Development of ciliary bands in larvae of the living isocrinid sea lily Metacrinus rotundus

Embryos and larvae of an isocrinid sea lily, Metacrinus rotundus, are described by scanning electron microscopy. Around hatching (35 h after fertilization), the outer surface of the gastrula becomes ubiquitously covered with short cilia. At 40 h, the hatched swimming embryo develops a cilia‐free zone of ectoderm on the ventral side. By 3 days, the very early dipleurula larva develops a cilia‐free zone ventrally, densely ciliated regions laterally, and a sparsely ciliated region dorsally. At this stage, the posterior and anterior ciliary bands first appear: the former runs along a low ridge separating the densely from the sparsely ciliated epidermal regions, while the latter is visible, at first discontinuously, along the boundary between the densely ciliated lateral regions and the cilia‐free ventral zone. In the late dipleurula larva (5 days after fertilization), the anterior and posterior loops of ciliary bands are well defined. The transition from the dipleurula to the semidoliolaria larva occurs at 6 days as the posterior loop becomes rearranged to form incompletely circumferential ciliary bands. The larva becomes competent to settle at this stage. The arrangement of the ciliary bands on the semidoliolaria is maintained during the second week of development, while the larva retains its competence to settle. The larval ciliary patterns described here are compared with those of stalkless crinoids and eleutherozoan echinoderms. The closest morphological similarities are between M. rotundus and the basal eleutherozoan class Asteroidea.     

INFOLDED BASAL PLASMA MEMBRANES FOUND IN EPITHELIA NOTED FOR THEIR WATER TRANSPORT

Epithelia noted for their water transport have been studied by electron microscopy with particular emphasis upon basal specializations. Epithelia of the submaxillary gland, choroid plexus, and ciliary body are described in this article, and compared with previous observations on the kidney. The basal surface of all these epithelia is tremendously expanded by folds which penetrate deeply into the cytoplasm. In the submaxillary gland this is particularly notable in cells of the serous alveoli and in the secretory ducts. In these instances the folds have a fairly regular distribution and have a marked tendency to turn back upon themselves and so form repeating S-shaped patterns. In the choroid plexus the penetrating basal folds are limited to the lateral regions of each ependymal cell where they blend with the intercellular membranes that are also folded. In the epithelium of the ciliary body it is the inner layer that is specialized. The surface adjacent to the cavity of the eye penetrates irregularly, nearly through the full depth of the cell layer. The exposed surface is, in a fundamental sense, the basal surface of this epithelial layer. It is apparent that the pattern of folding is quite distinctive in the different epithelia. Therefore, the specializations should be regarded as analogous rather than homologous. Topographic considerations presumably limit the manner in which basal cell surfaces might be expanded. Penetrating folds would seem to represent almost the only possible solution.     

Structure and differentiation of the inner egg membrane of Trichocephaloides megalocephala (Cestoda, Dilepididae)

Electron microscope studies of the inner membrane of developing eggs of T. megalocephala were carried out. At early developmental stages the inner membrane is a syncytial cytoplasmatic layer lying on the basal plate of the embryo. At the preoncosphere stage the division of the membrane into two zones (external and internal ones) takes place. Initially the differentiation manifests itself in the cytoplasm polarisation; at the end of the middle preoncosphere stage the zones are divided by the "oncosphere membrane". The formation of the "oncosphere membrane" is accomplished by the external part of the internal zone. Embryophore is a derivative of the external zone, at the final stages of the formation the embryophore material is transformed from granular into thin-fibrillary. The origin of the external integument of oncospheres of cyclophillids, which, as it has been shown for T. megalocephala, is a derivative of the inner membrane rather than of specialized epithelial oncosphere cells, is considered.     

Ultrastructure of the ocular ciliary epithelium of the common frog

The ultrastructure of the adult frog ciliary epithelium cells has definite regional differences. Cells of ciliary epithelium folds near the iris display morphological features characterizing its barrier and secretory functions which lead to the formation of aqueous humor. These are junctional complexes with tight junctions (zonula occludents) in the apical parts of contacting sides of cells of the inner leaf: a great quantity of mitochondria, ribosomes and various vesicles, well developed endoplasmic reticulum in the cytoplasm, much folded basal surface, gap junctions between cells of external and internal leaflets. In the mammalian inner epithelial layer different cell junctions are known to be arranged in a fixed spatial fashion. Unlike, in the frog's epithelium both zonula adherent and desmosomes may be found in any sequence. Tight junctions are formed during metamorphosis, on the place of focal junctions, whereas gap junctions, referred to earlier as "extended", start functioning between cells just on the very early stages of eye morphogenesis (Dabagyan et al., 1979). The epithelium of the posterior part of the ciliary fold and pars plana of the ciliary body have, in addition, the number of morphological sign indicating the cell involvement in the accomodational function of any eye (i. e. a majority of desmosomes binding all cells together and of zonulae adherentes, well developed intracellular skeleton of tonofilament bundles). These features are characteristic of the whole distal part of ciliary epithelium rather than of the place of attachment of zonula fiber only.     

Embryogenesis in <Emphasis Type="Italic">Sedum acre</Emphasis> L.: structural and immunocytochemical aspects of suspensor development

The changes in the formation of both the actin and the microtubular cytoskeleton during the differentiation of the embryo-suspensor in Sedum acre were studied in comparison with the development of the embryo-proper. The presence and distribution of the cytoskeletal elements were examined ultrastructurally and with the light microscope using immunolabelling and rhodamine-phalloidin staining. At the globular stage of embryo development extensive array of actin filaments is present in the cytoplasm of basal cell, the microfilament bundles generally run parallel to the long axis of basal cell and pass in close to the nucleus. Microtubules form irregular bundles in the cytoplasm of the basal cell. A strongly fluorescent densely packed microtubules are present in the cytoplasmic layer adjacent to the wall separating the basal cell from the first layer of the chalazal suspensor cells. At the heart-stage of embryo development, in the basal cell, extremely dense arrays of actin materials are located near the micropylar and chalazal end of the cell. At this stage of basal cell formation, numerous actin filaments congregate around the nucleus. In the fully differentiated basal cell and micropylar haustorium, the tubulin cytoskeleton forms a dense prominent network composed of numerous cross-linked filaments. In the distal region of the basal cell, a distinct microtubular cytoskeleton with numerous microtubules is observed in the cytoplasmic layer adjacent to the wall, separating the basal cell from the first layer of the chalazal suspensor cells. The role of cytoskeleton during the development of the suspensor in S. acre is discussed.     

Formation of actin filament bundles in the ring canals of developing Drosophila follicles

Growing the intracellular bridges that connect nurse cells with each o ther and to the developing oocyte is vital for egg development. These ring canals increase from 0.5 microns in diameter at stage 2 to 10 microns in diameter at stage 11. Thin sections cut horizontally as you would cut a bagel, show that there is a layer of circumferentially oriented actin filaments attached to the plasma membrane at the periphery of each canal. By decoration with subfragment 1 of myosin we find actin filaments of mixed polarities in the ring such as found in the "contractile ring" formed during cytokinesis. In vertical sections through the canal the actin filaments appear as dense dots. At stage 2 there are 82 actin filaments in the ring, by stage 6 there are 717 and by stage 10 there are 726. Taking into account the diameter, this indicates that there is 170 microns of actin filaments/canal at stage 2 (pi x 0.5 microns x 82), 14,000 microns at stage 9 and approximately 23,000 microns at stage 11 or one inch of actin filament! The density of actin filaments remains unchanged throughout development. What is particularly striking is that by stages 4-5, the ring of actin filaments has achieved its maximum thickness, even though the diameter has not yet increased significantly. Thereafter, the diameter increases. Throughout development, stages 2-11, the canal length also increases. Although the density (number of actin filaments/micron2) through a canal remains constant from stage 5 on, the actin filaments appear as a net of interconnected bundles. Further information on this net of bundles comes from studying mutant animals that lack kelch, a protein located in the ring canal that has homology to the actin binding protein, scruin. In this mutant, the actin filaments form normally but individual bundles that comprise the fibers of the net are not bound tightly together. Some bundles enter into the ring canal lumen but do not completely occlude the lumen. all these observations lay the groundwork for our understanding of how a noncontractile ring increases in thickness, diameter, and length during development.     

Experimental induction of microphthalmia in the chick embryo with a single dose of cisplatin

Chick embryos were injected on the fifth day of incubation with 75 ng cis-diamminedichloroplatinum II (cisplatin) and killed at daily intervals. Bilateral microphthalmia appeared in 88% of the surviving embryos; the decrease in eye size was noticeable 2 or 3 days after injection. Coinciding with this, macroscopic, histological, and ultrastructural changes started to appear in the ciliary body: ciliary processes failed to form and the cells in the inner layer of the ciliary epithelium underwent degenerative changes. Changes in the retina appeared somewhat later. Despite the decreased growth rate of the whole eye the neural layer of the retina continued to grow rapidly; as a result, it formed numerous folds and acquired a glandular appearance. In the most severe cases the rapidly growing retina would invade the ciliary region and replace completely the degenerated inner layer of the ciliary epithelium. It has been shown by previous authors that intraocular pressure is a determinant of eye expansion and also that the secretion of water and ions by the ciliary epithelium is important for the maintenance of that intraocular pressure. On this basis, our results are interpreted as indicating that the primary lesion induced by cisplatin was in the ciliary epithelium and that microphthalmia was the consequence of decreased pressure. It is also concluded that the retinal changes were due to the fact that the retina continued to grow despite the lack of expansion of the eye as a whole.     

Multipotent and Stem Cells in the Developing, Definitive, and Regenerating Vertebrate Eye

This is a review of the experimental studies on the vertebrate retina neurogenesis. Data are provided on the distribution and localization of multipotent and stem cells in the developing, definitive, and regenerating eye. At the early stages of retina development, the neuroepithelial cells divide synchronously, thus leading to the accumulation of a certain number of the retinal rudiment cells. Synchronous divisions precede the asynchronous ones, when the differentiation of the retinal cells is initiated. The neuroepithelial cells are multipotent: the neuroblast is a source of the cells of different types, for example, neurons and glial cells. The proliferating multipotent cells are preserved in the ciliary-terminal zone of the retina of amphibians, fish, and chickens during their entire life. The differentiated pigment epithelium cells also proliferate in this area of the eye. The multipotent cells of the retinal ciliary-terminal zone and cells of the pigment epithelium in the eye periphery provide for the growth of amphibian and fish eyes during the entire life of these animals. In adult mammals, clonable and self-renewable cells were found among the pigmented differentiated cells in the ciliary folds. In a culture, the stem cells form spheroids consisting of depigmented and proliferating cells. Upon transdifferentiation, the cells of spheroids form rods, bipolar cells, and ganglion and glial cells, thus suggesting the possible regenerative potencies of the stem cells in the ciliary body of the mammalian eye. The main event of retinal regeneration in newts is the transdifferentiation of the pigment epithelium cells. The results of comparative analysis suggest that the stem cells of the ciliary body in the mammalian eye and pigment epithelium cells in lower vertebrates exhibit similar potencies and use similar mechanisms during the formation of the cells of the neural series.     

Ultrastructural evidence for the occurrence of three types of mechanosensitive cells in the tentacles of the cubozoan polypCarybdea marsupialis

Summary The ectodermal cell layer in the tentacles of the cubozoan polypCarybdea marsupialis contains four types of cells (types 1–4) bearing specialized cilia. Epitheliomuscular cells (type 1) are characterized by motile cilia with dynein-decorated axonemes. 200 nm long extramembranous filaments of unknown function are restricted to a belt-like region distal to the transition zone. Up to 40 rn long rigid cilia formed by a slender epithelial cell type (type 2) are surrounded by rings of short microvilli. The axonemes of these cilia are composed of incomplete microtubules and lack dynein. Microvilli and cilia are linked by intermembrane connectors. Microtubuledoublets and ciliary membrane are interconnected by microtubule-associated cross-bridges only within this contact region. At the tip of each tentacle a single nematocyte (type 3) is surrounded by 7–10 accessory cells (type 4). These both cell types are equipped with similar cilium-stereovilli-complexes consisting of a cone-like arrangement of stereovilli and a modified cilium. The axonemal modifications of the cilium, its interconnections with the surrounding stereovilli and the linkages between ciliary axoneme and ciliary membrane are similar to those known from the cnidocil-complexes of hydrozoons and other epithelial mechanosensitive cells of the collar-receptor type. Our data indicate that besides the nematocyte two other types of mechanosensory cells (types 2 and 4) are integrated in the ectodermal cell layer ofCarybdea which possibly affect the triggering mechanism of nematocyst discharge.     

Ultrastructure of the cyanobacterium,Mastigocladus laminosus

The morphology and ultrastructure of the thermophilic cyanobacteriumMastigocladus laminosus were examined by scanning and transmission electron microscopy. Mature cultures consisted of relatively old, wide filaments that branched frequently to form younger, thinner filaments. The cells of the younger filaments had a consistently cylindrical morphology, while those of older filaments were rounded and pleomorphic. The internal ultrastructure of the cells depended somewhat on their age. As young cells became larger and wider, their thylakoids underwent slight rearrangement and spread out toward the center of the cytoplasm. Polyphosphate bodies, carboxysomes (polyhedral bodies), and lipid-body-like structures increased in number as the cells aged, but ribosomes and cyanophycin granules were depleted. Cell division involved septum formation followed by ingrowth of the outer membrane and sheath. Cells in older filaments were separated from each other by a complete layer of sheath material. Septum formation in older cells was also seen to occur parallel to the long axis of the filament, thereby confirming that true branching took place.     

The oral apparatus of Tetrahymena pyriformis, strain WH-6. IV. Observations on the organization of microtubules and filaments in the isolated oral apparatus and the differential effect of potassium chloride on the stability of oral apparatus microtubules.

This report is an ultrastructural analysis of the organization of the isolated oral apparatus of Tetrahymena pyriformis, strain WH-6, syngen 1. Attention has been focused on the organization of microtubules and filaments in oral apparatus membranelles. Oral apparatus membranellar basal bodies were characterized with respect to structural differentiations at the distal and proximal ends. The distal region of membranellar basal bodies contains the basal plate, accessory microtubules and filaments. The proximal end contains a dense material from which emanate accessory microtubules and filaments. There are at least two possibly three different arrangements of accessory structures at the proximal end of membranellar basal bodies. All membranellar basal bodies appear to have a dense material at the proximal end from which filaments emanate. Some of these basal bodies have accessory microtubules and filaments emanating from this dense material. A possible third arrangement is represented by basal bodies which have lateral projections, from the proximal end, of accessory microtubules and filaments which constitute cross or peripheral connectives. There are at least three examples of direct associations between oral apparatus microtubules and filaments: (1) filaments which form links between basal body triplet microtubules, (2) filaments which link the material of the basal plate to internal basal body microtubules, (3) filaments which link together microtubule bundles from membranellar connectives. KCl extraction of the isolated oral apparatus resulted in the selective solubilization of oral apparatus basal bodies, remnants of ciliary axonemes and fused basal plates. Based on their response to KCl extraction two distinct sets of morphologically similar micro tubules can be identified: (a) microtubules which constitute the internal structure of basal bodies and ciliary axonemes, (b) microtubules which constitute the fiber connectives between basal bodies.     

Development of the ciliature of Tetrahymena thermophila: II. Spatial subdivision prior to cytokinesis

The cell surface of Tetrahymena thermophila is made up of an anterior region in which virtually all basal bodies of ciliary rows are ciliated, and the remainder in which ciliated and unciliated basal bodies are fairly irregularly interspersed. This pattern persists through interfission development until the stage of appearance of the equatorial ring of gaps in the ciliary rows that marks the fission zone. The ciliation pattern then becomes subdivided, in large part through the rapid ciliation of contiguous basal bodies located posterior to the fission zone. We interpret this process as a wave of ciliation of preexisting basal bodies that propagates posteriorly from the site of the fission zone. The location, extent, and timing of the ciliation process are the same in inverted as in normally oriented ciliary rows, in spite of the fact that in inverted rows the visible fission zone gap is tardily formed and the local configuration of ciliature around this gap is abnormal. The putative ciliation wave thus does not depend directly upon the local manifestations of the fission zone. However, in a cell-division-arrest mutant, cdaA1, analyzed under conditions in which formation of fission-zone gaps is permanently prevented in some ciliary rows but not in all, it is found that the ciliation pattern becomes subdivided in those ciliary rows that express fission-zone gaps and fails to become subdivided in neighboring rows that fail to manifest gaps. We interpret this combination of findings to indicate that a signal localized at the cell equator initiates a set of polarized developmental events that simultaneously create and demarcate two cellular fields within what was previously one. We further suggest that the characteristic tandem cell division pattern of ciliates is fundamentally a process of segmentation, which might involve mechanisms of gradient subdivision analogous to those taking place during segmentation of insects and other multicellular organisms.     

Elektronenmikroskopische Untersuchungen über Glaskörperrindenzellen und Zonulafasern

Zusammenfassung Es werden folgende Befunde zur Feinstruktur des Glaskörpers beim 16 Tage alten Rattenembryo und der Glaskörperrinde beiderseits der Ora serrata beim 3 Jahre alten, an Retinoblastom erkrankten Kind mitgeteilt:Der Glaskörper des Rattenembryos und die Glaskörperrinde des kindlichen Auges enthalten Fibroblasten. Sie unterscheiden sich nicht von den im Bindegewebe vorkommenden Fibroblasten. Im embryonalen Rattenglaskörper wurden außerdem faserbildende Zellen mit wabiger Struktur des Zytoplasmas beobachtet.Die Fibroblasten der Glaskörperrinde bilden die Fibrillen des Glaskörpergerüstes und der Zonulafasern. Diese Fibrillen zeigen eine deutliche Querstreifung. Die Streifung ist unregelmäßig oder periodisch. Die Länge der Perioden beträgt in unseren Schnitten bei den Glaskörperfibrillen des Rattenembryos und des kindlichen Auges meist etwa 120, seltener 210 A. An den Fibrillenbündeln einer Zonulafaser des kindlichen Auges wurden Perioden von 90–120, 400, 440 und 630 A beobachtet.Die Fibroblasten der Glaskörperrinde des kindlichen Auges liegen im Bereich der Pars plana corporis ciliaris auch tief in den Buchten und Falten des Ciliarepithels. Hierdurch wird eine maximal große Anheftungsfläche für die von ihnen produzierten Fibrillen der Zonulafasern gewährleistet.Die Pars plana corporis ciliaris des kindlichen Auges ist von einem dichten Netz von Fibroblastenfortsätzen überzogen. Auch vereinzelte Makrophagen finden sich hier.Unsere elektronenmikroskopischen Befunde bestätigen die Angaben von Balazs über das Vorkommen von Fibrocyten (Fibroblasten) und Makrophagen in der Glaskörperrinde. Ferner bestätigen sie die bereits von früheren Autoren lichtmikroskopisch gewonnenen Erkenntnisse, wonach es sich beim Glaskörper um mesenchymales Gewebe, bei den Zonulafasern im Bindegewebsfasern handelt.

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Summary The following electron microscopical findings in the vitreous body of 16-day-old rat embryos and in the vitreoretinal border layer on both sides of the ora serrata in a 3-year-old child are reported:The vitreous body of the rat embryo and the vitreoretinal border layer of the infant eye contain fibroblasts. These fibroblasts do not differ from those present in connective tissue. The embryonic vitreous body of the rat contains fibre-forming cells, which show an alveolar structure of the cytoplasm.The fibroblasts in the cortical tissue layer of the vitreous body form the fibrils of the stroma of the vitreous body and the zonula fibres. These fibrils show a marked cross striation. The striation is either irregular or shows periodicity. In the vitreous body of the rat embryo and of the infant eye the lenght of these periods has been measured with 120 and 210 A. Periods of 90–120, 400, 440 and 630 A could be shown in the fibrillar bundles of a zonula fibre of the infant eye. In the region of the pars plana corporis ciliaris the fibroblasts of the cortical tissue layer of the vitreous body of the infant eye are also found deep down in the sinus and folds of the ciliary epithelium. Thus they guarantee an as large as possible area for the attachment of the fibrils of the zonula fibres which they produce.The pars plana corporis ciliaris of the infant eye is covered with a dense network of fibroblast processes. Also cells of the macrophage type may be found in this region.Our electron microscopical findings confirm those of earlier light microscopists and lately by Balazs. The vitreous body of the eye is formed by mesenchymal tissue, whereas the zonula fibres are formed by connective tissue.

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Mit dankenswerter Unterstützung durch den Schweizerischen Nationalfonds zur Förderung der Wissenschaftlichen Forschung.     

ULTRASTRUCTURE OF CARPOSPOROPHYTE DEVELOPMENT IN THE RED ALGA GLOIOSIPHONIA VERTICILLARIS (CRYPTONEMIALES,GLOIOSIPHONIACEAE)

The ultrastructure of carposporophyte development is described for the red alga Gloiosiphonia verticillaris Farl. The auxiliary cell produces gonimoblast initials, which divide to produce two types of gonimoblast cells—the nondividing vacuolate cells and terminal generative gonimoblast cells. The generative gonimoblast cells form clusters of carpospore initials, which eventually differentiate into carpospores. After gonimoblast filaments are formed, the auxiliary cell undergoes autolysis, causing degeneration of septal plugs between the auxiliary cell and adjacent cells, thus forming a fusion cell. Since this cell lacks starch and appears degenerate throughout carposporophyte development, a nutritive function cannot be ascribed to the fusion cell. Carpospore differentiation is simple and proceeds through three developmental stages. Young carpospores structurally resemble gonimoblast cells, because they contain undeveloped plastids, large quantities of floridean starch, and are surrounded by extensive mucilage instead of a distinct wall. In addition, dictyosomes form and begin to produce vesicles with fibrous contents representing carpospore wall material. During the intermediate stage, dictyosomes continue to produce vesicles that contribute additional carpospore wall material, thereby compressing the mucilage and creating a darker-staining layer outside the carpospore wall. Plastids form internal thylakoids by invaginations of the inner membrane of the peripheral thylakoid. The endoplasmic reticulum forms large granular vacuoles that appear to be degraded during subsequent stages of development. Mature carpospores form cored vesicles. They also contain mature chloroplasts, large amounts of floridean starch, and occasionally granular vacuoles. During this stage, interconnecting carpospore-carpospore and carpospore-gonimoblast cell septal plugs begin to undergo degeneration. This process may be mediated by tubular structures.     

THE FINE STRUCTURE OF CORTICAL COMPONENTS OF PARAMECIUM MULTIMICRONUCLEATUM

The electron microscope was used to study the structure and three dimensional relationships of the components of the body cortex in thin sections of Paramecium multimicronucleatum. Micrographs of sections show that the cortex is covered externally by two closely apposed membranes (together ~250 A thick) constituting the pellicle. Beneath the pellicle the surface of the animal is molded into ridges that form a polygonal ridgework with depressed centers. It is these ridges that give the surface of the organism its characteristic configuration and correspond to the outer fibrillar system of the light microscope image. The outer ends of the trichocysts with their hood-shaped caps are located in the centers of the anterior and posterior ridges of each polygon. The cilia extend singly from the depressed centers of the surface polygons. Each cilium shows two axial filaments with 9 peripheral and parallel filaments embedded in a matrix and the whole surrouned by a thin ciliary membrane. The 9 peripheral filaments are double and these are evenly spaced in a circle around the central pair. The ciliary membrane is continuous with the outer member of the pellicular membrane, whereas the plasma membrane is continuous with the inner member of the pellicular membrane. At the level of the plasma membrane the proximal end of the cilium is continuous with its tube-shaped basal body or kinetosome. The peripheral filaments of the cilium, together with the material of cortical matrix which tends to condense around them, form the sheath of the basal body. The kinetodesma connecting the ciliary kinetosomes (inner fibrillar system of the light microscopist) is composed of a number of discrete fibrils which overlap in a shingle-like fashion. Each striated kinetosomal fibril originates from a ciliary kinetosome and runs parallel to other kinetosomal fibrils arising from posterior kinetosomes of a particular meridional array. Sections at the level of the ciliary kinetosomes reveal an additional fiber system, the infraciliary lattice system, which is separate and distinct from the kinetodesmal system. This system consists of a fibrous network of irregular polygons and runs roughly parallel to the surface of the animal. Mitochondria have a fine structure similar in general features to that described for a number of mammalian cell types, but different in certain details. The structures corresponding to cristae mitochondriales appear as finger-like projections or microvilli extending into the matrix of the organelle from the inner membrane of the paired mitochondrial membrane. The cortical cytoplasm contains also a particulate component and a system of vesicles respectively comparable to the nucleoprotein particles and to the endoplasmic reticulum described in various metazoan cell types. An accessory kinetosome has been observed in oblique sections of a number of non-dividing specimens slightly removed from the ciliary kinetosome and on the same meridional line as the cilia and trichocysts. Its position corresponds to the location of the kinetosome of the newly formed cilium in animals selected as being in the approaching fission stage of the life cycle.     

L'Organisation Ultrastructurale Corticale de la Gregarine Lecudina pellucida; ses Rapports avec l'Alimentation et la Locomotion

SYNOPSIS. The structure of the cortical region (epicyte and ectoplasm) of the gregarine Lecudina pellucida , an intestinal parasite of the polychete worm Perinereis cultrifera was studied by electron microscopy.
The epicitary folds have 3 unit type membranes. Between the 1st and 2nd is a layer probably composed of fine longitudinal fibrils which has an arch-like or gutter-like structure at the crest of the folds. Inside these folds is cytoplasm without any noticeable differentiation or inclusion except for a granular (or finely fibrillar) layer under the limiting inner membrane and close to it.
The ectoplasmic zone of the entocyte is separated from the epicitary region by a lengthwise discontinuous cylindrical opaque layer, inwardly tangential to the folds. The ectoplasm lacks paraglycogen granules but has various organelles: apparently pinocytic vesicles against the wall between the folds, vesicles with myelinic membranes, opaque granules, a few mitochondria with blistered internal vesicles, and a few circular tubular fibers.
The superficial zone of the gregarine is supposed to contribute to nutrition, thru the extensive surface furnished by its folds and thru the pinocytic vesicles; but this alimentary intake is incomplete compared with that of the previously studied anterior region.
Insufficient mucus is discharged to account for locomotion. There are some circular ectoplasmic fibers, but locomotory myonemes are completely absent. However, there are deformations of the folds and corresponding waves that could account for locomotion by creeping or swimming. These movements of the folds might be due to the action of the contractile proteins and correspond with some of the layers seen in the wall.     

Development and differentiation of the rat epididymis. I: ultrastructural aspects of the peritubular zone

We investigated the ultrastructural aspects of the peritubular cells of epididymis and their development from birth to adult age. At birth the peritubular zone consisted of polygonal cells which did not differ from other interstitial cells. Cytoplasmic filaments were visible in the cells of the inner layer at day 6. From day 22 the peritubular cells reached the adult aspect. The peritubular cells in the rat epididymis had aspects similar to those of peritubular smooth muscle cells of rat testis, with a more precocious appearance of cytoplasmic filaments. This finding concurs with the observed precocious contractility of epididymis.     

Ultrastructural study of metamorphosis in the freshwater bryozoan Plumatella fungosa (Bryozoa,Phylactolaemata)

Summary

At metamorphosis the attachment of the Plumatella larva to the substrate is effected by secretions from glandular cells in the apical plate, the leading pole during swimming. The larval mantle folds back and slides down towards the substrate. By ciliary activity an adhesive secretion is spread over the metamorphosing larva and the attachment area. Two polypides appear through the larval terminal opening. The mantle fold, together with gland cells, nerve cells, sensory cells, and muscle cells from the larva form a nutritive cell mass. Reduction of this nutritive cell mass is accomplished by autolysis and phagocytosis. An invaginated area of the nutritive cell mass is provided with a dense layer of microvilli, which seem to have an absorbtive function. The nutritive cell mass consisting of transitory larval tissues provides a significant source of nutrient for the developing polypide buds.