The ontogeny of interstitial cells in Pennaria tiarella

The interstitial cells of Pennaria tiarella differentiate exclusively from the central endoderm of the planula. Shortly after their appearance, most of the interstitial cells become cnidoblasts. Subsequently, as the larva transforms into a polyp, both cnidoblasts and interstitial cells migrate from the endoderm, through endoblast and mesoglea, into the ectoderm. It is suggested that some interstitial cells remain in the endoderm and differentiate into the gland and mucous cells of the polyp gastroderm.     

海蜇胚胎发育和变态过程超微观察

采用扫描电镜、透射电镜和蛋白银染色等方法研究了海蜇胚胎发育和变态过程中细胞超微结构变化。结果显示: (1)海蜇自受精卵至原肠期阶段细胞均等分裂, 细胞间存在大量连接, 细胞形态相近, 未出现显著分化; (2)海蜇自早期浮浪游虫阶段, 其外胚层细胞开始出现空泡化, 至4触手螅状体阶段外胚层细胞空泡体积逐渐增大, 而内胚层细胞仅在4触手螅状体阶段才出现空泡化。伴随着外胚层细胞空泡化比例的增大, 杯状体和4触手螅状体阶段出现疑似凋亡小体结构; (3)刺细胞分化于早期浮浪游虫期的外胚层近中胶层区域, 而后逐渐向外转移, 至4触手螅状体阶段发育成熟并转移至表面; (4)纤毛形成于早期浮浪幼虫, 在杯状体阶段逐渐退化, 并于4触手螅状体阶段完全消失; (5)在海蜇早期发育各个阶段, 其内部均发现大量着色较深的卵黄体, 且在浮浪游虫阶段首次发现了海蜇外层细胞主动吞噬细菌现象, 表明海蜇早期发育营养来自内源性和外源性两部分。研究结果可为阐明刺胞动物早期发育模式提供依据。     

Embryonic development and metamorphosis of the scyphozoan <Emphasis Type="Italic">Aurelia</Emphasis>

We investigated the development of Aurelia (Cnidaria, Scyphozoa) during embryogenesis and metamorphosis into a polyp, using antibody markers combined with confocal and transmission electron microscopy. Early embryos form actively proliferating coeloblastulae. Invagination is observed during gastrulation. In the planula, (1) the ectoderm is pseudostratified with densely packed nuclei arranged in a superficial and a deep stratum, (2) the aboral pole consists of elongated ectodermal cells with basally located nuclei forming an apical organ, which is previously only known from anthozoan planulae, (3) endodermal cells are large and highly vacuolated, and (4) FMRFamide-immunoreactive nerve cells are found exclusively in the ectoderm of the aboral region. During metamorphosis into a polyp, cells in the planula endoderm, but not in the ectoderm, become strongly caspase 3 immunoreactive, suggesting that the planula endoderm, in part or in its entirety, undergoes apoptosis during metamorphosis. The polyp endoderm seems to be derived from the planula ectoderm in Aurelia, implicating the occurrence of “secondary” gastrulation during early metamorphosis.     

The effect of larval age on developmental changes in the polyp prepattern of a hydrozoan planula

The larvae of many marine organisms including hydrozoans are lecithotrophic and will not feed until after metamorphosis. In hydrozoans the aboral region of the planula becomes the holdfast and stolon, while the oral region becomes the stalk and hydranth that grows out of the holdfast following metamorphosis. If metamorphosis is delayed, the portion of the planula allocated to form holdfast and stolon shrinks and the region that forms the hydranth increases in size. Planulae also have the ability to regenerate their polyp prepattern. When the aboral region of the planula that does not normally form a hydranth is isolated and metamorphosis is delayed, it acquires the capacity to form a hydranth from the holdfast. A relatively high proportion of entodermal cells of young planulae engage in DNA synthesis (BrdU labeling index); as planulae age, the labeling index falls close to zero. When the polyp prepattern is modified during planula regeneration, entodermal cells are induced to engage in DNA synthesis. If DNA synthesis is inhibited in planulae, the polyp prepattern changes during regeneration and age-related developmental changes in planula are inhibited, suggesting that DNA synthesis is a necessary part of the pattern respecification process.     

On some features of embryonic development and metamorphosis of Aurelia aurita (Cnidaria, Scyphozoa)

Aurelia aurita is a cosmopolite species of scyphomedusae. Its anatomy and life cycle are well investigated. This work provides a detailed study on development and structure of A. aurita planula before and during its metamorphosis. Intravital observations and histology study during the settlement and metamorphosis of the planulae demonstrated that the inner manubrium lining of primary polyp (gastroderm) develops from the ectoderm of the planula posterior end. The spatial and temporal dynamics of serotonergic cells from the early embryonic stages until the formation of the primary polyp were studied for the first time. In addition, the distribution of tyrosinated tubulin and neuropeptide RF-amide at different stages of A. aurita development was traced.     

Early development, pattern, and reorganization of the planula nervous system in Aurelia (Cnidaria, Scyphozoa)

We examined the development of the nervous system in Aurelia (Cnidaria, Scyphozoa) from the early planula to the polyp stage using confocal and transmission electron microscopy. Fluorescently labeled anti-FMRFamide, antitaurine, and antityrosinated tubulin antibodies were used to visualize the nervous system. The first detectable FMRFamide-like immunoreactivity occurs in a narrow circumferential belt toward the anterior/aboral end of the ectoderm in the early planula. As the planula matures, the FMRFamide-immunoreactive cells send horizontal processes (i.e., neurites) basally along the longitudinal axis. Neurites extend both anteriorly/aborally and posteriorly/orally, but the preference is for anterior neurite extension, and neurites converge to form a plexus at the aboral/anterior end at the base of the ectoderm. In the mature planula, a subset of cells in the apical organ at the anterior/aboral pole begins to show FMRFamide-like and taurine-like immunoreactivity, suggesting a sensory function of the apical organ. During metamorphosis, FMRFamide-like immunoreactivity diminishes in the ectoderm but begins to occur in the degenerating primary endoderm, indicating that degenerating FMRFamide-immunoreactive neurons are taken up by the primary endoderm. FMRFamide-like expression reappears in the ectoderm of the oral disc and the tentacle anlagen of the growing polyp, indicating metamorphosis-associated restructuring of the nervous system. These observations are discussed in the context of metazoan nervous system evolution.     

Collar cells in planula and adult tentacle ectoderm of the solitary coral Balanophyllia regia (anthozoa eupsammiidae)

Summary The planula larva of the solitary coral Balanophyllia regia has an ectoderm of flagellate, diplosomal collar cells. The collar of these cells is composed of a ring of microvilli linked with mucus strands. Four types of flagellate gland cells, three types of nematocyst and spirocysts are present in the planula ectoderm. The function of these ectoderm cells is discussed. The mesogloeal muscular and packing tissues of the planula are briefly described. The tentacle of the adult coral, examined for comparison, has an ectoderm of flattened flagellate cells with a shallow collar. Collar cells similar to those of the planula are occasionally found on the tentacle and their function is not known. Independent sensory cells built on a modified collar cell plan with collar of thickened microvilli are common in the tentacle. These are quite separate from the three kinds of tentacular nematocyte. Distended glandular areas occur in the tentacle ectoderm. The flagellate tentacle gastrodermis, muscle and mesogloeal region are briefly described. The evolutionary significance of collar cell ectoderm in a planula is discussed and the occurrence of collar cells throughout the animal kingdom, reviewed.I am most grateful to Paul Tranter of the Plymouth Laboratory for providing material and to Gareth Morgan for assistance with electron microscopy.     

Pattern of cell proliferation in embryogenesis and planula development ofHydractinia echinata predicts the postmetamorphic body pattern

Summary During embryogenesis and planula development of the colonial hydroidHydractinia echinata cell proliferation decreases in a distinct spatio-temporal pattern. Arrest in S-phase activity appears first in cells localized at the posterior and then subsequently at the anterior pole of the elongating embryo. These areas do not resume S-phase activity, even during the metamorphosis of the planula larva into the primary polyp. Tissue containing the quiescent cells gives rise to the terminal structures of the polyp. The posterior area of the larva becomes the hypostome and tentacles, while the anterior part of the larva develops into the basal plate and stolon tips. In mature planulae only a very few cells continue to proliferate. These cells are found in the middle part of the larva. Labelling experiments indicate that the prospective material of the postmetamorphic tentacles and stolon tips originates from cells which have exited from the cell cycle in embryogenesis or early in planula development. Precursor cells of the nematocytes which appear in the tentacles of the polyp following metamorphosis appear to have ceased cycling before the 38th hour of embryonic development. The vast majority of the cells that constitute the stolon tips of the primary polyp leave the cell cycle not later than 58 h after the beginning of development. We also report the identification of a cell type which differentiates in the polyp without passing through a post-metamorphic S-phase. The cell type appears to be neural in origin, based upon the identification of a neuropeptide of the FMRFamide type.     

Reorganization of the nervous system during metamorphosis of a hydrozoan planula

Abstract. Laser scanning confocal microscopy is used to reveal the changes that occur in the RFamide-positive nerve net as a free-swimming, solid hydrozoan planula larva is transformed into a sessile, hollow, young polyp. Seven stages of development in Pennaria tiarella are described: planula competent to metamorphose, attaching planula, disc, pawn, crown, developing polyp, and developed primary polyp. The RFamide-positive nervous system undergoes dramatic reorganization during metamorphosis: (1) larval neurons degenerate; (2) new neurons differentiate and reform a nerve net; and (3) the overall distribution pattern of the nervous system changes. This study confirms earlier observations on RFamide-positive neurons of Hydractinia which also show the loss of these cells after the onset of metamorphosis.     

Die Cnidogenese der Octocorallia (Anthozoa,Cnidaria): II. Reifung,Wanderung und Zerfall von Cnidoblast und Nesselkapsel

Migration of cnidoblasts has never been observed in Anthozoa. In contrast to hydrozoans, anthozoans are repeatedly reported to develop nematocysts locally without migration in the entoderm as well as in the ectoderm. The majority of the nematocysts studied in different Octocorallia species (Alcyonaria:Alcyonarium digitatum, Parerythropodium coralloides; Gorgonaria:Pseudopterogorgia aerosa; Pennatularia:Veretillum cynomorium) originate from the ectoderm of the scapus, where, however, no mature nematocysts occur. Cnidoblasts containing immature nematocysts accumulate in the distal scapus, from where they migrate singly like amoebae into the pinnulae of the tentacles. The nematocysts mature during migration, during which the capsular matrix becomes completely electron-translucent. Only in the oral disc, where few nematocysts occur, do they mature locally without migration. In the Octocorallia, nematocyst development and maturation takes places only in the ectoderm. Development of nematocysts has never been observed in the entoderm, nor in the pharynx; this demonstrates its entodermal origin. The entoderm contains only degenerated or phagocytized nematocysts. Contrary to hydrozoans, the mature anthozoan cnidocyte is rounded and has no processes to the mesogloea. Instead of a cnidocil it has a ciliary cone consisting of a normal flagellum, stereocilia and macrovilli. The cnidocyte is characterised by abundant electron-translucent cytoplasm and nematocyst-anchoring structures made up of cross-striated, collagen-like fibrillae and a fibrous basal ring. The position of the cross-striated fibrillae is distally similar to that of the supportive rods in hydrozoan cnidoblasts. The present study clearly demonstrates that structure and, possibly, function of an octocorallian cnidocyte is much simpler than that of a hydrozoan cnidocyte. On the other hand, cnidoblast migration, occurring in Hydrozoa as well in Octocorallia, turned out to be a much older phylogenetic character than was formerly believed.     

Neural system reorganization during metamorphosis in the planula larva of Clava multicornis (Hydrozoa, Cnidaria)

The planula larva of the hydroid Clava multicornis (Forskål, 1775) has a complex nervous system, characterized by the presence of distinct, anteriorly concentrated peptidergic populations of amidated neurons, presumably involved in the detection of environmental stimuli and metamorphic signals. Differently from other hydrozoan larvae in C. multicornis planulae GLW-positive cells with putative sensory role have a peculiar dome-shaped forefront organization, followed by a belt of RF-positive nerve cells. By immunohistochemistry, we investigated the transformation of the peptidergic (GLW-amide and RF-amide) larval neuroanatomy at different stages of metamorphosis and the subsequent development of the primary polyp nervous system. By terminal transferase-mediated dUTP nick end-labeling assay, apoptotic nuclei were first identified in the anterior pole of the settled larva, in the same region occupied by GLW-amide positive putative sensory cells. In primary polyps, GLW-amide positive signals first encircled the hypostome area, later extending downwards along the polyp column or upwards over the hypostome dome, whereas RF-amide positive sensory cells initially appeared at the tentacles base to later extend in the tentacles and the polyp column. In spite of the possession of distinct neuroanatomies, different cnidarian planulae may share common developmental mechanisms underlying metamorphosis, including apoptosis and de novo differentiation. Our data confirm the hypothesis that the developmental dynamics of tissue rearrangements may be not uniform across different taxa.     

Cellular and intracellular pathways mediating the metamorphic stimulus in hydrozoan planulae

Summary Both the natural metamorphic stimulus (an unidentified bacterial product) and an artificial trigger of metamorphosis (Cs⁺) cause large calcium transients in planula cells of the hydrozoanMitrocomella polydiademata. When these transients are inhibited with calcium channel blockers, metamorphosis is also inhibited. All cells of theMitrocomella planula contain a calcium-specific photoprotein. The cells where the calcium transients occur during natural- and Cs⁺-induced metamorphosis have been visualized in normal and entoderm free planulae that lack ganglion cells, using a compound microscope coupled to an image intensifier and video camera. During bacteria- and Cs⁺-induced metamorphosis, groups of contiguous cells, occupying from about 10% to the entire visible surface of the planula, simultaneously exhibit calcium transients. When the cells that initiate a transient comprise only part of the planula surface, the calcium transient frequently propagates and can eventually involve every cell on the visible planula surface. There is no special site on the planula surface where calcium transients are more apt to be initiated. There is no indication that propagation of a flash in one direction is more likely than in another. The velocity of propagation is virtually the same in all directions. The only feature of the spatial distribution of bacteria- and Cs⁺-induced calcium transients that appears to be necessary for the induction of metamorphosis is that at least one transient must involve all of the surface cells of the planula. The spatial behavior of calcium transients is the same in entoderm free planulae (lacking ganglion cells) as in normal planulae. The propagation of these calcium transients most probably occurs via epithelial conduction. This metamorphic step involving calcium transients is probably the intercellular communication system that informs the cells of the planula that metamorphosis will commence.Metamorphosis inMitrocomella planulae can also be induced with phorbol esters. Calcium transients do not occur during phorbol ester-induced metamorphosis, indicating that they act at a different point in the metamorphic pathway. Calcium channel blockers do not inhibit phorbol ester-induced metamorphosis. Inhibitors of protein kinase-C, inhibit both phorbol ester-induced metamorphosis and Cs⁺- and bacteria-induced metamorphosis, but have no effect on the calcium transients induced by Cs⁺. This indicates that the calcium transient mediated step in the metamorphic pathway occurs prior to protein kinase-C activation. Calcium transients probably play a major role in activating protein kinase-C.     

The biology of coral metamorphosis: molecular responses of larvae to inducers of settlement and metamorphosis

Like many other cnidarians, corals undergo metamorphosis from a motile planula larva to a sedentary polyp. In some sea anemones such as Nematostella this process is a smooth transition requiring no extrinsic stimuli, but in many corals it is more complex and is cue-driven. To better understand the molecular events underlying coral metamorphosis, competent larvae were treated with either a natural inducer of settlement (crustose coralline algae chips/extract) or LWamide, which bypasses the settlement phase and drives larvae directly into metamorphosis. Microarrays featuring > 8000 Acropora unigenes were used to follow gene expression changes during the 12 h period after these treatments, and the expression patterns of specific genes, selected on the basis of the array experiments, were investigated by in situ hybridization. Three patterns of expression were common—an aboral pattern restricted to the searching/settlement phase, a second phase of aboral expression corresponding to the beginning of the development of the calicoblastic ectoderm and continuing after metamorphosis, and a later orally-restricted pattern.     

The Embryonic Origin of Neurosensory Cells and the Role of Nerve Cells in Metamorphosis in Phialidium gregarium (Cnidaria,Hydrozoa)

Summary

The embryonic origin of the nervous system in Phialidium gregarium was investigated. Entoderm-free planulae, surgically produced by bisection at mid-gastrulation, and normal planulae were examined by light and electron microscopy to determine their cellular composition. The cell types that occur in the epidermis of the normal planula were described. The entoderm-free planulae were found to be devoid of interstitial cells and their derivatives, the nematocytes and ganglion cells. Neurosensory cells were present, however, indicating that they are derivatives of the ectodermal epithelium.

The role of nerve elements in the initiation of metamorphosis was also examined. Normal and entoderm-free planulae treated for four hours with 0.4% colchicine at two, three, or four days of development fail to undergo cesium-induced metamorphosis. Since such treatment in other hydrozoans eliminates interstitial cells and their derivatives [1-3], it might be argued that ganglion cells are necessary to initiate metamorphosis. The observation that entoderm-free planulae, devoid of interstitial cell derivatives, are capable of responding to induction by bacteria or cesium, however, indicates that in Phialidium the colchicine effect is on other cell types. The results are compared with findings for other Cnidaria.     

Comparative fine structural studies of planulae and primary polyps of identical age of the sea pen,Ptilosarcus gurneyl

Electron microscopic study of an 18-day-old planulae and primary polyps of the sea pen, Ptilosarcus gurneyi, reveals 14 cell types: sustentacular cell A, sustentacular cell B, nerve cell, sensory cell, cnidoblast, interstitial cell, five types of gland cell (A, B, C, D and E), amoebocyte, style cell and endodermal cell. Of these, 9 are found in the planula, 12 in polyps and 7 are common to both stages. The fine structure of all cell types is described. Since the planulae and polyps in this study were identical in age of development, the gaining and losing of certain types of cells in the polyp are attributed to changes associated with settlement and metamorphosis. Modifications of the seven common cell types during metamorphosis can also be attributed to the change of life style from pelagic to benthic.     

脉红螺消化系统的形态学研究

脉红螺消化系统由十二个器官组成。其消化管壁都由粘膜层、粘膜下层、肌层和外膜四层结构构成。作者对消化腺的细胞进行了较详细的描述,并利用组化方法测定消化腺细胞中含有的酶类。作者还对部分器官的超微结构进行了观察。     

Endogenous photoproteins,calcium channels and calcium transients during metamorphosis in hydrozoans

Summary There are species of hydrozoans, Eutonina victoria, Mitrocomella polydiademata, and Phialidium gregarium whose eggs contain calcium-specific photoproteins. These cytoplasmic photoproteins are synthesized during oogenesis. During the cleavage stages of embryogenesis they are distributed to all of the cells of the developing planula larva. The amount of photoprotein slowly declines during the development of the planula larva, and markedly declines when the planula undergoes metamorphosis to become a polyp.Oocytes, unfertilized eggs, and fertilized eggs prior to the first cleavage do not produce light when treated with KCl. The ability to respond to KCl appears about the time of first cleavage, and is correlated with the appearance of active membrane responses. Both the KCl response and the action potentials will occur in sodium-free sea water, and both are inhibited by calcium channel blockers. These and other experiments suggest that voltage sensitive calcium channels first become active at about the time of first cleavage. These channels also appear on the same schedule in both unfertilized eggs and in enucleated egg fragments, which have been artificially activated with A23187.Developing planulae produce few or no spontaneous light responses before gastrulation. Later the frequency and magnitude of spontaneous light production increases presumably due to an increasing frequency and magnitude of calcium transients. Both the natural trigger of metamorphosis (bacteria) and an artificial trigger (CsCl) cause a conspicuous series of calcium transients. When these transients are inhibited by calcium channel blockers, metamorphosis is also inhibited.