Le rôle des protéines liant les odeurs (OBP) dans la transduction olfactive

Abstract

This paper reviews biochemical and functional properties of a family of proteins involved in the transduction process of chemical signals. Odorant-binding proteins (OBPs) are small soluble proteins highly concentrated in the chemosensory organs of Insects and Vertebrates. They are preferentially expressed in the nasal mucus of Vertebrates and in the sensillar lymph of Insects. They have been found to bind reversibly small hydrophobic molecules detected via the olfactory system. The vertebrate OBPs bind non-specific odorants with low affinities. They belong to the lipocalin family as well as other proteins involved in chemical communication and associated to different organs and functions. Nevertheless, no specific ligand for OBPs has been yet identified in Vertebrates. However, the large microdiversity of OBPs in the same animal suggests that OBPs could be involved in the discrimination of odors. Chemical communication in Noctuid moths was used as a model to study the molecular mechanisms of odor recognition. The pheromonal system is extremely sensitive and specific since the male is able to detect only few molecules of the pheromone and to recognize specific blends of the same molecules. The chemical signals were identified for a large number of Lepidopteran species and the associated behaviours they elicit were fully characterized. The Lepidopteran OBPs are divided into two sub-classes according to their ligands: pheromone-binding proteins (PBP) are expressed in sensilla trichodea responding to pheromonal compounds while general odorant binding proteins (GOBP) are associated with sensilla basiconica tuned to the detection of general odors, such as plant volatiles. The PBPs selectively bind components of the female sex-pheromone with measurable affinities. The ligand binding site was localized in the 40–60 aminoacids region. Substitutions in the binding site of different proteins are correlated with the fixation of different ligands, leading to the hypothesis that the primary structure encodes the ligand specificity. Other proteins expressed in chemosensory organs of other orders of Insects were cloned or purified. In absence of functional data, they were called OBP-like. Some of them were localized in the gustatory organs and could be common carriers of odors in both olfactory and gustatory systems. Many arguments are in accordance with an active role of the OBPs in the early steps of odor discrimination. The heterogeneity of OBPs inside species and between species, the spatial segregation in their expression and the different binding affinities of PBPs towards pheromonal compounds support the hypothesis that the coding of odors is realized as soon as the level of OBPs. More, the complex OBP/odor could be the stimulus for olfactory receptors cloned in Vertebrates and still putative in Insects. This hypothesis suggests that OBPs take part as an essential element of the chemosensory transduction.