Abstract

The SCAN or leucine-rich domain has been characterized as a highly conserved sequence in zinc finger transcription factors that mediates selective dimer formation between SCAN-domain-containing proteins. In order to accommodate various SCAN-domain sequence features, a minimal functional folding unit was defined on the premise of proper structural folding and biochemical binding. The 58-amino acid minimal functional units derived from each of four SCAN-domain protein families were subjected to a three-dimensional position-specific scoring matrix (3D-PSSM) and ungapped threading analysis. The resulting fold prediction represented the SCAN-domain's minimal functional unit as a bundle of three alpha helices folded to a core structure. In addition, the minimal functional folding unit biochemically retained the selective dimerization properties of the native proteins. In order to elucidate the structural components within the SCAN-domain that engage in binding interactions, we attempted to correlate the physicochemical helix properties, as represented by a hydropathy profile, with the experimental dimerization selectivities. The amino-terminal helix revealed the highest diversity measure among the three helices of the minimal functional unit and is therefore likely to offer critical surface-exposed binding residues. Indeed, by interchanging the amino-terminal helix between SCAN-domains without alteration of their structural frames consisting of conserved hydrophobic residues, a modulation of binding preferences was demonstrated. The minimal functional folding unit of SCAN-domains may therefore contain within the amino-terminal alpha helix structural components that determine selective dimerization patterns and combinatorial control of transcription factors.

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