High levels of structural disorder in scaffold proteins as exemplified by a novel neuronal protein, CASK-interactive protein1

Authors


P. Tompa, Institute of Enzymology, Biological Research Center, Hungarian Academy of Sciences, Karolina ut 29, 1113 Budapest, Hungary
Fax: +36 1 466 5465
Tel: +36 1 279 3143
E-mail: tompa@enzim.hu

Abstract

CASK-interactive protein1 is a newly recognized post-synaptic density protein in mammalian neurons. Although its N-terminal region contains several well-known functional domains, its entire C-terminal proline-rich region of 800 amino acids lacks detectable sequence homology to any previously characterized protein. We used multiple techniques for the structural characterization of this region and its three fragments. By bioinformatics predictions, CD spectroscopy, wide-line and 1H-NMR spectroscopy, limited proteolysis and gel filtration chromatography, we provided evidence that the entire proline-rich region of CASK-interactive protein1 is intrinsically disordered. We also showed that the proline-rich region is biochemically functional, as it interacts with the adaptor protein Abl-interactor-2. To extend the finding of a high level of disorder in this scaffold protein, we collected 74 scaffold proteins (also including proteins denoted as anchor and docking), and predicted their disorder by three different algorithms. We found that a very high fraction (53.6% on average) of the residues fall into local disorder and their ordered domains are connected by linker regions which are mostly disordered (64.5% on average). Because of this high frequency of disorder, the usual design of scaffold proteins of short globular domains (86 amino acids on average) connected by longer linker regions (140 amino acids on average) and the noted binding functions of these regions in both CASK-interactive protein1 and the other proteins studied, we suggest that structurally disordered regions prevail and play key recognition roles in scaffold proteins.

Structured digital abstract

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