Calcium-binding by p26olf, an S100-like protein in the frog olfactory epithelium.

Frog p26olf is a novel S100-like Ca2+-binding protein found in olfactory cilia. It consists of two S100-like domains aligned sequentially, and has a total of four Ca2+-binding sites (known as EF-hands). In this study, to elucidate the mechanism of Ca2+-binding to each EF-hand (named EF-A, -B, -C and -D from the N-terminus of p26olf), we examined Ca2+-binding in wild-type p26olf and also in its mutants in which a glutamate at the -z coordinate position within each Ca2+-binding loop was substituted for a glutamine. Flow dialysis experiments showed that the wild-type binds nearly four Ca2+ per molecule maximally, while all the mutants bind approximately three Ca2+. Although EF-B and -D are p26olf-specific EF-hands and their role in Ca2+-binding is not known, the result unequivocally showed that they actually bind Ca2+. The overall Ca2+-binding affinity decreased in the three mutants. The decrease was very large in the mutants of EF-A and -B, which suggested that the Ca2+-affinities are high in EF-A and -B in the wild-type. Assuming the presence of four steps of Ca2+-binding, we determined the dissociation constant of each step in wild-type p26olf. To assign which step takes place at which EF-hand, we measured the antagonistic effect of K+ on each step, as the effect of K+ is thought to be a function of the number of the carboxyl groups in an EF-hand. Although the actual Ca2+-binding mechanism may not be so simple, this study together with the mutation study suggested a tentative Ca2+-binding model of p26olf: the order of Ca2+-binding to p26olf is EF-B, EF-A, EF-C and EF-D. Based on these results, we speculate that similar Ca2+-binding takes place in an S100 dimer.