffolds to immunoglobulin antibodies due to their unique structural and biophysical features. In particular, repeat proteins show high stability against temperature and chaotic agents. Despite many studies, structural features for the stability of repeat proteins remain poorly understood. Here we present an interesting result from in silico analyses pursuing the factors which affect the stability of repeat proteins. Previously developed repebody structure based on variable lymphocytes receptors (VLRs) which consists of leucine-rich repeat (LRR) modules was used as initial structure for the present study. We constructed extra six repebody structures with varying numbers of repeat modules and those structures were used for molecular dynamics simulations. For the structures, the intramolecular interactions including backbone H-bonds, van der Waals energy, and hydrophobicity were investigated and then the radius of gyration, solvent-accessible surface area, ratio of secondary structure, and hydration free energy were also calculated to find out the relationship between the number of LRR modules and stability of the protein. Our results show that the intramolecular interactions lead to more compact structure and smaller surface area of the repebodies, which are critical for the stability of repeat proteins. The other features were also well compatible with the experimental results. Based on our observations, the repebody-5 was proposed as the best structure from the all repebodies in structure optimization process. The present study successfully demonstrated that our computer-based molecular modeling approach can significantly contribute to the experiment-based protein engineering challenge.
Highlights
Modular proteins are among the most abundant classes of naturally occurring protein–protein interaction modules [1]
We have demonstrated that thermodynamic stability of the modular protein composed of leucine-rich repeat (LRR) modules is significantly affected by the number of constituting modules
Our molecular modeling study provides the critical physicochemical features affecting the thermodynamic stability of the modular protein
Summary
Modular proteins are among the most abundant classes of naturally occurring protein–protein interaction modules [1]. Modular proteins have been identified in a variety of functionally related proteins, and their modular architecture has evolved to be suitable for protein-protein interactions, mediating many important biological functions including cell adhesion, signaling process, neural development, bacterial pathogenicity, extracellular matrix assembly, and immune response [4,5,6,7]. Due to their unique structural and biophysical features, modular proteins have recently attracted much attention as alternative scaffolds to immunoglobulin antibodies [8]. Much effort has been made to develop the alternatives, and a number of diverse protein scaffolds have been reported [9]
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