The ontogeny of swimming behavior in the scyphozoan, Aurelia aurita. II. The effects of ions and drugs.

1. The responses of Aurelia medusae to pharmacological agents and ionic variation were classified into four response types: Type I, no response; Type II, inhibition of pacemaker activity; Type III, inhibition of both pacemakers and swimming muscles; and Type IV, increase in pacemaker output. 2. The swimming pacemakers of Aurelia medusae become hyperactive in Mg+2-free solutions (Type IV). This response appears to be general in swimming scyphozoa. 3. The response pattern to pharmacologically-active compounds indicates that the coelenterate neuromuscular system is quite different than those in other phyla. In fact, the response spectrum is not consistent within the Cnidaria. 4. Similarly, the responses of adult medusae to ionic variation show no consistent pattern within various scyphomedusae. 5. Test solutions from each response type established with medusae were selected and tested on the scyphistoma and strobila stages. The comparison of the responses to the test solutions between the medusa, scyphistoma, and strobila showed that the neuromuscular systems are physiologically different. The strobila, specificially the ephyra, is a mixture of both polypoid and medusoid response types. The strobila, therefore, is physiologically an intermediate stage in the development of the adult medusa.     

Structural and Developmental Disparity in the Tentacles of the Moon Jellyfish Aurelia sp.1

Tentacles armed with stinging cells (cnidocytes) are a defining trait of the cnidarians, a phylum that includes sea anemones, corals, jellyfish, and hydras. While cnidarian tentacles are generally characterized as structures evolved for feeding and defense, significant variation exists between the tentacles of different species, and within the same species across different life stages and/or body regions. Such diversity suggests cryptic distinctions exist in tentacle function. In this paper, we use confocal and transmission electron microscopy to contrast the structure and development of tentacles in the moon jellyfish, Aurelia species 1. We show that polyp oral tentacles and medusa marginal tentacles display markedly different cellular and muscular architecture, as well as distinct patterns of cellular proliferation during growth. Many structural differences between these tentacle types may reflect biomechanical solutions to different feeding strategies, although further work would be required for a precise mechanistic understanding. However, differences in cell proliferation dynamics suggests that the two tentacle forms lack a conserved mechanism of development, challenging the textbook-notion that cnidarian tentacles can be homologized into a conserved bauplan.     

CO-ORDINATION IN A SCYPHISTOMA

The scyphistoma of Amelia unrila was stimulated electricallyand mechanically in various well defined regions. Each of theseregions is neurologically independent in that the effects ofthe stimulation are localized to just one region of the polyp.Co-ordination of the different regions during prey capture andingestion is still possible however because of the arrangementof the parts of the polyp in which one action sets off anotherone mechanically. The polypoid form of the scyphistoma is ageometrical arrangement allowing mechanical co-ordination. Sucha co-ordination mechanism would not be suitable for the lifeof a medusa whose complicated problems necessitate neurologicalconnections between the body regions for their co-ordination.On the principle that simple organisms arose first during evolution,it is maintained that the polypoid preceded the medusoid formin the Class Scyphozoa. Of the three polypoid types viz. hydropolyp,scyphopolyp and anthopolyp, the scyphopolyp has the simplestneuromuscular system and behavior.     

Muscle and nerve net organization in stalked jellyfish (Medusozoa: Staurozoa)

Staurozoan cnidarians display an unusual combination of polyp and medusa characteristics and their morphology may be informative about the evolutionary origin of medusae. We studied neuromuscular morphology of two staurozoans, Haliclystus ‘sanjuanensis ’ and Manania handi , using whole mount immunohistochemistry with antibodies against FMRFamide and α‐tubulin to label neurons and phalloidin to label muscles. All muscles appeared to lack striations. Longitudinal interradial muscles are probable homologues of stalk muscles in scyphopolyps, but in adult staurozoans they are elaborated to inwardly flex marginal lobes of the calyx during prey capture; these muscles are pennate in M. handi . Manubrial perradial muscles, like the manubrium itself, are an innovation shared with pelagic medusae and manubrial interradial muscles are shared with scyphozoan ephyra. Marginal muscles of M. handi displayed occasional synchronous contraction reminiscent of a medusa swim pulse, but contractions were not repetitive. The nerve net in both species showed regional variation in density and orientation of neurons. Some areas labeled predominantly by α‐tubulin antibodies (exumbrellar epidermis), other areas labeled exclusively by FMRFamide antibodies (dense plexus of neurites surrounding the base of secondary tentacles, neuronal concentration at the base of transformed primary tentacles; gastrodermal nerve net), but most areas showed a mix of neurons labeled by these two antibodies and frequent co‐labeling of neurons. Transformed primary tentacles had a concentration of FMRFamide‐immunoreactive neurons at their base that was associated with a pigment spot in M. handi; this is consistent with their homology with rhopalia of medusae, which are also derived from primary tentacles. The muscular system of these staurozoans embodies characteristics of both scyphopolyps and pelagic medusae. However, their nerve net is more polyp‐like, although marginal concentrations of the net associated with primary and secondary tentacles may facilitate the richer behavioral repertoire of staurozoans relative to polyps of other medusozoans. J. Morphol. 278:29–49, 2017. ©© 2016 Wiley Periodicals,Inc.     

Organization of the subumbrellar musculature in the ephyra,juvenile, and adult stages of Aurelia aurita Medusae

We used fluorescently labeled phalloidin to examine the subumbrellar musculature of the scyphozoan jellyfish Aurelia aurita in a developmental series from ephyra to adult medusa. In the ephyra, the swim musculature includes a disc‐like sheet of circular muscle, in addition to two radial bands of muscle in each of the eight ephyral arms. The radial muscle bands join with the circular muscle, and both circular and radial muscle act together during each swim contraction. As the ephyra grows into a juvenile medusa, arms tissue is resorbed as the bell tissue grows outward, so eventually, the ephyral arms disappear. During this process, the circular muscle disc also grows outward and the radial muscle bands of the arms also disappear. At this time, a marginal gap appears at the bell margin, which is devoid of circular muscle cells, but has a loose arrangement of radial muscle fibers. This marginal gap is preserved as the medusa grows, and contributes to the floppy nature of the bell margin. Radial distortions in the circular muscle layer involve muscle fibers that run in random directions, with a primarily radial orientation. These are believed to be remnants of the radial muscle of the ephyral arms, and the distortions decrease in number and extent as the medusa grows. Since the mechanics of swimming changes from drag‐based paddling in the ephyra to marginal rowing in the adult medusa, the development of the marginal gap and the presence of radial distortions should be considered in terms of this mechanical transition.     

Feeding and wounding responses in Hydra suggest functional and structural polarization of the tentacle nervous system

The nervous system of Hydra, a freshwater cnidaria, occurs as dispersed, or diffuse, nerve net throughout the animal. It is widely accepted that in a diffuse nervous system an external stimulus is conducted in all directions over the net. Here I report observations that hydra tentacles respond to feeding and wounding stimuli in a unidirectional manner. Upon contact of a tentacle with a brine shrimp larva during feeding, tissue on the proximal side of the point of contact contracted strongly, whereas tissue on the distal side contracted only very weakly. Feeding a tentacle to which a second tentacle was grafted to the proximal end in the reversed orientation showed that unidirectional conduction, once initiated, was blocked by the reversal of polarity, demonstrating that the distal to proximal polarity of tissue is crucial for unidirectional conduction. Unidirectional conduction was obtained also by mechanically pinching the tissue. The response of tentacles devoid of neurons examined was bidirectional, demonstrating that the nervous system is responsible for the unidirectional responses. These observations suggest that polarized property of the nerve net in hydra tentacles is responsible for the unidirectional tentacle contraction.     

Evolution and taxonomy in capitate hydroids and medusae (Cnidaria: Hydrozoa)

A cladistic analysis of Capitata groups the families in four suborders based on medusa characters (such as manubrium morphology, position of gonads, and position and number of marginal tentacles) and hydroid characters (such as presence or absence of an oral tentacle whorl, and the different development of the tentacles of the oral and aboral whorls). On the family and generic levels, the revision results in changes which unite the separate hydroid and medusa taxonomic systems, defining genera which are not based on characters solely relating to the reduction of medusae to fixed gonophores. In those families where the reduction of the medusa can be analysed, it is shown that the reduction occurred after all synapomorphies defining the genera had evolved and usually affected individual species within a genus rather than the original species from which the other species in the genus evolved. This supports the view that medusa reduction is not in itself a valid generic character. A discussion of the theories of 'inconsistent' or 'mosaic' evolution concludes that no difference in evolutionary rate or degree of specialization can be demonstrated among taxa with free medusae and taxa with gonophores.     

Fish assemblage structure in urban streams of Puerto Rico: the importance of reach- and catchment-scale abiotic factors

Cotylorhiza tuberculata is a common symbiotic scyphozoan in the Mediterranean Sea. The medusae occur in extremely high abundances in enclosed coastal areas in the Mediterranean Sea. Previous laboratory experiments identified thermal control on its early life stages as the driver of medusa blooms. In the present study, new ecological aspects were tested in laboratory experiments that support the pelagic population success of this zooxanthellate jellyfish. We hypothesized that planulae larvae would have no settlement preference among substrates and that temperature would affect ephyra development, ingestion rates and daily ration. The polyp budding rate and the onset of symbiosis with zooxanthellae also were investigated. Transmission electron microscopy revealed that zooxanthella infection occurred by the polyp stage. Our results showing no substrate selectivity by planulae and high polyp budding rates in high temperatures suggest increased benthic polyp populations, which would lead to higher medusa abundances. Rates of transition from ephyrae to medusae and the feeding of early medusa stages also increased with temperature. Continuing changes in coastal ecosystems such as future climate warming and marine construction may lead to increased populations of jellyfish to the detriment of fish globally.     

Comparative ultrastructure of catch tentacles and feeding tentacles in the sea anemone Haliplanella

TEM observations of catch tentacles revealed that the tentacle tip epidermis is filled with two size classes of mature holotrich nematocysts and a gland cell filled with electron-dense vesicles. Vesicle production is restricted to upper-middle and tentacle tip regions, whereas holotrich development occurs in the lower-middle and tentacle base regions. Thus, catch tentacles have a maturity gradient along their length, with mature tissues concentrated at the tentacle tip. Occasional feeding tentacle cnidae (microbasic p-mastigophores and basitrichs) and mucus gland cells occur in proximal portions of catch tentacles, but are phagocytized by amoeboid granulocytes and transported to the gastrodermis for further degradation. No feeding tentacle cnidae or mucus cells occur distally in catch tentacles. Unlike catch tentacles, feeding tentacles are homogeneous in structure along their length with enidocytes containing mature spirocysts, microbasic p-mastigophore or basitrich nematocysts distributed along the epithelial surface. Cnidoblasts are recessed beneath cnidocytes, occurring along the nerve plexus. Mucus gland cells and gland cells filled with electron-dense vesicles are present in feeding tentacles, distributed at the epithelial surface. Granular phagocytes are rare in the feeding tentacle tip, but common in the tentacle base.     

Dissociation and reaggregation of cells of Chrysaora quinquecirrha (Cnidaria, Scyphozoa)

Cells of scyphistomae, strobilae, and ephyrae were dissociated with trypsin and reaggregated. Clumping was inhibited in low Ca++ and by puromycin, but not by collagenase or sugars. Reaggregates from the oral end of the polyp developed tentacles and mouths first and basal structures later, whereas the opposite sequence occurred with cells from the lower gastric region. Nile-blue-stained cells from hypostome or peduncle did not form specific structures in the reconstructed polyp, but were distributed throughout the animal. Ephyra cell aggregates showed little morphogenesis, whereas cells from presumptive ephyra tissue gave rise to structures with tentacles and multiple oral openings. Mixed reaggregates containing equal proportions of polyp and ephyra cells formed irregular structures with transparent outer layer and opaque inner cell mass, suggesting stage-specific sorting.     

Bau und Lebensgeschichte des Polypen vonTripedalia cystophora (Cubozoa,class. nov., Carybdeidae) und seine Bedeutung für die Evolution der Cnidaria

FollowingHaeckel (1880), most zoologists have grouped the Cubomedusae with the class Scyphozoa. However, the actual systematic position and evolution of the Cubomedusae remained unclear because essential phenomena of the life cycle, i. e. life history and structure of the polyp generation and the process of medusa formation were unknown. Successful cultivation of the Carribean larviparousTripedalia cystophora Conant, 1898 elucidated for the first time the complete life cycle of a cubomedusa. Primary polyps could be raised from planulae which were transferred by air mail from La Parguera, Puerto Rico. The sessile polyp is solitary. Its morphology, anatomy, and behaviour are described. The body (length 0.6–1.0 mm) is radially constructed without any trace of tetramerous structures. 6 to 11 solid capitate tentacles insert in one circle, above which the body ends in a long contractile snout-like mouth cone (proboscis). The body is sac-like without gastric septa or gastric pockets; its base is enveloped by a small cup of thin, structureless periderm. Asexual reproduction by which the stock is enlarged quickly envolves lateral budding of small secondary polyps. After detachment these small polyps go through a creeping phase. The fully grown polyp shows a remarkable behavioural plasticity as it can migrate and change into an inactive encysted stage. The whole polyp metamorphoses into a single medusa. All externally visible metamorphosis phases are described. First, the polyp's body becomes tetramerous due to 4 longitudinal folds. The tentacles congregate into 4 groups, each in one quadrant. While the distal parts of the tentacles are resorbed, their bases develop into 4 perradial sensory organs (rhopalia). Interradially, 4 new tentacles are formed and become the primary tentacles of the medusa. Simultaneously, the complete body of the polyp transforms into the bell of the medusa. At the end of the metamorphosis which takes 5 to 6 days at 25 to 27° C, the young medusa begins to pulsate quickly and swims away leaving behind the empty peridermal cup. The morphology of the young medusa is described.T. cystophora has a tricnidom of basitrich haplonemes, holotrich haplonemes, and heterotrich microbasic euryteles. The ecology of both, polyp and medusa generation, is briefly outlined. A critical comparison between the polyp and medusa ofT. cystophora and the Scyphozoa and Hydrozoa reveals important differences. Consequently, a new class, Cubozoa, must be established and given the evolutionary position between Scyphozoa and Hydrozoa. Diagnoses are presented for the polyp ofT. cystophora and the class Cubozoa.     

Electrically induced tentacle contraction in the suctorian protozoonTrichophrya collini

Summary Extracellular electrical stimulation ofTrichophrya collini induces tentacle contraction. There is an inverse relationship between stimulus duration and voltage in producing a threshold response, and at a set voltage the response is graded depending upon duration of stimulus. With a threshold stimulus (6.3 V, 1,000 ms) the response is restricted to the anodal tentacles, and with increasing stimulus intensity or duration the response spreads to the cathodal and finally the intermediate tentacles. With a stimulus of 15 V, 1,000 ms the mean tentacle length is reduced to 28% of the control within 1.2 s. Recordings using intracellular microelectrodes give resting membrane potentials between –10mV and –40mV. Intracellular hyperpolarizing currents of 1nA and 2nA induce tentacle contraction to 50% and 25% of the control length respectively, but depolarizing currents do not induce contraction. SEM studies show that in the initial stages of contraction, only the central region of the tentacle shaft becomes shortened, but on full contraction shortening involves the whole of the shaft. TEM studies show that on contraction no depolymerization of tentacle axoneme microtubules occurs, but that the entire axoneme passes down into the body cytoplasm. These observations are discussed in relation to the possible mechanisms of tentacle contraction.Abbreviations Ax axoneme - C cortex - EDB elongate dense body - SEM scanning electron microscopy - TEM transmission electron microscopy     

THE COORDINATION OF POTENTIAL PACEMAKERS IN THE HYDROID TUBULARIA

Sectioning experiments and electrical recording indicate thatthere are many potential pacemakers in polyps of the hydroidTubularia. Functionally the pacemakers are organized primarilyinto pacemaker systems, groups within which there is tight coupling.The different pacemaker systems of a polyp are loosely coupledto one another. There are two principal systems in Tubularia,one in the polyp neck (the NP system) and one in the hydranth(the HP system). In addition, there are pacemakers controllingactivities of individual tentacles. Activity in the NP systemis usually not associated with observable polyp behavior. HPsystem activity is correlated with behavioral responses termedconcerts. Concerts are probably digestive activities; they resultin the mixing of food being digested and the distribution ofthe products of this digestion. The NP systems of polyps ona colony are loosely coupled to one another through one of thethree conducting systems found in Tubularia stalks. The loosecoupling between NP systems of polyps on a colony and the loosecoupling between NP and HP systems within single polyps resultsin there being some coordination of concert activity throughouta colony.     

Evolution and development of scyphozoan jellyfish

Scyphozoan jellyfish, or scyphomedusae, are conspicuous members of many ocean ecosystems, and have large impacts on human health and industry. Most scyphomedusae are the final stage in a complex life cycle that also includes two intermediate stages: the larval planula and benthic polyp. In species with all three life‐cycle stages, the metamorphosis of a polyp into a juvenile scyphomedusa (ephyra) is termed strobilation, and polyps can produce one ephyra (termed monodisc strobilation) or many ephyrae (termed polydisc strobilation). In contrast to species with planula, polyp and medusa stages, a handful of scyphozoan species possess modified life cycles with reduced or absent stages. The evolutionary patterns associated with strobilation and life‐cycle type have not been thoroughly investigated, and many studies of ephyra development and strobilation induction are not yet synthesized. Herein, I place the development of scyphomedusae in an evolutionary context. I first review the current evolutionary hypotheses for Scyphozoa. Next, I review what is known about scyphomedusa development across a broad diversity of species, including the first signs of strobilation, the formation of strobila segments, and the morphogenesis of ephyrae. I then review cases where the canonical scyphozoan life cycle has been modified, and take advantage of phylogenetic hypotheses to place these observations in an evolutionary context. I show that the evolution of monodisc strobilation occurred at least twice, and that the loss of intermediate life‐cycle stages occurred several times independently; by contrast, the reduction of the medusa stage appears to have occurred within a single clade. I then briefly review the major natural cues of strobilation induction. Finally, I summarize what is currently known about the molecular mechanisms of strobilation induction and ephyra development. I conclude with suggestions for future directions in the field.     

Neurobiology of Stomotoca. II. Pacemakers and conduction pathways.

Evidence is presented for separate conduction pathways for swimming and for tentacle coordination in the marginal nerves of the jellyfish Stomotoca. The effector muscles are fired through junctions sensitive to excess Mg++, probably represented by the neuromuscular synapses observed by electron microscopy. The swimming effector (striated muscle) fires one-to-one with nerve input signals and myoid conduction occurs. Tentacle responses (smooth muscle contractions) involve facilitation, presumably at the neuro-effector junction; responses are graded and nonpropagating. Electrical correlates of two further conducting systems using the marginal nerves have been recorded. Their functions are unknown. One, the bridge system, extends up the four radii and encircles the peduncle; the other (ring system) is confined to the margin. A fifth conducting system is inferred in the case of the pointing response and its distribution is plotted. Signals have not been obtained from it. Pointing is accompanied by a burst of muscle potentials in the radial smooth muscles and is exhibited after a lengthy latency, indicating a local pacemaker. A sixth conducting pathway is the epithelial system, which mediates crumpling, a response involving the radial muscles without pacemaker intervention. Characteristic conduction velocities and wave forms are noted for the first four systems and for epithelial pulses. All systems, except perhaps the pointing conduction system, through-conduct under excess Mg++. Spontaneous activity patterns are described for the swimming, tentacle pulse, and ring systems. Abrupt increases in light intensity inhibit spontaneous activity, sudden decreases augmenting it. In the absence of specialized photoreceptors, light is presumed to act directly on central neurons. Epithelial pulses inhibit swimming, apparently by blocking the generation or conduction of the primary nervous events. This observation, taken in conjunction with evidence of feedback inhibition of the primary swimming system by the cells it fires, is discussed in relation to possible mechanisms whereby the output of nerve cells might be altered by activity in the excitable epithelial cells which envelop them.     

Regulation of the length of the snail tentacle by the concentration-dependent contraction

The tentacle of terrestrial snail with olfactory organs on the tips display complex behavior when snail investigates the new environment. We reconstructed the trajectory of the tentacle in three dimensions from two simultaneous video recordings in freely moving snail without odor and after odor application. We found that without oder the snail displayed continuous environment scanning with elongated tentacles. Odor application elicited startle-like short-term flexions of the tentacle which were independent from odor concentration and concentration-dependent gradual tentacle contraction. Identified central motoneuron MtC3 is known to produce the most part of the central tentacle retraction to the noxious stimuli. In nose-brain preparation the MtC3 responded to odors in concentration-dependent manner similar by dynamics and duration to the concentration-dependent gradual tentacle contraction in intact snail. It suggests that the MtC3 provides the central control of the extent of the scanning area by limiting the tentacle length. The MtC3-related gradual contraction of the tentacle can be aimed to tune the olfactory behavior of the terrestrial snail to the particular odor environment.     

Neurobiology of Polyorchis. I. Function of effector systems.

The electrical correlates of activity in the effector systems responsible for swimming, crumpling and postural changes have been recorded in the anthomedusan Polyorchis penicillatus. Motor spikes (pre-swim pulses), that initiate swimming contractions, appear without delay at distant sites on the inner nerve-ring in unstimulated preparations. Levels of Mg++ anaesthesia which block the neuromuscular junctions between PSP giant neurons and swimming muscle do not affect PSP activity. Swimming muscle potentials can be recorded from subumbrella and velar muscle sheets using extra- and intracellular electrodes. These action potentials have a distinct plateau and are propagated in a myoid fashion. Resting potentials average -70 mV with spikes overshooting zero by some 62 mV. The effects of repetitive stimulation are described. Extracellular recordings indicate that neuronal pathways may play a major role in mediating crumpling, unlike many other species where epithelial pathways are more important. Endodermal spikes recorded intracellularly from the radial and ring canals have amplitudes of some 92 mV arising from resting potentials that average -55 mV. Repetitive stimulation causes a decrease in amplitude and increase in duration of epithelial action potentials. Tentacle length is controlled by a pacemaker system located in both nerve rings. The frequency of spikes (PTPs) generated by this system determines the length and tonus of tentacles. The neuromuscular junctions between the motor neurons and tentacle muscle are Mg++ sensitive and show facilitating properties.     

Neurobiology of Stomotoca. II. Pacemakers and conduction pathways

Evidence is presented for separate conduction pathways for swimming and for tentacle coordination in the marginal nerves of the jellyfish Stomotoca. The effector muscles are fired through junctions sensitive to excess Mg⁺⁺, probably represented by the neuromuscular synapses observed by electron microscopy. The swimming effector (striated muscle) fires one-to-one with nerve input signals and myoid conduction occurs. Tentacle responses (smooth muscle contractions) involve facilitation, presumably at the neuro-effector junction; responses are graded and nonpropagating. Electrical correlates of two further conducting systems using the marginal nerves have been recorded. Their functions are unknown. One, the bridge system, extends up the four radii and encircles the peduncle; the other (ring system) is confined to the margin. A fifth conducting system is inferred in the case of the pointing response and its distribution is plotted. Signals have not been obtained from it. Pointing is accompanied by a burst of muscle potentials in the radial smooth muscles and is exhibited after a lengthy latency, indicating a local pacemaker. A sixth conducting pathway is the epithelial system, which mediates crumpling, a response involving the radial muscles without pacemaker intervention. Characteristic conduction velocities and wave forms are noted for the first four systems and for epithelial pulses. All systems, except perhaps the pointing conduction system, through-conduct under excess Mg⁺⁺. Spontaneous activity patterns are described for the swimming, tentacle pulse, and ring systems. Abrupt increases in light intensity inhibit spontaneous activity, sudden decreases augmenting it. In the absence of specialized photoreceptors, light is presumed to act directly on central neurons. Epithelial pulses inhibit swimming, apparently by blocking the generation or conduction of the primary nervous events. This observation, taken in conjunction with evidence of feedback inhibition of the primary swimming system by the cells it fires, is discussed in relation to possible mechanisms whereby the output of nerve cells might be altered by activity in the excitable epithelial cells which envelop them.     

盐度对沙蜇有性繁殖阶段早期发育的影响

近几十年来,沙蜇的频繁暴发给东亚海域的海洋生态系统带来了广泛影响。在秋季,沙蜇成熟的雌雄水母体在沿岸水域聚集产卵,有性繁殖产生的受精卵发育成新的底栖螅状体,为螅状体种群数量进行补充。河口浅滩海域为沙蜇的繁育地,沿岸盐度较低,在秋季降雨期盐度多变,较低、多变的盐度可能对沙蜇有性繁殖阶段的早期发育产生重要作用,从而影响螅状体种群数量的补充。实验设置了4种不同盐度(15、20、25、30)试验组,在不同盐度下对沙蜇受精卵进行培养,探讨盐度对沙蜇早期发育过程中受精卵、浮浪幼虫发育以及早期螅状体生长及存活的影响。试验结果:沙蜇受精卵胚胎发育的适宜盐度为20,发育基本与盐度25、30同步,盐度15受精卵细胞发育迟缓,发育率显著降低;浮浪幼虫发育适宜盐度为20和25,两组浮浪幼虫附着变态率高于盐度15、30,盐度15时浮浪幼虫活力明显降低、发育迟缓,浮浪幼虫在盐度15时水中存活时间较长可达8 d,但附着时间集中在培养后的3、4天,与其他组相同;早期螅状体幼体适宜盐度为20、25、30,早期螅状体存活率、相对增长率及特定生长率均显著高于盐度15,三组间差异不显著。结果表明,盐度显著影响沙蜇有性繁殖阶段的早期发育,随着受精卵至螅状体的发育生长,其对盐度的适应范围逐步扩大。     

Cytologische Veränderungen während der Metamorphose des CubopolypenTripedalia cystophora (Cubozoa,Carybdeidae) in die Meduse

The life cycle ofTripedalia cystophora includes a sessile saclike polyp — the asexual reproducing form — and a pelagic tetraradial medusa — the sexually reproducing generation. Medusan development can be induced by temperature increase. It reveals neither budding nor strobilation, but a real metamorphosis of a polyp to only one medusa. According to morphological and anatomical criteria the metamorphosis can be subdivided into four different stages: (1) four longitudinal furrows segment the polyp, the tentacles of which are apportionated on the four quadrants of the body. (2) The subumbrellar cavity develops by invagination of the peristom; the relicts of the fused tentacles change to four rhopalia buds. (3) Medusan architecture including four new interradial tentacles, four rhopalia and the subumbrellar swimming musculature is completed. (4) A young tetraradial medusa starts swimming. Ultrastructural analysis of those metamorphic stages show the different processes of morphogenesis: (a) Gastrodermal cells — absorptive and spumous cells — undergo transdifferentiation and proliferation to medusan cells of the same structure and function. (b) Epidermal cells, excluding the epithel muscle cells, dissociate and are autolytically withdrawn. Dedifferentiated epithel muscle cells — interstitial cells — regain the ability to develop a complete new set of somatic cells, not originally present in the polyp. They include amongst others cross-striated muscle cells, medusan typic nematocyts and particularly sensory and nervous cells. Those cells establish a nervous system with lens-eyes, simple ocelli, statocysts, diffuse nerve net and an additional nerve ring.