A receptor and binding protein interplay in the detection of a distinct pheromone component in the silkmoth Antheraea polyphemus

Male moths respond to conspecific female-released pheromones with remarkable sensitivity and specificity, due to highly specialized chemosensory neurons in their antennae. In Antheraea silkmoths, three types of sensory neurons have been described, each responsive to one of three pheromone components. Since also three different pheromone binding proteins (PBPs) have been identified, the antenna of Antheraea seems to provide a unique model system for detailed analyzes of the interplay between the various elements underlying pheromone reception. Efforts to identify pheromone receptors of Antheraea polyphemus have led to the identification of a candidate pheromone receptor (ApolOR1). This receptor was found predominantly expressed in male antennae, specifically in neurons located beneath pheromone-sensitive sensilla trichodea. The ApolOR1-expressing cells were found to be surrounded by supporting cells co-expressing all three ApolPBPs. The response spectrum of ApolOR1 was assessed by means of calcium imaging using HEK293-cells stably expressing the receptor. It was found that at nanomolar concentrations ApolOR1-cells responded to all three pheromones when the compounds were solubilized by DMSO and also when DMSO was substituted by one of the three PBPs. However, at picomolar concentrations, cells responded only in the presence of the subtype ApolPBP2 and the pheromone (E,Z)-6,11-hexadecadienal. These results are indicative of a specific interplay of a distinct pheromone component with an appropriate binding protein and its related receptor subtype, which may be considered as basis for the remarkable sensitivity and specificity of the pheromone detection system.     

Species-specific pheromonal compounds induce distinct conformational changes of pheromone binding protein subtypes from Antheraea polyphemus

We have investigated the structural features of three pheromone binding protein (PBP) subtypes from Antheraea polyphemus and monitored possible changes induced upon interaction with the Antheraea pheromonal compounds 4E,9Z-14:Ac [(E4,Z9)-tetradecadienyl-1-acetate], 6E,11Z-16:Ac [(E6,Z11)-hexadecadienyl-1-acetate], and 6E,11Z-16:Al [(E6,Z11)-hexadecadienal]. Circular dichroism and second derivative UV-difference spectroscopy data demonstrate that the structure of subtype PBP1 significantly changes upon binding of 4E,9Z-14:Ac. The related 6E,11Z-16:Ac was less effective and 6E,11Z-16:Al showed only a small effect. In contrast, in subtype PBP2 pronounced structural changes were only induced by the 6E,11Z-16:Al, and the subtype PBP3 did not show any considerable changes in response to the pheromonal compounds. The UV-spectroscopic data suggest that histidine residues are likely to be involved in the ligand-induced structural changes of the proteins, and this notion was confirmed by site-directed mutagenesis experiments. These results demonstrate that appropriate ligands induce structural changes in PBPs and provide evidence for ligand specificity of these proteins. Electronic Publication     

Sex pheromone of the moth,Antheraea polyphemus

The sex pheromone system of Antheraea polyphemus was characterized from female abdominal tips by classical and electroantennogram techniques as rans-6,cis-11-hexadecadienyl acetate and trans-6,cis-11-hexadecadienal. A 90 : 10 mixture of acetate and aldehyde was highly attractive to wild males in the field. The synthetic pheromone and A. polyphemus females were not attractive to released Antheraea pernyi males.     

Three pheromone-binding proteins in olfactory sensilla of the two silkmoth species Antheraea polyphemus and Antheraea pernyi.

Females of the sibling silkmoth species Antheraea polyphemus and A. pernyi use the same three sex pheromone components in different ratios to attract conspecific males. Accordingly, the sensory hairs on the antennae of males contain three receptor cells sensitive to each of the pheromone components. In agreement with the number of pheromones used, three different pheromone-binding proteins (PBPs) could be identified in pheromone-sensitive hairs of both species by combining biochemical and molecular cloning techniques. MALDI-TOF MS of sensillum lymph droplets from pheromone-sensitive sensilla trichodea of male A. polyphemus revealed the presence of three major peaks with m/z of 15702, 15752 and 15780 and two minor peaks of m/z 15963 and 15983. In Western blots with four antisera raised against different silkmoth odorant-binding proteins, immunoreactivity was found only with an anti-(Apol PBP) serum. Free-flow IEF, ion-exchange chromatography and Western blot analyses revealed at least three anti-(Apol PBP) immunoreactive proteins with pI values between 4.4 and 4.7. N-Terminal sequencing of these three proteins revealed two proteins (Apol PBP1a and Apol PBP1b) identical in the first 49 amino acids to the already known PBP (Apol PBP1) [Raming, K. , Krieger, J. & Breer, H. (1989) FEBS Lett. 256, 2215-2218] and a new PBP having only 57% identity with this amino-acid region. Screening of antennal cDNA libraries with an oligonucleotide probe corresponding to the N-terminal end of the new A. polyphemus PBP, led to the discovery of full length clones encoding this protein in A. polyphemus (Apol PBP3) and in A. pernyi (Aper PBP3). By screening the antennal cDNA library of A. polyphemus with a digoxigenin-labelled A. pernyi PBP2 cDNA [Krieger, J., Raming, K. & Breer, H. (1991) Biochim. Biophys. Acta 1088, 277-284] a homologous PBP (Apol PBP2) was cloned. Binding studies with the two main pheromone components of A. polyphemus and A. pernyi, the (E,Z)-6, 11-hexadecadienyl acetate (AC1) and the (E,Z)-6,11-hexadecadienal (ALD), revealed that in A. polyphemus both Apol PBP1a and the new Apol PBP3 bound the 3H-labelled acetate, whereas no binding of the 3H-labelled aldehyde was found. In A. pernyi two PBPs from sensory hair homogenates showed binding affinity for the AC1 (Aper PBP1) and the ALD (Aper PBP2), respectively.     

Revisiting the specificity of Mamestra brassicae and Antheraea polyphemus pheromone-binding proteins with a fluorescence binding assay

Pheromone-binding proteins (PBPs), located in the sensillum lymph of pheromone-responsive antennal hairs, are thought to transport the hydrophobic pheromones to the chemosensory membranes of olfactory neurons. It is currently unclear what role PBPs may play in the recognition and discrimination of species-specific pheromones. We have investigated the binding properties and specificity of PBPs from Mamestra brassicae (MbraPBP1), Antheraea polyphemus (ApolPBP1), Bombyx mori (BmorPBP), and a hexa-mutant of MbraPBP1 (Mbra1-M6), mutated at residues of the internal cavity to mimic that of BmorPBP, using the fluorescence probe 1-aminoanthracene (AMA). AMA binds to MbraPBP1 and ApolPBP1, however, no binding was observed with either BmorPBP or Mbra1-M6. The latter result indicates that relatively limited modifications to the PBP cavity actually interfere with AMA binding, suggesting that AMA binds in the internal cavity. Several pheromones are able to displace AMA from the MbraPBP1- and ApolPBP1-binding sites, without, however, any evidence of specificity for their physiologically relevant pheromones. Moreover, some fatty acids are also able to compete with AMA binding. These findings bring into doubt the currently held belief that all PBPs are specifically tuned to distinct pheromonal compounds.     

Sequence complexities of mRNA populations during adult wing development in the silkmoth Antheraea polyphemus

The total poly A⁺ messenger RNAs of epidermal cells in the wing sac of the silkmoth Antheraea polyphemus as a function of development (which is under the influence of the moulting hormone, 20-hydroxyecdysone) has been analyzed by cDNA-mRNA hybridizations. Kinetic and numerical analysis of homologous hybridizations indicate the messenger populations to be made up of several kinetic classes, the total complexity being similar at all stages of development. Heterologous hybridizations indicate clear differences between two stages: (i) at the beginning of development characterized by growth and development and (ii) at the end of development characterized by differentiation and cuticular secretion. The principal difference between the two stages has been shown, by isolation and characterization of null cDNA (cDNA enriched for the second stage) to be due to the appearance of several hundred new mRNAs belonging to the moderately abundant class at the second stage. Analysis of translation products by SDS-PAGE and immunoprecipitation confirm and extend these results.     

Morphogenesis of the antenna of the male silkmoth, Antheraea polyphemus. IV. Segmentation and branch formation

The imaginal antenna of the male silkmoth Antheraea polyphemus is a featherlike structure; its flagellum consists of about 30 stem segments each giving off two pairs of side branches. The antenna develops during the pupal stage (lasting in total about 21 days) from a leaf-shaped anlage by incisions proceeding from the periphery towards the prospective antennal stem. Primary incisions, starting about 3 days after apolysis, form double branches, which arethen split into single branches by parallel running secondary incisions. The initial pattern of tracheae and peripheral nerves is completely rearranged during these morphogenetic processes which are finished 9-10 days after apolysis. In Antheraea the dorsal and ventral epithelial monolayers of the antennal anlage are successively subdivided during development into a pattern of repetitive epithelial zones. Within the first day after apolysis alternating stripes of sensillogenic and non-sensillogenic epithelium are differentiating. Then the latter are further subdivided, and at last four different stripelike zones (I-IV) can be discriminated. Long basal protrusions of the epidermal cells ('epidermal feet'), and most probably haemocytes, seem to be involved in the reconstruction of the epithelium: both show characteristic arrangements within the antennal anlage during successive developmental stages.     

Morphogenesis of the antenna of the male silkmoth, Antheraea polyphemus. V. Development of the peripheral nervous system

The imaginal antenna of the male silkmoth Antheraea polyphemus is a feather-shaped structure consisting of about 30 flagellomeres, each of which gives off two pairs of side branches. During the pupal stage (lasting for 3 weeks), the antenna develops from a leaf-shaped, flattened epidermal sac ('antennal blade') via two series of incisions which proceed from the periphery towards the prospective antennal stem. The development of the peripheral nervous system was studied by staining the neurons with an antibody against horseradish peroxidase as well as by electron microscopy. The epithelium is subdivided in segmentally arranged sensillogenic regions alternating with non-sensillogenic regions. Immediately after apolysis, clusters consisting of 5 sensory neurons each and belonging to the prospective sensilla chaetica can be localized at the periphery of the antennal blade in the sensillogenic regions. During the first day following apolysis, the primordia of ca. 70 000 olfactory sensilla arise in the sensillogenic regions. Axons from their neurons are collected in segmentally arranged nerves which run towards the CNS along the dorsal as well as the ventral epidermis and are enveloped by a glial sheath. This 'primary innervation pattern' is completed within the second day after apolysis. A first wave of incisions ('primary incisions') subdivide the antennal blade into segmental 'double branches' without disturbing the innervation pattern. Then a second wave of incisions ('secondary incisions') splits the double branches into single antennal branches. During this process, the segmental nerves and their glial sheaths are disintegrated. The axons are then redistributed into single branch nerves while their glial sheath is reconstituted, forming the 'secondary', or adult, innervation pattern. The epidermis is backed by a basal lamina which is degraded after outgrowth of the axons, but is reconstituted after formation of the single antennal branches.     

Morphogenesis of the antenna of the male silkmoth, Antheraea polyphemus. VI. Experimental disturbance of antennal branch formation

In the male silkmoth Antheraea polyphemus, the formation of the side branches of the quadripectinate antennal flagellum was disturbed by an experimental manipulation. Normally the side branches develop in the pupa via deep incisions which proceed from the periphery towards the centerline of the leaf-shaped antennal anlage. Local removal of the uppermost, pigmented cuticular layers of the pupal antennal pocket ('cuticular window') led to a local standstill of branch formation in the manipulated region of the pocket, most probably caused by increased evaporation of water through the remaining layers of meso- and endocuticle. These parts of the antenna retained an unbranched, plate-like shape. This early morphogenetic stage was conserved by the secretion of antennal cuticle. Besides cuticle formation, development of sensilla is not impeded by the manipulation. In the plate-shaped regions, the initial pattern formed by the sensilla in the antennal epidermis is preserved, because they maturate at their birthplaces. In the individual segments, the pattern of sensilla shows a mirror-like symmetry with respect to the segmental midline. From the edge to the midline, we found large s. trichodea, followed by small s. trichodea, s. basiconica, and s. coeloconica on the dorsal side whereas on the ventral side, there are only large s. trichodea and s. campaniformia. We conclude that the development of the featherlike antennal shape on the one hand and the development of sensilla and cuticle on the other hand are independent processes.     

Candidate pheromone binding proteins of the silkmoth Bombyx mori

Pheromone reception is thought to be mediated by pheromone binding proteins (PBPs) in the aqueous lymph of the antennal sensilla. Recent studies have shown that the only known PBP of Bombyx mori (BmorPBP1) appears to be specifically tuned to bombykol but not to bombykal, raising the question of whether additional subtypes may exist. We have identified two novel genes, which encode candidate PBPs (BmorPBP2, BmorPBP3). Comparison with PBPs from various moth species have revealed a high degree of sequence identity and the three BmorPBP-subtypes can be assigned to distinct groups within the moth PBP family. In situ hybridization revealed that BmorPBP2 and BmorPBP3 are expressed only in relatively few cells compared to the number of cells expressing BmorPBP1. Double-labeling experiments have shown that the two novel BmorPBPs are expressed in the same cells but are not co-expressed with BmorPBP1. Furthermore, unlike BmorPBP1, cells expressing the newly identified PBPs did not surround neurons containing the BmOR-1 receptor. The results indicate that BmorPBP2 and BmorPBP3 are located in sensilla types, which are different from the long sensilla trichodea.Data deposition: The sequences reported in this paper have been deposited in the EMBL database under accession nos. AM403100 (BmorPBP2) and AM403101 (BmorPBP3).     

Membrane binding of MARCKS-related protein studied by tryptophan fluorescence spectroscopy

MARCKS-related protein (MRP) is a peripheral membrane protein whose binding to membranes is mediated by the N-terminal myristoyl moiety and a central, highly basic effector domain. MRP mediates cross-talk between protein kinase C and calmodulin and is thought to link the actin cytoskeleton to the plasma membrane. Since MRP contains no tryptophan residues, we mutated a phenylalanine in the effector domain to tryptophan (MRP F93W) and used fluorescence spectroscopy to monitor binding of the protein to phospholipid vesicles. We report in detail the evaluation procedure necessary to extract quantitative information from the raw data. The spectra of MRP F93W obtained in the presence of increasing amounts of lipid crossed at an isosbestic point, indicating a simple transition between two states: free and membrane-bound protein. The change in fluorescence toward values typical of a more hydrophobic environment was used to quantify membrane binding. The partition coefficient agreed well with values obtained previously by other methods. To study the interaction of the N-terminus of MRP with membranes, a tryptophan residue was also introduced at position 4 (MRP S4W). Our data suggest that only the myristoylated N-terminus interacted with liposomes. These results demonstrate the versatility of site-directed incorporation of tryptophan residues to study protein-membrane interactions.     

Resolution of pheromone pulses in receptor cells of Antheraea polyphemus at different temperatures

The ability of pheromone receptor cells of male Antheraea polyphemus (Saturniidae) to resolve stimulus pulses was determined at different temperatures (8°, 18°, 28°C). The cells were stimulated by repeated 20-ms puffs of the pheromone components (E, Z)-6, 11-hexadecadienyl acetate and (E, Z)-6,11-hexadecadienal. At higher temperatures, higher frequencies of stimulus pulses were resolved by the nerve-impulse response: about 1.25 pulses per second at 8°C, 2.5 pulses/s at 18°C and 5 pulses/s at 28°C. The decreased ability of receptor cells to resolve stimulus pulses at low temperatures may reduce the male moth's chance of reaching the pheromone source. The peak nerve-impulse frequency increased whereas the duration of nerve-impulse responses to single stimulus pulses decreased at higher temperatures. At a given temperature and stimulus intensity the peak nerveimpulse frequency decreased with shorter intervals between the stimulus pulses, but the duration of the responses remained almost constant. The time needed for recovery from adaptation caused by a single stimulus pulse was longer at lower temperatures. The aldehyde receptor cell recovered more quickly than the acetate cell. At low stimulus concentration, the resolution ability of the acetate cell was strongly decreased, whereas in the aldehyde cell it was only slightly impaired.     

Morphogenesis of the antenna of the male silkmoth. Antheraea polyphemus, III. Development of olfactory sensilla and the properties of hair-forming cells

During adult development of the male silkmoth Antheraea polyphemus, the anlagen of olfactory sensilla arise within the first 2 days post-apolysis in the antennal epidermis (stage 1-3). Approximately on the second day, the primary dendrites as well as the axons grow out from the sensory neurons (stage 4). The trichogen cells start to grow apical processes approximately on the third day, and these hair-forming 'sprouts' reach their definite length around the ninth day (stages 5-6). Then the secretion of cuticle begins, the cuticulin layer having formed on day 10 (stage 7a). The primary dendrites are shed, the inner dendritic segments as well as the thecogen cells retract from the prospective hair bases, and the inner tormogen cells degenerate around days 10/11 (stage 7b). The hair shafts of the basiconic sensilla are completed around days 12/13 (stage 7c), and those of the trichoid sensilla around days 14/15 (stage 7d). The trichogen sprouts retract from the hairs after having finished cuticle formation, and the outer dendritic segments grow out into the hairs: in the basiconic sensilla directly through, and in the trichoid sensilla alongside, the sprouts. The trichogen sprouts contain numerous parallel-running microtubules. Besides their cytoskeletal function, these are most probably involved in the transport of membrane vesicles. During the phase of cuticle deposition, large numbers of vesicles are transported anterogradely from the cell bodies into the sprouts, where they fuse with the apical cell membrane and release their electron-dense contents (most probably cuticle precursors) to the outside. As the cuticle grows in thickness, the surface area of the sprouts is reduced by endocytosis of coated vesicles. When finally the sprouts retract from the completed hairs, the number of endocytotic vesicles is further increased and numerous membrane cisterns seem to be transported retrogradely along the microtubules to the cell bodies. Here the membrane material will most probably be used again in the formation of the sensillum lymph cavities. Thus, the trichogen cells are characterized by an intensive membrane recycling. The sensillum lymph cavities develop between days 16-20 (stage 8), mainly via apical invaginations of the trichogen cells. The imago emerges on day 21.     

The solution NMR structure of Antheraea polyphemus PBP provides new insight into pheromone recognition by pheromone-binding proteins

Pheromone-binding proteins (PBPs) located in the antennae of male moth species play an important role in olfaction. They are carrier proteins, believed to transport volatile hydrophobic pheromone molecules across the aqueous sensillar lymph to the membrane-bound G protein-coupled olfactory receptor proteins. The roles of PBPs in molecular recognition and the mechanisms of pheromone binding and release are poorly understood. Here, we report the NMR structure of a PBP from the giant silk moth Antheraea polyphemus. This is the first structure of a PBP with specific acetate-binding function in vivo. The protein consists of nine alpha-helices: alpha1a (residues 2-5), alpha1b (8-12), alpha1c (16-23), alpha2 (27-34), alpha3a (46-52), alpha3b (54-59), alpha4 (70-79), alpha5 (84-100) and alpha6 (107-125), held together by three disulfide bridges: 19-54, 50-108 and 97-117. A large hydrophobic cavity is located inside the protein, lined with side-chains from all nine helices. The acetate-binding site is located at the narrow end of the cavity formed by the helices alpha3b and alpha4. The pheromone can enter this cavity through an opening between the helix alpha1a, the C-terminal end of the helix alpha6, and the loop between alpha2 and alpha3a. We suggest that Trp37 may play an important role in the initial interaction with the ligand. Our analysis also shows that Asn53 plays the key role in recognition of acetate pheromones specifically, while Phe12, Phe36, Trp37, Phe76, and Phe118 are responsible for non-specific binding, and Leu8 and Ser9 may play a role in ligand chain length recognition.     

Morphogenesis of the antenna of the male silkmoth, Antheraea polyphemus. I. The leaf-shaped antenna of the pupa from diapause to apolysis

The antenna of the male silkmoth Antheraea polyphemus is a featherlike structure consisting of a central stem and ca. 120 side branches, which altogether carry about 70,000 olfactory sensilla. We investigate the development during the pupal phase. At the end of diapause, the antennal rudiment consists of a leaf-shaped, one-layered epidermal sac. It is supplied with oxygen via a central main trachea, which gives off numerous thin side branches. These are segmentally arranged into bundles which run to the periphery of the antennal blade. When the epidermis retracts from the pupal cuticle (apolysis; stage 1), it consists of cells which are morphologically uniform. The epidermal cells form a network of long, irregular basal protrusions (epidermal feet), which crisscross the antennal lumen. During the first day post-apolysis (stage 2), the antennal epidermis differentiates into alternating thick 'sensillogenic' and thin 'non-sensillogenic' areas arranged in stripes which run in parallel to the tracheal bundles. Numerous dark, elongated cells, which might be the sensillar stem cells, are scattered in the sensillogenic epithelium. A number of very early sensilla has been found at the distal edges of the sensillogenic stripes in positions which later will be occupied by sensilla chaetica. The whole antennal blade is enveloped by the transparent ecdysial membrane, consisting of the innermost layers of the pupal cuticle which are detached during apolysis.     

Morphogenesis of the antenna of the male silkmoth, Antheraea polyphemus. II. Differential mitoses of 'dark' precursor cells create the Anlagen of sensilla

The antenna of the male silkmoth Antheraea polyphemus develops from a one-layered, flattened epidermal sac during the pupal phase. Within the first day post-apolysis (developmental stages 1 and 2), this epithelium differentiates into 'sensillogenic' and 'nonsensillogenic' regions, while numerous slender 'dark cells' interpreted as the precursor cells of sensilla arise in the former. Approximately between the first and second day post-apolysis (developmental stage 3), the dark cells retract to the apical pole of the epidermis, assume a round shape, and undergo a series of differential mitoses with spindles usually oriented parallel to the epidermal surface. These mitoses finally yield the Anlagen of the olfactory sensilla trichodea, each consisting of mostly 6-7 dark cells arranged side by side. In most of the Anlagen, 3-4 of these cells are situated more basally, each giving off a slender apical process which together are arranged in a fascicle. These are the prospective 2-3 sensory neurons plus the thecogen cell, which most probably is a sister cell of the former. Three additional cells are arranged more apically and partly enclose the fascicle of presumed sensory and thecogen cell processes. These are interpreted as the trichogen plus 2 tormogen cells, one of the latter degenerating later during development. In the basal region of the sensillogenic epidermis, massive signs of cell degeneration have been found. At stage 3, the basal epidermal feet in the non-sensillogenic regions have assumed a more uniform orientation as compared with the preceding stages.     

Probing ligand protein binding equilibria with fluorescence fluctuation spectroscopy

We examine the binding of fluorescent ligands to proteins by analyzing the fluctuation amplitude g(0) of fluorescence fluctuation experiments. The normalized variance g(0) depends on the molecular brightness and the concentration of each species in the sample. Thus a single g(0) measurement is not sufficient to resolve individual species. Titration of the ligand with protein establishes the link between molecular brightness and concentration by fitting g(0) to a binding model and allows the separation of species. We first apply g(0) analysis to binary dye mixtures with brightness ratios of 2 and 4 to demonstrate the feasibility of this technique. Next we consider the influence of binding on the fluctuation amplitude g(0). The dissociation coefficient, the molecular brightness ratio, and the stochiometry of binding strongly influence the fluctuation amplitude. We show that proteins with a single binding site can be clearly differentiated from proteins with two independent binding sites. The binding of fluorescein-labeled digoxigenin to a high-affinity anti-digoxin antibody was studied experimentally. A global analysis of the fluctuation amplitude and the fluorescence intensity not only recovered the dissociation coefficient and the number of binding sites, but also revealed the molecular heterogeneity of the hapten-antibody complex. Two species were used to model the molecular heterogeneity. We confirmed the molecular heterogeneity independently by fluorescence lifetime experiments, which gave fractional populations and molecular brightness values that were virtually identical to those of the g(0) analysis. The identification and characterization of molecular heterogeneity have far-reaching consequences for many biomolecular systems. We point out the important role fluctuation experiments may have in this area of research.     

Diffusion barriers in silkmoth sensory epithelia: application of lanthanum tracer to olfactory sensilla of Antheraea polyphemus and Bombyx mori

The distribution of diffusion barriers in silkmoth olfactory sensilla has been investigated with ionic lanthanum. The tracer was applied from the apical side of the sensory epithelium by first pinching off the hair tips and then dipping the antennal branches into the La(NO(3))(3) solution. The tracer neither passed the apical septate junctions between the dendrite and the thecogen cell nor those between thecogen, trichogen, and tormogen cells, nor the tight contact between the apical membrane of the tormogen cell and the cuticle. After perfusing the hemolymph space with La(NO(3))(3) solution, the tracer was found in the clefts between the thecogen, trichogen, tormogen, and epidermis cells, but not in those between the receptor cells and the thecogen cell, or between the axon and the glial envelope. Lanthanum neither entered the receptor-lymph space nor the subcuticular space. Therefore, (i) receptor-lymph space, subcuticular space, and hemolymph space are isolated from each other, and (ii) the cleft between thecogen and sensory cell is separated from the hemolymph as well as from the receptor-lymph spaces. Furthermore, the results indicate that pleated septate junctions form the diffusion barriers in silkmoth olfactory sensilla.