RESUMO
Olfactory systems have evolved the extraordinary capability to detect and discriminate volatile odorous molecules (odorants) in the environment. Fundamentally, this process relies on the interaction of odorants and their cognate olfactory receptors (ORs) encoded in the genome. Here, we conducted a cell-based screen using over 800 mouse ORs against seven odorants, resulting in the identification of a set of high-affinity and/or broadly-tuned ORs. We then test whether heterologously expressed ORs respond to odors presented in vapor phase by individually expressing 31 ORs to measure cAMP responses against vapor phase odor stimulation. Comparison of response profiles demonstrates this platform is capable of discriminating between structural analogs. Lastly, co-expression of carboxyl esterase Ces1d expressed in olfactory mucosa resulted in marked changes in activation of specific odorant-OR combinations. Altogether, these results establish a cell-based volatile odor detection and discrimination platform and form the basis for an OR-based volatile odor sensor.
Assuntos
Odorantes , Mucosa Olfatória/metabolismo , Neurônios Receptores Olfatórios/metabolismo , Receptores Odorantes/metabolismo , Acetofenonas , Aldeídos , Animais , Benzoatos , Hidrolases de Éster Carboxílico/metabolismo , AMP Cíclico/metabolismo , Cicloexanonas , Discriminação Psicológica , Eugenol , Cetonas , Camundongos , Proteínas dos Microfilamentos , Percepção Olfatória , PentanóisRESUMO
In Drosophila, sexual differentiation, physiology, and behavior are thought to be mediated by numerous male- and female-specific effector genes whose expression is controlled by sex-specifically expressed transcriptional regulators. One such downstream effector gene, sex-specific enzyme 1 (sxe1, cyp4d21), has been identified in a screen for genes with sex-biased expression in the head. Sxe1 was also identified in another screen as a circadian regulated gene. Here, we analyzed the spatial and temporal regulation of sxe1 and identified a function for this gene in male courtship. We show that male-specific transcriptional regulator DSX(M) and the clock genes are necessary for cycling of sxe1 mRNA during the diurnal cycle. Similar to sxe1 mRNA, expression of SXE1 protein oscillates in a diurnal fashion, with highest protein levels occurring around midnight. SXE1 protein expression is restricted to nonneuronal cells associated with diverse sensory bristles of both the chemo- and mechanosensory systems. Suppression or knockout of sxe1 significantly reduces mating success throughout the diurnal cycle. Finally, the metabolomic profile of wild-type and sxe1 mutant males revealed that sxe1 likely functions as a fatty acid omega-hydroxylase, suggesting that male courtship and mating success is mediated by small compounds generated by this enzyme.