Functional morphology of the larval tentacles of Phragmatopoma californica (Polychaeta: Sabellariidae): composite larval and adult organs of multifunctional significance

Larvae of the sabellariid polychaete Phragmatopoma californica (Fewkes), which were collected in San Diego, California and were competent to metamorphose after 18 to 30 d of development were observed in vivo by videoequipped light microscopy, and the fine structure of the larval tentacles was examined by transmission and scanning electron microscopy. Each tentacle has tufts of at least two types of immotile cilia arranged in dorsolateral and ventrolateral rows, and a ventral groove covered by two types of motile cilia that beat independently of each other. The epidermis is regionalized into glandular, sensory, locomotory, and support cell types and contains four longitudinal bundles of basiepithelial nerve fibers. A layer of connective tissue separates the epidermis and the nerve tracts from obliquely striated muscles that occur within the peritoneum that lines the central coelomic cavities. The peritoneum forms an intact coelomic epithelium that overlies and interdigitates with the muscle cells, with no intervening basal lamina. The muscle cells are considered to be intraperitoneal because they are located above the basal lamina and they lack intercellular junctions with the peritoneal cells. Specialized peritoneal cells form a striated myoepithelial blood vessel that partitions the coelom into medial and lateral cavities. No neuromuscular junctions were found, but both muscular and ciliary movement seem to be under neuronal control. The basiepithelial nerve terminals appear to synapse into the connective tissue layer toward the intraperitoneal muscle. Several similarities in tissue organization are noted between the larval tentacles of P. californica and the tube feet of echinoderms. Observations on the ontogeny, morphology, and behavior of the tentacles suggest that they are multifunctional organs involved in feeding, construction of the juvenile sand tube, locomotion, attachment, and sensory perception during larval and adult lives.     

The cellular basis of photobehavior in the tufted parenchymella larva of demosponges

The mechanisms by which light elicits a phototactic response in sponge larvae remain poorly understood. Here we investigate histological and behavioral aspects of the photoresponse in parenchymella larvae of three demosponges. Two species are photonegative during their entire larval life, while the other, initially photopositive, becomes photonegative only after swimming in the laboratory for 4 h to 6 h. All larvae are bullet-shaped, with a uniformly ciliated surface, except at their posterior end, which is unciliated but surrounded by a distinctive ring of long cilia, the tuft. The short cilia beat metachronally, generating the thrust to move the larva forward with clockwise rotation. The long cilia of the tuft do not beat metachronally and are apparently more involved in maneuvering than in the generation of thrust. Transmission electron microscopy revealed in one species that the axoneme of the short cilia contains a distinctive "9×3+2" microtubule pattern at its base, but the presence of such an arrangement in cilia of the tuft remains uncorroborated. Nevertheless, the differences in beating characteristics between the monociliated cells of the tuft and those in the rest of the body correspond to other cytological differences. Cilia of the tuft have a type-I basal body, a large basal foot, and a branched rootlet, whereas the remaining cilia have a type-II basal body, a smaller and simpler basal foot, and an unbranched rootlet. Furthermore, the cells forming the tuft have a characteristic distal protrusion filled with pigments and mitochondria. Several of these traits suggest that the monociliated cells of the tuft are involved in the larval photoresponse both as sensors and effectors. Drastic changes in light intensity have no effect on the beating of the short cilia. In contrast, they cause a predictable and instantaneous movement of each cilium in the tuft, triggering expansions and contractions of either a part or the entire tuft, which in turn alters the direction of swimming. Observations on free-swimming larvae suggest that the tuft works as a passive light-sensitive rudder in both photonegative species that contract their posterior cilia under high irradiance and in photopositive species that expand their cilia under high irradiance. However, in photonegative larvae that expand the tuft under high irradiance, an active ciliary coordination by the larva needs to be invoked to explain a deviation of the swimming trajectory.     

Methods of ciliary filter feeding in adult Phoronis muelleri (phylum Phoronida) and in its free-swimming actinotroch larva

Microscope-video recordings were used to describe basic characteristics of particle capture in adult Phoronis muelleri and in its actinotroch larva. The larva captures food particles by means of close interplay between the tentacles and the oral hood. Suspended particles in the incoming water flow set up by the lateral "pump" cilia on the tentacles approach the tentacles with a velocity of about 1.5 mm s^-1. Near the tentacles, the particles are stopped by the stiff sensory laterofrontal cilia acting as a mechanical sieve. Simultaneous with stoppage of a particle, the oral hood is rapidly lifted so that water from the surrounding area flows in to occupy the volume created under the hood. Due to the proximity of the tentacle with the arrested particle, this suction will draw the particle away from the laterofrontal cilia into the increased space under the oral hood with a velocity of about 0.6 mm s^-1 before it is subsequently carried to the mouth. If a particle is stopped near the tip of a tentacle this may trigger a tentacle flick, with a tip velocity of about 5-7 mm s^-1, which brings the particle down toward the lifting edge of the hood. A stopped particle may cause a local disruption of the metachronism of the lateral cilia for about 0.14 s. Likewise in the adult, when an incoming particle with a velocity of about 1.6 mm s^-1 is stopped near the tip of a tentacle this triggers a flick, which brings the particle down towards the mouth. The duration of the active flick phase is about one-tenth of the flick cycle. Only when a particle is stopped on the outer part of a tentacle is a flick triggered. Otherwise the particle is either transported down along the frontal surface of the tentacle by means of the frontal cilia, or transferred into the downward current created by the lophophore. The metachronal wave velocity is about 0.25 mm s^-1, the wavelength about 12 µm, and hence the ciliary beat frequency about 21 Hz (at ~16°C). Essential features of the filter-feeding process in both actinotroch larvae and adult P. muelleri reported here resemble the ciliary-sieving process described for bryozoans in recent years. It should be pointed out that the stiff, mechanosensory laterofrontal cilia may be a decisive factor for understanding ciliary upstream collecting, also in pterobranchs and brachiopods in which sensory laterofrontal cilia are present.     

The osphradium in Placopecten magellanicus and Pecten maximus (Bivalvia,Pectinidae): histology,ultrastructure, and implications for spawning synchronisation

The bivalve osphradium is a band of putatively sensory tissue located in the gill axis, whose function is uncertain. In the present study, extending from 1987 to 1994, anatomical, histological, and electron microscopical techniques were used to elucidate the structure and ultrastructure of the osphradium in hatchery Pecten maximus L. and Placopecten magellanicus (Gmelin) (collected from Passamaquoddy Bay, New Brunswick, Canada). The osphradium consists of two distinct regions which run longitudinally on both sides of each gill axis: the osphradial ridge, and the dorsal tuft cilia region. The osphradial ridge was largely devoid of cilia other than those of the few free nerve fibres. The dorsal tuft cilia region contained free nerve fibres and ciliary tufts, separated by undifferentiated epithelial cells. No paddle cilia were observed under isosmotic fixation conditions, although under hypotonic conditions such cilia were quite common, suggesting an artefactual nature. Most of the cells of the osphradial ridge were highly secretory, the principal products being large pigment granules (in Pecten maximus) directly secreted by the Golgi bodies, and numerous small, electron-dense vesicles. These vesicles were arranged along extensive microtubule arrays in the basal region, indicative of axonal transport. These data support and extend Haszprunar's hypothesis of the role of the osphradium in the reception of chemical spawning cues and in the synchronization of gamete emission. Together with independent data on nerve pathways, osphradial sensory modalities, and monoamine localisation, an anatomical pathway and neurophysiological mediator are postulated.     

Function of lateral cilia in suspension feeding of lophophorates (Brachiopoda,Phoronida, Ectoprocta)

Suspension feeding by the brachiopod Laqueus californianus (Koch), the phoronid Phoronis vancouverensis Pixell, the ectoprocts Bugula sp., Membranipora villosa Hincks, and Schizoporella unicornis (Johnston), and actinotrocha and cyphonautes larvae was observed. Lophophorates retain particles on the upstream side of the band of lateral cilia, even after particles have moved lateral to the frontal surface. This suggests that these animals utilize an induced local reversal of beat of the lateral cilia for concentration and capture of suspended food particles. Retention of particles can cease while the current past the tentacles continues. Movement of particles down the frontal surface of the tentacles of L. californianus and the ectoproct species confirms previous observations that mucus strands are not used in particle capture. Possible functions of latero-frontal cilia or bristles are considered. Distribution of the feeding mechanism among phyla, clearance rates, and the lack of fusion of tentacles in brachiopods are discussed. The impingement mechanism previously suggested for lophophorates cannot account for the movements of particles observed here.     

Fine structure of some prosobranch ospharadia

The fine structure of the osphradia of Buccinum undatum 1. three Hawaiian Conus spp., Nassarius reticulatus (L), Nucella lapillus (L) and Littorina littorea (L) was examined. There is a remarkable uniformity in the arrangement of ultrastructural cell types in all the ospharadia investigated. The marginal glandular region is characterised by a single layer of cells, bearing a regular pallisade of microvilli and including two types of mucous cell. The epithelium of the sensory region is several cells deep, and bears a complex layer of microvilli in many orientations. Besides indifferent cells it contains two types of cell bodies of ciliated nerve processes. One type ends at the surface of the sensory region. The other, containing an elaborate array of smooth membranes in the perikaryon, has a process which enters the transitional region between sensory and glandular areas. In the transitional region, specialised cells with motile cilia adjoin the glandular region, and similar, but unciliated cells, containing large pigment granules scattered throughout the cytoplasm, adjoin the sensory region. The distal surface of both cell types is dissected by elefts extending 2 to 3 proximally, then widening into extensive spaces which contain cytoplasmic processes. The ciliated neurites which enter the transitional region end in the spaces at the base of the unciliated transitional cell elefts. It is suggested that the neuroepithelial cell processes, both those distributed over the sensory region and those concentrated in the transitional region, are receptors.     

Functional morphology and feeding behavior of Paraprionospio pinnata (Polychaeta: Spionidae)

The functional morphology and feeding behavior of Paraprionospio pinnata (Ehlers) were studied. The tentacular feeding palps of P. pinnata possess four groups of cilia: laterals, latero-frontal cirri, frontals and basal transverse rows. The lateral cilia beat in metachronal waves creating in current that flows toward the frontal surface of the palp. The latero-frontal cirri deflect suspended particles onto the frontal surface and potentially resuspend deposited particles. The frontal cilia line the groove of the palp and transport particles to the ciliated pharynx. The basal transverse cilia also beat in metachronal waves and together with the frontal cilia of the branchiae produce a U-shaped current that removes particles rejected by the pharynx from the burrow. The significance of particle selection at the site of the pharynx in spionid polychaetes is hypothesized to be constrained by the interaction of specific morphologies and behaviors that reduce the effects of epifaunal predation and browsing. The relationship between sediment permeability and type of respiratory or ventilation current is hypothesized to be a potentially important factor in understanding the distribution of spionid polychaetes.     

Ultrastructure of spermiogenesis in the gastropodHeliacus variegatus (Architectonicidae), with description of a banded periaxonemal helix

Spermiogenesis and spermatozoa of the marine gastropodHeliacus variegatus Gmelin were examined using transmission electron microscopy (TEM). Mature spermatozoa are composed of an acrosomal vesicle, helical nucleus, elongate midpiece, annulus, glycogen piece and short end piece. The midpiece consists of a 9+2 axoneme, nine coarse fibres, and a banded helix, all enclosed by a continuous mitochondrial sheath (with multiple, helically coiled grooves). Anterior extensions of the mitochondrial sheath and banded helix form a double sheath around the basal half of the nucleus—an arrangement possibly unique in the Mollusca. During spermiogenesis, dense plaques delineating the anterior and posterior poles of the spermatid nucleus become attachment sites for the acrosomal vesicle and the axial complex (respectively). As the nucleus condenses and elongates, midpiece formation involves fusion of numerous, oblong mitochondria along the length of the axoneme. The coarse fibres and banded helix of the midpiece probably are derived through centriolar activity. Results of the study support inclusion of the Architectonicidae within the Heterobranchia, but in view of midpiece specializations, do not clarify the precise relationship of the family within this subclass.     

Sperm ultrastructure of the giant clam Tridacna maxima (Tridacnidae: Bivalvia: Mollusca) from the Great Barrier Reef

Using transmission electron microscopy, spermatozoa from a member of the Tridacnidae, or giant clams, are described for the first time and compared with spermatozoa of other bivalves, especially other heterodonts. The acrosomal vesicle of Tridacna maxima (Röding, 1798) is short (0.37?μm), blunt-conical, and exhibits a prominent basal ring. A narrow apical elaboration of the nucleus, the nuclear peg, projects deep into the basal invagination of the acrosomal vesicle. Aside from this specialization, the nucleus is a solid elongate-cylindrical structure (7.66?μm) that exhibits several small irregular lacunae. Four or occasionally three round-ovate mitochondria surround a pair of orthogonally-arranged, triplet-substructure centrioles. The proximal centriole is connected to a small indentation of the nuclear base by a thin layer of granular pericentriolar material, whereas the distal centriole is anchored to the plasma membrane by nine terminally-forked satellite fibres. The 9?+?2 pattern axoneme of the tail is continuous with the distal centriole. Comparison with other bivalves indicates a very close relationship between tridacnids and cardiids based on sperm ultrastructure. Specifically, the presence of a nuclear peg links Tridacna spp. with the cardiid genus Cerastoderma, but further information on the many unstudied genera is required to test the exact nature of this relationship. The sperm ultrastructure provides additional support for the recently proposed hypothesis that the Tridacnidae may be no more than a specialized subfamily of the Cardiidae.     

A hydromechanical principle for particle retention in Mytilus edulis and other ciliary suspension feeders

It is generally thought that the laterofrontal cirri of the bivalve gill act as filters that retain suspended particles in the through current and transfer the particles onto the frontal surface of the gill filaments. In Mytilus edulis calculations indicated that if water passed between the branching cilia of the cirri that are assumed to constitute the filter the pressure drop needed would amount to about 10 times the actual pressure drop across the whole gill. Thus, instead of acting as filters the laterofrontal cirri seem to move water. Presumably, the cirri together with the frontal cilia produce the water currents along the frontal surface of the gill filaments. Particle retention in the bivalve gill implies the transfer of suspended particles from the current of water about to enter an interfilamentar space into a neighbouring frontal surface current. The complex three-dimensional pattern of flow that arises where the 2 systems of current meet is characterized by steep velocity gradients. Particles that enter such steep, steady velocity gradients become exposed to transverse forces that cause the particles to migrate perpendicularly to the direction of flow. Whether particles enter the surface current, i.e. are retained, or they stay within the through current andescape, depends primarily upon particle size, and upon the steepness and height of the gradients within the boundary zone between the surface current and through current. Further studies are needed to evaluate the capacities and relative importance of this hydromechanical particle-trapping mechanism in suspension feeding bivalves. It is suggested that in downstream particle-retaining systems, e.g. on the tentacles of polychaetes and entoprocts, velocity gradients between through currents and surface currents also act as the particle-collecting mechanism.     

Comparative morphology and cytology of siphons and siphonal sensory organs in selected bivalve molluscs

 The form, anatomy and cytology of the water-passages in siphon-possessing and siphon-lacking species of a selected group of bivalve molluscs from the Red Sea (Callista florida, Circe currogata, C. crocea, Lucinia dentifera, Dosinia histrio, Pitar hebraea, Tridacna maxima, Pteria aegyptica), and from the Mediterranean Sea (Spondylus spinosus, Pinctada radiata, Pinna nobilis, Donax trunculus, D. semistriatus, Mactra stultorum, Tapes decussatus, Petricola lithophaga, Brachidontes pharaonis) were studied by means of light and electron microscopy. In the mytiloids, ostreoids and ptrioids studied, the water-passages are covered by a ciliated epithelium and the few tentacles around their openings are identical to those found on the mantle edges. Contrary to this, in the veneroids studied, the siphons are covered by a microvillar epithelium and their tentacles, especially of the inhalant siphon, reveal characteristic branching. The so-called Type I, Type II and Type III ciliated sensory organs on and within the siphons are similar to those observed in other bivalves, differing from each other in the dimension, number and form of cilia. In the studied mytiloid species only Type I and Type II organs were found. The form and structure of the siphons and the distribution of sensors on them can be used as markers for ecological as well as phylogenetic considerations. Received: 28 January 2000 / Accepted: 28 May 2000     

Effects of varying dilutions, pH, temperature and cations on spermatozoa motility in fish Larimichthys polyactis

The objectives of this present study were to assess the effects of varying dilutions, pH, temperature and cations on spermatozoa motile parameters (SMPs) in fish Larimichthys polyactis. Optimal SMPs were observed when emen was diluted in artificial seawater (ASW) at a ratio of 1 to 100, with temperature of 10 degreesC and pH 8.0. The spermatozoa of L. polyactis were immotile in distilled water and motile in solution containing different cations. Maximum SMPs were obtained in each solution containing 0.4 mol NaCI, 0.4 mol KCI, 0.2 mol CaCI2 and 0.2 mol MgCl2. This study provides baseline knowledge of L. polyactis spermatozoa sensitivity of pH, temperature and cationic effects.     

A functional interpretation of cilia and mucocyte distributions on the abfrontal surface of bivalve gills

The lack of fundamental data on the abfrontal surface of bivalve gills has prompted a comparative study of cilia and mucocytes on this surface, using scanning electron microscopy and histology on eight species of bivalves, representing seven families and the four major gill types: Mytilus edulis, Modiolus modiolus, Arca zebra, Placopecten magellanicus, Crassostrea virginica, Spisula solidissima, Mercenaria mercenaria, and Mya arenaria. Abfrontal cilia and mucocytes were found in all species studied, with types and densities differing within and between gill types. The three species of homorhabdic filibranchs presented different densities of abfrontal cilia and mucocytes, from very dense in M. edulis to sparse in A. zebra. The heterorhabdic gills had intermediate cilia and mucocyte densities, with highest concentrations of both abfrontal cilia and mucocytes on the principal filaments. The eulamellibranchs showed low ciliary densities together with high mucocyte densities, especially in S. solidissima, where the abfrontal mucocytes were glandular. These results indicate that: (1) the abfrontal surface is a vestigial mucociliary surface; (2) the abfrontal surface cannot participate in water pumping in most species, due to low ciliary densities; and (3) species with high densities of abfrontal mucocytes could utilize abfrontal mucus to reduce drag, especially in the highly fused gills, such as those of the eulamellibranchs. The differing distributions of abfrontal cilia and mucocytes may reflect different selective pressures acting on the gills within the various taxa. Received: 12 February 2000 / Accepted: 10 September 2000     

Microarchitecture and function of the lophophore in the bryozoan Cryptosula pallasiana

The architecture and function of the lophophore of the marine bryozoan Cryptosula pallasiana (Moll) are described, including some new features not previously discovered in bryozoans. The nature of fluid movements within the lophophoral coelom during feeding activities is postulated on the basis of the arrangements of epithelia and muscles. Epithelial cells at the tentacle bases are blastemic in nature, and there is a ciliated pit of unknown function in the angle between every pair of tentacles. There are 6 nerves in each tentacle, including a pair of single-axon subperitoneal nerves. Neurosecretory-like vesicles and glycogen occur in some neurons of the ganglion. The basal lamina collagen has a diameter smaller than that previously recorded for an invertebrate. Filament dimensions are given for several different muscles. Tentacle muscles and lophophore retractor muscles are smooth. Thick paramyosin-like filaments up to 75 nm diameter occur in two muscle types. A new set of muscles is described: the basal transverse muscles of the tentacles.     

Feeding of the copepod Acartia tonsa on the diatom Nitzschia closterium and brown algae (Fucus vesiculosus) detritus

Integumental sensilla were examined in 39 species of meso- and bathypelagic shrimps and 6 species of epibenthic shrimps. A tuft organ, consisting of a group of openended, tubular setae and so probably functioning as a chemosensor, is described. A single tuft with ancillary smaller tufts occur on the dorsal median surface of the fourth abdominal segment and two pairs of tufts occur on the proximal dorsal region of the telson of all oplophorid and pandalid shrimps examined. An additional tuft is present on the fifth abdominal segment of the rare bathypelagic Physetocaris microphthalma Chace. No tuft organs were identified in Processa canaliculata Leach, suggesting that they may not occur in all families of caridean shrimps. Acanthephyrid, systellaspid and pandalid shrimps have the integument completely covered by scales. These are extremely delicate and are normally removed during the process of catching the shrimp through abrasion of the integument by the net. The scales are peculiarly orientated, pointing anteriorly in the anterior half and posteriorly in the posterior half of the body. They probably have a sensory function as distance receptors, monitoring water currents and disturbances in the environment surrounding the shrimp.     

Variations in sperm motility of the Atlantic herring Clupea harengus

Sperm characteristics and fertilization success were measured in two groups of Manx autumn-spawning herring, Clupea harengus L., captured 1 wk apart. Samples contained motile sperm for up to 45 min after activation (average 7 min). Individual spermatozoa were motile for up to 5 min. The activation of individual spermatozoa is probably phased, although the mechanism for the delay is not clear. This can account for the overall low levels of active sperm at any one time, the periodic fluctuations observed in the proportion of motile sperm, and for successful fertilization rates achieved using samples of apparently immotile sperm. The proportion of motile sperm was not affected by the presence of eggs, but the duration of motility was longer when sperm was activated in the presence of eggs rather than in seawater alone. Individual males differed significantly in the duration of motility in their sperm samples and in the fertilization rates achieved, but not in the proportion of motile sperm in each sample. There were no consistent changes in the characteristics of the spawners or the sperm between the two sample dates. Sperm motility and duration of motility were significantly correlated, but none of the sperm characteristics measured was significantly related to fertilization success. Received: 13 March 1999 / Accepted: 20 May 1999     

Ciliary feeding of tornaria larvae of Ptychodera flava (Hemichordata: Enteropneusta)

Ciliary feeding by tornariae of Ptychodera flava (Eschholtz) and other tornariae from the plankton is compared with Garstang's (1939) account of feeding by these larvae, which account contains errors, and with ciliary feeding by echinoderm larvae. Some details of ciliation are also described. As in echinoderm larvae, band cilia beat away from the food grooves and retain particles on the upstream side of the ciliated band, but tornariae use muscles less in ingestion and rejection. In early-stage and most late-stage echinoderm larvae, the ciliated band functions in both swimming and feeding, but in tornariae the ciliated band is arranged meridionally so that few portions of the ciliated band produce a posteriorly-directed current and a locomotory teletroch is needed for swimming. Faster-swimming tornariae observed in bowls achieved higher ingestion and clearance rates. These observations raise questions about form and function in the giant Planctosphaera pelagica. Cilia of the locomotory telotroch increase in length as tornariae increase in size, but there is little increase in length of cilia which capture food. Instead, the length of the ciliated band increases relative to other larval tissues by means of increasing convolution of the band. Hence, the volume of water processed for food probably increases relative to energy expended by larvae during development to the tentaculate stage. However, the length of the ciliated band may decrease relative to other larval surfaces with continued increase in size beyond this stage. These interpretations of growth and feeding efficiency are consistent with the reported geographic distribution of tornariae with and without tentacles.     

Fluid mechanics of the mussel gill: The lateral cilia

Quantitative data on the water currents produced by the ciliary tracts of the gill filaments are needed to understand the fluid mechanics of suspension feeding in bivalves, as well as in other ciliary suspension feeders. This paper investigates the water currents produced by the bands of lateral cilia, as studied on isolated gill filaments, gill fragments, and intact gills of the mussel Mytilus edulis L with severed adductor muscles. The metachronally beating cilia produce oscillatory currents near the oscillating enveloping surface of the ciliary bands and rectilinear currents, the interfilamentary through-currents, farther from the surface. It is suggested that the oscillatory currents play an important role in the fluid mechanical capture of suspended particles. In the intact gill the interfilamentary currents pass the bands of lateral cilia at velocities that are two or more times higher than those generated by the bands of isolated filaments. The mussel gill is compared with an optimized peristaltic pump.     

Spermatozoa and spermatogenesis in a monoplacophoran mollusc,Laevipilina antarctica: ultrastructure and comparison with other Mollusca

Ultrastructural features of spermatozoa and spermatogenesis are described for the first time in a monoplacophoran and compared with data for other conchiferan molluses. Spermatozoa of Laevipilina antarctica Warén and Hain, 1992, are of the structurally simple, aquasperm type, featuring a conical acrosome, a compact nucleus with lacunae, a short midpiece and a single flagellum. The acrosomal vesicle shows an electron-dense inner zone, and a basal invagination (subacrosomal space) contains granular material but no axial rod. The nucleus exhibits a shallow indentation apically which contains subacrosomal material, and five (sometimes four) indentations posteriorly which partially accommodate the five (rarely four) midpiece mitochondria. Two centrioles are present, the distal connected to the annulus by satellite fibres and acting as a basal body for the flagellum (axoneme probably 9+2 structure). Spermatogonia, characterized by an oblong nucleus and one or two nucleoli, line the basal membrane of the testis wall; spermatids of varying stages of maturity occupy the remainder of the testis. Acrosome and flagellum production is already well advanced in spermatids and probably commences at the spermatocyte stage. Cytoplasmic bridges occur in all developmental stages, most visibly in spermatids. The spermatid chromatin condenses in large tracts, leaving electron-lucent lacunae. Mitochondria collect posteriorly and form, presumably by fusion, the five (or four) larger, spherical mitochondria which gather around the centrioles.     

Feinstruktur des Trichterepithels von Rhinomuraena ambonensis (Teleostei,Anguilliformes)

The ultrastructure of the funnel-like tubes of the olfactory organ in Rhinomuraena ambonensis was investigated by electron microscopy. Frontal sections of the tubes demonstrate a symmetrical arrangement of an inner epithelium, connective tissue, and an outer epithelium. The surface of each peripheral cell of the epithelia bears a system of small ridges which does not correspond with that of the adjacent cells. In case of a rectilinear course of the epithelial cell borders, numerous desmosomes are located along the cell membranes. The fine structure of the desmosomes was analysed. Number and size of the intercellular spaces increases with increasing depth of the epithelium cell layers. The fine structure of epithelial, basal and secretory cells is described. The outer region of each epithelial cell contains densely packed tonofilaments. The fine structure of sensory “buds” which are sparsely distributed within the outer epithelium of the funnels is described. The basal border of the epithelia consists of a rather thick basal membrane. Blood vessels, nerve bundles, chromatophores and storage cells with cristalline inclusions are embedded in the connective tissue. The fine structure of the chromatophores and storage cells is described. The importance of desmosomes, tonofilaments and intercellular spaces, as well as the basal membrane and the amount of collagen is discussed in relation to the reinforcement of the funnels.