Ultrastructural analysis of nematocyte removal in Hydra

A consecutive series of ultrathin sections through the distal one-third of a Hydra tentacle has revealed at least four categories of nematocytes: (1) normal, mounted nematocytes, in specific arrangements within the battery cells; (2) degenerating nematocytes, within the battery cells; (3) mature nematocytes, enclosed within endodermal cells; (4) a mature nematocyte, in the enteric cavity. The degenerating nematocytes within the battery cells and the nematocytes in the endoderm and enteric cavity appeared to be aging nematocytes undergoing death and removal. The results provide the first ultrastructural evidence for nematocyte degeneration within battery cells and also suggest phagocytosis of mature nematocytes by endodermal cells.     

Nerve cell and nematocyte production in Hydra is deregulated by lithium ions

Summary LiCl, a well-known vegetalising agent, interferes with the commitment of stem cells to nerve cells and nematocytes in Hydra attenuata. Treatment with 20 mM LiCl inhibits commitment to nerve cells, treatment with 1 mM LiCl inhibits commitment to nematocytes. However, LiCl does not prevent stem cells committed to the nematocyte pathway from dividing and differentiating into nests of nematocytes. Following LiCl treatment, determination to nerve cells and nematocytes is triggered again. Commitment to nerve cells is strongly stimulated within the first 3 h following pulse treatment with LiCl if the animals have been fed immediately prior to treatment. In Hydra exposed to LiCl for 10 days the stem cell density is reduced by at least 90% of the initial value, and nematocytes are almost completely missing, whereas the density of nerve cells is within the normal range in animals with normal morphology. Animals which developed a transverse constriction in the middle of the body axis contain a 1.7-fold higher nerve cell density in the lower part than is observed in control animals.     

Thiol-induced discharge of acontial nematocytes

The discharge of nematocytes, the stinging cells of Coelenterata, is a poorly understood phenomenon. In particular, little is known about the chemical stimuli that trigger the discharge. In this paper, we show that thiols are able to initiate the nematocyst discharge in isolated nematocytes. Among the thiols tested, reduced glutathione and cysteine were found to be the most effective. The effect of glutathione was likely two-fold: it formed mixed disulfides with membrane thiols, as shown by the ability of the mercapto-blocking reagent iodoacetamide to abolish its action; and it bound to the membrane through the glutamate moiety, as demonstrated by competitive experiments with free glutamate. Glutathione triggered the discharge at concentrations higher than those sufficient to activate the feeding response of Coelenterates. However, our results demonstrate for the first time that the modification of membrane thiols by selective agents may be a key event in the discharge of 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.     

Neurotoxin localization to ectodermal gland cells uncovers an alternative mechanism of venom delivery in sea anemones

Jellyfish, hydras, corals and sea anemones (phylum Cnidaria) are known for their venomous stinging cells, nematocytes, used for prey and defence. Here we show, however, that the potent Type I neurotoxin of the sea anemone Nematostella vectensis, Nv1, is confined to ectodermal gland cells rather than nematocytes. We demonstrate massive Nv1 secretion upon encounter with a crustacean prey. Concomitant discharge of nematocysts probably pierces the prey, expediting toxin penetration. Toxin efficiency in sea water is further demonstrated by the rapid paralysis of fish or crustacean larvae upon application of recombinant Nv1 into their medium. Analysis of other anemone species reveals that in Anthopleura elegantissima, Type I neurotoxins also appear in gland cells, whereas in the common species Anemonia viridis, Type I toxins are localized to both nematocytes and ectodermal gland cells. The nematocyte-based and gland cell-based envenomation mechanisms may reflect substantial differences in the ecology and feeding habits of sea anemone species. Overall, the immunolocalization of neurotoxins to gland cells changes the common view in the literature that sea anemone neurotoxins are produced and delivered only by stinging nematocytes, and raises the possibility that this toxin-secretion mechanism is an ancestral evolutionary state of the venom delivery machinery in sea anemones.     

Nematocyte development in Hydra attenuata is dependent on both the interstitial cells and the epithelial cells

The aberrant, a morphological mutant of Hydra attenuata, has altered patterns of the development and distribution of nematocytes. The number of nematoblasts and nematocytes is higher in the aberrant than in the normal. Stenotele differentiation is incomplete and the numbers of desmonemes and holotrichous isohrizas mounted on the body column are much higher than normal. Because nematocytes arise by differentiation from the interstitial cells, epithelial cell/interstitial cell chimeras between the aberrant and normal strains were made to determine whether the lesion giving rise to the alterations in the mutant was due to the epithelial cells or a cell type in the nematocyte lineage. Only the chimera in which both cell types were derived from the aberrant exhibited the altered nematocyte development. If the chimera contained a normal cell type, either epithelial cell or interstitial cell, nematocyte development was normal. Thus, both epithelial cells and cells of the nematocyte lineage are involved in the control of nematocyte development. A defect in one of the lineages can be compensated for by the other cell type.     

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.     

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.     

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.     

Regulation of interstitial cell differentiation inHydra attenuata

Summary The axial position of interstitial-cell (i-cell) differentiation into nematocytes inHydra was studied. Nests of developing nematoblasts of three types of nematocytes were distributed in a non-uniform manner along the body column. Stenotele nematoblasts were distributed in a gradient with a maximum in the peduncle. Desmoneme and atrichous isorhiza nematoblasts were found predominantly in the upper half of the body region. These results suggest that the type of nematocyte differentiation an i-cell undergoes is influenced by the axial position of the i-cell. Because the assayed stage of nematocyte differentiation occurred 6–7 days after beginning of differentiation, the axial position of the anticedent i-cell at the time of commitment was determined by correcting for tissue displacement.     

Regulatory volume decrease in nematocytes isolated from acontia of Aiptasia diaphana.

Regulatory volume decrease (RVD) and the mechanisms of its regulation were investigated in microbasic mastigophore nematocytes isolated from the acontia of Aiptasia diaphana (Coelenterates, Cnidaria), a marine species that can be exposed to considerable changes in osmotic pressure. Exposure of isolated cells to a 35% hypoosmotic shock lead to the expected osmotic swelling followed by a rapid RVD. RVD was blocked if Ca2+ influx was prevented either by applying a Ca2+-free medium or by treating the cells with Gd3+. Furthermore, the calmodulin action inhibitor trifluoperazine (TFP), prevented RVD and also caused a larger swelling than that induced by preventing Ca2+ influx. Treatment of nematocytes with quinine completely blocked the RVD. Such an effect was prevented by gramicidine. A partial inhibition of RVD was caused by treatment with 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS). It is concluded that: i) the nematocytes regulate volume under hypoosmotic shock; ii) the regulatory mechanisms consist mainly in increased conductance to K+, and consequently, of Cl-, and, to a lesser extent, in H+/K+-Cl-/HCO3- exchange, and iii) the ionic fluxes are triggered by increased [Ca2+]i with the possible involvement of calmodulin.     

The contributions of microtubules and F-actin to the in vitro migratory mechanisms of Hydra nematocytes as determined by drug interference experiments.

In order to investigate the contributions of microtubules and of F-actin to the in vitro migration mechanisms of Hydra nematocytes we have studied the effects of agents directed against cytoskeletal structures. Disassembly of microtubules by treatment with the drug nocodazole in moving nematocytes resulted in the loss of all locomotory activity within 20 min after the onset of treatment and in the detachment from the substratum after about 30 min. Depolymerization of microtubules by exposure to low temperatures had the same effect but was reversible in this case. Locomoting cells treated with cytochalasin D, which disrupts the actin filaments, stopped movement 2 min after drug administration and detached from the substratum after 15 min. The pattern of F-actin, alpha-tubulin, and tyrosinated tubulin in drug- or cold-treated cells was determined by immunocytochemical techniques and confocal laser scanning microscopy. These patterns and the reactions of the cells to the various drug treatments suggest that both actin filaments and microtubules play a crucial role in nematocyte locomotion. Analysis of the cytoskeletal pattern in drug-treated cells shows that the microtubules which are involved in locomotion are mostly tyrosinated. Furthermore it is suggested that microtubules and actin filaments interact with each other during the locomotion of nematocytes.     

Differential binding of concanavalin A by dissociated cells of Hydra attenuata

Summary Living dissociated cells of hydra were exposed to fluorescein- and ferritin-conjugated concanavalin A (con A) and observed by light and electron microscopy. Fluorescence microscopy indicated that the isolated cells bound con A differentially; epidermal battery cells showed the greatest binding, whereas small cells belonging to the interstitial cell class displayed the lowest levels of binding. Mature nematocytes had strong localized con A binding at the opercular region. Electron microscopy permitted accurate identification of interstitial cells, early nematoblasts, and nerve cells. The use of ferritin-labeled con A allowed quantitative assessment of lectin binding on these cells. There were significantly fewer con A-binding sites on interstitial cells as compared to nematoblasts and nerve cells, and the amount of con A binding appeared to increase with the maturation of nematocysts from nematoblasts. The findings are discussed in relation to a likely role of cell surface glycoconjugates in the development of positional signals and intercellular junctions that govern final positioning of nematocytes and nerves in hydra.     

Characterization of interstitial stem cells in hydra by cloning.

A procedure has been developed for cloning interstitial stem cells from hydra. Clones are prepared by introducing small numbers of viable cells into aggregates of nitrogen mustard-inactivated host tissue. Clones derived from added stem cells are identified after 1–2 weeks of growth by staining with toluidine blue. The incidence of clones increases with increasing input of viable cells according to one-hit Poisson statistics, indicating that clones arise from single cells. After correction for cell losses in the procedure, about 1.2% of the input cells are found to form clones. This compares with estimates from in vivo experiments of about 4% stem cells in whole hydra [David, C. N., and Gierer, A. (1974). Cell cycle kinetics and development of Hydra attenuata. III. Nerve and nematocyte differentiation. J. Cell Sci.16, 359–375.]Differentiation of nematocytes and nerve cells in clones was analyzed by labeling precursors with [³H]thymidine and scoring labeled nerves and nematocytes 2 days later. Nine clones examined in this way contained both differentiated nerve cells and nematocytes, demonstrating that the interstitial stem cell is multipotent. This result suggests that the observed localization of nerve and nematocyte differentiation in whole hydra probably occurs at the level of stemcell determination. The observation that differentiated cells occur very early in clone development suggests that a stem cell's decision to proliferate or differentiate is regulated by shortrange feedback signals which are already saturated in young clones.     

Functional organization of battery cell complexes in tentacles of Hydra attenuata

Ultrastructural and light microscopic observations on the organization of thick and thin regions of hydra's tentacles, made on serial sections and on whole fixed, plastic-embedded tentacles, reveal the existence of two levels of anatomical order in the tentacle ectoderm: (1) The battery-cell complex (BCC), composed of a single epitheliomuscular cell (EMC) and its content of enclosed nematocytes and neurons; and (2) the battery cell complex ring (BCC ring), an arrangement of 4 or more BCCs into larger units organized as rings around the circumference of the tentacle. All EMCs of the distal tentacle appear to contain batteries of nematocytes, and are, therefore, called “battery cells.” Apart from battery cell complexes and migrating nematocytes, there are no other cell types in the tentacle ectoderm. Battery cells are composed of three distinct regions: the cell body, peripheral attenuated extensions and myonemes. Thick tentacle bands are composed of cell bodies, whereas thin bands are made up of attenuated extensions. Myonemes contribute to both thick and thin regions. It was confirmed that each battery cell has several myonemes, which appear to interdigitate with myonemes of other more proximal and distal battery cells, but not with battery cells of the same BCC ring. Nematocytes have several basal processes. Some processes insert between myonemes and contact the mesoglea; other processes insert into cuplike extensions of myonemes, and are connected to myonemal cups by desmosomal junctions. These observations are discussed in relation to mechanical and electrical aspects of tentacular contraction and bending.     

Monoclonal antibodies against surface components of the mechano-and chemosensitive cnidocil complex of Hydra vulgaris

Summary Two monoclonal antibodies (Gc3.2 and Bd 2.2) against surface components of the cnidocil complex of Hydra vulgaris have been produced. In indirect immunofluorescence and in immunogold-labelling, the Gc 3.2-antibody stains the complete surface of all nematocytes, whereas other cellular surfaces are not labelled. The Bd 2.2-antibody, in contrast, produces only a small band of fluorescence on isolated cnidocils. This pattern of fluorescence and the corresponding immunogold-labelling indicate that the Bd 2.2-antibody exclusively binds to those intermembrane connectors that link the cnidocil and stereovillar cone in situ. In isolated and decnidociliated nematocytes, the tips of the stereovilli are also labelled by the Bd 2.2-antibody. Physiological experiments suggest that the Bd 2.2-antibody disturbs the reconstitution of intermembrane connectors during cnidocil regeneration. These data confirm the hypothesis that the intermembrane connectors are formed by two identical subunits located at the cnidociliar and stereovillar surfaces.     

The septate junction limits mobility of lipophilic markers in plasma membranes ofHydra vulgaris (attenuata)

Summary Fluorescent lipophilic probes were used to study the role of septate junctions in maintaining distinct apical and basolateral domains of plasma membranes in epithelial cells of hydra. In short-term experiments, a 16-carbon chain aminofluorescein probe (AFC₁₆) was localized to the apical plasma membranes of ectodermal and endodermal epithelial cells when presented in the culture medium or injected into the gastric lumen, but did not demarcate basolateral membranes. In longer term experiments, basolateral membranes were stained and the staining was independent of temperature conditions. A dual 18-carbon chain indocarbocyanine probe (DiIC₁₈) gradually diffused across the septate junction to label basolateral membranes at room temperature, but not at 4°C. DiIC₁₈ also filled and stained certain mounted nematocytes. The results indicate that in hydra, lipophilic probes may be limited in mobility within the membrane plane by the septate junctions in a manner similar to vertebrate tight junctions, and that apical membranes of mature nematocytes are differentially permeable.     

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.     

A modified view on octocorals: Heteroxenia fuscescens nematocysts are diverse, featuring both an ancestral and a novel type

Cnidarians are characterized by the presence of stinging cells containing nematocysts, a sophisticated injection system targeted mainly at prey-capture and defense. In the anthozoan subclass Octocorallia nematocytes have been considered to exist only in low numbers, to be small, and all of the ancestral atrichous-isorhiza type. This study, in contrast, revealed numerous nematocytes in the octocoral Heteroxenia fuscescens. The study demonstrates the applicability of cresyl-violet dye for differential staining and stimulating discharge of the nematocysts. In addition to the atrichous isorhiza-type of nematocysts, a novel type of macrobasic-mastigophore nematocysts was found, featuring a shaft, uniquely comprised of three loops and densely packed arrow-like spines. In contrast to the view that octocorals possess a single type of nematocyst, Heteroxenia fuscescens features two distinct types, indicating for the first time the diversification and complexity of nematocysts for Octocorallia.     

Immunocytochemical evidence for an NMDA1 receptor subunit in dissociated cells of<Emphasis Type="Italic"> Hydra vulgaris</Emphasis>

We have previously reported immunocytochemical, biochemical, behavioral, and electrophysiological evidence for glutamatergic transmission through (±)--amino-3-hydroxy-5-methyl-isoxazole-4-propionic acid (AMPA)/kainate receptors in hydra. We now report specific localization of the N-Methyl-D-aspartic acid receptor subunit 1 (NMDAR1) in epithelial, nerve, nematocytes, and interstitial cells of hydra. Macerates of tentacle/hypostome pieces of Hydra vulgaris were prepared on agar-coated slides, fixed with buffered formaldehyde/glutaraldehyde, and fluorescently labeled with monoclonal antibodies against mammalian NMDAR1. Negative controls omitted primary antibody. Digital images were recorded and analyzed. Specific localized and intense labeling was found in ectodermal battery cells, other epithelial cells, nematocytes, interstitial cells, and sensory and ganglionic nerve cells, and in battery cells was associated with enclosed nematocytes and neurons. The labeling of myonemes was more diffuse and less intense. In nerve and sensory cells, punctate labeling was prominent on cell bodies. These results are consistent with our earlier evidence for glutamatergic neurotransmission and kainate/NMDA regulation of stenotele discharge. They support other behavioral and biochemical evidence for a D-serine-sensitive, strychnine-insensitive, glycine receptor in hydra and suggest that the glutamatergic AMPA/kainate-NMDA system is an early evolved, phylogenetically old, behavioral control mechanism.