Cytoskeleton-membrane interactions in the cnidocil complex of hydrozoan nematocytes

Summary Each cnidocil complex of the hydrozoans Tubularia larynx and Hydra vulgaris consists of 9 or 7–10 large stereovilli (=stereocilia), respectively, and a modified cilium, the cnidocil. The cnidocils comprise the regular 9 microtubule doublets, up to 30 additional microtubules, as well as a central filament body. Adjacent stereovilli are linked together by intermembrane connectors forming the stereovillar cone. The distal tips of the stereovilli surround the cnidocil in a closed tubular arrangement measuring up to 0.7 m in length. Within this contact region the cnidocil is linked to the stereovillar tube by another set of intermembrane connectors, which seem to hold the cnidocil in a central position within the stereovillar cone. Stereovillar membrane and actin core are linked by 16-nm long cross bridges, which display a periodicity of 16 nm and emerge from the actin core. Within the cnidocils periodically arranged membrane-cytoskeleton bridges are uniformly restricted to the contact region. Here, 24-nm long cross bridges, which are spaced by a regular distance of 20 nm, interconnect the A-tubules of the microtubule doublets and the membrane. The cnidociliary membrane is differentiated into distinct domains as revealed by freeze-fracturing. Within the contact region of the nematocytes of Tubularia larynx, intramembrane particles are arranged in 9 rows of 700 nm length and 50 nm width, separated by particlefree areas. Intramembrane particles are irregularly distributed distal to the contact region. Considering recent physiological results we presume that the latter represent chemoreceptor units, while mechanical stimuli are transmitted via the intermembrane connectors and the microtubule-membrane bridges to mechanosensitive channels within the domain of the cnidociliary membrane in the contact region.     

Mechanoreception and synaptic transmission of hydrozoan nematocytes

Mechanoelectric transduction and its ultrastuctural basis were studied in the cnidocil apparatus of stenotele nematocytes of marine and freshwater Hydrozoa (Capitata and Hydra) as a paradigm for invertebrate hair cells with concentric hair bundles. The nematocytes respond to selective deflection of their cnidocil with phasic-tonic receptor currents and potentials, similar to vertebrate hair cells but without directional dependence of sensitivity. Ultrastructural studies and the use of monoclonal antibodies allowed correlating the mechanoelectric transduction with structural components of the hair bundle. Two other types of depolarising current and voltage changes in nematocytes are postsynaptic, as concluded from their ionic and pharmacological characteristics. One of these types is induced by mechanical stimulation of distant nematocytes and sensory hair cells. It is graded in amplitude and duration, but different from the presynaptic receptor potential. Adequate chemical stimulation of the stenoteles strongly increases the probability of discharge of their cnidocyst, if the chemical stimulus precedes the mechanical one. Simultaneously, the probability of synaptic signalling induced by mechanical stimulation is increased, reaching nearly 100%. The chemoreception of the phospholipids used could be localized in the shaft of the cnidocil, because of the water-insolubility of the stimulant. This chemical stimulation itself does not cause a receptor potential; its action is classified as a modulatory process. Electron microscopy of serial sections of the tentacular spheres of Coryne revealed synapses that are efferent to nematocytes and hair cells besides neurite–neurite synapses, each containing 3–10 clear and/or dense-core vesicles of 70–150 nm diameter. The only candidates to explain the graded afferent signal transmission of nematocytes and hair cells are regularly occurring cell contacts associated with 1(–4) clear vesicles of 160–1100 nm diameter. Transient fusion and partial depletion of stationary vesicles are discussed as mechanisms to reconcile functional and structural data of many cnidarian synapses. Review contributed to the Symposium on Neuro-Anatomy and -Physiology of Coelenterates; 7th International Conference on Coelenterate Biology, Lawrence, Kansas, USA; July 6–11, 2003.     

Monoclonal antibodies that depress a specific subset of multiple components of the glutathione-induced response ofHydra

Summary Reduced glutathione evokes a feeding response, the tentacle-ball formation inHydra japonica. This response consists of at least 5 components (R1–R5). We raised 6 monoclonal antibodies (mAbs), each of which depressed a specific subset of these components, and we also examined the immunocytochemical localization of antigens with these mAbs at light microscopic level. The 2 mAbs that depressed R2 and R4 bound to the cnidocils of the desmoneme and the stenotele nematocytes; the 3 mAbs that depressed R5 bound to the apical surface adjacent to the cnidocils of the nematocytes; and the 2 mAbs that depressed R1 and R3 bound to the apical spot structures of unidentified cells in the ectoderm.Together with the specificity of the action of the mAbs on the behavioral response, the correspondence between the effects on the response and the structures visualized with these mAbs suggests that these structures include components of the receptor-effector system relevant to chemoreception.     

Fine structure of the nematocytes of Polypodium hydriforme Ussov (Cnidaria)

The fine structure of the stinging cells (nematocytes) and stinging capsules (nematocysts) is described for Polypodium hydriforme. a freshwater coclenterate with a prominent endoparasitie stage in its life cycle. All the nematocysts belong to the type of lesser glutinants (atrichous isorhiza) and fall into three size classes. The internal structure of the capsules is similar in the three classes. A novel type of organization of the cnidocil apparatus of the nematocysts is described. The cnidocil lacks a root fibre and its kinctosome sits directly on the operculum of the nematocyst, so that the entire cnidocil apparatus has a radial rather than bilateral symmetry. It is compared with that of other types of nematocytes and its similarity with the mechanoreccptors of the coelentcratcs is noted. The possible place of the Polypodium nematocytes in the evolution of the collar receptors of the Metazoa is discussed.     

Surface charges of the membrane and cell adhesion substances determine the structural integrity of hair bundles from the inner ear of fish

Summary The hairs (stereocilia = stereovilli) of sensory cells from the inner ear of vertebrates are interconnected by several types of connectors, whose role is unknown. They appear to stabilize the hair bundle mechanically, and may be directly involved in mechano-electric transduction. Our transmission electron-microscopical investigation of sensory epithelia from two species of fish (Rutilus rutilus, Scardinius erythrophthalmus, both Leuciscidae) has shown that not only the connectors but also the surface charges of the membrane are important factors for determining the shape of the hair bundle and the spatial interrelation of the stereovilli. A reduction of the ionic strength in the medium leads to an increase in distance between the stereovilli. This may be the result of an extension of the spread of the surface potential of the membrane at low ionic strength. The connectors are not broken by the increase in distance between the stereovilli. They are EDTA (ethylene-diamine-tetra-acetic-acid) resistant as are some cell adhesion molecules such as N-CAM (nerve-cell adhesion molecule) and protein A from Dictyostelium discoideum. The connectors do not prevent polycation-induced fusion of adjacent stereovillar membranes.     

The ciliated sensory cell of Stauridiosarsia producta (Cnidaria,Hydrozoa) — a nematocyst-free nematocyte?

Summary A mechanosensitive ciliated cell type of the polyp Stauridiosarsia producta (Hydrozoa) was investigated by means of electron microscopy. These cells bear at their apical cell surface a modified cilium, a set of seven stereovilli, a so-called pseudovillar system and a large vacuole. Cilium and stereovilli are interconnected like the cnidocil apparatus of hydrozoan nematocytes which is responsible for mechanoelectric transduction. The vacuole is enclosed by and linked to the pseudovillar system by a microtubular basket. Considering its structural organization and physiological activities the ciliated sensory cell closely resembles a nematocyte that has lost its ability ot produce a nematocyst.     

Apical surface of hydrozoan nematocytes: Structural adaptations to mechanosensory and exocytotic functions

At the apical cell pole of the nematocytes of a hydrozoan (Hydra vulgaris), cytoskeletal elements of different molecular families (microfilaments, microtubules, cross-striated rootlets) are combined in a complex framework. As determined by transmission and scanning electron microscopy, the stimulus-transducing cnidocil apparatus of these mechanosensitive cells is forced into a lateral position, facilitating the close apposition of the nematocyst to the apical cell membrane. The nematocyst, a single, extraordinarily large, exocytotic organelle, is held in position by a microtubular basket. The cnidocil apparatus and microtubular basket are linked to an ellipsoid arrangement of pseudovilli, i.e., small surface protrusions containing cross-striated rods. These nematocyte-specific, cytoskeletal elements mediate the anchorage of the entire cytoskeletal framework to the apical cell membrane. The apical membranes of the nematocyte and nematocyst are separated by a distance of only ～ 50 nm. Structural modifications on the external side of the cyst membrane resemble those of synaptic membranes. © 1994 Wiley-Liss, Inc.     

Arrangement of accessory cells and nematocytes bearing mastigophores in the tentacles of the cubozoan Chironex fleckeri

Nematocytes containing microbasic mastigophores are intimately associated with accessory cells in the epidermis of Chironex fleckeri. Large microbasic mastigophores may be surrounded by seven to nine such cells. Each accessory cell possesses an apical portion containing secretory droplets and a basal portion which carries a radially oriented fibre linking the cell to the underlying mesogloea. The fibre is capable of projecting and retracting the accessory cell. Junctional complexes occur between accessory cells and the apical regions of neighbouring mastigophores. Each nematocyte bearing a mastigophore contains a triggering apparatus consisting of a cnidocil surrounded by microvilli. This apparatus protrudes from an invagination in the apical region of the nematocyte and is exposed when the mastigophore is in the fire-ready position. A basket of filaments which make contact with microvilli surrounds the apical end of the nematocyst like a collar. The basket is linked via fibrous bundles which envelop the mastigophore to radially oriented fibres basally. These fibres are capable of projecting and retracting the mastigophore and its associated triggering apparatus. Up to nine such fibres were observed to be associated with a single large microbasic mastigophore. Microtubules averaging 25 nm in diameter and linked via cross bridges to electrondense material were detected in the radial fibres of both nematocytes and accessory cells. Retraction of the accessory cells and projection of nematocytes result in mastigophores being brought to the firing line and in the exposure of the cnidocil apparatus.     

Cilium evolution: identification of a novel protein, nematocilin, in the mechanosensory cilium of Hydra nematocytes

The cnidocil at the apical end of Hydra nematocytes is a mechanosensory cilium, which acts as a "trigger" for discharge of the nematocyst capsule. The cnidocil protrudes from the center of the cnidocil apparatus and is composed of singlet and doublet microtubules surrounding an electron-dense central filament. In this paper, we identify a novel protein, nematocilin, which is localized in the central filament. Immunofluorescence staining and immunogold electron microscopy show that nematocilin forms filaments in the central core of the cnidocil. Nematocilin represents a new member of the intermediate filament superfamily. Two paralogous sequences of nematocilin are present in the Hydra genome and appear to be the result of recent gene duplication. Comparison of the exon-intron structure suggests that the nematocilin genes evolved from the nuclear lamin gene by conserving exons encoding the coiled-coil domains and replacing the C-terminal lamin domains. Molecular phylogenetic analyses also support the hypothesis of a common ancestor between lamin and nematocilin. Comparison of cnidocil structures in different cnidarians indicates that a central filament is present in the cnidocils of several hydrozoan and a cubozoan species but is absent in the cnidocils of anthozoans. A nematocilin homolog is absent in the recently completed genome of the anthozoan Nematostella. Thus, the evolution of a novel ciliary structure, which provides mechanical rigidity to the sensory cilium during the process of mechanoreception, is associated with the evolution of a novel protein.     

Mechanoelectric transduction in nematocytes of a hydropolyp (Corynidae)

In sensitivity and ultrastructure of their cnidocil apparatus (CA), the nematocytes (stinging cells) of hydrozoans are analogous to hair cells of vertebrates and epidermal mechanoreceptors of insects. Intracellular recordings using current and voltage clamp in the capitate tentacles of the marine hydropolyp Stauridiosarsia producta (Corynidae) now revealed that depolarizing receptor potentials and receptor currents are generated in nematocytes (stenotele type) in response to mechanical stimulation of the CA. The responsive cells were identified by injection of Lucifer Yellow. For recording, the tentacles were isolated from the polyp and held by a suction capillary. Stimuli were applied by a glass probe moved electromagnetically or piezoelectrically.The mechanosensitivity of the nematocytes was found to be strictly limited to the CA. The characteristics of the mechanoelectric transduction were those typical of mechanoreceptor cells: phasic-tonic time course of an increase in membrane conductance; latency between stimulus and receptor response < 50 s; sigmoid relationship between receptor-response amplitude and stimulus amplitude; maximal increase in conductance of 15 nS; reversal potential between + 35 mV and — 10 mV; unspecific cation dependence and reversible blocking by streptomycin. The results suggest a direct mechanical control of unspecific cation channels such as has been found for mechanoreceptor cells.Suprathreshold receptor potentials elicit two forms of regenerative depolarization: non-inactivating, steplike potentials and action potentials. The latter can trigger discharge of the nematocyst.The discharge of nematocysts in the intact animal (without recording) in response to adequate stimuli was blocked by streptomycin and Na⁺ depletion in the same way as the receptor potential.Mechanoreceptor potentials are thus the beginning of a stimulus-induced electrical reaction cascade that ends in nematocyst discharge.     

The differentiation of cytoskeletal structures in nematocytes of Hydra

Nematocytes of hydra feature a complex cytoskeleton consisting mainly of several bundles of actin filaments and a basket-like structure formed by microtubules. The aim of this study was to establish the sequence of appearance of cytoskeletal elements during nematocyte development using immuno-fluorescence and electron microscopical techniques. Our results are a first step in trying to understand developmental hierarchies and mechanisms which govern the synthesis and assembly of the cytoskeleton in nematocytes. The finger-shaped rods around the apex of the capsule are the first detectable elements of the cytoskeleton. Microtubules of the basket structure then follow and later, the actin filaments of microvilli which support the cnidocil. The actin filaments, however, do not show the highly ordered bundling pattern characteristic of filaments in functional nematocytes.     

Differentiation of the interstitial cell line in hydrozoan planulae

Repopulation of epithelial (colchicine-treated) planular tissue by interstitial cells, nematoblasts/nematocytes, and ganglionic cells was examined via grafting. Seventy-two-hour epithelial planular head pieces were grafted to 72-hour control labelled planular tail pieces, left in contact for 24 h, separated, and the head pieces were analyzed for interstitial cells and their derivatives. The reciprocal experiment of grafting 72-hour epithelial planular tails to 72-hour control labelled planular heads was also done and the tail pieces were examined. Repopulated planular head pieces contained interstitial cells, ganglionic cells and a reforming neural plexus but few nematoblasts/nematocytes. Reconstituted planular tail pieces contained interstitial cells and nematoblasts/nematocytes but no ganglionic cells. Results possibly suggest that the migrating interstitial cell population of 72-hour planulae is rich in committed precursors.     

Bud formation in the scyphozoan Cassiopea andromeda: epithelial dynamics and fate map

Cassiopea andromeda scyphistomae reproduce asexually by forming spindle shaped buds which, after detachment, metamorphose into polyps. Parent polyps appear to contribute to the buds' ecto- and endodermal epithelial cells, septal muscle cells, nematocytes and some zooxanthellae. Herein we describe bud morphogenesis, define 5 bud stages, and investigate the recruitment of bud ectoderm. India ink vital marking experiments reveal permanent apicobasal displacement of ectoderm. Labelled polyp cells are displaced towards and incorporated into the emerging bud. Ectoderm is recruited from all angular positions and cells labelled at increasing distances from the bud center are traced at increasingly more proximal positions on the buds. Unlike in Hydra attenuata, the recruitment area appears to be asymmetric since the zone contributing ectoderm from below is smaller than the zones above and lateral to the buds.     

Pulses of ammonia and methylamine induce down-regulation of nematocyte and nerve cell populations in Hydrozoa (Hydra; Hydractinia)

Summary Hydrozoa replace used-up nematocytes (cnidocytes) by proliferation and differentiation from interstitial stem cells (i cells). Repeated pulsed exposure ofHydra to elevated levels of unprotonated ammonia leads to successive loss of the various types of nematocytes: first of the stenoteles, then of the isorhizas and finally of the desmonemes. The loss is due to deficits in supply; the number of nematoblasts and differentiating intermediates is reduced. In the hydroidHydractinia the main process leading to numerical reduction was observed in vivo: mature nematocytes as well as precursors emigrate from their place of origin into the gastrovascular channels where they are removed by phagocytosis. This is a regular means by which these animals down-regulate an induced surplus of nematocytes. With lower effectiveness, pulses of methylamine, trimethylamine and glutamine also induce elimination of the nematocyte lineages. In the long term the population of nerve cells, which are permanently but slowly renewed from interstitial neuroblasts, decreases, too. After 2 months of daily repeated treatment the density of the Arg-Phe-amide-positive nerve cells was reduced to 50% of its normal level. Thus, ammonia induces down-regulation of all interstitial cell lineages. The temporal sequence of the ammonia-induced loss reflects the diverse rates with which the various i cell descendants normally are renewed.     

Cytoskeletal elements in migrating and tentacle-integrated nematocytes of a marine hydrozoan

Summary— Actively migrating nematocytes of the marine polyp Stauridiosarsia producta are converted into completely immotile cells as soon as they become integrated in the ectodermal tissue of the tentacles. Immunocytochemical and electron microscopical methods revealed that cytoskeletal elements composed of actin, tubulin, centrin and a still unidentified protein are interwoven within the complete cell. While the organization of the sensory pole of the nematocyte, containing the cnidocil complex, the pseudovillar system and the distal half of a microtubular basket surrounding the nematocyst, is not affected by the transition from a motile to an immotile cell, the cytoskeletal elements in the basal portion of the cell are re-organized. Thus, the basolateral cytoplasm of migrating cells contains less organized microtubular arrays and bundles of about 10 nm-thick filaments. In the tentacle-integrated state, the 10-nm filaments are concentrated within a stalk-like foot which is stabilized by some rigid microtubular arrays derived from the microtubular basket. By elongation of the microtubular basket towards the cellular basis, the nematocyst becomes indirectly anchored at the mesoglea. As indicated by pharmacological treatments, the stiffness of the stalk depends on its microtubular content only.     

High Prevalence of Batrachochytrium dendrobatidis in Wild Populations of Lowland Leopard Frogs Rana yavapaiensis in Arizona

Batrachochytrium dendrobatidis (Bd) is a fungus that can potentially lead to chytridiomycosis, an amphibian disease implicated in die-offs and population declines in many regions of the world. Winter field surveys in the last decade have documented die-offs in populations of the lowland leopard frog Rana yavapaiensis with chytridiomycosis. To test whether the fungus persists in host populations between episodes of observed host mortality, we quantified field-based Bd infection rates during nonwinter months. We used PCR to sample for the presence of Bd in live individuals from nine seemingly healthy populations of the lowland leopard frog as well as four of the American bullfrog R. catesbeiana (a putative vector for Bd) from Arizona. We found Bd in 10 of 13 sampled populations. The overall prevalence of Bd was 43% in lowland leopard frogs and 18% in American bullfrogs. Our results suggest that Bd is widespread in Arizona during nonwinter months and may become virulent only in winter in conjunction with other cofactors, or is now benign in these species. The absence of Bd from two populations associated with thermal springs (water >30°C), despite its presence in nearby ambient waters, suggests that these microhabitats represent refugia from Bd and chytridiomycosis.     

Inhibition of photosynthetic reactions under water stress: interaction with light level

When the shrub Nerium oleander L., growing under full natural daylight outdoors, was subjected to water stress, stomatal conductance declined, and so did non-stomatal components of photosynthesis, including the CO₂-saturated rate of CO₂ uptake by intact leaves and the activity of electron transport by chloroplasts isolated from stressed plants. This inactivation of photosynthetic activity was accompanied by changes in the fluorescence characteristics determined at 77 K (-196°C) for the upper leaf surface and from isolated chloroplasts. The maximum (F _M) and the variable (F _V) fluorescence yield at 692 nm were strongly quenched but there was little effect on the instantaneous (F _O) fluorescence. There was a concomitant quenching of the maximum and variable fluorescence at 734 nm. These results indicate an inactivation of the primary photochemistry associated with photosystem II. The lower, naturally shaded surfaces of the same leaves were much less affected than the upper surfaces and water-stress treatment of plants kept in deep shade had little or no effect on the fluorescence characteristics of either surface, or of chloroplasts isolated from the water-stressed leaves. The effects of subjecting N. oleander plants, growing in full daylight, to water stress are indistinguishable from those resulting when plants, grown under a lower light regime, are exposed to full daylight (photoinhibition). Both kinds of stress evidently cause an inactivation of the primary photochemistry associated with photosystem II. The results indicate that water stress predisposes the leaves to photoinhibition. Recovery from this inhibition, following restoration of favorable water relations, is very slow, indicating that photoinhibition is an important component of the damage to the photosynthetic system that takes place when plants are exposed to water stress in the field. The underlying causes of this water-stress-induced susceptibility to photoinhibition are unknown; stomatal closure or elevated leaf temperature cannot explain the increased susceptibility.Abbreviations and symbols Chl chlorophyll - PFD photon flux area density - PSI, PSII photosystem I, II - F _M, F _O, F _V maximum, instantaneous, variable fluorescence emission - leaf water potential C.I.W.-D.P.B. Publication No. 775     

Electron microscope autoradiography of14C photosynthate distribution at the haustorium-host interface in powdery mildew ofPisum sativum

Summary Haustorial complexes were isolated from leaves ofPisum sativum infected withErysiphe pisi and exposed to¹⁴CO₂ for 2 hours. The constituents of the isolated fraction were quantified and ultrastructurally described and the distribution of¹⁴C studied by electron microscope autoradiography and statistical treatment. Most (86%) of the isotope in the fraction was associated with haustorial complexes. Three classes of haustorial complexes were distinguished by degree of labelling and ultrastructure. Most of the haustorial complexes were termed healthy (i.e., they showed a normal ultrastructure) and were heavily labelled; necrotic complexes were unlabelled; and a class with intermediate labelling, modified extrahaustorial membrane and usually a normal haustorial cytoplasm was termed pre-necrotic. In healthy haustorial complexes the haustorial lobes and extrahaustorial membrane showed the highest grain densities and the body and extrahaustorial matrix were also significantly labelled. Comparison of the results suggest that ultrastructural modifications leading to necrosis were caused by dehydration which in turn determined reduction in photosynthate transfer. Other factors influencing transport into haustoria and the status of the extrahaustorial matrix are also discussed.U.V. fluorescence microscopy with acetamido-isothiocyanatostilbene salt was used to distinguish healthy and pre-necrotic haustorial complexes. It is recommended as a simple technique to monitor the functional quality of isolated haustorial complexes.     

Immunohistochemical and immunocytochemical detection of SchS34 antigen in <Emphasis Type="Italic">Stachybotrys chartarum</Emphasis> spores and spore impacted mouse lungs

The purpose of this study was to evaluate the distribution of a 34 kD antigen isolated from S. chartarum sensu lato in spores and in the mouse lung 48 h after intra-tracheal instillation of spores by immuno-histochemistry. This antigen was localized in spore walls, primarily in the outer and inner wall layers and on the external wall surfaces with modest labelling observed in cytoplasm. Immuno-histochemistry revealed that in spore impacted mouse lung, antigen was again observed in spore walls, along the outside surface of the outer wall and in the intercellular space surrounding spores. In lung granulomas the labelled antigen formed a diffusate, some 2–3× the size of the long axis of spores, with highest concentrations nearest to spores. Collectively, these observations indicated that this protein not only displayed a high degree of specificity with respect to its location in spores and wall fragments, but also that it slowly diffuses into surrounding lungs.     

盐胁迫对二穗短柄草幼苗生长及不同器官中盐离子稳态的影响

采用4种浓度的NaCl溶液(50、100、150、200 mmol/L)处理二穗短柄草和拟南芥(对照)幼苗,测定不同浓度盐胁迫下2种植物幼苗的生长指标和离子分布,以探讨二穗短柄草在盐胁迫下主要阳离子平衡机制.结果表明:(1)盐胁迫显著抑制二穗短柄草根叶的生物量积累.(2)根冠比数据显示,在盐胁迫条件下二穗短柄草能够更好地维系地下部分的生物量积累.(3)在4种浓度盐胁迫下,二穗短柄草叶中Na+含量低于根系,而且K+、Cl-含量和K+/Na+比值始终高于根系,说明在二穗短柄草中Na+从地下到地上的转运受到抑制,但对Cl-的转运缺乏有效的调控.(4)回归分析发现,盐胁迫下二穗短柄草和拟南芥根部Na+与K+含量变化呈正相关关系,而在叶部则不相关,说明二穗短柄草和拟南芥Na+与K+在根部具有相同的离子通道,而在叶部却具有各自独立的转运途径.