Inhibition of metamorphosis by RFamide neuropeptides in planula larvae of Hydractinia echinata

The primitive nervous system in planula larvae of Hydractinia echinata (Cnidaria) has sensory neurons containing LWamide or RFamide neuropeptides. LWamides have been shown to induce metamorphosis of planula larvae into adult polyps. We report here that RFamides act antagonistically to LWamides. RFamides inhibit metamorphosis when applied to planula larvae during metamorphosis induction by treatment with LWamides (or other inducing agents such as CsCl ions, diacylglycerol and bacterial inducers). Our results show further that RFamides act downstream of LWamide release, presumably directly on target cells mediating metamorphosis. These observations support a model in which metamorphosis in H. echinata is regulated by sensory neurons secreting LWamides and RFamides in response to environmental cues.Edited by D. Tautz     

Stimulation of metamorphosis in Hydractinia echinata involves generation of lysophosphatidylcholine

Summary Whilst the significance of the phosphoinositide cycle in the activation of developmental events by extra-cellular signals is well established, the involvement of the phosphatidylcholine (PC) cycle is a matter just emerging. In the present study, the metabolism of phosphatidylcholine in early metamorphosis of Hydractinia echinata (Coelenterata; Hydrozoa) was investigated by incubation of planula larvae with ³H-choline, extraction of the metabolites and isolation of the metabolites by thin-layer chromatography (TLC). Phosphatidylcholine (PC), lysophosphatidylcholine (LPC), acetylcholine and glycerophosphocholine were the labelled metabolites. Induction of metamorphosis did not stimulate an increased incorporation of choline into PC. In larvae preincubated with ³H-choline to a steady state level of incorporation, a significant transient elevation of the radioactive label in LPC was observed 90 min after addition of metamorphosis stimulating agents. LPC probably derived from PC by the action of a phospholipase A₂ (PLA₂). LPCs from bovine and soybean origin as well as isolated larval LPC did not influence metamorphosis. PLA₂ from bee venom promoted Cs⁺-induced metamorphosis but did not influence phorbol ester-induced metamorphosis. The data suggest that a PLA₂ is activated during metamorphosis. This PLA₂ activation does not occur in those putative receptor cells which receive the primary external inducing stimulus but in the many larval cells which resume proliferation or differentiation in response to a second, internally propagated signal. Offprint requests to: T. Leitz     

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.     

Necessity of protein synthesis for metamorphosis in the marine hydroidHydractinia echinata

Summary In the marine colonial hydroidHydractinia echinata metamorphosis from the larval to the adult (polyp) stage is induced by various agents, including CsCI and dioctanoylglycerol (diC8). Induction is prevented when the inhibitors of protein synthesis cycloheximide or ementine were applied simultaneously with the metamorphosis-inducing agents. With diC8 treatment, the inhibitors caused most animals to transform into mosaics consisting of larval and polyp body parts instead of normal shaped polyps. In contrast, treatment with cycloheximide or ementine just before or after incubation with the metamorphosis-inducing agents did not prevent larvae from metamorphosis. No substantial quantitative changes in protein synthesis occur during induction of metamorphosis, however, the protein pattern is changed upon induction. The most prominent new polypeptides (25 and 73 kD) were observed when CsCI was used to trigger metamorphosis. In addition, both in CsCl- and in diC8-treated larvae, the synthesis of a new 23 kD protein occurred, whilst synthesis of others ceased (41 and 44 kD).     

Analysis of pattern formation during embryonic development of Hydractinia echinata

Summary Patterning processes during embryonic development of Hydractinia echinata were analysed for alterations in morphology and physiology as well as for changes at the cellular level by means of treatment with proportioning altering factor (PAF). PAF is an endogenous factor known to change body proportions and to stimulate nerve cell differentiation in hydroids (Plickert 1987, 1989). Applied during early embryogenesis, this factor interferes with the proper establishment of polarity in the embryo. Instead of normal shaped planulae with one single anterior and one single posterior end, larvae with multiple termini develop. Preferentially, supernumerary posterior ends, which give rise to polyp head structures during metamorphosis, form while anterior ends are reduced. The formation of such polycaudal larvae coincide with an increase in the number of interstitial cells and their derivatives at the expense of epithelial cells. Treatment of further advanced embryonic stages causes an increase in length, presumably due to the general stimulation of cell proliferation observed in such embryos. Also, the spatial arrangement of cells (i.e. cells in proliferation and RFamide (Arg-Phe-amide immunopositive nerve cells) is altered by PAF. Larvae that develop from treated embryos display altered physiological properties and are remarkably different from normal planulae with respect to their morphogenetic potential: (1) Larvae lose their capacity to regenerate missing anterior parts; isolated posterior larva fragments form regenerates of a bicaudal phenotype. (2) In accordance with the frequently observed reduction of anterior structures, the capacity to respond to metamorphosis-inducing stimuli decreases. (3) The morphogenetic potential to form basal polyp parts is found to be reduced. In contrast, the potential to form head structures during metamorphosis increases, since primary polyps with supernumerary hypostomes and tentacles metamorphose from treated animals.     

Heat shock as inducer of metamorphosis in marine invertebrates

Summary In most sessile marine invertebrates, metamorphosis is dependent on environmental cues. Here we report that heat stress is capable of inducing metamorphosis in the hydroid Hydractinia echinata. The onset of heat-induced metamorphosis is correlated with the appearance of heat-shock proteins. Larvae treated with the metamorphosis-inducing agents Cs⁺ or NH₄ ⁺ also synthesize heat-shock proteins. In heat-shocked larvae, the internal NH₄ ⁺-concentration increases. This fits the hypothesis that methylation plays a central role in control of metamorphosis. In the tunicate Ciona intestinalis, a heat shock is able to induce metamorphosis too. Offprint requests to: M. Walther     

Protein kinase C in hydrozoans: involvement in metamorphosis of Hydractinia and in pattern formation of Hydra

A wealth of information has suggested the involvement of protein kinase C (PKC) in metamorphosis of Hydractinia echinata and in pattern formation of Hydra magnipapillata. We have identified a Ca²⁺- and phospholipid-dependent kinase activity in extracts of both species. The enzyme was characterized as being similar to mammalian PKC by ion exchange chromatography. Gel filtration experiments revealed a molecular weight of about 70 kD. In phosphorylation assays of endogenous Hydractinia proteins, a protein with a molecular weight of 22.5 kD was found to be phoshorylated upon addition of phosphatidylserine. Bacterial induction of metamorphosis of Hydractinia echinata caused an increase in endogenous diacylglycerol, the physiological activator of PKC, suggesting that the bacterial inducer acts by activating receptor-regulated phospholipid metabolism. Exogenous diacylglycerol leads to membrane translocation of PKC, indicative of an activation. On the basis of our results and those of Freeman and Ridgway (1990) a model for the biochemical events during metamorphosis is presented.     

Metamorphosis inHydractinia: Studies with activators and inhibitors aiming at protein kinase C and potassium channels

Summary Metamorphosis of planula larvae involves an activation of morphogenetically quiescent cells. The present work extends a previous study [Leitz T and Müller WA (1987) Dev Biol 121:82–89] on the participation of the phosphatidylinositol/diacylglycerol/protein kinase C system. Metamorphosis is stereospecifically induced by diacylglycerols, 1,2,-sn-dioctanoylglycerol (diC₈) being by far the most effective substance. K-252a and sphingosine, inhibitors of mammalian protein kinases C, profoundly inhibited metamorphosis. Phorbolester-binding studies and the corresponding Scatchard plots revealed a specific and saturable binding of [³H]phorbol 12,13-dibutyrate to a single site of particulate fractions ofHydractinia with a specific binding affinityK _d = 50 nM. K⁺ ionophores stimulated Cs⁺ — but inhibited diC₈-induced metamorphoses, K⁺-channel blockers enhanced the inducing action of Cs⁺ or diC₈. On the basis of these data and observations of others we propose that the activation ofHydractinia larvae takes place in some cells at the anterior end as a result of activation of a kinase-C-like enzyme, which directly or indirectly leads to the closure of K⁺ channels. Closure of these channels then causes depolarisation and, thus, release of an internal signal. This hypothesis unifies notions about the role of K⁺ channels and of the phosphatidylinositol system in initiation of metamorphosis inHydractinia.     

Metamorphosis of <Emphasis Type="Italic">Hydractinia echinata</Emphasis>—natural versus artificial induction and developmental plasticity

Many marine invertebrates reproduce through a larval stage. The settlement and metamorphosis of most of the species are synchronised and induced by environmental organisms, mainly bacteria. The hydrozoan Hydractinia echinata has become a model organism for metamorphosis of marine invertebrates. In this species, bacteria, e.g. Pseudoalteromonas espejiana, are the natural inducers of metamorphosis. Like in other species of marine invertebrates, metamorphosis can be induced artificially by monovalent cations, e.g. Cs⁺. In this study, we present systematic data that metamorphosis—with both inducing compounds, the natural one from bacteria and the artificial one Cs⁺—are indeed similar with respect to (a) the morphological progression, (b) the localisation of the primary induction signal in the larva, (c) the pattern of apoptotic cells occurring during the initial 10 h of metamorphosis and (d) the disappearance of RFamide-dependent immunocytochemical signals in sensory neurons during this process. However, a difference occurs during the development of the anterior end, insofar as apoptotic cells and settlement appear earlier in planulae induced with bacteria. Thus, basically, Cs⁺ may be used as an artificial inducer, mimicking the natural process. However, differences in the appearance of apoptotic cells and in settlement raise the question of how enormous developmental plasticity in hydrozoans actually can be, and how this is related to the absence of malignant devolution in hydrozoans.     

Metamorphosin A is a neuropeptide

A novel biologically active peptide (metamorphosin A, MMA, pEQPGLW.NH₂) has recently been described. It was isolated from Anthopleura elegantissima and triggers metamorphosis in Hydractinia echinata. Antibodies directed against the C-terminal part of the molecule immunohistochemically stain neurosensory cells and processes in the anterior part of larvae of H. echinata. We assume that in metamorphosis MMA (or a closely related LW-amide) is an internal signal transmitted from the anterior to the posterior body parts. Immunoreactivity is also found in ectodermal nerve processes — but not cell bodies — in the tentacles and in the basal disk of the foot of Hydra magnipapillata. This is, to our knowledge, the first report of LW-amide(s) as (a) neuropeptide(s).     

Histological changes in the pituitary-thyroid axis during spontaneous and artificially-induced metamorphosis of larvae of the flounder Paralichthys olivaceus

Summary Histological changes in the pituitary TSH cells and in the thyroid gland of flounder (Paralichthys olivaceus) larvae during spontaneous or artificially induced metamorphosis were studied. Activity of the immunoreactive TSH cells (IrTSH cells) gradually increased during premetamorphosis, reaching the highest level in prometamorphic larvae, and the cells were degranulated in metamorphic climax. The IrTSH cells were most inactive at the post-climax stage. The thyroid gland was morphologically the most active in metamorphic climax when the degranulation occurred in the pituitary IrTSH cells, and appeared inactive at post-climax. A few weeks after metamorphosis, both the IrTSH cells and the thyroid gland appeared to be activated again in the benthic, juvenile flounder. Administration of thyroxine or thiourea revealed negative feedback regulation of the pituitary-thyroid axis in flounder larvae. These results indicate that activation of the pituitary-thyroid axis induces metamorphosis in the flounder.     

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.     

Metamorphosis and acquisition of symbiotic algae in planula larvae and primary polyps of Acropora spp.

Coral planulae settle, then metamorphose and form polyps. This study examined the morphological process of metamorphosis from planulae into primary polyps in the scleractinian corals Acropora nobilis and Acropora microphthalma, using the cnidarian neuropeptide Hym-248. These two species release eggs that do not contain Symbiodinium. The mode of acquisition of freshly isolated Symbiodinium (zooxanthellae) (FIZ) by the non-symbiotic polyp was also examined. Non-Hym-248 treated swimming Acropora planulae did not develop blastopore, mesenteries or coelenteron until the induction of metamorphosis 16 days after fertilization. The oral pore was formed by invagination of the epidermal layer after formation of the coelenteron in metamorphosing polyps. At 3 days after settlement and metamorphosis, primary polyps exposed to FIZ established symbioses with the Symbiodinium. Two–four days after exposure to FIZ, the distribution of Symbiodinium was limited to the gastrodermis of the pharynx and basal part of the polyps. Eight–ten days after exposure to FIZ, Symbiodinium were present in gastrodermal cells throughout the polyps.     

Ammonia induces metamorphosis of the oral half of buds into polyp heads in the scyphozoan Cassiopea

Summary The scyphozoan polyp Cassiopea forms vegetative free swimming buds that metamorphose into sessile polyps. In sterile sea water metamorphosis does not take place. Buds keep swimming for weeks. Application of millimolar quantities of NH ₄ ⁺ causes the buds to metamorphose within one day. The resulting animals bear hypostome and tentacles, however, only occasionally peduncle and foot. Almost all transform either completely into solitary polyp head or only the oral half of the bud developes into a head while the aboral half remains bud tissue which becomes constricted off. Under suited conditions this small bud is able to transform into a normal shaped polyp.     

Cholera toxin and thyrotropine can replace natural inducers required for the metamorphosis of larvae and buds of the scyphozoanCassiopea andromeda

Summary The scyphozoan medusaCassiopea andromeda forms free swimming planulae and buds that metamorphose into tentacle bearing sedentary polyps. About 30% of the planulae and 7% of the buds undergo such metamorphosis within 30 days in sterile natural seawater from the Red Sea. In sterile artificial sea water devoid of any organic substances, normal metamorphosis does not take place. This indicates that both the planulae and the buds require organic morphogenetic inducers present in the sea to settle and metamorphose. The addition of cholera toxin or thyrotropin to preparations of sterile artificial sea water, induced normal metamorphosis. These inducers enhanced the rate of metamorphosis and up to 100% of the planulae and buds formed polyps within 2–18 days. We conclude that our preparations of cholera toxin and thyrotropin mimic the action of natural inducers.     

Development and neuromodulation of spinal locomotor networks in the metamorphosing frog

Metamorphosis in the anuran frog, Xenopus laevis, involves profound structural and functional transformations in most of the organism's physiological systems as it encounters a complete alteration in body plan, habitat, mode of respiration and diet. The metamorphic process also involves a transition in locomotory strategy from axial-based undulatory swimming using alternating contractions of left and right trunk muscles, to bilaterally-synchronous kicking of the newly developed hindlimbs in the young adult. At critical stages during this behavioural switch, functional larval and adult locomotor systems co-exist in the same animal, implying a progressive and dynamic reconfiguration of underlying spinal circuitry and neuronal properties as limbs are added and the tail regresses. To elucidate the neurobiological basis of this developmental process, we use electrophysiological, pharmacological and neuroanatomical approaches to study isolated in vitro brain stem/spinal cord preparations at different metamorphic stages. Our data show that the emergence of secondary limb motor circuitry, as it supersedes the primary larval network, spans a developmental period when limb circuitry is present but not functional, functional but co-opted into the axial network, functionally separable from the axial network, and ultimately alone after axial circuitry disappears with tail resorption. Furthermore, recent experiments on spontaneously active in vitro preparations from intermediate metamorphic stage animals have revealed that the biogenic amines serotonin (5-HT) and noradrenaline (NA) exert short-term adaptive control over circuit activity and inter-network coordination: whereas bath-applied 5-HT couples axial and appendicular rhythms into a single unified pattern, NA has an opposite decoupling effect. Moreover, the progressive and region-specific appearance of spinal cord neurons that contain another neuromodulator, nitric oxide (NO), suggests it plays a role in the maturation of limb locomotor circuitry. In summary, during Xenopus metamorphosis the network responsible for limb movements is progressively segregated from an axial precursor, and supra- and intra-spinal modulatory inputs are likely to play crucial roles in both its functional flexibility and maturation.     

A low-molecular weight factor from colonial hydroids affects body proportioning and cell differentiation

Treatment of metamorphosing planulae of Hydractinia echinata with proportion altering factor (PAF) causes oversizing in the hypostome of developing primary polyps. With increasing concentrations more specimens fail to acquire the appearance of a primary polyp but remain as cones lacking tentacles. Yet, such specimens are true primary polyps as they contain neurons of RF-amide-like immunoreactivity that are typical of the polyp stage. Numbers of RF-amide-positive cells are increased up to 2.5 times compared with the normal value. In intact Hydra vulgaris, PAF increases the number of neurons that differentiate from cycling precursor cells, or even from stem cells. The effect is dose dependent.     

Changes in whole body concentrations of thyroid hormones and cortisol in metamorphosing conger eel

Summary To clarify the hormonal regulation of metamorphosis of the conger eel (Conger myriaster), changes in whole body concentrations of thyroid hormones, thyroxine (T₄) and triiodothyronine (T₃), and cortisol during metamorphosis were examined, as well as the changes in the histological activity of the thyroid gland. In larvae before metamorphosis, T₄ and T₃ levels were less than 5 and 0.15 ng·g^-1 respectively. Levels of T₄ increased to about 30 ng·g^-1 during early metamorphosis, and decreased subsequently. Levels of T₃ increased gradually in early metamorphosis, and then increased abruptly to about 2.0 ng·g^-1 in late metamorphosis. Before metamorphosis, cortisol levels of the leptocephali less than 11 cm in total length were greater than 200 ng·g^-1. Cortisol levels decreased rapidly in larger premetamorphic leptocephali, and low levels were maintained throughout the metamorphic period. Histological observation revealed an activation of the thyroid gland in early metamorphosis; thyroid follicle epithelial cells became columnar and their nuclei larger. Active uptake of colloid by these cells and intensive vascularization of the gland were also observed. By the end of metamorphosis, follicle epithelial cells became squamous, indicating a low level of glandular activity. These results suggest that thyroid hormone plays an important role in regulation of conger eel metamorphosis.Abbreviations AL anal length - TL total length - T ₃ triiodothyronine - T ₄ thyroxine     

Induction of cell fusion by a factor released by the cellular slime mold Polysphondylium pallidum

Heterokaryons and hybrid cells, which are extremely useful for research in cell biology, can be produced artificially by treating cells with either polyethylene glycol or certain inactivated viruses that alter the plasma membrane. We report here a novel cell-fusion inducing factor secreted by CK-8 strain cells of cellular slime mold Polysphondylium pallidum. Treatment of other strains or other species of cellular slime molds, such as NC-4 of Dictyostelium discoideum with the diluted fraction, containing molecules larger than 50 kDa, of the conditioned medium of CK-8 cell culture induces cell fusion at high frequency and produces multinucleated large cells. This cell fusion is inducible between cells of either a single strain or of two different strains of cellular slime molds.Abbreviations BSS Bonner's salt solution - CM conditioned medium - EDTA ethylenediaminetetraacetic acid - F2 fraction containing cell-fusion induction factor - Mr molecular mass