Chaetotaxy and ultrastructure of sensory receptors in the cercaria of a species of Allassogonoporus Olivier, 1938 (Digenea:Lecithodendriidae)

A standard procedure that combines chaetotaxic, ultrastructural and neuromorphological observations has recently provided a new perspective to the study of cercarial sensory systems. In the present work, we aimed to extend the use of this combination of techniques to investigate the chaetotaxy of Allassogonoporus sp. in conjunction with the ultrastructure of sensory receptors and neuromorphology. Five nerve regions were distinguished. A conspicuous bilobed cerebral ganglion was observed at the level of the pharynx. The chaetotaxic pattern was generally consistent with that of other lecithodendriids. Four types of receptors were distinguished with scanning electron microscopy. These types differed in cilium length (short, moderately long or long) and tegumentary collar length (moderately low or high). Internal ultrastructure of receptor type IIAL revealed an unsheathed cilium, a closed basal body, septate extracellular junctional complexes and thickened nerve collars. Some receptor types were site-specific. Long uniciliated receptors were found mainly on the dorsal surface, whereas short uniciliated receptors were widespread across the tegument. Ultrastructure and site-specificity observations suggest that most sensory receptors are mechanoreceptors, probably reflecting the important role mechanoreception plays in host finding.     

Ultrastructure and chaetotaxy of sensory receptors in the cercaria of a species of Allopodocotyle Pritchard, 1966 (Digenea: Opecoelidae)

Previous investigations of sensory systems in opecoelid cercariae have focused on chaetotaxy and ultrastructure of sensory receptors. They revealed chaetotaxic patterns within family, genus, and species as well as different receptors. Chaetotaxic and ultrastructural observations have rarely been combined. We investigated the ultrastructure of cercarial sensory receptors in conjunction with chaetotaxy and neuromorphology in a species of Allopodocotyle. Cercariae were treated with acetylthiocholine iodide and silver nitrate, and some were processed for light, scanning (SEM), and transmission (TEM) electron microscopy. Five nerve regions were distinguished. Chaetotaxy was consistent with that of other opecoelids. Five types of receptors were distinguished with SEM. Types differed in number of cilium-like structures (one or more), length of cilium-like structure (short, moderately long, or long), presence or absence of a tegumentary collar, and length of tegumentary collar (low, moderately low, or very high). Internal ultrastructure of some types revealed unsheathed cilium-like structures, basal body, and thickened nerve collars. Possible subtegumentary and sheathed receptors are introduced. Some receptor types were site-specific. For example, receptors with multiple cilium-like structures were concentrated on cephalic region whereas receptors with short cilium-like structure were widespread throughout most regions. Ultrastructure and site-specificity observations suggest that most receptors are mechanoreceptors.     

Description and surface topography of the cercaria of Austrobilharzia sp. (Digenea: Schistosomatidae)

The cercaria of Austrobilharzia sp. from the marine prosobranch gastropod Planaxis sulcatus in Kuwait Bay is described. The surface microtopography and pattern of the tegumentary sensory receptors are examined using scanning electron microscopy. The general microtopography of the surface of the cercaria is similar to that previously observed in cercariae of mammalian schistosomes, although differences are recorded in the types, numbers and distribution of the sensory receptors. The study identified more than 13 types of receptors comprising aciliated, uniciliated and for the first time a multiciliated receptor in a strigeid cercaria. The ciliated receptor types differ in the cilium length and structure of the surrounding collar and tegumentary base. The receptor types are site specific: (1) the aciliated and pitlike on the anterior organ-neck region and ventral sucker; (2) the uniciliated with a long flexible cilium with or without collar or a tegumentary base on the body and tail; and (3) the uniciliated with a short rigid cilium and a robust collar and tegumentary base, and the multiciliated with 6 flexible cilia and a high cylindrical collar on the anterior organ tip. The reported SEM information on the sensory receptors may contribute to elucidating their functional role and to establishing morphological characters for the phylogeny of the family Schistosomatidae.     

Topography and ultrastructure of the tegument of Bucephalus anguillae (Digenea: Bucephalidae), a parasite of the European eel Anguilla anguilla (Osteichthyen: Anguillidae)

The tegumental ultrastructure of the intestinal fluke Bucephalus anguillae was studied with the use of scanning and transmission electron microscopy. The surface of the tegument is covered by transverse ridges from which protrude numerous closely packed, digitated, and claw-shaped spines. Cobblestone-like units of the tegument were observed on the crescent-shaped formation of the rhynchus and at the posterior part of the body. Three types of sensory structures were examined, i.e., 2 uniciliated receptors and 1 without cilia. As anterior-posterior differences were observed, particular attention was given to spines and sensory receptors. Spine insertion zones and average cilia length are variable between anterior and posterior tegument areas. Ultrastructural study revealed that the tegument of B. anguillae has a typical syncytial organization with a distal cytoplasm lying over a basal matrix and cytons below. Cytoplasmic bridges allowed transit of secretory vesicles and granules. Diagrams of spines and sensory receptors were made to help in understanding the nature of these structures.     

The Nervous System of the Male Dinophilus gyrociliatus (Annelida: Polychaeta). I. Number, Types and Distribution Pattern of Sensory Cells

The entire nervous system of the smallest annelid hitherto known, the dwarf male of the highly dimorphic species Dinophilus gyrociliatus , has been reconstructed by means of TEM investigations of serial ultrathin sections. Altogether there are 68 neurons, 40 of which have a sensory function. The structure and distribution of them is described. The receptor endings of the 20 sensory cells of each side are located either in two groups — the anterior receptor group and the posterior receptor group — or are singly positioned in the integument. Structural differences of the apical portion of the dendrites enables four types of receptors to be distinguished: three types with emergent cilia and one type with non-emergent cilia. Neurons with emergent cilia can be monociliated collar cells as well as mono- or multiciliated cells without collar. Special vesicle-in-vesicle structures, are located close to the basal portion of the cilia in some of these cells. The non-emergent cilia border closely to a neighbouring epidermal cell and contain a prominent intraciliary vesicle. The function of receptors is discussed with regard to a comparison with receptors in other polychaete species, structural specializations and their distribution pattern on the animal's surface.     

Observations on cercarial chaetotaxy as a means for the identification of European species of Trichobilharzia Skrjabin & Zakharow, 1920 (Digenea: Schistosomatidae)

In order to evaluate the importance of cercarial chaetotaxy in the identification of European avian schistosomatids of the genus Trichobilharzia Skrjabin & Zakharow, 1920, papillary patterns of T. franki Müller & Kimmig, 1994 and T. ocellata (La Valette, 1855) Brumpt, 1931 were examined and compared. Scanning electron microscopy (SEM) was also employed to confirm the number and distribution of the sensory papillae. The chaetotaxy of T. franki and T. ocellata were identical, which suggests a close kinship between the two species. Some sensory papillae stained insufficiently with silver nitrate or were difficult to examine using light microscopy. Thus, the use of SEM in future examinations of Trichobilharzia chaetotaxy will ensure the collection of data that are comparable between studies, even though some argentophilic structures are not visible using SEM.     

日本棘隙吸虫体被超微结构的研究

本文报道扫描电镜观察下日本棘隙吸虫皮式、体棘和3种感觉乳突的形态和分布。     

Life cycle of Brachylaima mascomai n. sp. (Trematoda: Brachylaimidae), a parasite of rats in the Llobregat delta (Spain)

The terrestrial triheteroxenous life cycle of Brachylaima mascomai n. sp. (Trematoda: Brachylaimidae) is elucidated. Operculated, assymetric, embryonated eggs (25.4 x 12.7 microm) are passed with feces of the natural (Rattus norvegicus and R. rattus) and experimental (albino and wild mice, albino rats, Apodemus sylvaticus, Mus spretus [Muridae] and the golden gerbil) definitive hosts and ingested by the helicid gastropod Pseudotachea splendida, the only natural and experimental first intermediate host. Microcaudate cercariae harbored in branched sporocysts in the digestive gland emerge from this snail and contact P. splendida, Otala punctata, Theba pisana, and Helix (C.) aspersa snails developing into unencysted infective metacercariae in the kidney. Definitive hosts are infected by ingestion of infected snails; the adult parasites inhabit the small intestine. Chaetotaxic cercarial pattern specific at acetabular (S(II) 8-10 papillae) and cephalic (C(III) 13-15 papillae, H 16 papillae) levels. Three types of cercarial papillae are observed by scanning electron microscopy (SEM) and their arrangement is correlated with chaetotaxy for the first time in trematodes: argentophilic papillae with fingerlike process (cephalic, body, and acetabular levels), argentophilic papillae with opening (2 papillae in the M body level), and nonargentophilic dome-shaped papillae (alternated with argentophilic S(II) papillae on the ventral sucker). SEM detected interlacing network of ridges covering the metacercarial body. Adults with multidigitate tegumentary spines were observed by SEM. Subequal suckers; the acetabulum located in the posterior part of anterior fifth of body. Vitellaria extend from between middle level and anterior margin of anterior testis to between middle level and posterior margin of acetabulum. Uterus almost reaches the intestinal bifurcation.     

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.     

纤细背孔吸虫体被超微结构的研究

本文对人工感染获得的纤细背孔吸虫Notocotylus attenuatus(Rud.,1809)成虫的体被进行了扫描电镜观察。发现虫体不同部位的体被有着不同的被式。口吸盘处为放射状条索;虫体腹面口吸盘后至中列第一腹腺前为无棘区,呈石板条块状,其余部分均为银杏叶和尖叶形体棘所覆盖。虫体背面边缘一圈为有棘区,其圈内为珠状突起结构。     

Ciliated sensory receptors of the unactivated metacestode of Hymenolepis microstoma

The fine structure of the ciliated sensory endings of the unactivated metacestode of Hymenolepis microstoma is described. The type I sensilla, localized in areas of the scolex and sucker tegument, are characterized by a long cilium (1.20 × 0.20 μ) embedded in a bulb containing two electron-dense collars and three to five mitochondria. The type II sensilla, located in tegumentary pits of the rostellum, are characterized by a short cilium (0.62 × 0.28 μ) possessing ciliary rootlets, embedded in a bulb containing a single electron-dense collar and one to three mitochondria. Both sensory cilia are characterized by a 9 + 6 + 1 microtubular substructure. The sensory bulbs contain large numbers of membrane bound electron-lucent vesicles; neurotubules are absent at this stage of development.     

Ultrastructure of sensory cells on the mantle tentacles of the gastropod Notoacmea scutum

Previous studies have indicated that the mantle margin of the gastropod mollusc Notoacmea scutum is sensitive to chemical, photic, and mechanical stimulation. Here, the ultrastructure of sensory cells on the mantle tentacles of N. scutum is examined by transmission electron microscopy to determine if morphological types of sensory cells can be correlated with known sensory capabilities. The sensory cells of the mantle tentacles are found to be ciliated, primary receptors with subepithelial nuclei. The ciliated sensory endings are concentrated at the tip of the tentacles, but also occur in smaller numbers along the shaft. Ultrastructural differences between cilia form the basis of distinguishing two types of sensory ending. Type 1 sensory endings, which are over 90% of the endings, bar unusual cilia that typically are filled with an electron-dense material. Type 2 sensory endings bear cilia that have a 9 + 2 arrangement of longitudinal elements and thus more closely resemble previously reported sensory cilia of molluscs.     

Ultrastructure of multiciliated collar cells in the pilidium larva of Lineus bilineatus (Nemertini)

Summary The ultrastructure of the apical plate of the free-swimming pilidium larva of Lineus bilineatus (Renier 1804) is described with particular reference to the multiciliated collar cells. In the multiciliary collar cells there are several, up to 12, cilia surrounded by a collar of about 20 microvilli extending from the cells' apical surface. The cilia have the typical 9+2 axoneme arrangement and are equipped with striated caudal rootlets extending from the basal bodies. No accessary centriole or rostral rootlet were observed. Microvilli surrounding the cilia are joined in a cylindrical manner by a mucus-like substance to form a collar. In comparison with many sensory receptor cells built on a collar cell plan the multiciliary collar cells of the pilidium larva apical plate are rather simple and unspecialized. In other pilidium larvae monociliated collar cells are found in the apical plate. The possible function and phylogenetic implications of multiciliated collar cells in Nemertini are briefly discussed.List of Abbreviations a axoneme - b basal body - c cilia or flagella - d desmosome - G Golgi apparatus - m mitochondria - mf microfilaments - mu mucus - mv microvilli - n nucleus - nt neurotubules - pm plasma membrane - r rootlet - ri ribosomes - v secretory vesicles     

Photoreceptors of Bryozoan Larvae (Cheilostomata, Cellularioidea)

The ultrastructure of potential photoreceptors in larvae of Tricellaria occidentalis and four species of Bugula is described and compared with previously reported photoreceptors in larvae of Bugula neritina and Scrupocellaria bertholetti. A single sensory cell forms the functional unit of each photoreceptor. This cell is distinguished by a concentration of pigment vesicles in its apical part, a direct connection with the nervous system, and a large number of cilia that form the photoreceptoral organelle. These cilia have axonemes morphologically identical to those of motile cilia. The membranes of sensory cilia are unbeaded and qualitatively less osmophilic than those of the motile cilia of adjacent accessory and coronal cells. Three photoreceptor types are designated based on topological complexity: Type I, in which the sensory cell is flush with adjacent coronal cells and the photoreceptoral organelle is unprotected; Type II, in which the apical surface of the sensory cell is invaginated, forming a lumen containing the photoreceptoral organelle; and Type III, in which the sensory cell is at the base of an epidermal invagination and the photoreceptoral organelle is protected in a lumen formed by the sensory cell and accessory cells. There is a greater range of morphological variation among photoreceptors in larvae of Bugula spp. than between those of two species of the related genera Scrupocellaria and Tricellaria.     

Head sensory organs of Halobiotus stenostomus (Eutardigrada, Hypsibiidae)

The structure and arrangement of sensory organs in the tardigrade Halobiotus stenostomus (Richters 1908) have been studied using transmission and scanning electron microscopy techniques. The sensory organs found on the head of H. stenostomus are as follows: the circumoral sensory field, cephalic papillae, anterolateral and posterolateral sensory fields, and suboral sensory region. Four types of ciliated receptor structures are described in the sensory fields. The lateral sensory fields contain two types of receptor endings, dense and lucent, which differ in the presence or absence of a collar and in the structure of the outer dendrite segment. Two more types of receptor endings, ultrastructurally differing from the lateral sensory field receptors, are located in the suboral sensory region. Receptors with an asymmetric collar have been found, and a receptor ending without a collar is described for the first time in tardigrades. Unlike in other species studied, the sensory organs of H. stenostomus lack the lymph cavity surrounding the outer receptor segment. Similarity and differences in the ultrastructure of receptors between H. stenostomus and other species of Eutardigrada and Heterotardigrada are discussed.     

Putative sensory structures in marine bryozoans

Abstract. SEM studies of 21 species of marine bryozoans demonstrated that the abfrontal side of the tentacles bears a row of mono- or multiciliated cells, which are presumably sensory. In stenolaemates, the abfrontal cells, as well as the cells at the tentacle tips and the laterofrontal cells, are monociliated. In the 17 gymnolaemate species studied, each tentacle tip bears at least 3 multiciliated cells, each with a tuft of 5–7 stiff cilia of various lengths. On the abfrontal tentacle surface, mono- and multiciliated cells alternate, but all species studied have multiciliated cells at the base and the tip of each tentacle. In live animals, single cilia perform occasional flicks, whereas the tufts of 7–15 cilia on the multiciliated cells are immotile. Length and number of abfrontal cilia vary between species. Two types of multiciliated, putative sensory organs were found on the introvert of some gymnolaemates. One has an apical knob surrounded by a ring of cilia; the other has an apical tuft of cilia. The ultrastructure of the sensory cells of tentacles and introvert was studied in Rhamphostomella ovata . Our observations on both fixed and living material all suggest that these cells are primitive mechanoreceptors. The few species lacking ciliary structures on the introvert have long proximal ciliary tufts on the abfrontal tentacle surface.     

Innervation of cercarial tegumentary receptors investigated by the Sevier-Munger method

The investigation of the sensory nature of tegumentary receptors in platyhelminths remains a challenge due to technical difficulties related to nerve tissue exposure and its experimental handling. Neuromorphological studies have been carried out but few demonstrated the association of these receptors with the nervous system. This paper introduces the Sevier-Munger method as an alternative approach to study the innervation of tegumentary receptors in larval flatworms. Twenty heterophyid cercariae were fixed in hot 5% formalin, with all washes performed in tap and distilled water. They were developed in a solution of ammoniacal silver and 2% formalin under the microscope for 10 min, with preparations shaken gently throughout the procedure. In all specimens, nerve cells stained black against a pale gold background. Fine nerve fibers of the subsurface nerve plexus were observed. These fibers sent distal branches from the plexus to the cercarial tegument. The branches became fine nerve endings, projecting as receptors in the cephalic (5CIV₅, 2CV₂, and 2CV₄), anterior (4AIL, 3AIIL, 2AIIIL), midbody (1ML, 3MV), posterior (1PIL, 1PIIL, and 1PIIIL), and caudal (2UD) regions of the cercaria. These results indicate that the Sevier-Munger method is useful to demonstrate the association of cercarial tegumentary receptors with the subsurface nerve plexus. They also recommend the use of alternative methods to further investigate flatworm nervous systems. Moreover, there is a pressing urge for a standardized protocol, combining a plethora of methods and techniques. Interdisciplinary collaboration aiming at a better understanding of the function of flatworm nervous systems is particularly encouraged.     

Ribeiroia marini: Surface ultrastructure of redia,cercaria, and adult

Rediae, cercariae, and adults of Ribeiroia marini were examined using a scanning electron microscope to determine the types of tegumental sensory structures and their locations. Sensory structures were observed among numerous tegumental folds in the area immediately surrounding the mouth of the rediae. These sensory structures are similar in appearance, location and fine structure to sensory structures described from the anterior tips of rediae known to be predacious on the sporocysts of Schistosoma mansoni. These uniciliated structures may function as chemoreceptors to aid the redia in migration through snail tissue. Five types of sensory structures bearing one, two, or multiple cilia were distinguishable on the cercariae. These structures were located on and around the oral sucker, dorsal and ventral body surfaces and on the tail. They may be used by the cercariae to locate the intermediate host fish and to find suitable sites within the lateral line scales for encystment. The ventral surface of the adult fluke is covered with spines and shows an absence of sensory structures on the general body surface. Sensory structures were seen in the area surrounding the oral and ventral suckers. The extended cirrus organ has a folded tegument, but lacks spines or sensory structures.     

Two ciliate sense receptors in the larva of Austramphilina elongata Johnston, 1931 (Amphilinidea)

Summary The ultrastructure of a uniciliate and a quadruciliate receptor in the anterior end of the larva of Austramphilina elongata is described on the basis of serial sections. The uniciliate receptor has numerous branched and interconnected microvilli at its surface, several rings forming the electron dense collar, and cross-striated rootlets diverging from the basal body of the cilium. The quadruciliate receptor has four short club-shaped sensory cilia and a single electron-dense collar.Abbreviations used in figures ec electron-dense collar - ep epidermis - m microvilli - nt neurotubules - pe process of electron-dense collar - r rootlet of cilium - sc sensory cilium - sd septate desmosome     

Scanning electron microscopy of Echinostoma revolutum (Trematoda) during development in the chick embryo and the domestic chick

Fried B. and Fujino T. 1984. Scanning electron microscopy of Echinostoma revolutum (Trematoda) during development in the chick embryo and the domestic chick. International Journal for Parasitology14: 75–81. Scanning electron microscopy (SEM) was used to study the development of chemically excysted metacercariae of Echinostoma revolutum on the chick chorioallantois. SEM studies were also made on preovigerous adults of E. revolutum grown in the domestic chick. During worm development on the chorioallantois the tegument changed from smooth to granular and sensory papillae on the suckers became well-defined. As worms developed on the chorioallantois the cephalic collar spines became thicker and more curved and the tegumentary spines showed marked changes in shape, size and distribution on both ventral and dorsal aspects of the body. Changes in the surface ultrastructure of worms grown on the chorioallantois were essentially similar to those observed in preovigerous worms from chicks.