Qualitative and quantitative freeze-fracture studies on olfactory and nasal respiratory structures of frog,ox, rat,and dog

Summary A comparative study using freeze-fracturing has been made of surface structures of olfactory and nasal respiratory epithelia of frog, ox, rat and dog. Special attention has been paid to cilia and microvilli present at these surfaces, although the observations include various other structures such as small intracellular vacuoles present in the olfactory receptor endings and infrequent brush cells. Within the mucus overlying the olfactory epithelium membranous vesicles, often attached to olfactory cilia, are seen. Some of these show intramembranous particle distributions similar to those of the rest of the cilia, whereas others are devoid of particles. Smooth vesicles are also found in the mucus of other types of epithelium (respiratory epithelium and Bowman's glands). The freeze-fracture morphology of intracellular secretory vacuoles present in olfactory supporting, Bowman's and respiratory glandular cells of the frog is similar in all these epithelia. Quantitative comparisons are made of the different structures of interest. When corrected for cilia which were not observed, mammalian receptor endings bear 17 cilia on average, whereas frog receptor endings have 6 cilia. The relative magnitudes of the diameters of the cilia and microvilli are, except for frog, the same for all species studied. Dimensions of other structures e.g., axons, dendrites and dendritic endings are compared in the various species. Freeze-fracture diameters are usually larger than those seen by techniques using dehydration. Dendritic ending densities range from 4.5 × 10⁶ (frog) to 8.3 × 10⁶ (dog) endings per cm². Possible sex-dependent differences are only found for these densities and dendritic ending diameters.     

Ultrastructural evidence for multiple mucous domains in frog olfactory epithelium

Summary This study showed that the olfactory mucus is a highly structured extracellular matrix. Several olfactory epithelial glycoconjugates in the frog Rana pipiens were localized ultrastructurally using rapid-freeze, freeze-substitution and post-embedding (Lowicryl K11M) immunocytochemistry. Two of these conjugates were obtained from membrane preparations of olfactory cilia, the glycoproteins gp95 and olfactomedin. The other conjugates have a carbohydrate group which in the olfactory bulb appears to be mostly on neural cell-adhesion molecules (N-CAMs); in the olfactory epithelium this carbohydrate is present on more molecules. Localization of the latter conjugates was determined with monoclonal antibodies 9-OE and 5-OE. Ultrastructurally all antigens localized in secretory granules of apical regions of frog olfactory supporting cells and in the mucus overlying the epithelial surface, where they all had different, but partly overlapping, distributions. Monoclonal antibody 18.1, to gp95, labeled the mucus throughout, whereas poly- and monoclonal anti-olfactomedin labeled a deep mucous layer surrounding dendritic endings, proximal parts of cilia, and supporting cell microvilli. Labeling was absent in the superficial mucous layer, which contained the distal parts of the olfactory cilia. Monoclonal antibody 9-OE labeled rather distinct areas of mucus. These areas sometimes surrounded dendritic endings and olfactory cilia. Monoclonal antibody 5-OE labeled membranes of dendritic endings and cilia, and their glycocalyces, and also dendritic membranes.     

Polarized dendritic transport and the AP-1 mu1 clathrin adaptor UNC-101 localize odorant receptors to olfactory cilia

Odorant receptors and signaling proteins are localized to sensory cilia on olfactory dendrites. Using a GFP-tagged odorant receptor protein, Caenorhabditis elegans ODR-10, we characterized protein sorting and transport in olfactory neurons in vivo. ODR-10 is transported in rapidly moving dendritic vesicles that shuttle between the cell body and the cilia. Anterograde and retrograde vesicles move at different speeds, suggesting that dendrites have polarized transport mechanisms. Residues immediately after the seventh membrane-spanning domain of ODR-10 are required for localization; these residues are conserved in many G protein-coupled receptors. UNC-101 encodes a mu1 subunit of the AP-1 clathrin adaptor complex. In unc-101 mutants, dendritic vesicles are absent, ODR-10 receptor is evenly distributed over the plasma membrane, and other cilia membrane proteins are also mislocalized, implicating AP-1 in protein sorting to olfactory cilia.     

Prion Shedding from Olfactory Neurons into Nasal Secretions

This study investigated the role of prion infection of the olfactory mucosa in the shedding of prion infectivity into nasal secretions. Prion infection with the HY strain of the transmissible mink encephalopathy (TME) agent resulted in a prominent infection of the olfactory bulb and the olfactory sensory epithelium including the olfactory receptor neurons (ORNs) and vomeronasal receptor neurons (VRNs), whose axons comprise the two olfactory cranial nerves. A distinct glycoform of the disease-specific isoform of the prion protein, PrP^Sc, was found in the olfactory mucosa compared to the olfactory bulb, but the total amount of HY TME infectivity in the nasal turbinates was within 100-fold of the titer in the olfactory bulb. PrP^Sc co-localized with olfactory marker protein in the soma and dendrites of ORNs and VRNs and also with adenylyl cyclase III, which is present in the sensory cilia of ORNs that project into the lumen of the nasal airway. Nasal lavages from HY TME-infected hamsters contained prion titers as high as 10^3.9 median lethal doses per ml, which would be up to 500-fold more infectious in undiluted nasal fluids. These findings were confirmed using the rapid PrP^Sc amplification QuIC assay, indicating that nasal swabs have the potential to be used for prion diagnostics. These studies demonstrate that prion infection in the olfactory epithelium is likely due to retrograde spread from the olfactory bulb along the olfactory and vomeronasal axons to the soma, dendrites, and cilia of these peripheral neurons. Since prions can replicate to high levels in neurons, we propose that ORNs can release prion infectivity into nasal fluids. The continual turnover and replacement of mature ORNs throughout the adult lifespan may also contribute to prion shedding from the nasal passage and could play a role in transmission of natural prion diseases in domestic and free-ranging ruminants.     

Cytochemical localization of adenylate cyclase activity in rat olfactory cells

Summary Adenylate cyclase activity was demonstrated in the cilia, dendritic knob and axon of rat olfactory cells by using a strontium-based cytochemical method. The activity in the cilia and the dendritic knob was enhanced by non-hydrolyzable GTP (guanosine triphosphate) analogues and forskolin, and inhibited by Ca²⁺, all in agreement with biochemical reports of the odorant-sensitive adenylate cyclase. The results support the hypothesis of cyclic AMP working as a second messenger in olfactory transduction and imply that the transduction sites exist not only in the olfactory cilia but also in the dendritic knob. Enzymatic activity was also observed in the olfactory dendritic shaft by treating the tissue with 0.0002% Triton X-100, although the properties and role of the enzyme in this region are uncertain. The detergent inhibited the enzymatic activity in the cilia and the dendritic knob.     

Differential synthesis of β-tubulin isotypes in gerbil nasal epithelia

Compartmentalization of beta-tubulin isotypes within cells according to function was examined in gerbil olfactory and respiratory epithelia by using specific antibodies to four beta-tubulin isotypes (beta(I), beta(II), beta(III), and beta(IV)). Isotype synthesis was cell-type-specific, but the localization of the isotypes was not compartmentalized. All four isotypes were found in the cilia, dendrites, somata, and axons of olfactory neurons. Only two isotypes (beta(I) and beta(IV)) were present in the cilia of nasal respiratory epithelial cells. The beta(IV) isotype, thought to be an essential component of cilia, was present in olfactory neurons and respiratory epithelial cells, which are ciliated, but was not found in basal cells (the stem cells of olfactory sensory neurons, which have no cilia). Olfactory neurons therefore do not synthesize beta(IV)-tubulin until they mature, when functioning cilia are also elaborated. The failure to observe compartmentalization of beta-tubulin isotypes in olfactory neurons sheds new light on potential functions of the beta-tubulin isotypes.     

Green fluorescent protein (GFP) expression patterns in the olfactory epithelium of GFP transgenic cloned Jinhua pigs

Domestic pigs possess a well‐developed sense of smell. However, the morphology of the porcine olfactory epithelium (OE) is poorly understood. Recently, several strains of transgenic cloned pigs that are presumed to ubiquitously express green fluorescent protein (GFP) have been created. Thus, the purpose of this study was to elucidate the features of porcine OE using the tissues of GFP transgenic cloned pigs. Based on observations of Hematoxylin and Eosin staining and measurements of thickness, porcine OE tissue portions were classified into three categories (thick, standard, and thin). Cryosections revealed that the prominent GFP signals were expressed in olfactory sensory neurons (OSN), Bowman's glands, and olfactory nerve. A few GFP‐expressing sustentacular cells were seen; however, the intensity of GFP fluorescence was slight. In the thick portion, numerous GFP‐expressing polygonal OSN that did not possess dendrites were found. In the standard portions, GFP‐expressing cells had longitudinal dendrites. A few GFP‐expressing cells were found in the thin portion. In the thick and standard portions, most of the prominent GFP‐expressing cells were positive for olfactory marker protein. Moreover, double immunofluorescence staining with boiled GFP and Sox2 antibody revealed that GFP expression patterns in OSN are synchronized with Sox2 immunoreactive patterns.     

Histology and ultrastructure of the olfactory organ of the freshwater pulmonate Helisoma trivolvis

Summary The olfactory organ of Helisoma trivolvis is located on the surface of the body at the base of the cephalic tentacles. An evagination of skin, the olfactory plica, at the base of the tentacle extends over the olfactory organ dorsally. The epithelium of the olfactory organs contains unspecialized epithelial cells, ciliated epithelial cells, basal cells, mucous secretory cells, and sensory dendrites. The surface of the epithelium has a complex brush border of thick plasmatic processes, which branch to form several terminal microvillar twigs. Long slender cytoplasmic processes form a dense spongy layer among the plasmatic processes beneath the level of the terminal twigs. Bipolar primary sensory neurons clustered beneath the epithelium of the olfactory organ send dendrites through the epithelium to the free surface. Some sensory endings have a few short cilia, but most bear only microvilli. Cilia of sensory endings and epithelial cells extend beyond the brush border of the epithelium. Small axons arise from the perikarya of the sensory neurons and enter a branch of the olfactory nerve. HRP tracing indicates that the axons pass to the cerebral ganglion without interruption. Histochemical tests indicate that the sensory neurons are neither aminergic nor cholinergic.     

Genetic Ablation of Type III Adenylyl Cyclase Exerts Region-Specific Effects on Cilia Architecture in the Mouse Nose

We recently reported that olfactory sensory neurons in the dorsal zone of the mouse olfactory epithelium exhibit drastic location-dependent differences in cilia length. Furthermore, genetic ablation of type III adenylyl cyclase (ACIII), a key olfactory signaling protein and ubiquitous marker for primary cilia, disrupts the cilia length pattern and results in considerably shorter cilia, independent of odor-induced activity. Given the significant impact of ACIII on cilia length in the dorsal zone, we sought to further investigate the relationship between cilia length and ACIII level in various regions throughout the mouse olfactory epithelium. We employed whole-mount immunohistochemical staining to examine olfactory cilia morphology in phosphodiesterase (PDE) 1C^-/-;PDE4A^-/- (simplified as PDEs^-/- hereafter) and ACIII^-/- mice in which ACIII levels are reduced and ablated, respectively. As expected, PDEs^-/- animals exhibit dramatically shorter cilia in the dorsal zone (i.e., where the cilia pattern is found), similar to our previous observation in ACIII^-/- mice. Remarkably, in a region not included in our previous study, ACIII^-/- animals (but not PDEs^-/- mice) have dramatically elongated, comet-shaped cilia, as opposed to characteristic star-shaped olfactory cilia. Here, we reveal that genetic ablation of ACIII has drastic, location-dependent effects on cilia architecture in the mouse nose. These results add a new dimension to our current understanding of olfactory cilia structure and regional organization of the olfactory epithelium. Together, these findings have significant implications for both cilia and sensory biology.     

Binding of the pheromonal steroid, 5alpha-androst-16-en-3-one, to membrane-enriched fractions of boar and rat olfactory epithelium; preliminary evidence for binding protein being a glycoprotein

A high degree of binding of 5alpha-[3H]-androstenone was recorded in membrane-enriched fractions of porcine olfactory tissue. The specific (i.e. high affinity, low capacity) binding had a mean Ka approximately 2x10(8)M(-1). A Hill plot of the data showed a Hill coefficient of approximately 2, possibly suggesting co-operativity of binding, with binding constants increasing from 8x10(7) to 1.6x10(9)M(-1) with increasing substrate concentration. The level of specific binding of 5alpha-[3H]-androstenone was nearly 10-fold higher than in corresponding respiratory tissue preparations and was markedly reduced in the presence of excess (approximately 1 microM) unlabelled 5alpha-androstenone. Corresponding fractions derived from rat olfactory tissue showed only 25% of the binding recorded for the pig. After incubation of 5alpha-[3H]-androstenone with solubilised olfactory cilial tissue (porcine), gel filtration and chromatography on a typical "glycoprotein" column (Concanavalin A-Sepharose B) were performed. Specific binding was recorded only in fractions corresponding to glycoproteins with Mr of approximately 70-90 kDa. In a third series of experiments, fractions containing high concentrations of cilia, some still attached to the dendritic endings (as shown by electron microscopy) were obtained by a novel method involving stripping them off the nasal epithelium. The basal adenylate cyclase (AC) activity was very significantly (P<0.01) higher in olfactory, compared with respiratory, cilia; storage at -70 degrees C for 3 weeks greatly reduced AC activity. When fresh male and female porcine olfactory cilia preparations were incubated with 5alpha-androstenone plus GTP, AC activity was increased fourfold (P<0.01). However, responses of porcine respiratory cilia were not significant statistically, neither were changes in basal levels of AC activities in rat olfactory cilia.     

Heterogeneous distribution of the cAMP receptor protein RII in the nervous system: evidence for its intracellular accumulation on microtubules, microtubule-organizing centers, and in the area of the Golgi complex

The cellular and subcellular distribution of the regulatory subunit RII of cAMP-dependent protein kinase was studied by light and electron microscopy immunocytochemistry in tissue sections from rat brain and in primary cultures of brain cells. RII immunoreactivity was present in most neurons, although at variable concentration. In addition, RII was also detectable in other cell types including glia, neuroepithelial cells, and cells of mesenchymal origin. In the cell cytoplasm, RII immunoreactivity was concentrated at certain sites. An accumulation of RII immunoreactivity was found in all RII-positive cells at the Golgi area, precisely at a region directly adjacent to one of the two major faces of the Golgi complex. RII was also highly concentrated in some microtubule-rich cell processes such as cilia and neuronal dendrites, but was below detectability in most axons. In neurons, its concentration in dendrites is consistent with the previously demonstrated high affinity interaction between RII and the dendritic microtubule-associated protein 2. In addition, RII was accumulated at basal bodies of cilia and at centrosomes, i.e., sites known to act as microtubule organizers. RII-labeled centrosomes, however, were visible only in cells where the Golgi complex had a pericentrosomal organization, and not in cells where the Golgi complex was perinuclear such as in neurons and glia in situ. We hypothesize that centrosomal RII is bound to the pericentriolar microtubule-organizing material and that this material remains associated with the trans region of the Golgi complex when the latter is no longer associated with the centrosome. Our results suggest a key but not obligatory role of cAMP in the Golgi-centrosomal area, the headquarters of cell polarity, mobility and intracellular traffic, and in the function of a subpopulation of microtubules.     

Sodium/calcium exchanger in rat olfactory neurons

The chemo-electrical transduction process in olfactory neurons is accompanied by a rapid and transient increase in intracellular calcium concentrations. The notion that Na⁺/Ca²⁺ exchanger activities may play a major role in extruding calcium ions out of the cell and maintaining Ca²⁺ homeostasis in olfactory receptor cells was assessed by means of laser scanning confocal microscopy in combination with the fluorescent indicators Fluo-3 and Fura-Red. The data indicate that high exchanger acitivity, which was inhibited by amiloride derivatives, is located in the dendritic knob and probably in the olfactory cilia. This result was supported by experiments using specific antiserum raised against retinal Na⁺/Ca²⁺ exchanger protein which labelled an immunoreactive protein of 230 kDa in Western blots from olfactory tissue and strongly stained the ciliary layer of the olfactory epithelium.     

Dendritic Integration in Olfactory Sensory Neurons: A Steady-State Analysis of How the Neuron Structure and Neuron Environment Influence the Coding of Odor Intensity

Response properties of the receptor potential at steady state were analyzed in a biophysical model of an olfactory sensory neuron embedded in a multicell environment. The neuron structure was described as a set of several identical dendrites (or cilia) bearing the transduction mechanisms, joined to a nonsensory part—dendritic knob, soma, and axon. The different ionic compositions of the media surrounding the neuron sensory and nonsensory parts and the extraneuronal voltage sources, which both result from the presence of auxiliary cells, were also taken into account. Analytical solutions were found to describe how the receptor potential at the nonsensory part responds to a uniform change in the odorant-dependent conductance resulting from odorant stimulation of the sensory dendrites. We investigated the influence of various geometrical and electrical parameters on the receptor-potential response in the classical model neuron within a homogeneous environment and in the model neuron surrounded with auxiliary cells. First, it was found that the maximum amplitude of the receptor potential is independent of the neuron structure in the absence of auxiliary cells but not in their presence. In the latter case, the amplitude decreases with the length and number of sensory dendrites and with the input resistance of the nonsensory part. Second, the sensitivity (as measured by the increase in membrane conductance at half-maximum response) of the neuron model in the absence of auxiliary cells is higher, but its dynamic range is narrower than in their presence. The dynamic range is wide and the sensitivity low when the input resistance of the nonsensory part is small and the sensory dendrite is unbranched. Both sensitivity and dynamic range are higher for a longer dendrite. These results help understand the morphology of insect olfactory sensilla and can be generalized to other neuron types.     

Sensory and secretory cells ofOphryotrocha puerilis (Polychaeta)

Summary As revealed by glyoxylic acid induced fluorescence, the protandric polychaeteOphryotrocha puerilis possesses different types of catecholaminergic primary bipolar sensory cells, the perikarya of which are located beneath the epidermis. About 20 of such receptors are situated in each segment but they are mostly found on antennae, palps, urites and parapodial cirri. The dendrites of these sensory neurones run to the cuticle and dilate to form receptive endings. Three different types of dendritic endings could be distinguished: (1) multiciliary receptors with 4–8 cilia and ciliary rootlets, (2) monociliary receptors with microvilli arranged like a funnel and electron-dense cuffs and (3) monociliary receptors of the collar-type with, constantly, ten microvilli surrounding one single central cilium. The latter type is also characterized by rootlet fragments. Dendrites and dilated receptive endings of all three types contain clear (putative secretory) vesicles, multivesicular bodies and mitochondria. Pharmacological treatment (dopamine, reserpine) does not affect the number of secretory vesicles of the receptor neurones. Extra vesicular storage of catecholamines is discussed. Secretory cells of unknown function containing large numbers of electron-dense vesicles are usually found in close association with sensory cells.Abbreviations CA catecholamines - DA dopamine - RE reserpine     

Vomeronasal receptors in Turtles

Summary The functional similarities observed with electrophysiological techniques between olfactory and vomeronasal receptors allow speculation that morphological details essential to the common function should be observed in both cases. Both mucosae have primary receptors within the epithelium which are surrounded, but not completely isolated, by so-called supporting cells. These last secrete a granular product. In both epithelia receptor cells contact each other at the axonal, perikaryal, dendritic and junctional complex levels. The axons of the two types of receptors are unmyelinated and their diameter ranges from 0.1 to 0.4 micron. The most interesting difference between the two types of receptors lies at the level of their exposed endings. The olfactory vesicle, as it is classically represented in olfactory receptors and is common in those of turtles in the form of a ball-like protrusion above the epithelial surface, is usually missing in the vomeronasal receptors. These have a tapering cone-shaped irregular projection always complicated by a set of branched microvilli. They do, furthermore, consistently lack cilia. This observation is in agreement with recent TEM observations. The assumption that cilia are essential in the mechanism of olfactory transduction is discussed on the basis of these anatomical findings.     

The fine-structural distribution of G-protein receptor kinase 3, β-arrestin-2, Ca2+/calmodulin-dependent protein kinase II and phosphodiesterase PDE1C2, and a Cl−-cotransporter in rodent olfactory epithelia

The sequentially activated molecules of olfactory signal-onset are mostly concentrated in the long, thin distal parts of olfactory epithelial receptor cell cilia. Is this also true for molecules of olfactory signal-termination and -regulation? G-protein receptor kinase 3 (GRK3) supposedly aids in signal desensitization at the level of odor receptors, whereas β-arrestin-2, Ca²⁺/calmodulin-dependent protein kinase II (CaMKII) and phosphodiesterase (PDE) PDE1C2 are thought to do so at the level of the adenylyl cyclase, ACIII. The Na⁺, K⁺-2Cl^?-cotransporter NKCC1 regulates Cl^?-channel activity. In an attempt to localize the subcellular sites olfactory signal-termination and -regulation we used four antibodies to GRK3, two to β-arrestin-2, five to CaMKII (one to both the α and β form, and two each specific to CaMKII α and β), two to PDE1C2, and three to Cl^?-cotransporters. Only antibodies to Cl^?-cotransporters labeled cytoplasmic compartments of, especially, supporting cells but also those of receptor cells. For all other antibodies, immunoreactivity was mostly restricted to the olfactory epithelial luminal border, confirming light microscopic studies that had shown that antibodies to GRK3, β- arrestin-2, CaMKII, and PDE1C2 labeled this region. Labeling did indeed include receptor cell cilia but occurred in microvilli of neighboring supporting cells as well. Apical parts of microvillous cells that are distinct from supporting cells, and also of ciliated respiratory cells, immunoreacted slightly with most antibodies. When peptides were available, antibody preabsorption with an excess of peptide reduced labeling intensities. Though some of the antibodies did label apices and microvilli of vomeronasal (VNO) supporting cells, none immunoreacted with VNO sensory structures.     

Cell surface carbohydrates reveal heterogeneity in olfactory receptor cell axons in the mouse

Cell surface carbohydrates, both in the olfactory system and elsewhere, have been proposed to play critical roles in axon guidance and targeting. Recent studies have used plant lectins to study the heterogeneous distribution of carbohydrates in the olfactory system. One lectin, Dolichos biflorus agglutinin (DBA), heterogeneously labels subsets of glomeruli. In the olfactory epithelium DBA labeled a subset of olfactory sensory neurons (OSNs) including their cilia, dendrites, and somata. OSN axons were also labeled and readily observed in the olfactory nerve and bulb. The patterns of glomerular innervation by DBA labeled (DBA(+)) axons were diverse; some glomeruli contained many labeled axons, while others contained few or no labeled axons. To characterize the heterogeneous innervation of glomeruli, we double labeled olfactory bulbs with DBA and an antibody to olfactory marker protein (OMP). OMP colocalized in most, but not all, DBA(+) axons. To determine if those axons that did not express OMP were immature, we double labeled olfactory bulbs with DBA and anti-GAP-43. GAP-43 rarely colocalized with DBA, suggesting that DBA(+) axons are not, as a population, immature. Triple labeling with all three markers revealed a small subset of DBA(+) axons which did not express either OMP or GAP-43. Electron microscopy established that DBA labels axons in the olfactory nerve and DBA-labeled axons form typical glomerular axodendritic synapses.     

Qualitative and quantitative freeze-fracture studies on olfactory and respiratory epithelial surfaces of frog,ox, rat,and dog

Summary A comparison of the necklaces of sensory olfactory, and non-sensory nasal respiratory cilia of four vertebrate species (frog, ox, rat and dog) shows that the olfactory cilia have 7±1 (mean±standard deviation) strands in the three mammalian species and 6±1 strands in the frog; for the respiratory cilia these values are 5±1 and 4±1. This function- and species-dependency of ciliary necklace strand numbers is supported by a review of the literature. Necklaces show no other structural differences. Necklace strand densities range from 25–33 strands/m. In both sensory and non-sensory cilia ciliogenesis is preceded by the formation of necklace strands. Sometimes cilia do not develop properly, as demonstrated by the presence of necklace-like structures in the membranes of olfactory dendritic endings and respiratory axonemal aggregates.     

Sensory cells in the head skin of pond snails

Summary Several types of receptor endings were identified with scanning electron microscopy and silver-impregnation techniques in the skin of the tentacles, lips, dorsal surface of the head and mouth region of the pond snails Lymnaea stagnalis and Vivipara viviparus. Sensory endings at the tips of dendrites of primary receptor neurones, scattered below the epithelium, differ in structure, i.e., the endings exposed to the surface of the skin possess different proportions of cilia and microvilli, which vary in number, length, and packing. Type-I endings have microvilli and a few (1–5) cilia, 5–12 m in length. Type-2 endings have abundant (20–40), interwoven long (9–12 m) cilia and random microvilli. Type-3 endings show typical packing of 10–25 cilia in the form of bundles or brushes. They may be composed either of long (9–18 m) or short (2–7 m) cilia, or of both long and short ones. Microvilli here are absent. Type-4 endings have only microvilli. Two other types of skin receptors do not extend their sensory endings to the surface and can be indentified only in silver-stained preparations. Type-5 endings are branching dendrites of skin receptors cells that terminate among epithelial cells. In type-6, the sensory endings also terminate among epithelial cells but their cell bodies are located outside of the skin. In both species all skin regions examined possess the receptors of all six types differing only in their relative proportion. Possible functional roles of different receptors are discussed.