In vitro migration ofHydra nematocytes: The influence of the natural extracellular matrix (the mesoglea), of collagen type IV and type I, laminin, and fibronectin on cell attachment, migration parameters, and on patterns of cytoskeletal proteins

Calcium and cytoskeleton signaling during cell volume regulation in isolated nematocytes of Aiptasia mutabilis (Cnidaria: Anthozoa)

Cell volume regulation has not been completely clarified in Coelenterates. The present investigation focuses on cell volume regulation under anisosmotic conditions, both hyposmotic and hypertonic, and on the underlying signals in nematocytes isolated from the Coelenterate Aiptasia mutabilis living in sea water. Nematocytes, once isolated from acontia, that were submitted to either hyposmotic (35%) and hypertonic shock (45%) show RVD and RVI capabilities, respectively. In order to ascertain the role of Ca2+ in triggering such regulatory mechanisms and the possible involvement of cytoskeleton components, tests were performed by employing either Ca2+ free conditions, Gd3+ as Ca2+ channel blockers, TFP as calmodulin inhibitor, colchicine as microtubule inhibitor and cytochalasin B as microfilament polymerization inhibitor. Results show that isolated nematocytes of A. mutabilis can regulate their volume upon both hyposmotic and hypertonic challenge. Ca2+ both from external medium and from internal stores is needed to perform RVD mechanisms, whereas, intracellular Ca2+ seems to be mainly involved in RVI. Moreover cytoskeletal components may play an important role since a significant RVD and RVI inhibition was observed in treated cells. On the basis of our observations further studies are warranted to further verify the role of signals, including phosphatases and phosphorylases, in cell volume regulation of primitive eukaryotic cells.

Epithelial morphogenesis in hydra requires de novo expression of extracellular matrix components and matrix metalloproteinases

As a member of the phylum Cnidaria, the body wall of hydra is organized as an epithelium bilayer (ectoderm and endoderm) with an intervening extracellular matrix (ECM). Previous studies have established the general molecular structure of hydra ECM and indicate that it is organized as two subepithelial zones that contain basement membrane components such as laminin and a central fibrous zone that contains interstitial matrix components such as a unique type I fibrillar collagen. Because of its simple structure and high regenerative capacity, hydra has been used as a developmental model to study cell-ECM interaction during epithelial morphogenesis. The current study extends previous studies by focusing on the relationship of ECM biogenesis to epithelial morphogenesis in hydra, as monitored during head regeneration or after simple incision of the epithelium. Histological studies indicated that decapitation or incision of the body column resulted in an immediate retraction of the ECM at the wound site followed by a re-fusion of the bilayer within 1 hour. After changes in the morphology of epithelial cells at the regenerating pole, initiation of de novo biogenesis of an ECM began within hours while full reformation of the mature matrix required approximately 2 days. These processes were monitored using probes to three matrix or matrix-associated components: basement membrane-associated hydra laminin β1 chain (HLM-β1), interstitial matrix-associated hydra fibrillar collagen (Hcol-I) and hydra matrix metalloproteinase (HMMP). While upregulation of mRNA for both HLM-β1 and Hcol-I occurred by 3 hours, expression of the former was restricted to the endoderm and expression of the latter was restricted to the ectoderm. Upregulation of HMMP mRNA was also associated with the endoderm and its expression paralleled that for HLM-β1. As monitored by immunofluorescence, HLM-β1 protein first appeared in each of the two subepithelial zones (basal lamina) at about 7 hours, while Hcol-I protein was first observed in the central fibrous zone (interstitial matrix) between 15 and 24 hours. The same temporal and spatial expression pattern for these matrix and matrix-associated components was observed during incision of the body column, thus indicating that these processes are a common feature of the epithelium in hydra. The correlation of loss of the ECM, cell shape changes and subsequent de novo biogenesis of matrix and matrix-associated components were all functionally coupled by antisense experiments in which translation of HLM-β1 and HMMP was blocked and head regeneration was reversibly inhibited. In addition, inhibition of translation of HLM-β1 caused an inhibition in the appearance of Hcol-I into the ECM, thus suggesting that binding of HLM-β1 to the basal plasma membrane of ectodermal cells signaled the subsequent discharge of Hcol-I from this cell layer into the newly forming matrix. Given the early divergence of hydra, these studies point to the fundamental importance of cell-ECM interactions during epithelial morphogenesis.

Hydra and Niccolo Paganini (1782-1840)--two peas in a pod? The molecular basis of extracellular matrix structure in the invertebrate, Hydra

The body wall of Hydra is organized as an epithelial bilayer with an intervening extracellular matrix (ECM). Molecular and biochemical analyses of Hydra ECM have established that it contains components similar to those seen in more complicated vertebrates such as human. In terms of biophysical parameters, Hydra ECM is highly flexible; a property that facilitates continuous movements along the organism's longitudinal and radial axis. A more rigid ECM, as in vertebrates, would not be compatible with this degree of movement. The flexible nature of Hydra ECM can now be explained in part by the unique structure of the organism's collagens. Interestingly, some aspects of the structural features of Hydra collagens mimic what is seen in Ehlers-Danlos syndrome, an inherited condition in humans that results in an abnormally flexible ECM that can be debilitating in extreme cases. This review will focus on structure-function relationships of the ECM of Hydra.

Characterization of hydra type IV collagen. Type IV collagen is essential for head regeneration and its expression is up-regulated upon exposure to glucose

Hydra vulgaris mesoglea is a primitive basement membrane that also exhibits some features of an interstitial matrix. We have characterized cDNAs that encode the full-length hydra alpha1(IV) chain. The 5169-base pair transcript encodes a protein of 1723 amino acids, including an interrupted 1455-residue collagenous domain and a 228-residue C-terminal noncollagenous domain. N-terminal sequence analyses of collagen IV peptides suggest the molecule is homotrimeric. Denatured hydra type IV collagen protein occurs as dimers and higher order aggregates held together by nonreducible cross-links. Hydra collagen IV exhibits no functional evidence for the presence of a 7 S domain. Type IV collagen is expressed by the ectoderm along the entire longitudinal axis of the animal but is most intense at the base of the tentacles at the site of battery cell transdifferentiation. Antisense studies show that inhibition of collagen IV translation causes a blockage in head regeneration, indicating its importance in normal hydra development. Exposure of adult hydra to 15 mm glucose resulted in up-regulation of type IV collagen mRNA levels within 48 h and significant thickening of the mesoglea within 14 days, suggesting that basement membrane thickening seen in diabetes may be, in evolutionary terms, an ancient glucose-mediated response.

Alteration of fibronectin affinity during differentiation modulates the in vitro migration velocities of Hydra nematocytes

In the fresh water Cnidarian Hydra nematocytes differentiate from stem cells in the body column of the polyps and are functional in the tentacles to where they migrate as single cells in an amoeboid fashion. The fluorescent vital stain TROMI (tetramethyl-rhodamine-5/6-maleimide) allows to easily discriminate between cells located in the body column and cells mounted in the tentacles. The two cell populations were found to have different in vitro migration properties. These differences appear to be due largely to a differential attachment to fibronectin. Nematocytes from the tentacles show significantly lower in vitro migration velocities on isolated pieces of the organisms extracellular matrix (the mesoglea) and attach more firmly to fibronectin-coated substrates than cells from the body column. Pretreatment of the mesogleae with antibodies against the cell binding domain of fibronectin or addition of RGD-peptides results in an increase of the average migration velocity of cells from the tentacles and a decreased velocity of the cells from the body column. These findings suggest that (1) modulation of the attachment to fibronectin is decisive for the observed differential migration properties of the two cell populations and (2) the in vitro migration of nematocytes is dependent on subtle and transient interactions of cell surface receptors (most probably integrins) and fibronectin.

Cell-substrate interactions in cnidaria

Studies on morphogenesis and regeneration in cnidarians have a long history, and the importance of cell-ECM (extracellular matrix) interactions for these processes has been well recognized and studied since the middle of the 20th century. Cnidarians have a life cycle with a larva, a polyp, and often a medusa generation. In the medusa, the ECM (mesoglea) is very prominent and essentially shapes the animal. In the larva and the polyp, the ECM is a thin layer. Some of the ECM components known from vertebrates have been identified in cnidarians by immunohistochemistry, electron microscopy, rotary shadowing, biochemistry, and molecular cloning. In vivo and in vitro experiments suggest that the cnidarian ECM plays a role in cell migration and morphogenesis comparable to that known from other developmental systems. In the fresh water polyp Hydra, regeneration of body patterns and migration of nematocytes seems to require the presence of ECM ligands and the corresponding cell receptors. In hydrozoan medusae, DNA replication and the stability of the differentiated state of isolated tissue can be influenced by altering the properties of the ECM substrate. When cultured, most cnidarian cells survive only when attached to ECM substrates, they rarely divide and die within short times.

Novel tools for the study of development, migration and turnover of nematocytes (cnidarian stinging cells)

The rhodamine derivatives tetramethyl-rhodamine-5/6-maleimide (TROMI) and tetramethyl-rhodamine-6-isothiocyanate (TRITC) were allowed to react with living Hydra vulgaris. The two fluorescent dyes stain the polyps to different degrees, apparently without impairing their viability and behaviour. Concerning nematocytes, TROMI preferentially couples to cytoskeletal elements only of mounted nematocytes whereas TRITC selectively reacts with structural components of cysts of late nematoblasts, which thereafter develop apparently normally into mature nematocytes. Hence TROMI-labelling indicates that nematocytes are mounted and ready for discharge; TRITC-labelling can be used as a tool to investigate the final maturation, migration and installation of nematocytes in Hydra. Together with a new non-fixative method to dissociate Hydra polyps into single, identifiable cells, the two labelling methods allow direct quantitative dynamic studies of nematocyte turnover and open new possibilities of investigating the regulation and the mechanisms of nematocyte supply and migration.

Cell-extracellular matrix interactions under in vivo conditions during interstitial cell migration in Hydra vulgaris

Interstitial cell (I-cell) migration in hydra is essential for establishment of the regional cell differentiation pattern in the organism. All previous in vivo studies have indicated that cell migration in hydra is a result of cell-cell interactions and chemotaxic gradients. Recently, in vitro cell adhesion studies indicated that isolated nematocytes could bind to substrata coated with isolated hydra mesoglea, fibronectin and type IV collagen. Under these conditions, nematocytes could be observed to migrate on some of these extracellular matrix components. By modifying previously described hydra grafting techniques, two procedures were developed to test specifically the role of extracellular matrix components during in vivo I-cell migration in hydra. In one approach, the extracellular matrix structure of the apical half of the hydra graft was perturbed using beta-aminopropionitrile and beta-xyloside. In the second approach, grafts were treated with fibronectin, RGDS synthetic peptide and antibody to fibronectin after grafting was performed. In both cases, I-cell migration from the basal half to the apical half of the grafts was quantitatively analyzed. Statistical analysis indicated that beta-aminopropionitrile, fibronectin, RGDS synthetic peptide and antibody to fibronectin all were inhibitory to I-cell migration as compared to their respective controls. beta-xyloside treatment had no effect on interstitial cell migration. These results indicate the potential importance of cell-extracellular matrix interactions during in vivo I-cell migration in hydra.

The attachment of nematocytes from the primitive invertebrate Hydra to fibronectin is specific and RGD-dependent

The transient attachment of cells to components of the extracellular matrix is an important step in the complex molecular mechanisms involved in amoeboid cell locomotion. We have analyzed the attachment of nematocytes from the freshwater cnidarian Hydra to fibronectin which is a constituent of the mesoglea, the extracellular matrix, of the polyps. The percentage of attaching cells increased gradually in a concentration-dependent manner and reached a plateau value at a fibronectin concentration of 50 micrograms/ml. Attachment was inhibited by exposure of the fibronectin-coated surfaces to antibodies against the cell binding domain of fibronectin or by incubating the cells with peptides containing the recognition sequence Arg-Gly-Asp (RGD) known from vertebrate cells. This, together with data obtained by affinity chromatography, indicates that RGD-dependent binding to fibronectin, mediated by a receptor which possibly belongs to the integrin family, already occurs in Hydra, a member of an evolutionary low invertebrate phylum.

The contributions of microtubules and F-actin to the in vitro migratory mechanisms of Hydra nematocytes as determined by drug interference experiments

In order to investigate the contributions of microtubules and of F-actin to the in vitro migration mechanisms of Hydra nematocytes we have studied the effects of agents directed against cytoskeletal structures. Disassembly of microtubules by treatment with the drug nocodazole in moving nematocytes resulted in the loss of all locomotory activity within 20 min after the onset of treatment and in the detachment from the substratum after about 30 min. Depolymerization of microtubules by exposure to low temperatures had the same effect but was reversible in this case. Locomoting cells treated with cytochalasin D, which disrupts the actin filaments, stopped movement 2 min after drug administration and detached from the substratum after 15 min. The pattern of F-actin, alpha-tubulin, and tyrosinated tubulin in drug- or cold-treated cells was determined by immunocytochemical techniques and confocal laser scanning microscopy. These patterns and the reactions of the cells to the various drug treatments suggest that both actin filaments and microtubules play a crucial role in nematocyte locomotion. Analysis of the cytoskeletal pattern in drug-treated cells shows that the microtubules which are involved in locomotion are mostly tyrosinated. Furthermore it is suggested that microtubules and actin filaments interact with each other during the locomotion of nematocytes.