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.     

Head regeneration and polarity reversal inHydra attenuata can occur in the absence of DNA synthesis

Summary Regeneration in hydra is considered to be morphallactic because it can occur in the absence of cell division. Whether DNA synthesis is required for regeneration or other repatterning events is not known. The question was investigated by blocking DNA synthesis with hydroxyurea and examining several developmental processes. Head regeneration, reversal of regeneration polarity and battery cell differentiation all took place in the absence of DNA synthesis. Hence, morphallactic regulation in hydra is independent of both DNA synthesis and mitosis.     

The origin of mucous cells inHydra viridis

Summary The origin of hypostomal mucous cells during regeneration and budding has been studied inHydra viridis. NormalHydrae were transected at two levels along their body column — sub-hypostomal and mid-gastric — and the cells which participated in hypostome regeneration were identified histologically and with the electron microscope. An earlier paper in this series (Rose and Burnett, 1968b) showed that zymogen cells transformed to mucous cells in sub-hypostomal regenerates. The work reported in the present paper demonstrates that gastrodermal basophilic cells are the primary source of new mucous cells in animals cut in the mid-gastric region. Evidence is presented to support the thesis that these basophilic cells are derived from epidermal interstitial cells. This choice between zymogen cell versus basophilic cell reflects the distribution of these cells along the parent body column at the sites of the transections.Bud morphogenesis inHydra viridis was also studied because budding provides conditions similar to those of regeneration, and yet, no injury is inflicted on the animal to be studied—that is, a new hypostome must be formed at the distal end of the bud and it must be populated with new mucous cells. The origin of these cells is not from pre-existing mucous cells. The results supported the conclusion that interstitial cells migrate from the epidermis into the gastrodermis of the developing hypostome and differentiate into mucous secretory cells.

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Zusammenfassung Die Herkunft hypostomaler Schleimzellen inHydra viridis wurde während der Regeneration und Knospung studiert. Normale Hydren wurden auf zwei Niveaus ihrer Körpersäule durchschnitten — subhypostomal und mittelgastral — und dann wurden die Zellen, die an der Hypostomregeneration teilnahmen, histologisch und elektronenmikroskopisch identifiziert. Eine frühere Publikation dieser Serie (Rose und Burnett, 1968b) zeigte, daß Zymogenzellen in subhypostomalen Regeneraten sich in Schleimzellen transformierten. Die vorliegende Arbeit demonstriert, daß gastrodermale, basophile Zellen die hauptsächliche Quelle neuer Schleimzellen sind in Tieren, die in der mittel-gastralen Region durchschnitten wurden. Diese basophilen Zellen scheinen von epidermalen Interstitialzellen abgeleitet zu sein. Diese Wahl zwischen Zymogenzellen, resp. basophilen Zellen spiegelt die Verteilung dieser Zellen längs der elterlichen Körpersäule an den Stellen der Schnitte wieder.Knospen-Morphogenese inHydra viridis wurde ebenfalls studiert, weil Knospung ähnliche Bedingungen schafft wie Regeneration, wobei allerdings das Tier keine Verwundung erhält; d. h. ein neues Hypostom muß gebildet werden am distalen Ende der Knospe, und es muß mit neuen Schleimzellen bevölkert werden. Diese Zellen stammen nicht von prä-existierenden Schleimzellen ab. Die Ergebnisse unterstützen die Schlußfolgerung, daß Interstitialzellen aus der Epidermis in die Gastrodermis des sich entwickelnden Hypostoms wandern und sich in Schleimzellen differenzieren.

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Part of a dissertation submitted to the faculty of the Graduate School of Arts & Sciences of Case Western Reserve University in partial fulfillment of the requirements for the Degree of Doctor of Philosophy, 1969.

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Research supported by a grant from the National Science Foundation, No. GB-7345 to A.L.B.     

Regulation of interstitial cell differentiation in Hydra attenuata. I. Homeostatic control of interstitial cell population size.

Mechanisms regulating the population size of the multipotent interstitial cell (i-cell) in Hydra attenuata were investigated. Treatment of animals with 3 cycles of a regime of 24 h in 10-2 M hydroxyurea (HU) alternated with 12 h in culture medium selectively killed 95-99% of the i-cells, but had little effect on the epithelial cells. The i-cell population recovered to the normal i-cell:epithelial cell ratio of I:I within 35 days. Continuous labelling experiments with [3H]thymidine indicate that the recovery of the i-cell population is not due to a change in the length of the cell cycle of either the epithelial cells or the interstitial cells. In control animals 60% of the i-cell population undergo division daily while 40% undergo differentiation. Quantification of the cell types of HU-treated animals indicates that a greater fraction of the i-cells were dividing and fewer differentiating into nematocytes during the first 2 weeks of the recovery after HU treatment. Therefore, the mechanism for recovery involves a shift of the 60:40 division:differentiation ratio of i-cells towards a higher fraction in division until the normal population size of the i-cells is regained. This homeostatic mechanism represents one of the influences affecting i-cell differentiation.     

A head signal influences apical migration of interstitial cells in Hydra vulgaris

Although interstitial cells of hydra can migrate either apically or basally along the body column, there is a distinct bias toward apical cell accumulation. This apical bias could be produced by a local vectorial property of the tissue or it may be controlled by a more global property, such as a signal from the apical head region. The migration behavior of BrdU-labeled interstitial cells was examined in several types of grafts to distinguish between these two general types of migration control. Grafting BrdU-labeled midgastric region tissue into a host in either the normal or the reverse orientation had no effect on the apical bias, indicating that a local vectorial cue was probably not guiding cells apically. In grafts with heads or with feet at both ends of the body column, there was no directional bias in migration if the labeled tissue was equidistant from both ends. In the two-headed grafts, if the labeled tissue was closer to one end, there was a bias in the direction of the closer head. The results suggest that a graded signal emanating from the head creates the apical bias and may attract cells via chemotaxis. The apical bias is enhanced in decapitated animals regenerating a head, indicating that the attracting signal is present and is possibly stronger in regenerating heads. The signal for cell migration may be involved in a patterning process underlying head regeneration.     

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.     

An electron microscopic and histochemical study of the secretory cells inHydra viridis

Summary The fresh water coelenterateHydra viridis possesses a unique distribution of mucous and serous secretory cells in the gastrodermis. The mucous cells are found only in the hypostome, a region devoid of the serous zymogen cells. On the other hand, the zymogen cells are found extending from the tentacles to the peduncle. Histochemical stains indicated that the two hypostomal mucous cells, spumous and granular, secreted an acid mucopolysaccharide, and incorporated radiosulfate. The radiosulfate label was not sensitive to hyaluronidase digestion, but was removed by acid methanolysis. In contrast, the secretory product of the zymogen cell was rich in proteins and a PAS-positive moiety (unsulfated).The ultrastructure of these cells was correlated with their histochemical staining properties. It was demonstrated that glutaraldehyde preserved the ultrastructure of the secretory granules better than osmium, and also preserved more components within the granules. The mucous cell granules contained an electrolucent and an electron dense component. The cells were both PAS-positive and alcianophilic. After osmium fixation the dense component was lost and the cells were primarily alcianophilic. Osmium also failed to preserve the electron dense component in the zymogen cells.Observations of corresponding thick and thin sections showed a cell containing granules similar to the granules seen in mouse Paneth cells. The dense core was osmiophilic and the lighter halo was alcianophilic.These results lead us to conclude that the electrolucent filamentous component is an alcianophilic acid mucopolysaccharide and the dense granular component is probably a PAS-positive material.

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Zusammenfassung Der FrischwassercölenteratHydra viridis weist eine einzigartige Verteilung von mukösen und serösen sekretorischen Zellen in der Gasterodermis auf. Die mukösen Zellen finden sich nur im Hypostom, in welchem seröse Zymogenzellen fehlen. Die Zymogenzellen andereseits finden sich von den Tentaklen bis zum Pedunkulus. Histochemische Methoden zeigten, daß die zwei Typen hypostomaler muköser Zellen, d.h. spumöse und granuläre, ein saures Mukopolysaccharid ausscheiden und radioaktives Sulfat einbauen. Der Radiosulfat-Markierer war nicht sensitiv gegenüber Hyaluronidase, konnte aber entfernt werden mit saurem Methanol. Im Gegensatz dazu war das Produkt der Zymogenzellen reich an Proteinen und enthielt PAS-positives Material.Die Feinstruktur dieser Zellen war korreliert mit diesen histochemischen Befunden. Glutaraldehyd erhielt die Feinstruktur der Sekretgranula besser und fixierte mehr Komponenten als Osmium. Die Granula der mukösen Zellen enthielten elektronendichte und -durchsichtige Komponenten; diese Zellen färbten sich mit PAS und Alcyan. Nach Osmium-Fixierung war die elektronendichte Komponente abwesend und die Zellen waren hauptsächlich alcyanophil. Auch in den Zymogenzellen vermochte Osmium nicht, die elektronendichte Komponente zu erhalten. Beobachtungen an alternierenden dicken und dünnen Schnitten zeigten eine Zelle mit Körnern ähnlich den Granulen von Maus Paneth-Zellen. Das dichte Zentrum dieser Granula war osmiophil, der hellere Halo alcyanophil.Diese Resultate lassen uns schließen, daß die elektronen-durchsichtige filamentöse Komponente ein alcyanophiles Mukopolysaccharid ist; das dichte, zentrale Material ist wahrscheinlich PAS-positiv.

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This paper was prepared from a thesis submitted in partial fulfillment for the degree of Master of Arts.

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This work was supported by the National Institutes of Health grant no. GM-11218.

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I wish to thank Dr.Marcus Singer for permission to use the E. M. facilities in the Dept. of Anatomy, Case Western Reserve University, and Dr.Joseph A.Grasso for instruction in the techniques of electron microscopy and the use of his facilities.     

Transplantation stimulates interstitial cell migration in hydra

Migration of interstitial cells and nerve cell precursors was analyzed in Hydra magnipapillata and Hydra vulgaris (formerly Hydra attenuata). Axial grafts were made between [3H]thymidine-labeled donor and unlabeled host tissue. Migration of labeled cells into the unlabeled half was followed for 4 days. The results indicate that the rate of migration was initially high and then slowed on Days 2-4. Regrafting fresh donor tissue on Days 2-4 maintained high levels of migration. Thus, migration appears to be stimulated by the grafting procedure itself.     

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.     

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.     

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.     

Mechanisms of force generation and force transmission during interstitial leukocyte migration

For innate and adaptive immune responses it is essential that inflammatory cells use quick and flexible locomotion strategies. Accordingly, most leukocytes can efficiently infiltrate and traverse almost every physiological or artificial environment. Here, we review how leukocytes might achieve this task mechanistically, and summarize recent findings on the principles of cytoskeletal force generation and transduction at the leading edge of leukocytes. We propose a model in which the cells switch between adhesion‐receptor‐mediated force transmission and locomotion modes that are based on cellular deformations, but independent of adhesion receptors. This plasticity in migration strategies allows leukocytes to adapt to the geometry and molecular composition of their environment.