A FIVE-RESIDUE DELETION ALTERS COMPLETELY THE FOLDING AND INCREASES DRASTICALLY THE STABILITY OF ROP

M. Kokkinidis¹, G. Cesareni², H.-J. Hinz³, Y. Papanikolau⁴ and M. Vlassi⁴

¹University of Crete, Dept. of Biology & IMBB/FORTH, PO Box 1527, GR-71110 Heraklion, Crete, Greece
² Dipt. Di Biologia, Il Universita degli Studi di Roma, Via C, 00173 Rome, Italy
³ Institut f. Physikalische Chemie der Westfaelischen Wilhelms-Universitaet, Schlossplatz 4/7, 48161 Muenster, Germany
⁴ NCSR "Demokritos", Ag. Paraskevi Attikis, PO Box 60228, GR-15130 Athens, Greece

ROP is a dimeric four-alpha-helical bundle protein with two subunits of 63 amino acids, each consisting of two antiparallel helices joined by a tight hairpin bend [1]. The simplicity and high regularity of its structure make ROP an ideal model system for an analysis of the sequence-structure relationships of four-alpha-helical bundles [2]. The sequence of the protein exhibits a characteristic pattern of hydrophobic and hydrophilic residues which is organized in heptads. The regular heptad pattern however, breaks down in the bend region. A regular pattern can be restored either by the insertion of two bend residues or by the deletion of five. While the insertion of two residues causes negligible changes to the wild-type structure of ROP [3], the deletion mutant shows dramatic changes in its thermodynamic and structural properties. The protein becomes hyperthermophilic with a transition temperature of T_1/2=99^oC. Furthermore, there is a dramatic change in its tertiary and quaternary structure: At the tertiary structure level the monomer changes from an antiparallel pair of helices connected by a hairpin bend, to a single, long helix. At the quaternary structure level the protein changes from dimer to tetramer, although the topology of a four-alpha helical bundle is conserved. The bundle is formed by the long alpha helices of four monomers. There is a complete reorganization of the hydrophobic core in this bundle; compared to the wild-type protein, the mutant shows a simplified pattern of hydrophobic interactions. The behaviour of the mutant reveals an interesting aspect of protein folding, in that the protein sequence codes for a specific topology (four-alpha-helical bundle) rather than for a specific structure. Topology is established at the quaternary structure level by the assembly of a suitable number (two or four) of subunits and is conserved for the bend mutations tested so far, while the folding of the monomer may drastically change.

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3. Vlassi, M., Tsernoglou, D., Z. Dauter and Kokkinidis, M., Restored heptad pattern continuity does not alter the folding of a 4-á-helical bundle (Nature, Structural Biology 1, 706-714 (1994))