Linkers of secondary structures in proteins.

Abstract

Linkers that connect repeating secondary structures fall into conformational classes based on distance and main-chain torsion clustering. A data set of 300 unique protein chains with low pairwise sequence identity was clustered into only a few groups representing the preferred motifs. The linkers of two to eight residues for the nonredundant data set are designated H-Ln-H, H-Ln-E, E-Ln-H, E-Ln-E, where n is the length, H stands for alpha-helices, and E for beta-strands. Most of the clusters identified here corroborate earlier findings. However, 19 new clusters are identified in this paper, with many of them having seven and eight residue linkers. In our first analysis, the secondary structures flanking the linkers are both interacting and noninteracting and there is no precise angle of orientation between them. A second analysis was performed on a set of proteins with restricted orientations for the flanking elements, namely, mainly alpha class of proteins with orthogonal architecture. Two definite clusters are identified, one corresponding to linkers of orthogonal helices and the other to linkers of antiparallel helices. Loops forming binding sites or involved in catalytic activity are important determinants of the function of proteins. Although the structural conservation of the residues around the catalytic triad of serine proteases has been studied widely, there has not been a systematic analysis of the conformation of the loops that contain them. Residues of the catalytic triad reside in the linkers of beta-strands, with varying lengths of more than eight residues. Here, we analyze the structural conservation of such linkers by superposition, and observe a conserved structural feature of the linkers incorporating each of the three residues of the catalytic triad.