Ultrastructure of potential photoreceptor organs in the larva ofScrupocellaria bertholetti (bryozoa)

Summary Pigmented spots have been implicated as potential photoreceptors in many bryozoan larvae which display phototactic behavior. Larvae ofScrupocellaria bertholetti, initially photopositive on release from the brood chambers, have a pair of identical posterolateral pigmented spots and a third morphologically different spot in the anteromedian line. The presumed photoreceptoral organelle in each is composed of numerous unmodified cilia which have the typical 9+2 arrangement of microtubules with electron-dense arms extending from thea-microtubule of each peripheral pair. The posterolateral pigmented spot is composed of two modified coronal cells and a basal sensory cell. Cilia arising from the apical part of this basal cell are aligned vertically. Densely packed pigment vesicles in the three cells form a shield that restricts light entry to one direction. The anteromedian pigmented spot is composed of four cells, two lateral and two posterior. Cilia of the opposing lateral cells are horizontally aligned, whereas cilia of the posterior cells are vertical and curve outward from the oral margin of the pigmented spot. Pigment vesicles are present in all four cells to form a complete shield. Extensions of the larval nervous system are in direct contact with the four cells of the anteromedian spot and the basal cells of the posterolateral spots. The posterolateral pigmented spots share structural and topological similarities with the pigmented spots ofBugula neritina, the only other supposed photoreceptors in lophophorates which have been studied at the ultrastructural level. It is not yet possible to homologize these potential photoreceptors with those of other groups.     

Fine structure of the cephalic sensory organ in veliger larvae of Littorina littorea, (L.) (Mesogastropoda,Littorinidae)

The cephalic sensory organ (CSO) in planktonic veliger larvae of Littorina littorea is situated dorsally between the velar lobes at the level of the shell aperture. It consists of ciliated primary sensory cells, adjacent accessory cells and supporting epithelial cells. Cell bodies of the ciliated cells originate in the cerebral commissure and their dendrites pass to the epidermis. The flask-shaped sensory cells are characterized by a deep invaginated lumen with modified cilia arising from the cell surface in the lumen. These cilia are presumed to be non-motile because they lack striated rootlets and show a modified microtubular pattern (6 + 2, 7 + 2 and 8 + 2). The adjacent accessory cells never possess an invaginated lumen; occasionally cilia and branched microvilli arise from the apical surface. These cells may be sensory, but there is no obvious direct connection with the nervous system. The supporting epithelial cells are part of the epidermis and flank the apical necks of the sensory and accessory cells. Morphological evidence suggests that the CSO may function in chemoreception related to substrate selection at settlement, feeding or other behaviour.     

The homodimeric kinesin, Kif17, is essential for vertebrate photoreceptor sensory outer segment development

Sensory cilia and intraflagellar transport (IFT), a pathway essential for ciliogenesis, play important roles in embryonic development and cell differentiation. In vertebrate photoreceptors IFT is required for the early development of ciliated sensory outer segments (OS), an elaborate organelle that sequesters the many proteins comprising the phototransduction machinery. As in other cilia and flagella, heterotrimeric members of the kinesin 2 family have been implicated as the anterograde IFT motor in OS. However, in Caenorhabditis elegans, OSM-3, a homodimeric kinesin 2 motor, plays an essential role in some, but not all sensory cilia. Kif17, a vertebrate OSM-3 homologue, is known for its role in dendritic trafficking in neurons, but a function in ciliogenesis has not been determined. We show that in zebrafish Kif17 is widely expressed in the nervous system and retina. In photoreceptors Kif17 co-localizes with IFT proteins within the OS, and co-immunoprecipitates with IFT proteins. Knockdown of Kif17 has little if any effect in early embryogenesis, including the formation of motile sensory cilia in the pronephros. However, OS formation and targeting of the visual pigment protein is severely disrupted. Our analysis shows that Kif17 is essential for photoreceptor OS development, and suggests that Kif17 plays a cell type specific role in vertebrate ciliogenesis.     

Intercoronal cell complex of larvae of the bryozon Watersipora arcuata (cheilostomata: Ascophora)

The coronate larva of the ascophoran bryozoan Watersipora arcuata has a ring of 32 large, multiciliated coronal cells that are used for swimming. Fourteen pairs of small cells are intercalated between the lateral margins of adjacent coronal cells. These intercoronal cells are arranged in a precise pattern and are polymorphic: seven pairs have multiple cilia and seven pairs are mono- or oligociliated. Three pairs of multiciliated intercoronal cells have their cilia arranged as a whorl that is recessed in a pocket formed between the adjacent coronal cells, and they are thought to be photoreceptors that sense general light intensity. Two other pairs of multiciliated cells with cohesive tufts of cilia may be chemo- or mechanoreceptors. Roles of the other intercoronal cells in this species are not evident, but it is proposed that the majority, if not all, of them are sensory. The close proximity of all the intercoronal cells to the equatorial nerve ring is compatible with this interpretation. Analyses of the literature on cleavage patterns, pigment cup ocelli, and flagellar tufts that serve as balancers in coronate larvae lead us to propose that (1) an intercoronal cell is the sensory element of most, if not all, pigment cup ocelli of bryozoan larvae; and (2) intercoronal cells are not modified coronal cells but probably are specialized supra- and/or infracoronal ones that have migrated to an intercoronal position.     

Ultrastructure of a cephalic sensory organ in larvae of the gastropod Phestilla sibogae (Aeolidacea, Nudibrachia)

The cephalic sensory organ is a superficial sensory receptor located between the velar lobes at the level of the shell aperture. Three cell types make up this sensory area: (1) six flask-shaped cells bearing numerous cilia; (2) adjacent supporting or accessory cells which have numerous, often branched, microvilli; and (3) vacuolated cells which occupy the center of the area. The flask-shaped cells appear to be the sensory units. These cells have a deep invaginated lumen, with cilia arising from the cell surface in the lumen oriented either toward the base of the lumen or toward the epidermal surface. These cilia, some of which extend slightly above the body surface, are presumed to be non-motile, as they lack (dynein?) arms on the axonemal A tubules and lack striated rootlets. The six flask cells are in intimate contact with the underlying cerebral ganglia and axons from each cell pass into ganglionic tissue. The supporting cells may be sensory, but no direct connection with the nervous system was seen. The function of the central vacuolated cells is not known. This cephalic organ may be a derivative of the original apical tuft of the trochophore stage.     

Surface specializations of the olfactory epithelium of rainbow trout, Salmo gairdneri

Receptors for olfactory stimulus molecules appear to be located at the surface of olfactory receptor cells. The ultrastructure of the distal region of rainbow trout (Salmo gairdneri) olfactory epithelium was examined by transmission electron microscopy. On the sensory olfactory epithelium, which occurs in the depressions of secondary folds of the lamellae of the rosettes, five cell types were present. Type I cells have a knob-like apical projection which is unique in this species because it frequently contains cilia axonemes within its cytoplasm in addition to being surrounded by cilia. Type II cells bear many cilia oriented unidirectionally on a wide, flat surface. Type III cells have microvilli on a constricted apical surface and centrioles in the subapical cytoplasm. Type IV cells contain a rod-like apical projection filled with a bundle of filaments, and type V cells are supporting cells. Cilia on the sensory epithelium contain the 9 + 2 microtubule fiber pattern. Dynein arms are clearly present on the outer doublet fibers, which suggests that the cilia in the olfactory region are motile. Their presence in olfactory cilia of vertebrates has been controversial. The cilia membrane in this species is unusual in often showing outfoldings, within which are included small, irregular vesicles or channels. In addition, cilia on type II cells frequently contain dense-staining bodies closely apposed to the membranes, along with a densely stained crown at the cilia tip. Previous biochemical evidence indicates that odorant receptors are associated with the cilia.     

The Par-PrkC Polarity Complex Is Required for Cilia Growth in Zebrafish Photoreceptors

Specification and development of the apical membrane in epithelial cells requires the function of polarity proteins, including Pard3 and an atypical protein kinase C (PrkC). Many epithelial cells possess microtubule-based organelles, known as cilia, that project from their apical surface and the membrane surrounding the cilium is contiguous with the apical cell membrane. Although cilia formation in cultured cells required Pard3, the in vivo requirement for Pard3 in cilia development remains unknown. The vertebrate photoreceptor outer segment represents a highly specialized cilia structure in which to identify factors necessary for apical and ciliary membrane formation. Pard3 and PrkC localized to distinct domains within vertebrate photoreceptors. Using partial morpholino knockdown, photo-morpholinos, and pharmacological approaches, the function of Pard3 and PrkC were found to be required for the formation of both the apical and ciliary membrane of vertebrate photoreceptors. Inhibition of Pard3 or PrkC activity significantly reduced the size of photoreceptor outer segments and resulted in mislocalization of rhodopsin. Suppression of Pard3 or PrkC also led to a reduction in cilia size and cilia number in Kupffer’s Vesicle, which resulted in left-right asymmetry defects. Thus, the Par-PrkC complex functions in cilia formation in vivo and this likely reflects a general role in specifying non-ciliary and ciliary compartments of the apical domain.     

Ultrastructure of epidermal eyespots of Microstomum lineare (Turbellaria,macrostomida)

Summary The eyespots of Microstomum lineare were studied by electron microscopy, light microscopy, and fluorescence microscopy. Each eyespot consists of two ciliary photoreceptor cells shielded by pigment cells and additional sensory cells. The photoreceptor cells are characterized by a distal intracellular cavity lined with 50–100 interwoven cilia. The other sensory cells are of two ultrastructurally different types, one with long cilia predominating and the other with balloonlike cilia. The pigment cells, which envelop processes of the sensory cells, contain pigment vacuoles varying in size and content and give a bright red fluorescence by the Falck-Hillarp method. The eyespots are suggested to perform a dual function as photoreceptors and chemoreceptors. The evolutionary significance of ciliary photoreceptors in Turbellaria is discussed.     

Epithelial sodium channels (ENaC) are uniformly distributed on motile cilia in the oviduct and the respiratory airways

Epithelial sodium channels (ENaCs) are located on the apical surface of cells and funnel Na⁺ ions from the lumen into the cell. ENaC function also regulates extracellular fluid volume as water flows across membranes accompanying Na⁺ ions to maintain osmolarity. To examine the sites of expression and intracellular localization of ENaC, we generated polyclonal antibodies against the extracellular domain of human α-ENaC subunit that we expressed in E. coli. Three-dimensional (3D) confocal microscopy of immunofluorescence using these antibodies for the first time revealed that ENaCs are uniformly distributed on the ciliary surface in all epithelial cells with motile cilia lining the bronchus in human lung and female reproductive tract, all along the fimbrial end of the fallopian tube, the ampulla and rare cells in the uterine glands. Quantitative analysis indicated that cilia increase cell surface area >70-fold and the amount of ENaC on cilia is >1,000-fold higher than on non-ciliated cell surface. These findings indicate that ENaC functions as a regulator of the osmolarity of the periciliary fluid bathing the cilia. In contrast to ENaC, cystic fibrosis transmembrane conductance regulator (CFTR) that channels chloride ions from the cytoplasm to the lumen is located mainly on the apical side, but not on cilia. The cilial localization of ENaC requires reevaluation of the mechanisms of action of CFTR and other modulators of ENaC function. ENaC on motile cilia should be essential for diverse functions of motile cilia, such as germ cell transport, fertilization, implantation, clearance of respiratory airways and cell migration.     

Making sense of cilia and flagella

Data reported at an international meeting on the sensory and motile functions of cilia, including the primary cilium found on most cells in the human body, have thrust this organelle to the forefront of studies on the cell biology of human disease.     

Structure and function of vertebrate cilia, towards a new taxonomy

In this review, we propose a new classification of vertebrate cilia/flagella and discuss the evolution and prototype of cilia. Cilia/flagella are evolutionarily well-conserved membranous organelles in eukaryotes and serve a variety of functions, including motility and sensation. Vertebrate cilia have been traditionally classified into conventional motile cilia and sensory primary cilia. However, an avalanche of emerging evidence on the variations of cilia has made it almost impossible to classify them in a simple dichotomic manner. For example, conventional motile cilia are also involved in the sensation of bitter taste to facilitate the beating of cilia as a defense system of the respiratory system. On the other hand, the primary cilium, often regarded as a non-motile sensory organelle, has been revealed to be motile in vertebrate embryonic nodes, where they play a crucial role in the determination of left-right asymmetry of the body. Moreover, choroid plexus epithelial cells in the cerebral ventricular system exhibit multiple primary cilia on a single cell. Considering these lines of evidence on the diversity of cilia, we believe the classification of cilia should be based on their structure and function, and include more detailed criteria. Another intriguing issue is how in the evolution of cilia, their function and morphology are combined. For example, has motility been acquired from originally sensory cilia, or vice versa? Alternatively, were they originally hybrid in nature? These questions are inseparable from the classification of cilia per se. We would like to address these conundrums in this review article, principally from the standpoint of differentiation of the animal cell.     

Cross species analysis of Prominin reveals a conserved cellular role in invertebrate and vertebrate photoreceptor cells

The two fundamental types of photoreceptor cells have evolved unique structures to expand the apical membrane to accommodate the phototransduction machinery, exemplified by the cilia-based outer segment of the vertebrate photoreceptor cell and the microvilli-based rhabdomere of the invertebrate photoreceptor. The morphogenesis of these compartments is integral for photoreceptor cell integrity and function. However, little is known about the elementary cellular and molecular mechanisms required to generate these compartments. Here we investigate whether a conserved cellular mechanism exists to create the phototransduction compartments by examining the functional role of a photoreceptor protein common to both rhabdomeric and ciliated photoreceptor cells, Prominin. First and foremost we demonstrate that the physiological role of Prominin is conserved between rhabdomeric and ciliated photoreceptor cells. Human Prominin1 is not only capable of rescuing the corresponding rhabdomeric Drosophila prominin mutation but also demonstrates a conserved genetic interaction with a second photoreceptor protein Eyes Shut. Furthermore, we demonstrate the Prominin homologs in vertebrate and invertebrate photoreceptors require the same structural features and post-translational modifications for function. Moreover, expression of mutant human Prominin1, associated with autosomal dominant retinal degeneration, in rhabdomeric photoreceptor cells disrupts morphogenesis in ways paralleling retinal degeneration seen in ciliated photoreceptors. Taken together, our results suggest the existence of an ancestral Prominin-directed cellular mechanism to create and model the apical membranes of the two fundamental types of photoreceptor cells into their respective phototransduction compartments.     

Structure and function of the spermatheca in a snail host of schistosomiasis, Biomphalaria glabrata

The histochemistry and ultrastructure (SEM and TEM) of the spermatheca of Biomphalaria glabrata was investigated to elucidate the function of this organ and to compare its structure and function to similar organs found in other species. The spermatheca has a debris-filled lumen surrounded by a thin wall of tissue. The cells adjacent to the lumen are of three columnar epithelial cell types. Two cell types have abundant microvilli and mammalian cell-like organelle distribution and morphology. The above cell types differ in the electron density of their cytoplasms, nuclear morphologies, and organelle content. The third cell type differs from the other two in its cytoplasmic makeup. However, the most distinctive difference is the presence of large numbers of cilia at the apical surface with no evidence of microvilli. These columnar cells rest on a basal lamina adjacent to a two to three cell thick muscle layer. The entire organ is surrounded by an adventitia of unusual morphology. Histochemical investigation demonstrated that DNAase, RNAase, and protease are present in the lumen, alkaline phosphatase is associated primarily with the microvilli, small amounts of acid phosphatase are concentrated in the midcell area of the columnar epithelium, and ATPase activity is localized in the muscle cells and just below the absorptive surface of the microvillous cells. The luminal contents and adventitial areas are Sudan Black B positive, all areas of the lumen and organ wall are PAS positive, the cell nuclei and amorphous masses in the lumen showed Feulgen staining, and large vesicles in the columnar cells were Oil Red O positive. Apparently, the spermatheca of B. glabrata is both a digestive and absorptive structure. Although this organ shares functional similarities with those found in opisthobranchs and terrestrial pulmonates, the epithelia of the spermatheca differ dramatically in these groups.     

Transmembrane assemblage of the photoreceptor connecting cilium and motile cilium transition zone contain a common immunologic epitope.

The photoreceptor connecting cilium bears a unique transmembrane assemblage which stably links cell surface glycoconjugates with the underlying axonemal cytoskeleton. Structural similarities between the photoreceptor connecting cilium and the transition zone of motile cilia suggests that this assemblage may also be present in motile cilia. Using a subcellular fraction enriched in detergent-extracted photoreceptor axonemes, three high molecular mass glycoconjugates (425, 600, and 700 kD) were previously identified as potential components of the assemblage. Through oligosaccharide characterization and binding of a specific monoclonal antibody, we have verified the localization of the 425 kD glycoconjugate to the transmembrane assemblage. Binding of the lectin peanut agglutinin (PNA) to the 425 kD glycoconjugate on nitrocellulose blots, and to isolated detergent-extracted axonemes, was assessed following treatment with the enzymes neuraminidase and O-glycanase. Changes in binding to the 425 kD glycoconjugate precisely paralleled changes in binding to intact axonemes, supporting the hypothesis that the 425 kD glycoconjugate is a component of the transmembrane assemblage. Furthermore, the results suggest that the 425 kD glycoconjugate contains sialated galactose-N-acetylgalactosamine oligosaccharides which are O-linked to the protein backbone. To directly assess the distribution of the 425 kD glycoconjugate, we produced a monoclonal antibody directed against this glycoconjugate. The antibody, K26, recognizes only the 425 kD on transblots of the axoneme fraction. K26 immunoreactivity of intact axonemes is identical to that seen by PNA staining. K26 staining of isolated photoreceptors and whole retina is uniquely localized to the region of the connecting cilium. Thus, in the photoreceptor, the 425 kD is not only a component of the transmembrane assemblage but is also completely restricted to the connecting cilium. Based on morphological similarities, the photoreceptor connecting cilium is thought to be homologous to the transition zone of the motile cilium. As such, we have stained oviduct epithelium with the K26 monoclonal antibody. Immunoreactivity is restricted to the region of the transition zone at the base of motile cilia.     

Structure of ocellus photoreceptors in the ascidian Ciona intestinalis larva as revealed by an anti-arrestin antibody

Although there have been several studies on the structure of the ocellus photoreceptors in ascidian tadpole larvae using electron microscopy, the overall structure of these photoreceptor cells, especially the projection sites of the axons, has not been revealed completely. The number of photoreceptor cells is also controversial. Here, the whole structure of the ocellus photoreceptors in the larvae of the ascidian Ciona intestinalis was revealed by using an anti-arrestin (anti-Ci-Arr) antibody. The cell bodies of 30 photoreceptor cells covered the right side of the ocellus pigment cell and their outer segments extended through the pigment cell into the pigment cup. The axons of the photoreceptor cells were bundled together ventro-posteriorly in a single tract extending towards the midline. The nerve terminals diverged antero-posteriorly at the midline of the posterior sensory vesicle (SV). The Ci-arr gene was expressed throughout the SV at the embryonic mid-tailbud stage and it became restricted to the neighborhood of the ocellus pigment when ocellus pigmentation occurred. At the same time, the Ci-Arr protein was first detected, suggesting that the photoreceptor cells began to differentiate. The development of photoreceptor cells after hatching was also investigated using the anti-Ci-Arr antibody. Three hours after hatching, the photoreceptor terminals began to ramify and then expanded. Previous behavioral analysis showed that the larvae did not respond to the step-down of light until 2 h after hatching and then the photoresponse became robust. Accordingly, our results suggest that growth of the photoreceptor terminal is critical for the larvae to become photoresponsive.     

Cytological basis of photoresponsive behavior in a sponge larva.

Ontogenetic changes in the photoresponse of larvae from the demosponge Reneira sp. were studied by analyzing the swimming paths of individual larvae exposed to diffuse white light. Larvae swam upward upon release from the adult, but were negatively phototactic until at least 12 hours after release. The larval photoreceptors are presumed to be a posterior ring of columnar monociliated epithelial cells that possess 120-microm-long cilia and pigment-filled protrusions. A sudden increase in light intensity caused these cilia to become rigidly straight. If the light intensity remained high, the cilia gradually bent over the pigmented vesicles in the adjacent cytoplasm, and thus covered one entire pole of the larva. The response was reversed upon a sudden decrease in light intensity. The ciliated cells were sensitive to changes in light intensity in larvae of all ages. This response is similar to the shadow response in tunicate larvae or the shading of the photoreceptor in Euglena and is postulated to allow the larvae to steer away from brighter light to darker areas, such as under coral rubble-the preferred site of the adult sponge on the reef flat. In the absence of a coordinating system in cellular sponges, the spatial organization and autonomous behavior of the pigmented posterior cells control the rapid responses to light shown by these larvae.     

Ultrastructure of phaosomous photoreceptors in Stylaria lacustris (Naididae, ‘Oligochaeta’, Clitellata) and their importance for the position of the Clitellata in the phylogenetic system of the Annelida

Many species of Naididae possess a pair of pigmented eyes. Within Clitellata, eyes are generally present in Hirudinea, whereas Naididae are the only oligochaete taxon having these sense organs. The eyes of Naididae are epidermal structures and consist of a multicellular pigment cup in which a single row of five to six photoreceptor cells is embedded. The sensory cells are typical phaosomes: the photoreceptive structures (microvilli) project into a cavity formed by the sensory cell itself. In Stylaria lacustris this cavity opens to the exterior, clearly documenting that it represents an invagination of the apical cell membrane. The density of sensory microvilli is comparatively low and a central vitreous body is lacking. Similar phaosomous photoreceptors, not associated with either pigmented or unpigmented supporting cells, occur in the epidermis of the anterior end. These photoreceptors correspond to those found in other Clitellata, confirming that phaosomes are the only known type of photoreceptor cell occurring in this taxon. As a result of their simple structure they have been regarded as plesiomorphic for Annelida. However, an out‐group comparison with eyes and photoreceptors occurring in polychaetes and other spiralians reveals that they, in fact, are a rather specialized type of photoreceptor. Despite the simple structure, they most likely represent an autapomorphy of Clitellata. It follows that in all probability, these phaosomes are a secondarily evolved type of photoreceptor, which arose within the oligochaete clade after the primary photoreceptors present in the out‐groups had been lost. This loss might have occurred during evolution of a burrowing life style within the sediment and subsequent invasion of the terrestrial environment.     

Cilia containing 9 ＋ 2 structures grown from immortalized cells

Cilia depend on their highly differentiated structure, a 9 ＋ 2 arrangement, to remove particles from the lung and to transport reproductive cells. Immortalized cells could potentially be of great use in cilia research. Immortalization of cells with cilia structure containing the 9 ＋ 2 arrangement might be able to generate cell lines with such cilia structure. How- ever, whether immortalized cells can retain such a highly differentiated structure remains unclear. Here we demonstrate that （1） using Ela gene transfection, tracheal cells are immortalized; （2） interestingly, in a gel culture the immortalized cells form spherical aggregations within which a lumen is developed; and （3） surprisingly, inside the aggregation, cilia containing a 9 ＋ 2 arrangement grow from the cell＇s apical pole and protrude into the lumen. These results may influence future research in many areas such as understanding the mechanisms of cilia differentiation, cilia generation in other existing cell lines, cilia disorders, generation of other highly differentiated structures besides cilia using the gel culture, immortalization of other ciliated cells with the Ela gene, development of cilia motile function, and establishment of a research model to provide uniform ciliated cells.     

Characterization of single channel currents from primary cilia of renal epithelial cells

The primary cilium is a ubiquitous, non-motile microtubular organelle lacking the central pair of microtubules found in motile cilia. Primary cilia are surrounded by a membrane, which has a unique complement of membrane proteins, and may thus be functionally different from the plasma membrane. The function of the primary cilium remains largely unknown. However, primary cilia have important sensory transducer properties, including the response of renal epithelial cells to fluid flow or mechanical stimulation. Recently, renal cystic diseases have been associated with dysfunctional ciliary proteins. Although the sensory properties of renal epithelial primary cilia may be associated with functional channel activity in the organelle, information in this regard is still lacking. This may be related to the inherent difficulties in assessing electrical activity in this rather small and narrow organelle. In the present study, we provide the first direct electrophysiological evidence for the presence of single channel currents from isolated primary cilia of LLC-PK1 renal epithelial cells. Several channel phenotypes were observed, and addition of vasopressin increased cation channel activity, which suggests the regulation, by the cAMP pathway of ciliary conductance. Ion channel reconstitution of ciliary versus plasma membranes indicated a much higher channel density in cilia. At least three channel proteins, polycystin-2, TRPC1, and interestingly, the alpha-epithelial sodium channel, were immunodetected in this organelle. Ion channel activity in the primary cilium of renal cells may be an important component of its role as a sensory transducer.