Ultrastructural characteristics of interneuronal and neuromuscular relations in the trunkal part of the intraepidermal nervous system in Nerilla sp. (Archiannelida)

This study deals with ultrastructural analysis of interneuronal and neuromuscular relations in a representative of archiannelid Nerilla sp. with primitive intraepidermal type of the nervous system. A particular attention has been paid to the area of ventral ciliate groove and the associated site of epidermis. In the ciliate groove, sensitive and motor cilia are revealed and described. Sites of axonal terminals of the sensitive cells supplied with cilia are noted in the epidermal nervous plexus. Epidermal-muscular cells and nervous terminals on them are revealed. Various interneuronal contact variants both of non-synaptic and of typically synaptic types are described. An attention is drawn to a rare presence of compounds from the type of tight junctions among interneuronal contacts in Nerilla sp. In sufficiently differentiated synapses of the chemical type, phenomena of exocytosis are described. There are shown specific features of innervation of longitudinal (somatic) musculature of the nerillid body with entrance of synaptic vesicles into the basal plate substance and their translocation into the depth of the muscular layer.     

The fine structure of the newly discovered propodial ganglia of the veliger larva of the nudibranch Onchidoris bilamellata

Summary Two pairs of ganglia are found in the propodial region of the veliger of Onchidoris bilamellata: the anterolateral pair is located at the foremost corners of the propodium, and the frontal pair is located beside the propodial midline. Both sets of ganglia are positioned below the epidermis, and they are joined to the cerebral ganglia by large, common connectives. Each ganglion possesses sensory cells, nerve cells and sheath cells, and the frontal pair contains a complement of secretory cells. Externally, the propodial ganglia are manifested as sensory fields. The fields of the anterolateral pair are elliptical in shape, and each appears as a band of cilia bordering an unciliated zone. The region devoid of cilia is composed of ordinary epidermal cells, whereas the ciliated portion is comprised of dendritic endings originating from cells in the ganglion. Dendrites arise from one type of sensory cell and pass through the epidermis in bundles. Each dendrite terminates as a single cilium at the epidermal surface. Sensory fields of the frontal ganglia are key-shaped and oppose one another on the anterior end of the foot. Each field appears as a flat, circular, unciliated region which extends into a ciliated groove that runs dorsally toward the mouth. The groove contains the terminals of secretory cells, ciliated sensory cells, and the cell bodies of nonciliated sensory cells. The nonciliated sensory cells, characterized by a microvillous apex, are the dominant cells in the flattened circular zone. The space between the frontal ganglia and the epidermis is bridged by bundles of processes which are similar to those of the anterolateral ganglia. However, these tracts contain collections of the apical processes of secretory cells, the dendrites of ciliated sensory cells, and the axons of nonciliated sensory cells. Morphological and behavioral evidence indicates that the propodial ganglia serve a chemosensory function during settlement and metamorphosis.     

On the Fine Structure of Rastrognathia macrostoma gen. et sp.n. Placed in Rastrognathiidae fam.n. (Gnathostomulida)

Rastrognathia macrostoma gen. et sp.n. is described as belonging to Rastrognathiidae fam.n. The ultrastructure is described, especially the nervous and digestive systems and the epidermal specializations. In the epidermis the single cilia belong to the choanocyte-like cell type. An epidermal sensory cell with several cilia is described. The intraepithelial nervous system shows an orthogon pattern. Two ventral nerve trunks unite into a buccal ganglion. The jaws are secreted by the buccal epidermis. The endoderm consists of a single cell type. The food consists of bacteria. The mesodermal elements consist of six main longitudinal muscles.     

Neuronal Gap Junctions in Cortical Columns and Nuclei of the Ventral Thalamus of Rats

Functional cortical columns and nuclei of the ventral thalamus play a key role in processing of sensory information; therefore, detailed studies on formation of neuron-to-neuron gap junctions in these areas are of great theoretical and practical importance. In the present study, we applied electron-microscopy methods to examine the structure and specific distribution of interneuronal gap junctions in the cortical layer IV and thalamic nuclei, including VPM, RTN, Pom, and VPL. In the cortex, we found more interneuronal gap junctions than in thalamic nuclei. In all structures studied we revealed and described axo-dendritic, dendrodendritic, and “mixed” synapses. We report on the axo-dendritic gap junctions for the first time. It is suggested that this type of contacts plays some functional role in local synchronization of neuronal activity within one ensemble on the presynaptic level.     

淡水鱼类寄生肠袋虫一新种

19851986年,作者于长江上游的四川省忠县、涪陵两地收到的中华倒刺鲃(Barbodes sinensis Bleeker)肠道中发现一种肠袋虫,感染率为50％。经仔细观察比较,确定为一新种,命名为涪陵肠道虫(Balantidium fulinensis sp.nov.),现将其形态描述于后。       

Ultrastructure of the tentacle nerve plexus and putative neural pathways in sea anemones

Abstract. Neurons of sea anemone tentacles receive stimuli via sensory cells and process and transmit information via a plexus of nerve fibers. The nerve plexus is best revealed by scanning electron microscopy of epidermal peels of the tentacles. The nerve plexus lies above the epidermal muscular layer where it appears as numerous parallel longitudinal and short interconnected nerve fibers in Calliactis parasitica . Bipolar and multipolar neurons are present and neurites form interneuronal and neuromuscular synaptic contacts. Transmission electron microscopy of cross sections of tentacles of small animals, both C. parasitica and Aiptasia pallida , reveals bundles of 50–100 nerve fibers lying above groups of longitudinal muscle fibers separated by intrusions of mesoglea. Smaller groups of 10–50 slender nerve fibers are oriented at right angles to the circular muscle formed by the bases of the digestive cells. The unmyelinated nerve fibers lack any glial wrapping, although some bundles of epidermal fibers are partially enveloped by cytoplasmic extensions of the muscle cells; small gastrodermal nerve bundles lie between digestive epithelial cells above their basal myonemes. A hypothetical model for sensory input and motor output in the epidermal and gastrodermal nerve plexuses of sea anemones is proposed.     

Interneuronal synapses in the local ganglia of the cat urinary bladder.

The interneuronal synapses of the urinary bladder in the cat were studied by electron microscopy. The great majority of the fibres containing vesicles are found within the ganglia occurring in the trigonum area. Morphologically differentiated synaptic contacts could be observed on the surface of the local neurons and between the different nerve processes. The presynaptic terminals can be divided into three types based on a combination of synaptic vesicles. Type I terminals, presumably cholinergic synaptic terminals, contain only small clear vesicles of 40-50 nm in diameter. Type II terminals, presumably adrenergic terminals, are characterized by small granulated vesicles of 40-60 nm in diameter. Type III terminals, probably of local origin, contain a variable number of large granulated vesicles of 80-140 nm in diameter. Occasionally, a single nerve fibre contacted several (two or four) other nerve processes forming a typical synapse. In other cases, on one nerve cell soma or on other nerve processes there are two or three different-type nerve terminals establishing synapses. It might be inferred from these observations that convergence and divergence can occur in the local ganglia and that cholinergic and adrenergic synaptic terminals can modulate the ganglionic activity. However, a local circuit also can play an important role in coordinating the function of the bladder.     

Vesicular glutamate transporter 2 is expressed in different nerve fibre populations that selectively contact pulmonary neuroepithelial bodies

Pulmonary neuroepithelial body (NEB) receptors in rats receive at least four different nerve fibre populations. In addition to a spinal sensory innervation that contacts NEBs at their basal side, extensive vagal nodose sensory terminals and separate nitrergic and cholinergic nerve endings protrude between NEB cells. In the present study, antibodies against the vesicular glutamate transporter 2 (VGLUT2), a transmembrane protein responsible for loading glutamate into synaptic vesicles, were used to investigate whether some of the nerve terminals contacting NEBs in rat lungs might use glutamate as a neurotransmitter. VGLUT2 immunoreactivity (IR) was detected in extensive intraepithelial arborising nerve terminals that appeared to contact most of the NEBs. Multiple immunostaining showed VGLUT2 IR in the vagal nodose and spinal sensory nerve terminals contacting NEBs, and in another, most likely sensory, intraepithelial nerve fibre population, the origin and further characteristics of which remain to be elucidated. At least part of the VGLUT2-immunoreactive nerve fibres that contact NEBs were shown to be myelinated. The expression of VGLUT2 indicates that glutamate is stored and released as a neurotransmitter in terminals of several pulmonary (sensory) nerve fibre populations that selectively relate to the complex NEB receptors. The present study strongly suggests an involvement of glutamatergic mechanisms in the peripheral transduction of sensory stimuli from the lungs, via the release of glutamate from nerve terminals, thereby modulating the activity of NEB receptor cells or the excitability of afferent nerves.     

Cellular organization of the common nerve plexus of the body wall of the <Emphasis Type="Italic">Nephthys ciliata</Emphasis> (polychaeta) in connection with problem of relative morphofunctional autonomization of the peripheral part of the central nervous system of annelids

The study deals with neurohistological analysis of the common nerve plexus of the body wall of the polychaete Nephthys ciliata. Cellular composition and interneuronal relationships in subepidermal and intramuscular areas of the nerve plexus are demonstrated. Morphological data are presented on a possible origin of typical associative and, presumably, motor neurons located outside the abdominal ganglion on the basis of differentiating primary sensory bipolars. Axo-axonal, axo-dendritic, and axo-somatic interneuronal contacts are shown in the nerve plexus. A characteristic feature of the studied peripheral nerve plexus of the body wall of the Nephthys ciliata is emphasized: the sufficiently intensive development of associative neuronal population. This provides a structural basis for peripheral integration of nervous processes in the central nervous system of the whole animal. Small groups of sensory and associative neurons described in the present study also seem to contribute to a relative autonomization of the peripheral part of the central nervous system of Nephthys ciliata. This can also be promoted by single suggested motor neurons of the plexus. The studied nerve plexus is actually deprived of typical associative-motor neurons that are so characteristic of the abdominal ganglion of polychaetes, oligochaetes, and leeches.     

Ultrastructure and chaetotaxy of sensory receptors in the cercariae of a species of Crepidostomum Braun, 1900 and Bunodera Railliet, 1896 (Digenea: Allocreadiidae)

Previous investigations of cercarial sensory systems have focused on chaetotaxy and ultrastructure of sensory receptors and have revealed chaetotaxic patterns within families, genera, and species as well as different types of sensory receptors. However, chaetotaxic and ultrastructural observations have rarely been combined. We investigated the ultrastructure of cercarial sensory receptors in conjunction with the chaetotaxy and neuromorphology in 2 allocreadiid species belonging to the genera Crepidostomum and Bunodera. Cercariae were treated with acetylthiocholine iodide and silver nitrate, and for scanning electron microscopy (SEM) and transmission electron microscopy (TEM). Similar cholinergic nerve networks were revealed. Chaetotaxy was consistent with that of other allocreadiids. Seven and 6 types of receptors were distinguished with SEM in Crepidostomum sp. and Bunodera sp., respectively. Types differed in number of cilia (1 or 2), cilium length (short, moderately long, or long), presence or absence of a tegumentary collar and a domelike base, and tegumentary collar length (low, moderately low, or high), TEM of some types revealed unsheathed cilia, basal body, and thickened nerve collars. Some receptor types were site specific. Thus, long uniciliated receptors were concentrated on the dorsal surface. Other types, such as short uniciliated receptors, were widespread throughout most regions. Ultrastructure and site-specificity observations suggest that most receptors are mechanoreceptors.     

The fine structure of ciliated sensory cells in the epidermis of the earthworm Lumbricus terrestris

An ultrastructural study of the earthworm body wall has revealed three types of sensory cells. Two, the multiciliate and uniciliate sensory cells, are found only in the discrete sense organs and their cilia pass vertically through the cuticle. The third type-isolated multiciliate sensory cells-are scattered throughout the epidermis and never grouped together. However, their cilia do not pass through the cuticle, but run horizontally over the outer surface of the epidermal cells. The structure of the sensory cells is described and compared with that of ordinary epidermal cells and the supporting cells found in the sense organs. Their possible physiological roles are discussed.     

Sensory receptors of the miracidium of Gigantocotyle explanatum (Trematoda:Paramphistomidae)

Five types of sensory receptors are described. Both uniciliated and multiciliated nerve endings occur on the apical papilla. The former structures possibly have a tango- or rheo-receptive function, while the latter may have a chemoreceptive function. A number of uniciliated sensory structures are also present embedded within the intercellular ridges. A pair of unciliated lateral papillae are located in the intercellular ridge separating the first and second tiers of epidermal cells. Each is associated with a number of sheathed unciliate nerve bulbs. A pair of internal “lamellate ciliary organs” are ascribed a photoreceptive function. Each comprises a cylindrical cell body enclosing a large cavity, into which project eight or more cilia bearing a number of concentrically arranged spherical lamellae. A single unicellular “conical organ”, covered with microvilli, projects into an extracellular space, bounded in part by the lateral glands. This structure may represent a second type of photoreceptor, or alternatively may serve as a gyroscopic device.     

Ultrastructural organization of the synapses in ganglia of the hen intestinal nerve under various conditions of its activity

The interneuronal connections in ganglia of the caudal part of the hen intestinal nerve of Remak are presented as axodendritic and axosomatic synapses and symmetric axo-axonal, dendro-dendritic and axodendritic contacts, often forming complicated complexes. Under conditions of preliminary decentralization or under certain disturbances of nervous connections with the intestine, a part of synapses remains, and a part of them degenerates, this demonstrates participation of peripheral afferent neurons in formation of the synaptic apparatus of the ganglia mentioned. The axonal terminals differentiate by composition of the synaptic vesicles: some contain mainly light agranular vesicles, others--a large amount of granular ones. The characteristic peculiarities of the hen intestinal nerve ganglia, in contrast to analogous mammalian ganglia, are abundant axosomatic synapses in some neurons, and presynaptic terminals, containing a large number of granular vesicles.     

Synaptic contacts established by primary sensory fibers innervating the teeth of rats: An ultrastructural study of the pars interpolaris of the spinal trigeminal nucleus

Transganglionic degeneration was used in an electron microscopic study of afferent synaptic contacts in the dorsomedial region of the pars interpolaris of rats. In one experiment, the left inferior alveolar nerve was transected and in the other, partial pulpectomy of the first and second left lower molars was performed. Well defined degenerating terminals, almost completely occupied by round synaptic vesicle profiles were found in both ipsi and contralateral sides. In both experiments, approximately 70% of these terminals formed single asymmetric contacts with intermediate or distal dendritic segments. Fewer contacts were observed with proximal dendritic segments, dendritic spines, perikarya and other terminals. In addition, double and multiple synaptic contacts (synaptic glomeruli), accounting for 10% of the total, were also observed. Quantitative data regarding ultrastructural synaptic elements suggest that there is no preference for post-synaptic sites of fibers related to different sensory modalities such as pain, conveyed by dental fibers or other modalities, conveyed by the inferior alveolar nerve fibers.     

Neurosecretory fibres in the median eyes of the scorpion,Androctonus australis L.

Summary The retina of the median eyes of the North African scorpion, Androctonus australis L., is supplied with numerous neurosecretory nerve fibres which establish synaptoid contacts on the retinula cells. The number of fibres or profiles of varicosities of fibre terminals associated with a retinular unit (five retinula cells with a fused rhabdom) varies between 10 and 20. Electron-opaque vesicles with a diameter of 80–100 nm are abundant within the axonal profiles. The synaptoid junctions are characterized by postsynaptic electron-dense material on the inner leaflet of the retinula cell membrane and, frequently, presynaptic submembranous dense material. Because of these ultrastructural features, the junctions observed here resemble typical interneuronal synaptic contacts. Hence this kind of neurosecretory junction appears to be unique among arthropods.It is suggested that the neurosecretory fibres within the retina represent the efferent pathways for the control of the circadian pigment movements within the retinula cells.Supported by the Deutsche Forschungsgemeinschaft (F1 77/7)     

Scanning electron microscopy of the channel catfish olfactory lamellae

The olfactory lamellae of the channel catfish (Ictalurus punctatus) are composed of sensory and indifferent (non-sensory) epithelia organized into two distinct regions on both surfaces of each lamella. The smaller sensory region located adjacent to the midline raphe has fewer cilia per unit surface area than the indifferent epithelium and contains the olfactory neurons whose ciliated dendritic terminals occur at the epithelial surface. The indifferent epithelium, comprising the greater surface area of the olfactory lamella, is covered with a dense mat of non-sensory cilia. Fractured carbon dioxide critical point dried lamellar tissue revealed the underlying cellular structure. The lamellae are composed of two layers of epithelium enclosing a thin stromal layer. Olfactory receptors were observed in the fractured tissue only within the sensory epithelium.     

Immunohistochemical analysis of substance P containing nerve fibres and their contacts with mast cells in the diabetic rat's tongue

Sensory neuropathy is common symptom of the diabetes mellitus and the prevalence of oral lesions is higher in diabetic patients. The distribution of substance P was studied immunohistochemically in streptozotocin induced diabetic rat's tongue. The morphological association of sensory nerves (substance P immunoreactive) with mast cells (nerve fibre-mast cell contact) was monitored. The substance P nerve fibre mast cell contacts were very scanty in control tongue. The number of substance P nerve terminals and mast cells was significantly increased (p < 0.05) in diabetes mellitus after 4 weeks of the treatment compared with the control tongue. The number of mast cell nerve contacts was even more significantly increased (p < 0.001) in diabetes. The distance between nerve fibres and mast cells was about 1 mm and very often less than 200 nm. In some instances, the mast cells were degranulated in the vicinity to nerve fibres. Increased number of mast cell nerve contacts in neurogenic inflammation might cause vasoconstriction and lesions of the oral mucosa, so some disorders such lichen planus, leukoplakia and cancer might frequently develop in diabetes mellitus.     

Neurochemical pattern of the complex innervation of neuroepithelial bodies in mouse lungs

As best characterized for rats, it is clear that pulmonary neuroepithelial bodies (NEBs) are contacted by a plethora of nerve fiber populations, suggesting that they represent an extensive group of multifunctional intraepithelial airway receptors. Because of the importance of genetically modified mice for functional studies, and the current lack of data, the main aim of the present study was to achieve a detailed analysis of the origin and neurochemical properties of nerve terminals associated with NEBs in mouse lungs. Antibodies against known selective markers for sensory and motor nerve terminals in rat lungs were used on lungs from control and vagotomized mice of two different strains, i.e., Swiss and C57-Bl6. NEB cells were visualized by antibodies against either the general neuroendocrine marker protein gene-product 9.5 (PGP9.5) or calcitonin gene-related peptide (CGRP). Thorough immunohistochemical examination of NEB cells showed that some of these NEB cells also exhibit calbindin D-28 k (CB) and vesicular acetylcholine transporter (VAChT) immunoreactivity (IR). Mouse pulmonary NEBs were found to receive intraepithelial nerve terminals of at least two different populations of myelinated vagal afferents: (1) Immunoreactive (ir) for vesicular glutamate transporters (VGLUTs) and CB; (2) expressing P2X₂ and P2X₃ ATP receptors. CGRP IR was seen in varicose vagal nerve fibers and in delicate non-vagal fibers, both in close proximity to NEBs. VAChT immunostaining showed very weak IR in the NEB-related intraepithelial vagal sensory nerve terminals. nNOS- or VIP-ir nerve terminals could be observed at the base of pulmonary NEBs. While a single NEB can be contacted by multiple nerve fiber populations, it was clear that none of the so far characterized nerve fiber populations contacts all pulmonary NEBs. The present study revealed that mouse lungs harbor several populations of nerve terminals that may selectively contact NEBs. Although at present the physiological significance of the innervation pattern of NEBs remains enigmatic, it is likely that NEBs are receptor–effector end-organs that may host complex and/or multiple functional properties in normal airways. The neurochemical information on the innervation of NEBs in mouse lungs gathered in the present study will be essential for the interpretation of upcoming functional data and for the study of transgenic mice.     

Ultrastructure of the nuchal organ in the interstitial polychaete Stygocapitella subterranea (Parergodrilidae)

The nuchal organs of Stygocapitella subterranea are paired narrow pits. They are lined by unciliated cells at the opening and by ciliated cells at the basal parts. The primary sensory cells (6–8) are arranged in a single patch at the bottom of the nuchal pit. The nuclei of the sensory cells are located in the posterior portion of the brain. Their dendrites form the nuchal nerve which is sheathed by the ciliated cells. Each sensory cell bears up to 4 modified sensory cilia and several microvilli extending into the olfactory chamber. The sensory cilia show various patterns of axonemal organization and have no rootlets. The olfactory chamber is covered by a cuticular matrix. Another primary sensory cell lies at the opening of the nuchal pit. It bears cilia which penetrate the cuticle but are enveloped by the epicuticle. Retractor muscles insert caudally on the organ. The nuchal organ of S. subterranea shows similarities to those of opheliids but exhibits several features not to be found in other nuchal organs.     

Identification and Pattern of Primary Sensory Cells in the Body Wall Epithelium of the Tubificid Worm, Limnodrilus hoffmeisteri

This study compares the effectiveness of two examination methods suitable for morphological observations, scanning electron microscopy (SEM) and light microscopic NADH-diaphorase (NADP-d) histochemistry, to identify location and distribution pattern of primary sensory cells situated in the body wall epithelium of Limnodrilus hofmeisteri. SEM observations revealed that grouped sensory cells forming two distinct types of sensillas (or sense organs) are scattered over the body surface. The easily identifiable first type (ciliated sensilla) contains numerous penetrative ciliate sensory cells while no ciliate sensory cells were seen in the second type (sensory bud). NADH-d staining proved to be a suitable method to identify both structures further staining solitary sensory cells, and certain sensory fibres that could not be visualised by SEM preparations. Our results show that NADH-d staining, as a histochemical marker of primary sensory cells, is a suitable and effective method to reveal their morphology and distribution pattern in whole mount preparations in the smallest detail, suggesting that the application of this relatively simple and cheap method may contribute to understand the basic organisation and evolution of the peripheral sensory structures of oligochaetes.