Aktomyosinartige Filamente im Teilungsmakronukleus des Ciliaten Ichthyophthirius Multifiliis

Just before nuclear division, the chromosomal elements within the large, highly polyploid macronucleus of I. multifiliis carry out rotational movements. Electron micrographs of cells fixed during the rotational movements show islets filled with microfilaments in various states of aggregation. Both thick (80–200 Å) and thin (30–80 Å) filaments occur, either as a highly dense network or as straight, in part parallel, filaments embedded in a filamentous network of lower density. Other islets of the macronucleus contain large and dense aggregates of filaments, sometimes with globular particles measuring 50–60 Å arranged along the thick filaments, occasionally forming cross-bridges with the thinner ones. — After incubation of the cells before fixation in a contractionsolution containing 0.002 M ATP, all nuclear islets show a nearly uniform appear ance of filamentous aggregates: numerous long and thick filaments are arranged in parallel with thin filaments with which they are in some parts connected by bridges. The probable myosinoid and actinoid nature of thick and thin filaments is discussed. It is suggested that the pre-divisional intranuclear rotational movement is a mechanism to avoid aneuploidy by producing a random arrangement of replicated hereditary units prior to division.     

Methanothrix soehngenii gen. nov. sp. nov., a new acetotrophic non-hydrogen-oxidizing methane bacterium

A new genus of methanogenic bacteria is described, which was isolated from a mesophilic sewage digester. It is most probably the filamentous bacterium, earlier referred to asMethanobacterium soehngenii, fat rod or acetate organism. The single non-motile, non-sporeforming cells are rod-shaped (0.8×2 m) and are normally combined end to end in long filaments, surrounded by a sheath-like structure. The filaments form characteristic bundles.Methanothrix soehngenii decarboxylates acetate, yielding methane and carbon dioxide. Other methanogenic substrates (H₂–CO₂, formate, methanol, methylamines) are not used for growth or methane formation. Formate is split into hydrogen and carbon dioxide. The temperature optimum for growth and methane formation is 37°C and the optimal pH range is 7.4–7.8. Sulfide and ammonia serve as sulfur and nitrogen source respectively. Oxygen completely inhibits growth and methane formation, but the bacteria do not loose their viability when exposed to high oxygen concentrations. 100 mg/l vancomycin showed no inhibition of growth and methanogenesis. No growth and methane formation was observed in the presence of: 2-bromoethanesulfonic acid, viologen dyes, chloroform, and KCN. The bacterium has a growth yield on acetate of 1.1–1.4 g biomass per mol acetate. The apparent K _S of the acetate conversion system to methane and carbon dioxide is 0.7 mmol/l. The DNA base composition is 51.9 mol% guanine plus cytosine. The nameMethanothrix is proposed for this new genus of filamentous methane bacterium. The type species,Methanothrix soehngenii sp. nov., is named in honor of N. L. Söhngen.     

Giant flagellar bundles ofVibrio alginolyticus (NCMB 1803)

Summary Following swarming ofVibrio alginolyticus on solid medium a large number of giant flagellar bundles appear behind the growth front. The suggested sequence of events leading to bundle formation is as follows. After inoculation from liquid to solid media the short rods with a single polar sheathed flagellum develop peritrichous nonsheathed flagella and elongate into long filamentous swarmers. After division into short rods, some of the cells become spherical in shape with many peritrichous flagella concentrated at one pole in close association with the sheathed polar flagellum. These tufted spherical bodies form the template upon which masses of loose peritrichous flagella spontaneously aggregate.Flagellar bundles formed when bacteria are grown at pH 8.5 are longer than those formed at pH 7.2 and shorter when grown at pH 6.5. In distilled water the flagellar bundles disintegrate into masses of flagellar fragments.     

Submicroscopic structure of the membranous labyrinth

Summary Investigations were performed by light and electron microscope on the basilar membrane, limbus spiralis and spiral ligament.These different parts continue one into the other and make up a single morphological and functional structure which may be called the supporting structure of Corti's organ (s.s.C.o.).It is formed by a tissue the components of which are the cells and an intercellular substance in which are arranged the capillary vessels.The cells can be classed in two groups, the first consisting of the cells proper (basilar membrane, limbus spiralis and spiral ligament cells) which present structural changes parallel with the growth mechanism of the intercellular substance; the second of the cochlear duct covering cells (Corti's organ cells, inner and outer spiral sulcus cells, interdental cells, stria vascularis cells).The intercellular substance is organised in laminae, fibrolaminae, bundles and microscopic fibers composed of filaments with an intervening ground substance.The filaments have a diameter ranging from 85 to 105 Å. Topochemical tests with polarised light microscope, enzymatic tests, diffractographic and chemical analyses suggest that these filaments unquestionably consist of protein material which have nothing to do with collagen or elastic fibers. Perhaps it may be classed in the K.E.M.F. group.The ground substance generally appear anhistous and transparent but in some parts of the basilar membrane it presents a cottony appearance.The possible different hypotheses about the classification of the s.s.C.o. tissue are discussed.The quantity and architecture of the cells and the intercellular substance vary appreciably in the basilar membrane, limbus spiralis and spiral ligament, which are examined in detail one by one.The demonstration that the s.s.C.o. is formed of a tissue possessing an intercellular substance containing filamentous scleroproteins clearly corroborates the theory that is performs supporting activity in respect of Corti's organ. The term supporting structure of Corti's organ is based on this interpretation.Research financed by C.N.R. grant.     

The fine structure of neuroglia in the central nervous system of nereid polychaetes

Summary The principal supportive elements of the nereid central nervous system are non-neuronal cells that are referred to as supportive glia. Supportive glial cells form a conspicuous cortex in the nerve cord. The inner region of this cortex consists of closely packed processes and cell bodies of fibrous supportive glial cells that are arranged in concentric layers around the perimeter of the neuropile. The fibrous appearance of the glial cells results from dense bundles of cytoplasmic filaments. Many fibrous glial processes penetrate the neuropile and ramify among the neuronal elements. Larger, irregularly shaped cells are the chief supportive glial elements of the peripheral region of the cortex where they line the stromal sheath (neural lamella) and invest the neuronal perikarya with extensive concentric systems of lamellate processes. These glial cells usually possess a relatively undifferentiated cytoplasm with scattered glycogen granules, but occasionally have a well developed Golgi apparatus, endoplasmic reticulum and densely packed particulate glycogen. The supportive glia exhibits numerous desmosomes as well as 5-layered (tight) and 7-layered (gap) junctions. Interspersed among the supportive glial cells are non-neuronal cells referred to as granulocytes. These cells have abundant large, granular inclusions, electron lucent vesicles, plasmalemmal infoldings and microtubules. The granulocytes may be derived from undifferentiated glial cells or may represent coelomocytes that have invaded the nervous tissue.Supported by USPHS Grants No. NIH 5P01 NS-07512, NIH 2T01 GM-00102, and NB-00840.The author acknowledges the excellent technical assistance of Sarah Wurzelmann and Stanley Brown, and thanks Dr. Berta Scharrer for many stimulating discussions.     

Characterization of the fibrillar layer at the epithelial-mesenchymal junction in tooth germs

A characteristic layer containing numerous fibrils is associated with the basement membrane of the inner enamel epithelium during the early stages of odontogenesis. However, its nature is not well understood. In this study, the layer was examined with high-resolution electron microscopy and immuno-histochemical staining. Tooth germs of monkeys (Macaca fuscata) were studied and each fibril in the layer was found to be a tubular structure, 8–9 nm in width, resembling a basotubule, the tubular structure previously observed in various basement membranes. The space between the fibrils was filled with a network formed by irregular anastomosing strands with an average thickness of 4 nm; these strands resembled the cords forming the network in the lamina densa of basement membranes. After immunoperoxidase staining, fine threads immunoreactive for laminin staining were seen winding along the strands of the network, and 1.5-nm wide filaments, immunoreactive for type IV collagen, took the form of a network arrangement. The 5-nm-wide ribbon-like structures associated with the strands were identified as heparan sulfate proteoglycan by immunostaining. These results are similar to those obtained for the cord network of the lamina densa. The fibrillar layer therefore represents a highly specialized lamina fibroreticularis of the basement membrane of the inner enamel epithelium, and rich in basotubules.     

Dynamics of the cytoskeleton of epidermal cells in situ and in culture

Summary The cytoskeleton of primary tissue-culture cells from the epidermis of Xenopus laevis tadpoles was investigated by phase-contrast, immunofluorescence, and electron microscopy. The connection between the arrangement of different types of filaments and the mechanical properties of the epidermis is discussed. The bilayered epidermis attains stability from thick bundles of tonofilaments interconnecting the basal desmosomes. Twisting of tonofilaments around each other can explain the occurrence of elastic filamentous curls forming a meshwork braced between rows of small desmosomes in the apical region of the epidermis. Actin is arranged as a diffuse meshwork and sometimes forms bundles intermingling with tonofilament bundles. Surface membranes and rows of small desmosomes are delineated by actin and contain -actinin. Actin raises the tension for rounding and spreading of cells. Microtubules stabilize already well-developed lamellae.     

Lateral hydrodynamic effects of rotating filaments

On the basis of the filament rotation model that was elaborated for interpretations in cell motility, the lateral hydrodynamic effects of rotating filaments have been investigated by large-scale model experiments. Helices were rotated by small electric motors in a medium of high viscosity (honey or polyethyleneglycol). The observed effects, hitherto not investigated in detail by hydrodynamics, show some features that were attributed to the indefinable formative power or vital force of the past. The main effects generated by the rotating filaments are (1) flows and flow patterns with impact zones where flows collide, (2) regions of excessive pressure and negative pressure (corner effect) along a wall, (3) grooves and smoothly shaped ridges on a free fluid surface, and (4) rolling motions of freely hanging filaments. All effects and flow patterns depend on the appropriate distribution of rotating and counterrotating filaments. Each change of the rotational direction means a dramatic alteration. The application of the observed effects explains largely the function of the microtubule/microfilament hoops or helices during the cytokinesis of a plant cell. Interpretations or simulations are described for events as the formation of secondary wall thickenings, the orientation of their microfibrils, the motion of the preprophase band microtubules, the formation of the phragmosome, the migration, stationary position and shape of the preprophase nucleus, the girdle-, septum- and H-piece formation of cell walls in algae and some events of morphogenesis inMicrasterias. Further interpretations are related to the lateral flows and to invaginations of free cell membranes, to lateral filament motions, to the right-left problem, to the selfintertwining of filaments, to the rotation of a cell body by its flagellum, to the repulsion of chromatids during meiosis and to the tetragonal and hexagonal arrangement of filaments.Dedicated to Prof. DrLothar Geitler on the occasion of the 90th anniversary of his birthday.     

Catalase in salivary gland striated and excretory duct cells. II. ? Body: an ellipsoidal peroxisomal organelle with crystalloid axial projections

Synopsis A new distinctive and unique peroxisomal organelle with a spindle shape has been observed in luminal epithelial cells of striated and excretory ducts of mouse salivary glands. Light microscopic studies indicate it has an ellipsoidal centre from which catalase-positive filamentous or rod-like processes protrude along its major axis; hence, it is called a body. A role for this specialized peroxisome in the formation of nearby free filaments and rods is suggested by the frequent observation of segmentation of its axial processes. Complementary ultrastructural studies of osmium-fixed preparations show that the deformation to an oval shape results from the pressure of the extruding crystalloid coincident with the major axis of the ellipsoidal body. The size range and conformation of body axial processes are comparable to those of free catalase-positive rods and filaments observed in the same cells. The periodic substructure of the crystalloid in the body core is identical with that of nearby cytoplasmic rods. These observations are consistent with the view that the rods and filaments observed free in the cytoplasm are formed by extrusion from the crystalloid core of the body. Bodies could also be responsible for the Aver rods of leukemic leukocytes.     

Organization of the cytoskeleton in the coenocytic algaVaucheria longicaulis var.macounii: an experimental study

Summary The organization of the cytoskeleton of vegetative filaments ofVaucheria longicaulis Hoppaugh var.macounii Blum is investigated by fluorescence microscopy using monoclonal anti -tubulin antibodies and fluorescein (FITC)-labelled phalloidin. Confocal laser scanning microscopy observations give further information on the distribution of the cytoskeletal elements. Phalloidin labelling reveals F-actin bundles in the cortical cytoplasm of both fixed and unfixed vegetative filaments of this alga. In addition a more diffuse fluorescent component, seen at higher magnification to be made up of thinner F-actin bundles, can also be detected in unfixed cells. The distribution of the F-actin bundles resemble that of filamentous structures observed with differential interference contrast (DIC) microscopy in living cells. These structures seem to correspond to the microtubule associated reticulum (MAR) described in literature and overall the evidence suggests that actin and MAR elements are co-distributed. F-actin bundles are always found in association with focal masses (foci) of phalloidin-positive material. Foci are also observed by DIC microscopy associated with the cytoplasmic filamentous structures in living cells.Depolymerization of F-actin with cytochalasin D and the subsequent repolymerization that occurs on transfer ofVaucheria vegetative filaments to cytochalasin-free medium suggest that these foci are involved in the organization of the F-actin array. Immunofluorescence for -tubulin reveals microtubule bundles that are shorter in length and straighter in configuration than microfilament bundles. Microtubule bundles are associated with spot-like focal structures that, in many instances, show a close relationship with respect to nuclei. Oryzalin and cold temperature cause the depolymerization of the microtubule bundles and suggest, in conjunction with repolymerization studies, that these fluorescent spots associated with the ends of the microtubule bundles are involved in their organization; hence, they represent microtubule organizing centres or MTOCs. The importance of both microfilament and microtubule bundle focal regions is discussed with respect to the apical growth exhibited by the vegetative filaments of this alga.     

Structure and function of the amphibian follicular epithelium during ovulation

Summary Low concentrations of cytochalasin B (CCB) are known to inhibit ovulation in the frog, Hyla regilla. Examination of amphibian thecal cell ultrastructure reveals filaments (average diameter 71 Å) arranged in bundles parallel to the surface of the oocyte. These filaments are often associated with hemidesmosome-like plaques on the basal plasmalemma. While individual filaments appear unaltered morphologically by CCB (1–5 g/ml), their organization into bundles, apparent relationship to the hemidesmosomes, and the highly contorted configuration of the thecal cells after oocyte expulsion, suggest that a nonmuscular contractile system residing within the follicle plays a fundamental role in ovulation.Our data suggest that the flattened epithelioid thecal cells shorten all axes that run parallel to the oocyte surface via filament bundle contractions, while they remain tightly bound together by macular attachment plaques. These cells thus increase in height to become cuboidal-low columnar in shape; the area covered by the base of each is greatly reduced. As this thecal sac decreases in size, the compression generated by the contractile mechanism forces the oocyte through the enzymatically weakened apex of the follicle and ovulation results.This investigation was supported by grant HD-07194 from the National Institutes of Health. The authors are grateful to Dr. Arthur L. Cohen, Director of the Electron Microscope Center for use of the Center's scanning electron microscope. We are also indebted to Mrs. Gail M. McDole and Mr. James D. Huber for able technical assistance     

Inhibition of axonal transport in vitro in frog sciatic nerves by chlorpromazine and lidocaine

Summary The effects of chlorpromazine hydrochloride (CPZ HCl) and prochlorperazin-metansulfonate (PCPZ) on the fast axonal transport of labelled proteins were examined in vitro in a peripheral frog nerve.A 0.1 mM concentration of CPZ HCl and PCPZ reduced the amount of transported proteins by more than 50 per cent. An almost complete block was obtained with a 0.5 mM concentration of these two drugs. The lower concentration hardly affected the protein synthesis. The transport inhibiting effect of 0.1 mM of the drugs was reversible but not that of the higher concentration.The number of microtubuli was strongly decreased and the number of filaments increased at the transport inhibiting concentrations. The ultrastructural changes induced by 0.1 mM of the phenothiazine tranquilizer were largely reversible. The local anesthetics lidocaine (18.3 mM) and tetracaine (3.3 mM) both caused similar changes, i.e. a reduction in the number of microtubuli. No ultrastructural effects were observed after treatment with 1 mM ouabain. These three drugs are known to block the axonal flow in the present system at the above mentioned concentrations.The biochemical and ultrastructural results are discussed in relation to those induced by other drugs affecting axonal transport.The present work was supported by grants from Statens Naturvetenskapliga Forskningsråd (No. 2535-8), C.-B. Nathorsts Vetenskapliga och Allmännyttiga Stiftelser, the Swedish Medical Research Council (B73-12X-2543-05B), H. Hierta's Stiftelse and W. och M. Lundgrens Stiftelse. Thanks are due to Mrs B. Egnér, Mrs E. Fjällstedt, Mrs. E. Norström and Mrs U. Svedin for expert technical assistance.     

Changes in density of chromatin in the meristematic cells ofSinapis alba during transition to flowering

Summary Changes in the density of nuclear chromatin in the shoot apical meristem ofSinapis alba L. during floral transition (floral evocation) are described using Feulgen-stained 2 m thick semi-thin sections and scanning cytophotometric techniques. In both G1 and G2 nuclei the chromatin becomes less heterogeneous and less dense in evoked meristems compared to vegetative meristems. When chromatin is resolved into two fractions the dispersed fraction increases relative to the condensed fraction at evocation. This decondensation process occurs earlier in G1 than in G 2 nuclei. These chromatin changes are presumably closely related to the dramatic stimulation of biosynthetic activity and cell division during floral transition.     

Biochemical identification and immunological localization of two non-keratin polypeptides associated with the terminal differentiation of avian scale epidermis

Summary The expression of two previously uncharacterized polypeptides produced in epidermal cells of chick reticulate and scutate scales during late embryonic scale histogenesis and in hatchling birds has been studied biochemically and immunologically. These polypeptides have been identified by two-dimensional pH gradient gel electrophoresis as basic in charge, with apparent molecular weights of 20 and 23 kD, and they have been characterized immunologically and by amino acid analysis as non-keratin in nature. Monoclonal antibodies which react with both polypeptides have been used for immunohistochemical and immunogold electron-microscopic localization. Immunoreactivity was observed in suprabasal cells of reticulate scale epidermis, where it codistributed with bundles of -type cytokeratins in the -keratin-rich layers of epidermis known as the alpha stratum and in suprabasal cells of the outer epidermal surface of scutate scales, where it codistributed with -and -type keratin filament bundles in the -keratin-rich layers of epidermis known as the beta stratum.     

Histoenzymatic characterization of sub-types of Type I fibres in fast muscles of rats

Summary The histochemical activities of succinic dehydrogenase (SDH), myofibrillar Adenosine triphosphatase (ATPase) and alpha glycerophosphate dehydrogenase were studied in serial sections of rat vastus lateralis (red) (RVL), gastrocnemius and diaphragm muscles. Three main fibre-types were distinguished. The Type I fibres of RVL and gastrocnemius muscles fell into two distinct groups: one category-Type IA showed very low ATPase activity. The second category of Type IB fibres displayed moderate ATPase reaction. The Type IA fibres were divisible into two sub-groups when tested for SDH reaction. Type IA₁ fibres possessed a homogenous distribution of diformazan·granules throughout the fibre: Type IA₂ fibres displayed characteristic moth-eaten pattern of diformazan localization. The diaphragm muscle did not show either Type IB or Type IA₂ varieties. The great majority of Type I fibres were sub-type IA₁ in the three fast muscles studied. It is also demonstrated here that an inherent heterogeneity exists between Type I fibres of diaphragm and leg muscles in regard to -GPD localization. This histochemical data emphasizes the fact that subdivision of Type I striated muscle fibres of mammalian animals into two sub-types is only approximate and that a further subcategorization is possible.     

Possible sites of release of neurosecretory granules in the sinus gland of the crayfish,Orconectes nais

Summary The sinus gland is a neurohemal organ located in the crayfish eyestalk and represents a storage site for neurohormones prior to their release into the circulation. The sinus gland contains three classes of electron dense, membrane-limited granules. Class 3 granules are the largest and most electron dense of the granules found in the sinus gland. Granules of class 1 are the smallest, while those of class 2 are the most abundant. Generally, all granules undergo similar changes during their release.Release of neurosecretory material may be initiated by a preliminary fragmentation of the parent granules into smaller granules. Following the formation of numerous smaller granules, these move to the plasma membrane and their limiting membrane apparently fuses with it thus releasing its contents into the external lamina which is applied to the sinusoidal surface of the axon terminals. Granule release does not appear to occur along the entire plasma membrane adjacent to the blood sinus but, instead, probably occurs only at specific active sites on the membrane. The active sites are characterized in part by an accumulation of small granules and clear vesicles against the cytoplasmic side of the plasma membrane. At the site of release of the neurohormone, there is often an accumulation of dense homogeneous material beneath the axolemma.Occasionally, axon endings filled with large, electron lucent vesicles are seen. These clear granules vary from 1150–1750 Å in diameter and often exhibit broken limiting membranes. Few small vesicles are seen near the plasma membrane of these endings; however, instances of invaginations of the plasma membrane occur. The significance of endings filled with clear granules is discussed.Supported by a grant from the National Research Council of Canada (No. A-4675).     

Light-and electron microscopical observations on the terminal airways and the alveolar parenchyma of the antarctic seals Lobodon carcinophagus and Leptonychotes weddelli

Summary The terminal airways of two antarctic seals (Leptonychotes weddelli, Lobodon carcinophagus) are composed of typical small bronchi and bronchioles the initial segment of which contains cells probably representing Clara cells. The respiratory bronchioles are of considerable length. Their wall contains a highly developed system of spirally arranged bundles of smooth muscle cells. This is interpreted to represent the main means which by being closed before diving prevents the reabsorption of nitrogen while returning to the surface. The amount of smooth muscles evidently is greater in the deep diving Weddell seal than in the crabeater seal. The pneumocytes II occur both within the respiratory bronchioles and in the alveoli, their number seems to be relatively high in both species. The diameter of thin parts of the blood-air barrier in both species is 0.3–0.4 m (0.19–0.22 m in terrestrial mammals). The alveolar septa contain myofibroblasts and one layer of capillaries. The connective tissue of both seals lung is highly developed forming a dense, strong meshwork of septa and a thick pleura visceralis. The septa contain bundles of smooth muscle cells and extensive lymphatic vessels. Due to its particularly thick septa the lobulaton of the lung tissue of the Weddell seal is more obvious than in the crabeater seal, however, in both species the amount of connective tissue in the interlobular septa and the pleura visceralis is greater than in terrestrial carnivores.     

Some observations on the fine structure of the myotendinous junction in myotomal muscles of the tadpole tail

Summary Myotendinous junctions in the myotomal tail muscles of the tadpole of Rana rugosa were examined by electron microscopy. At the site of the myotendinous junction, the sarcolemma is covered on its sarcoplasmic aspect by the connecting filament layer and the attachment layer, and on the extracellular aspect by the intermediary layer and the external lamina, with associated collagen fibrils. The intermediary layer consists of filamentous structures which closely resemble microfibrils (Hanak and Böck, 1971), spine-like or thread-like profiles (Korneliussen, 1973) and intermediary layer (Nakao, 1975a, b) in the myotendinous junctions of other vertebrate skeletal muscles.Particularly interesting is the fact that all the coverings and linings of the sarcolemma, including the external lamina, are completely absent in the terminal segment of the finger-like sarcolemmal invagination characteristic of the myotendinous junction. Furthermore, special types of coupling between a sac of sarcoplasmic reticulum and a part of the sarcolemmal invagination are frequently observed. These couplings always occur along the region of the sarcolemma where the external lamina is absent. The couplings show features similar to those of the triad, such as SR feet , scalloped SR membranes and granular content of the SR sac, suggesting that they are analogous and functionally similar to the triad and other equivalent structures.     

The rotifer trap of Zoophagus

The predacious watermold Zoophagus insidians traps loricate rotifers on short, lateral branches of the main, hyphal axis. These branches or traps are packed at their distal ends with a number of vesicles filled with an electron-dense matrix. Electron micrographs of the mycelium disclose a two-layered wall; the outer layer is electron dense and the inner, electron transparent. The outer dense layer on the tip of the trap is organized into a number of fine ridges and occasional discontinuities. Thin sections through recently trapped rotifers indicate that the cilia of the animals are stuck to the trap by a glue. This adhesive is derived from secretion of the matrix of the vesicles aggregated in the tip of the trap. The secretion mechanism is triggered by the animal and is accompanied by: 1. The separation of the two layers of the wall, 2. fusion of the vesicles with the cell membrane and 3. extrusion of the glue through pits in the tip of the inner wall of the trap. After snaring a rotifer, the previously arrested branch grows as a haustorium into the body cavity of the animal. The host tissues disintegrate within a few hours and appear to be the main nutrient source of the fungus.     

Zur Feinstruktur der Elektrozeptorepidermis der Mormyridae (Teleostei,Pisces)

Zusammenfassung Die schwachelektrischen Mormyridae haben eine dreischichtige Epidermis, deren innere Schicht aus nur etwa 0,22 m dicken sechseckigen Zellen von ca. 60 m Durchmesser besteht. Die etwa 2 m dicken, linsenförmigen Kerne von 7,6 m Durchmesser liegen am Zellrand. Die Zellen sind zu Säulen aufgeschichtet. Ihr Rand ist ausgezackt und dort, wo er die Säulengrenze erreicht, auf etwa 0,34 m verdickt. In der Nähe der Säulengrenzen sind die Zellen über Desmosomen mit den Nachbarn in der eigenen und in der angrenzenden Säule verbunden. Diese Epidermisschicht ist auf die Körperpartien beschränkt, in denen auch Elektrorezeptoren ausgebildet sind.Die beiden anderen Epidermisschichten haben den üblichen Aufbau einer Fischepidermis, abgesehen vom Fehlen der Becherzellen.

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Ultrastructure of the electroceptor epidermis of the Mormyridae (Teleostei, Pisces)

Summary The weakly electric fish of the family Mormyridae have a three layered epidermis, with a medium layer consisting of hexagonal cells of only 0.22 m in thickness and about 60 m in diameter. The lens-shaped nuclei are about 2 m thick and 7.6 m in diameter and are situated near the border of the cells. The cells are piled up to hexagonal columns. Their margin is serrate and where it reaches the boundary of the column, it has a thickness of about 0.34 m. Close to the boundaries of the columns, the cells are linked to their neighbours within the column and of the adjoining column by desmosomes. This layer of the epidermis is confined to those regions of the body surface which also contain electroreceptors.The other layers of the epidermis have a structure as usual in fish, except for the lack of goblet cells.