Odorant-binding proteins (OBPs) and chemosensory proteins (CSPs) mediate both perception and release of chemical stimuli in insects. The genome of the honey bee contains 21 genes encoding OBPs and 6 encoding CSPs. Using a proteomic approach, we have investigated the expression of OBPs and CSPs in the mandibular glands of adult honey bees in relation to caste and age. OBP13 is mostly expressed in young individuals and in virgin queens, while OBP21 is abundant in older bees and is prevalent in mated queens. OBP14, which had been found in larvae, is produced in hive workers' glands. Quite unexpectedly, the mandibular glands of drones also contain OBPs, mainly OBP18 and OBP21. We have expressed three of the most represented OBPs and studied their binding properties. OBP13 binds with good specificity oleic acid and some structurally related compounds, OBP14 is better tuned to monoterpenoid structures, while OBP21 binds the main components of queen mandibular pheromone as well as farnesol, a compound used as a trail pheromone in the honey bee and other hymenopterans. The high expression of different OBPs in the mandibular glands suggests that such proteins could be involved in solubilization and release of semiochemicals.
The genome of the silkmoth Bombyx mori contains 44 genes encoding odorant-binding proteins (OBPs) and 20 encoding chemosensory proteins (CSPs). In this work, we used a proteomic approach to investigate the expression of proteins of both classes in the antennae of adults and in the female pheromone glands. The most abundant proteins found in the antennae were the 4 OBPs (PBP, GOBP1, GOBP2, and ABP) and the 2 CSPs (CSP1 and CSP2) previously identified and characterized. In addition, we could detect only 3 additional OBPs and 2 CSPs, with clearly different patterns of expression between the sexes. Particularly interesting, on the other hand, is the relatively large number of binding proteins (1 OBP and 7 CSPs) expressed in the female pheromone glands, some of them not present in the antennae. In the glands, these proteins could be likely involved in the solubilization of pheromonal components and their delivery in the environment.
Chemical communication in insects is mediated by soluble binding proteins, belonging to two large families, Odorant-binding Proteins (OBPs) and Chemosensory Proteins (CSPs). Recently, evidence has been provided that OBPs are involved in recognition of chemical stimuli. We therefore decided to investigate the expression of OBPs and CSPs in the honeybee at the protein level, using a proteomic approach. Our results are in agreement with previous reports of expression at the RNA level and show that 12 of the 21 OBPs predicted in the genome of the honeybee Apis mellifera and 2 of the 6 CSPs are present in the foragers' antennae, while the larvae express only three OBPs and a single CSP. MALDI mass spectrometry on crude antennal extracts and MALDI profiling on sections of antennae demonstrated that these techniques can be applied to investigate individual differences in the expression of abundant proteins, such as OBPs and CSPs, as well as to detect the presence of proteins in different regions of the antenna. Finally, as part of a project aimed at the characterization of all OBPs and CSPs of the honeybee, we expressed 5 OBPs and 4 CSPs in a bacterial system and measured their affinity to a number of ligands. Clear differences in their binding spectra have been observed between OBPs, as well as CSPs.
Two soluble proteins were isolated as major secretory products of horse sweat and of the parotid gland and characterized for structural and functional properties. The first protein, lipocalin allergen EquC1, was characterized for its glycosylation sites and bound glycosidic moieties. Only one (Asn53) of the two putative glycosylation sites within the sequence was post-translationally modified; a different glycosylation pattern was determined with respect to data previously reported. When purified from horse sweat, this protein contained oleamide and other organic molecules as natural ligands. Ligand binding experiments indicated good protein selectivity toward volatile compounds having a straight chain structure of 9-11 carbon atoms, suggesting a role of this lipocalin in chemical communication. The second protein, here reported for the first time in the horse, belongs to the group of parotid secretory proteins, part of a large superfamily of binding proteins whose function in most cases is still unclear. This protein was sequenced and characterized for its post-translational modifications. Of the three cysteine residues present, two were involved in a disulfide bridge (Cys155-Cys198). A model, built up on the basis of similar proteins, indicated a general fold characterized by the presence of a long hydrophobic barrel. Binding experiments performed with a number of different organic compounds failed to identify ligands for this protein with a well-defined physiological role.
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