Separation and specificity of action of four morphogens from hydra

Summary A procedure is presented by which four previously described morphogenetic substances can be purified from hydra: an activator and an inhibitor of head formation and an activator and an inhibitor of foot formation. We show that all four substances act specifically. At low concentrations, the head factors only influence head and not foot formation, and the foot factors only influence foot and not head formation.     

Analysis of morphogenetic mutants of hydra

Summary A mutant ofHydra attenuata is analysed, theaberrant, which is distinct from the wild type in having a smaller head with fewer tentacles and only half the number of head-specific cells. The rate of head and foot regeneration and the doubling time are slower inaberrants than in normal hydra.The lower head-forming potential is paralleled by a reduced concentration of head-specific morphogens: compared to the wild type, in theaberrant the concentration of head activator is reduced to 70% in the head and to 50% in the body, the concentration of head inhibitor is reduced to 50% in the head and to 80% in the body. Theaberrant is more sensitive (3 times) to added head activator and less sensitive (>5 times) to added head inhibitor than the wild type.The slower rate of foot regeneration is paralleled by a lower content of foot-specific morphogens: compared to the wild type, in theaberrant the foot activator is reduced to 40% and the foot inhibitor to 70%.     

The head and the foot inhibitor from hydra are not dowex artefacts

Summary In a recent publication in this journal (Berking 1983) it was claimed (1) that the head inhibitor we isolated from hydra is a Dowex artefact, (2) that a separate foot inhibitor does not exist in hydra and (3) that the only inhibitor that has so far been isolated from hydra is one which inhibits head and foot regeneration equally well. These statements are incorrect and require a response. In the following, I would like to summarise our evidence that the inhibitors isolated from hydra, including Berking's inhibitor, have different specificities for head and foot regeneration. In addition, I would like to show that none of our substances are Dowex artefacts.     

Head regeneration inHydra is initiated release of head activator and inhibitor

Summary Hydra regenerating heads release at least two substances into the surrounding medium: one stimulates and one inhibits head formation. The inhibitor is released mainly during the first hour after cutting, the activator is released more slowly with a maximum in the second hour and with substantial release still during the following six hours. The release of both substances seems to be specific for head regeneration: it is not found in animals regenerating feet. The sequential release of these substances leads to the early changes observed at the cellular level during head regeneration inhydra: the inhibitor produces a decrease, the activator an increase in the mitotic activity of interstitial and epithelial cells, if assayed on intact animals. Head regeneration is blocked, if the release of the head activator is prevented. It is therefore suggested that these substances are necessary to initiate head regeneration inhydra.     

Analysis of morphogenetic mutants of hydra

The mutantreg-16 is deficient in head regeneration and abnormal in size regulation. The gastric region becomes twice as long as that of normal animals before the first bud is produced. Both mutant characteristics are due to changes in head-specific morphogen concentrations.Reg-16 contains twice as much head inhibitor and only half as much head activator in its head as normal animals. This leads to a higher level of free head inhibitor in the whole animal resulting on one hand in a greater distance of buds from the head, and on the other hand in a total blockage of release of head activator and head inhibitor which would be necessary to initiate head regeneration.     

Size,shape and orientation of cells in budding hydra and regulation of regeneration in cell aggregates

Summary Changes in the number, shape, volume, orientation and vacuolization of cells involved in the budding of hydra were measured in histological sections. Before evagination, a group of about 800 epithelial cells are visibly recruited for the bud to be produced and this number increases to about 5,000 within a day. Thereafter, bud size increases mainly by proliferation of the cells within the bud. Upon recruitment for budding, the epithelial cells assume a columnar shape, with a smaller contact area facing the mesoglea, accompanied by a decrease in volume which is mostly accounted for by devacuolization. In later stages, cells progressively resume the form typical for non-budding areas of hydra. Evagination proceeds without reorientation of epithelio-muscular fibers, whereas elongation of the bud is accompanied by fiber reorientation.The process of sorting out and regeneration in aggregates of previously dissociated hydra cells was followed using various ratios of endodermal to ectodermal epithelial cells. From different initial compositions, the ratio in the regenerate rapidly approaches 11, the ratio found in normal hydra tissue.The experimental findings are discussed in the context of theoretical notions on pattern formation, evagination, elongation and stability of layered structures.     

Hydra pattern is controlled by two distinct but interacting morphogen sets

Summary Temporal course of regeneration of the hypostome and basal disc along the body length of the hydra is studied both in the presence and absence of the other determined centre. The regeneration times vary nonlinearly with distance from the original position indicating that the underlying processes are of non-linear nature. The presence of hypostome influences the regeneration of basal disc in an inhibitory manner throughout the body length, whereas, basal disc influences the regeneration of hypostome only in the lower portion of the body in a positive manner. A scheme in terms of the activators and inhibitors specific to hypostome and basal disc, is given. The implication of these results is that the two inhibitors are functionally distinct.     

A model for budding in hydra: pattern formation in concentric rings

Current models of pattern formation in Hydra propose head-and foot-specific morphogens to control the development of the body ends and along the body length axis. In addition, these morphogens are proposed to control a cellular parameter (positional value, source density) which changes gradually along the axis. This gradient determines the tissue polarity and the regional capacity to form a head and a foot, respectively, in transplantation experiments. The current models are very successful in explaining regeneration and transplantation experiments. However, some results obtained render problems, in particular budding, the asexual way of reproduction is not understood. Here an alternative model is presented to overcome these problems. A primary system of interactions controls the positional values. At certain positional values secondary systems become active which initiate the local formation of e.g. mouth, tentacles, and basal disc. (i) A system of autocatalysis and lateral inhibition is suggested to exist as proposed by Gierer and Meinhardt (Kybernetik 12 (1972) 30). (ii) The activator is neither a head nor a foot activator but rather causes an increase of the positional value. (iii) On the other hand, a generation of the activator leads to its loss from cells and therewith to a (local) decrease of the positional value. (iv) An inhibitor is proposed to exist which antagonizes an increase of the positional value. External conditions like the gradient of positional values in the surroundings and interactions with other sites of morphogen production decide whether at a certain site of activator generation the positional value will increase (head formation), decrease (foot formation) or increase in the centre and decrease in the periphery thereby forming concentric rings (bud formation). Computer-simulation experiments show basic features of budding, regeneration and transplantation.     

Is homarine a morphogen in the marine hydroid Hydractinia?

Summary Homogenate of coelenterate tissue interferes with metamorphosis in Hydractinia and pattern formation in both Hydractinia, and Hydra. From the extracts two fractions comprising low-molecular-weight compounds with strong metamorphosis-inhibiting activity were separated. One of these contains, as the active compound, homarine (N-methyl picolinic acid). Homarine concentrations down to 10^–6 mol/l stop or retard metamorphosis. High concentrations block the continuation of metamorphosis as long as they are maintained in the culture medium and treatment with homarine during metamorphosis influences the proportioning of the future polyp's body pattern. Most of the homarine found in Hydra tissue derives from Artemia given as food. It is not identical with inhibitor I, an activity partially purified from Hydra tissue, which prevents head and foot formation in Hydra.     

Genetic analysis of the wing vein pattern of Drosophila

Summary Of the many mutations known to affect the wing vein pattern we have selected the most extreme in 29 genes for study. Their phenotype can be classified in two major classes: lack-of-veins and excess-of-veins, and in several internally coherent groups. The study of multiple mutant combinations, within groups and between groups, reveals several genetic operations at work in the generation of the vein pattern. The finding that some of these mutations also affect cell proliferation in characteristic ways has prompted a generative model of wing morphogenetic and pattern formation based on cell behaviour properties defined by the corresponding wild-type genes.     

The fine structure of the hypostome and mouth of hydra

Summary The normal morphology of the hypostome and mouth of hydra were examined by transmission electron microscopy with conventional thin sections and freeze-fracture replicas. Myonemes of the hypostome are small in diameter, have gap and intermediate-type cell junctions within each epithelial layer and are associated with the opposite epithelial layer by transmesogleal processes and gap junctions. Nematocysts and sensory cells are aggregated in the circumoral region. The fine structure of adherent flagella arising from gastrodermal gland cells, and the transition region at the mouth between epidermis and gastrodermis are described in detail for the first time. The possible functional significance of the findings is discussed.     

Protein kinase modulators interfere with bud formation in Hydra vulgaris

The fresh water polyp Hydra can reproduce asexually by forming buds. These buds separate from the parent animal due to the development of foot tissue in a belt-like region and the formation of a constriction basal to that region. A single pulse treatment with activators of protein kinase C, including 1,2-dioctanoyl-rac-glycerol and 12-o-tetradecanoylphorbol-13-acetate, and inhibitors of various protein kinases, including staurosporine, H-7 and genistein, interfered with foot and constriction formation. The buds did not separate. Therewith, branched animals were formed, some of which bore a lateral foot patch. Simultaneous treatments with an activator and inhibitor led to a higher amount of branched animals than treatments with one of these agents alone. Based on the different specificities of the activators and inhibitors used we propose that activation of a protein kinase C and/or inhibition of a probably non-C-type protein kinase interfere with the decrease of positional value at the bud's base, a process necessary to initiate the pattern forming system leading to foot formation. Correspondence to: F. Perez     

Characterisation of two types of head activator receptor on hydra cells

A head activator (HA) analogue is described which even at high concentrations does not lose its biological activity. By cross-linking two HA molecules over a C8 spacer, the conformation was sufficiently altered, such that self-inactivation of HA by dimerisation was prevented. In addition, the introduction of a tyrosine instead of phenylalanine in one of the two HA molecules allowed radioactive labelling with iodine. This HA bipeptide was used to investigate the effect of HA at different concentrations and as ligand for HA receptor characterisation. We found that low concentrations (0.1-10 pM) sufficed to stimulate interstitial cell mitosis, and that higher concentrations (10-1000 pM) were required for the determination of interstitial cells to nerve cells. Binding of the radioactive HA ligand to living hydra and to purified membrane fractions was saturable and specific. Binding was compatible with HA analogues with a stable monomeric conformation, but less well with dimerising HA and HA analogues. Scatchard and kinetic analyses revealed the presence of at least two types of binding site in the membrane fraction, one with a 'lower' affinity (Kd = 10(-9) M) and one with a 100-fold higher affinity (Kd = 10(-11) M). Autoradiography showed that interstitial cells were differentially labelled, suggesting that the number or types of HA receptors may vary depending on cell cycle status. A mutant of hydra with a multiheaded morphology contained 6-20-times more HA receptors per mg protein than other hydra species or mutants.     

Pattern regulation during the development of the dorsal abdomen in the flesh fly,Sarcophaga agryostoma

Summary In dipteran flies the adult abdominal epidermis is formed from small nests of diploid histoblast cells which spread out and replace the larval epidermis during metamorphosis. The pattern of nest outgrowth and fusion in Sarcophaga shows that the large dorsal hemitergite is normally formed by the two dorsal nests, the spiracle nest and part of the ventral nest (which also forms the hemisternite). By rotating the dorsal histoblast nests, we demonstrate that the adult segment border lies between the flexible intersegmental membrane (ISM) and the naked anterior strip of tergite, the acrotergite. Deletion of histoblast nests often results in a corresponding deletion of adult structures, accompanied by enlargement of adjacent structures within the segment and in neighbouring segments. Pattern formation is not strictly coupled to cell division (as in imaginal discs), since the nests remaining after an ablation, in spreading to fill vacant areas, generate more cells and larger structures than normal. Nest deletions can also result in regeneration, with remaining nests forming additional structures in the dorsal-ventral or anterior-posterior axis of the segment. The deletion of strips of anterior and intersegmental larval epidermis without histoblasts results in the formation of double-posterior duplications of the adult hemitergite. Although these operations damage adjacent histoblast nests, several features of the results suggest that the duplications arise from the interaction (after healing) of histoblasts with larval cells which they would not normally encounter, leading to the intercalation of histoblast cells bearing intervening anterior-posterior positional values. A similar process of intercalation may occur in normal development, as the histoblasts spread from their local origins across the larval epidermal sheet, replacing the larval cells to form the entire epidermis of the adult segment. Offprint requests to: V. French     

Ultraviolet irradiation initiates ectopic foot formation in regenerating hydra and promotes budding

We have studied the effects of ultraviolet-C (UVC) and Ultraviolet-B (UVB) on growth and pattern formation inPelmatohydra oligactis. UVC brings about a significant increase in budding in intact hydra while UVB does not exhibit such an effect. Excessive budding could be a response for survival at wavelengths that damage biological tissues. If the head or base piece of a bisected hydra is irradiated and recombined with the unirradiated missing part, regeneration proceeds normally indicating that exposure of a body part with either an intact head or foot to UVC does not influence pattern formation. Most significantly, in the middle piece, but not in the head or the base piece of a trisected hydra, UVC leads to initiation of ectopic feet formation in almost one third of the cases. Thus, UV irradiation interferes with pattern formation in regenerating hydra, possibly by changing positional values, and promotes budding in intact hydra. This is the first report on induction of ectopic feet formation by UV in regenerating hydra and opens up the possibility of using UV irradiation as a tool to understand pattern formation in the enigmatic hydra     

Biosynthetic events of hydrid regeneration

Summary The results of a combined morphological and biochemical study of the role of DNA synthesis during distal regeneration inHydra oligactis revealed that a burst of³H-thymidine incorporation into DNA preceded the elaboration of each of the initial three tentacles. In addition, the relative level of each burst of precursor incorporation relfected the number of tentacles formed at that time. Cytological localization of concentrated amounts of labeled material in nuclei of the hypostome and tentacle regions provided corroborative evidence for the biochemical findings.Evidence that the increased DNA specific activity levels described above are associated with tentacle initiation derived from studies in which regenerating hydra were cultured in hydroxyurea and studies in which hydra regenerated proximally rather than distally. Hydra regenerating in 8 mg/ml (0.105 M) hydroxyurea developed morphologically recognizable hypostomes but no tentacles, and incorporated³H-thymidine into DNA at a level distinctly below that exhibited by uncut, untreated animals. Similarly, hydra regenerated a normal, functional basal disc in the absence of any increased DNA specific activity. Therefore, it is suggested that tentacle initiation inH. oligactis requires concomitant DNA synthesis and, as such, represents an epimorphic phenomenon.     

Actiniaria and Ceriantharia of the Azores (Cnidaria Anthozoa)

The common shallow water species of sea anemones (Actiniaria) and tube anemones (Ceriantharia) of the Azores are listed. Eight species of sea anemones are mentioned, the species Cereus pedunculatus and Sagartia affinis being new records for the archipelago. Both species of Ceriantharia, namely Arachnanthus nocturnus and Pachycerianthus solitarius, are recorded from the Azores for the first time. Arachnanthus nocturnus is also recorded from the Cape Verde Islands and from Madeira for the first time. Communicated by H.-D. Franke     

Metamorphosis ofHydractinia echinata Insights into pattern formation in Hydroids

Summary Hydractinia echinata is a marine, colony-forming coelenterate. Fertilized eggs develop into freely swimming planula larvae, which undergo metamorphosis to a sessile (primary) polyp. Metamorphosis can be triggered by means of certain marine bacteria and by Cs⁺. Half a day after this treatment a larva will have developed into a polyp. The induction of metamorphosis can be prevented by addition of inhibitor I, a substance partially purified from tissue ofHydra. The larvae ofH. echinata also appear to contain this substance. Inhibitor I appliedafter the onset of metamorphosis blocks its continuation as long as it remains in the culture medium. Cs⁺ applied within the same period of time also blocks the continuation of metamorphosis. However, these two agents have opposite effects on the body pattern of the resultant polyps. The experiments indicate that application of Cs⁺ triggers the generation of the pre-pattern. Inhibitor I appears to be a factor of this prepattern. A model is proposed which describes the basic features of head and foot/stolon formation not only forHydractinia but also for other related hydroids.     

Scanning electron microscopic analysis of spontaneous and UV-induced abnormal segment patterns in Chironomus samoensis (Diptera,Chironomidae)

Summary The embryonic body pattern of Chironomus samoensis, as well as other chironomids, can be altered dramatically by irradiating their eggs with ultraviolet light (UV). Anterior UV irradiation leads to the formation of double abdomen embryos whose anterior segments are replaced by posterior segments with reversed polarity. Most double abdomens are symmetrical showing a mirror image duplication of the posterior six or seven segments. However, in some cases the anterior end of the double abdomen is shorter, and comprises fewer segments, than its posterior counterpart. These asymmetries range from moderate to extreme. They involve the juxtaposition, at the plane of polarity reversal, of disparate segments. The same range of symmetrical and asymmetrical double abdomens is also formed spontaneously in an apparently mutant strain of C. samoensis. There are striking similarities between this natural variant and the Drosophila melanogaster mutant bicaudal which are also discussed with respect to models of embryonic pattern formation.