Bimodal pollination system of the bromeliad Aechmea nudicaulis involving hummingbirds and bees.

In order to compare the effectiveness of birds and insects as pollinators, we studied the floral biology of the bromeliad Aechmea nudicaulis (L.) Grisebach in the biome of the Atlantic rain forest, southern Brazil. On Santa Catarina Island, flowering extends from mid-September to the end of December, with diurnal anthesis. The reproductive system is obligatory xenogamy, thus pollinator-dependent. Flowers secrete 31.84 µl of nectar per day, with a mean sugar concentration of 23.2%. Highest nectar volume and sugar concentration occur at the beginning of anthesis. Most floral traits are characteristic for ornithophily, and nectar production appears to be adapted to the energy demand of hummingbirds. Continued secretion of the sucrose-dominated nectar attracts and binds visitors to inflorescences, strengthening trapline foraging behaviour. Experiments assessing seed set after single flower visits were performed with the most frequent visitors, revealing the hummingbird Thalurania glaucopis as the most effective pollen vector. In addition, bees are also functional pollinators, as substantiated by their high visitation frequency. We conclude that this pollination system is bimodal. Thus, there is redundancy in the pollination service provided by birds and bees, granting a high probability of successful reproduction in Ae. nudicaulis.

Integrin and talin in the jellyfish Podocoryne carnea.

We have isolated an integrin-beta and -alpha subunit from Podocoryne carnea (Cnidaria, Hydrozoa) and studied their expression in the life-cycle and during cell migration, in vitro transdifferentiation and regeneration. Comparison of the integrin expression pattern with a Podocoryne talin homologue by RT-PCR demonstrates that all three genes are maternal messages and continuously expressed in the life-cycle, in medusa development and in all medusae tissues. In situ hybridisation experiments confirm co-expression of both integrin subunits in the different life-stages. Integrin expression was furthermore studied in isolated striated muscle induced to transdifferentiate to new cell types, or grafted on ECM where the muscle adheres and migrates. Integrin expression was maintained continuously throughout both processes. These results suggest that in Podocoryne carnea processes such as cell migration and differentiation are not controlled by up- or downregulation of alternative integrin subunits, but by a single integrin heterodimer which activates different downstream signalling cascades.

The mesoderm specification factor twist in the life cycle of jellyfish.

The basic helix-loop-helix (bHLH) transcription factor Twist is highly conserved from Drosophila to vertebrates and plays a major role in mesoderm specification of triploblasts. The presence of a Twist homologue in diploblasts such as the cnidarian Podocoryne carnea raises questions on the evolution of mesoderm, the third cell layer characteristic for triploblasts. Podocoryne Twist is expressed in the early embryo until the myoepithelial cells of the larva differentiate and then again during medusa development. There, the gene is detected first when the myoepithelial cells of the polyp dedifferentiate to form the medusa bud and later Twist is found transiently in the entocodon, a mesoderm-like cell layer which differentiates into the smooth muscle and striated muscle of the bell. On the other hand, in later bud stages and the medusa, expression is seen where non-muscle tissues differentiate. Experimental analysis of in vitro transdifferentiation and regeneration demonstrates that Twist activity is not needed when isolated striated muscle regenerate medusa organs. Developmental roles of Twist are discussed with respect to early animal evolution from a common ancestor of cnidarians and bilaterians.

Characterization and expression analysis of an ancestor-type Pax gene in the hydrozoan jellyfish Podocoryne carnea.

We characterized a Pax gene from the hydrozoan Podocoryne carnea. It is most similar to cnidarian Pax-B genes and encodes a paired domain, a homeodomain and an octapeptide. Expression analysis demonstrates the presence of Pax-B transcripts in eggs, the ectoderm of the planula larva and in a few scattered cells in the apical polyp ectoderm. In developing and mature medusae, Pax-B is localized in particular endodermal cells, oriented toward the outside. Pax-B is not expressed in muscle cells. However, if isolated striated muscle tissue is activated for transdifferentiation, the gene is expressed within 1 h, before new cell types, such as smooth muscle and nerve cells, have formed. The expression data indicate that Pax-B is involved in nerve cell differentiation.

The HOX-like gene Cnox2-Pc is expressed at the anterior region in all life cycle stages of the jellyfish Podocoryne carnea.

The marine jellyfish Podocoryne carnea (Cnidaria, Hydrozoa) has a metagenic life cycle consisting of a larva, a colonial polyp and a free-swimming jellyfish (medusa). To study the function of HOX genes in primitive diploblastic animals we screened a library of P. carnea cDNA using PCR primers derived from the most conserved regions in helix 1 and helix 3 of the homeobox. A novel gene, Cnox2-Pc, has been isolated and characterized. Cnox2-Pc is a HOX cluster-like gene, and its homeodomain shows similarity to the Deformed subfamily of HOM-C/HOX genes. In situ hybridization revealed that Cnox2-Pc is expressed in the anterior region of the larva, the polyp head, and the most apical ectoderm of the differentiating bud during medusa development. In adult medusa expression is restricted to the gastrovascular entoderm. The results suggest that Cnox2-Pc is involved in establishment of an anterior-posterior axis during development in primitive metazoans.

Gene duplication and recruitment of a specific tropomyosin into striated muscle cells in the jellyfish Podocoryne carnea.

Cnidaria are the most basal animal phylum in which smooth and striated muscle cells have evolved. Since the ultrastructure of the mononucleated striated muscle is similar to that of higher animals, it is of interest to compare the striated muscle of Cnidaria at the molecular level to that of triploblastic phyla. We have used tropomyosins, a family of actin binding proteins to address this question. Throughout the animal kingdom, a great diversity of tropomyosin isoforms is found in non-muscle cells but only a few conserved tropomyosins are expressed in muscle cells. Muscle tropomyosins are all similar in length and share conserved termini. Two cnidarian tropomyosins have been described previously but neither of them is expressed in striated muscle cells. Here, we have characterized a new tropomyosin gene Tpm2 from the hydrozoan Podocoryne carnea. Expression analysis by RT-PCR and by whole mount in situ hybridization demonstrate that Tpm2 is exclusively expressed in striated muscle cells of the medusa. The Tpm2 protein is shorter in length than its counterparts from higher animals and differs at both amino and carboxy termini from striated muscle isoforms of higher animals. Interestingly, Tpm2 differs considerably from Tpm1 (only 19% identity) which was described previously in Podocoryne carnea. This divergence indicates a functional separation of cytoskeletal and striated muscle tropomyosins in cnidarians. These data contribute to our understanding of the evolution of the tropomyosin gene family and demonstrate the recruitment of tropomyosin into hydrozoan striated muscles during metazoan evolution. J. Exp. Zool. (Mol. Dev. Evol.) 285:378-386, 1999.

Reversible inactivation of cell-type-specific regulatory and structural genes in migrating isolated striated muscle cells of jellyfish.

We have investigated, by RT-PCR and in situ hybridization, expression of genes encoding regulatory and structural proteins in migrating mononucleated striated muscle cells of the medusa Podocoryne carnea. Expression of the three homeobox genes Otx, Cnox1-Pc, and Cnox3-Pc; a specific splice variant of the myosin heavy chain gene (Myo1); and a tropomyosin (Tpm2) is stable in isolated and cultured striated muscle tissue. When grafted onto cell-free extracellular matrix (ECM), muscle cells of the tissue fragments leave their native ECM and migrate as a coherent tissue onto a host ECM until a stretched cell monolayer is formed. Shortly after the first cells of the grafted isolate have made contact with the host ECM, Otx and Cnox1-Pc expression is completely turned off in all cells of the graft, including those still adhering to their native ECM. Myo1 message disappears with a delay while the expression level of Tpm2 is strongly reduced. However, expression of the homeobox gene Cnox3-Pc, a msh-like gene, and of the ubiquitously expressed elongation factor 1 alpha is not affected by the migration process. All genes are reexpressed after 12-24 h, once migration of the cells has ceased. Our results demonstrate that the first few migrating cells induce a change in gene expression which is rapidly communicated throughout the entire tissue. Furthermore, we showed that commitment of striated muscle cells remains stable despite the transient inactivation of cell-type-specific regulatory and structural genes.

The homeobox gene Otx of the jellyfish Podocoryne carnea: role of a head gene in striated muscle and evolution.

In many bilaterian animals members of the Otx gene family are expressed in head or brain structures. Cnidarians, however, have no clearly homologous head and no distinct brain; but an Otx homolog from the jellyfish Podocoryne carnea is highly conserved in sequence and domain structure. Sequence similarities extend well beyond the homeodomain and Podocoryne Otx can be aligned over its entire length to human OTX1, OTX2, and CRX. The overall structure of Otx is better conserved from Podocoryne to deuterostomes while protostomes appear to be more derived. In contrast, functions seem to be conserved from protostomes to vertebrates but not in Podocoryne or echinoderms. Podocoryne Otx is expressed only during medusa bud formation and becomes restricted to the striated muscle of medusae. Cnidaria are the most basal animals with striated muscle. Podocoryne polyps have no striated muscle and no Otx expression; both appear only during the asexual medusa budding process. The common ancestor of all animals that gave rise to cnidarians, protostomes, and deuterostomes already had an Otx gene more similar to today's Podocoryne and human homologs than to Drosophila otd, while the head-specific function appears to have evolved only later.

A toxin homology domain in an astacin-like metalloproteinase of the jellyfish Podocoryne carnea with a dual role in digestion and development.

Metalloproteinases of the astacin family such as tolloid play major roles in animal morphogenesis. Cnidarians are thought to be evolutionary simple organisms and, therefore, a metalloproteinase from the marine hydrozoan Podocoryne carnea was analysed to evaluate the role of this conserved gene familiy at the base of animal evolution. Surprisingly, the proteinase domain of Podocornyne PMP1 is more similar to human meprin than to HMP1 from another hydrozoan, the freshwater polyp Hydra vulgaris. However, PMP1 and HMP1 both contain a small C-terminal domain with six cysteines that distinguishes them from other astacin-like molecules. Similar domains have been described only recently from sea anemone toxins specific for potassium channels. This toxin homology (Tox1) domain is clearly distinct from epidermal growth factor (EGF)-like domains or other cysteine-rich modules and terminates with the characteristic pattern CXXXCXXC with three out of six cysteines in the last eight residues of the protein. PMP1 is transiently expressed at various sites of morphogenetic activity during medusa bud development. In the adult medusa, however, expression is concentrated to the manubrium, the feeding organ, where the PMP1 gene is highly induced upon feeding. These disparate expression patterns suggest a dual role of PMP1 comparable to tolloid in development and, like astacin in the crayfish, also for food digestion. The Tox1 domain of PMP1 could serve as a toxin to keep the pray paralysed after ingestion, but as a sequence module such Tox1 domains with six cysteines are neither restricted to cnidarians nor to toxins.

Transdifferentiation of isolated striated muscle of jellyfish in vitro: the initiation process.

Fragments of striated muscle tissue of Anthomedusae can be isolated and cultured. Without further treatment the isolated muscle fragments maintain the differentiated state. When treated with enzymes degrading the adhering extracellular matrix, drugs activating protein kinase C or substances destroying the actin cytoskeleton, dedifferentiation and DNA replication are initiated and transdifferentiation to several new cell types occurs. Initiation of DNA replication seems to be correlated with a disturbance of cell-ECM interactions. If muscle fragments are combined with isolated ECMs, cell migration onto the grafted ECMs occurs and DNA-replication and transdifferentiation are initiated in those cells which adhere to both, the native and the grafted ECM. If, however, the cells can stretch into a monolayer and adhere entirely to either the native or the grafted ECM, DNA-replication is inhibited. Carbohydrate moieties seem to be involved in mediating these cell-substrate interactions.

An extracellular matrix protein of jellyfish homologous to mammalian fibrillins forms different fibrils depending on the life stage of the animal.

A monoclonal antibody generated against the isolated extracellular matrix (ECM) of the medusa Podocoryne carnea M. Sars (Coelenterata, Cnidaria, Hydrozoa) stains a fibrillar component of the Podocoryne ECMs in immunohistochemical preparations. The antigen shows a different staining pattern according to the type of ECMs from the animals life cycle. In ontogeny the epitope first appears after gastrulation in the planula larva as single widely dispersed small fibrils, which later accumulate to form a dense meshwork in the larval ECM. The distribution of the antigen strongly suggests an important role of the molecule to cover the biomechanical needs of the animal. In immunoblots one band with a size of 330 kDa is detectable in the polyp ECM, whereas in the outer ECM of the medusa a 340-kDa band is observed. Both the 330- and the 340-kDa bands appear when probed on the inner ECM of the medusa or on ECMs of the larva. The antibody was used to isolate a cDNA clone from an expression library. The deduced amino acid sequence of this cDNA fragment reveals a molecular structure composed of tandemly repeated epidermal growth factor-like repeats interrupted by a second cystein-rich motif first found in the latent transforming growth factor beta binding protein. Comparison of the sequence to the data bases indicates < 40% identity to human fibrillins. The presence of fibrillin-like beaded microfibrils in the ECM of P. carnea is furthermore demonstrated by electron microscopy after rotary shadowing. Our results demonstrate for the first time the existence of this noncollagenous interstitial ECM protein in invertebrates and suggest that the structure and the function of fibrillin have been conserved during evolution.

Mechanochemical interactions between striated muscle cells of jellyfish and grafted extracellular matrix can induce and inhibit DNA replication and transdifferentiation in vitro.

Striated muscle tissue of jellyfish was isolated with its adhering extracellular matrix (ECM) and cultured. Without further treatment the cultured muscle cells maintain their differentiated state. If, however, the isolated tissues are combined with cell-free ECM from the jellyfish or its polyp, DNA replication and proteolytic activity are induced followed by transdifferentiation into RF-amide-positive nerve cells. Changes in the mechanochemical interactions between the cells and the grafted ECM seem to induce the signals which lead to transdifferentiation. If the isolates are combined with small floating pieces of ECM most cells will leave their own ECM and overgrow the ECM graft. All cells in the combinations will then transdifferentiate. If the isolates are grafted onto large pieces of ECM kept permanently stretched on glass, a majority of cells will migrate onto the grafted ECM where they form a flat monolayer. In this case, however, DNA replication and transdifferentiation occurs mainly in those cells which have remained on or near their own ECM. Labeling experiments with [3H]-thymidine demonstrate that initiation of DNA replication occurs first in those cells which bridge from the native ECM to the grafted ECM. On the other hand inhibition of DNA replication and transdifferentiation is generally suppressed whenever tissues are allowed to form a monolayer of well-stretched cells. From these observations we conclude that mechanochemical interactions between the muscle cells and their substrate are responsible for both activation and inhibition of DNA replication and transdifferentiation.

The proportion altering factor (PAF) and the in vitro transdifferentiation of isolated striated muscle of jellyfish into nerve cells.

The effect of proportion altering factor (PAF) on the transdifferentiation of isolated striated muscle into RFamide-positive nerve cells was investigated. The factor reduces incorporation of 3H-thymidine into replicating DNA; the effect is concentration-dependent and reversible. Transdifferentiation to nerve cells increases by up to 60% if PAF is applied shortly before or at the time of initiation of DNA synthesis. When treatment was terminated 4 h before the start of S-phase or when PAF was applied at the peak of S-phase no increase in nerve cell formation was observed.

Transdifferentiation from striated muscle of medusae in vitro.

We have established an in vitro transdifferentiation and regeneration system which is based entirely on mononucleated striated muscle cells. The muscle tissue is isolated from anthomedusae and activated by various means to undergo cell cycles and transdifferentiation to several new cell types. In all cases DNA-replication is initiated and the division products are smooth muscle cells, characterized by their ultrastructure and monoclonal antibodies, and nerve/sensory cells, characterized by their ultrastructure and FMRFamide-staining. Both cell types are found at a 1:1 ratio after the first division. The nerve cells stop to replicate, whereas the smooth muscle cells continue and keep producing in each successive division a smooth muscle cell and a nerve cell. The observed data indicate that smooth muscle cells behave like stem cells. Depending on the destabilization and culturing methods, some isolated muscle tissue will form a bilayered fragment and within only two cell cycles manubria (the feeding and sexual organ) or tentacles will regenerate. In this case six to eight new non-muscle cell types have been formed by transdifferentiation.

Species specificity in cell-substrate interactions in medusae.

A new system is described for the study of ECM-tissue interactions, using the ECM (called mesogloea) of various cnidarians and isolated striated muscle and endodermal tissue of jellyfish. The mesogloea consists mainly of water and collagen. It is present in all cnidarians and can be isolated without enzyme treatment. It can be used as a substrate to which cells and tissues adhere and on which they spread and migrate. Tissues of striated muscle and endoderm adhere and spread not only on mesogloea from regions they normally cover, but also from other regions of the animal. However, adhesion and spreading are highly species-specific. Species-specific adhesion is found throughout the whole mass of mesogloea even at regions where cells do not occur naturally. The cell adhesion factor can be extracted from the mesogloea so that the mesogloea no longer shows any cell adhesion properties. The extract consists mainly of a cysteine-containing collagen.

The jellyfish and its polyp: a comparative study of gene expression monitored by the protein patterns, using two-dimensional gels with double-label autoradiography.

The life cycle of Podocoryne carnea (Coelenterata, Anthomedusae) shows several distinct stages which differ considerably in terms of their ecology, morphology, cellular composition, and ultrastructure. Previously these stages had even been described as separate species. Using two-dimensional gel electrophoresis and a new method of double-label autoradiography, we show here for the first time for metagenic hydrozoans that only minor differences in gene expression exist between the various life cycle stages. Our results demonstrate the high resolution power of these techniques and show that the different life stages of P. carnea remain rather similar on the protein level. Most of the prominent spots of the two-dimensional gel protein patterns are common to all stages studied. These data show that the hydrozoan life cycle and development are regulated by only minor distinctions in gene expression which possibly explains the great morphogenetic repertoire of these animals described in many studies.

Cell cycles and in vitro transdifferentiation and regeneration of isolated, striated muscle of jellyfish.

Isolated, mononucleated, cross-striated muscle cells of a medusa can transdifferentiate in vitro to various new cell types and even form a complex regenerate. The transdifferentiation events follow a strict pattern. The first new cell type resembles smooth muscle and is formed without a preceding DNA replication. This cell type behaves like a stem cell and by quantal cell cycles produces all other new cell types. Some preparations develop an inner and an outer layer separated by a basal lamella. Formation of these layers does not depend on DNA replication. When layers do not form, each division results in nerve cells and smooth muscle cells. If separation into layers occurs, then a regenerate will be formed, and in the course of only two cell cycles all necessary cell types to form a functional regenerate will differentiate.