Components, structure, biogenesis and function of the Hydra extracellular matrix in regeneration, pattern formation and cell differentiation

The body wall of Hydra is organized as an epithelial bilayer (ectoderm and endoderm) with an intervening extracellular matrix (ECM), termed mesoglea by early biologists. Morphological studies have determined that Hydra ECM is composed of two basal lamina layers positioned at the base of each epithelial layer with an intervening interstitial matrix. Molecular and biochemical analyses of Hydra ECM have established that it contains components similar to those seen in more complicated vertebrate species. These components include such macromolecules as laminin, type IV collagen, and various fibrillar collagens. These components are synthesized in a complicated manner involving cross-talk between the epithelial bilayer. Any perturbation to ECM biogenesis leads to a blockage in Hydra morphogenesis. Blockage in ECM/cell interactions in the adult polyp also leads to problems in epithelial transdifferentiation processes. In terms of biophysical parameters, Hydra ECM is highly flexible; a property that facilitates continuous movements along the organism's longitudinal and radial axis. This is in contrast to the more rigid matrices often found in vertebrates. The flexible nature of Hydra ECM can in part now be explained by the unique structure of the organism's type IV collagen and fibrillar collagens. This review will focus on Hydra ECM in regard to: 1) its general structure, 2) its molecular composition, 3) the biophysical basis for the flexible nature of Hydra's ECM, 4) the relationship of the biogenesis of Hydra ECM to regeneration of body form, and 5) the functional role of Hydra ECM during pattern formation and cell differentiation.     

Sweet Tooth, a novel receptor protein-tyrosine kinase with C-type lectin-like extracellular domains

A gene encoding a novel type of receptor protein-tyrosine kinase was identified in Hydra vulgaris. The extracellular portion of this receptor (which we have named Sweet Tooth) contains four C-type lectin-like domains (CTLDs). Comparison of the sequences of these domains with the sequences of the carbohydrate recognition domains of various vertebrate C-type lectins shows that Sweet Tooth CTLD1 and CTLD4 have amino acids in common with those shown to be involved in carbohydrate binding by the lectins. Comparison of sequences encoding CTLD1 from the Sweet Tooth genes from different species of Hydra shows variation in some of the conserved residues that participate in carbohydrate binding in C-type lectins. The Sweet Tooth gene is expressed widely in the Hydra polyp, and expression is particularly high in the endoderm of the tentacles. Treatment of polyps with peptides corresponding to sequences in the Sweet Tooth CTLDs results in the disintegration of the animal. These same peptides do not block adhesion or morphogenesis of Hydra cell aggregates.     

Eisenstasin,new antistasin family inhibitor from the earthworm

A couple of new antistasin family serine protease inhibitors have been isolated from the non-hematophagous earthworm, Eisenia andrei. These novel inhibitors have been designated as eisenstasin I and II. Similar to other antistasin family inhibitors, eisenstasin I and II feature 3 and 4 internal repeats, respectively, of a 24–29 amino acid sequence, both of which exhibit a conserved pattern of 6-cysteine/2-glycine at an identical position between the third and fourth cysteine residues. This suggests that the eisenstasins isolated from the earthworm are members of the antistasin family. The eisenstasins are 82% similar with regard to amino acid sequences and exhibit over 70% similarity with the antistasins from the earthworm Lumbricus rubellus, while also displaying less than 40% sequence similarity with the leech antistasins. Earthworm eisenstasins are basic proteins, primarily due to the frequent occurrence of arginine residues in their structure, especially at the C-terminal region. As arginine is a key residue for the substrate specificity of some serine proteases including FXa, it is thought that these multiple arginine residues may play a role in the inhibitory characteristics of the eisenstasins. Considering the structure and number of the internal repeats derived from a variety of animal species, the deletion as well as the duplication of all or part of an internal repeat may be implicated in the evolution of the structure and function of the antistasin family inhibitors.     

Extracellular matrix (mesoglea) of Hydra vulgaris. I. Isolation and characterization.

Hydrozoans such as Hydra vulgaris, as with all classes of Cnidaria, are characterized by having their body wall organized as an epithelial bilayer with an intervening acellular layer termed the mesoglea. The present study was undertaken to determine what extracellular matrix (ECM) components are associated with Hydra mesoglea. Using polyclonal antibodies generated from vertebrate ECM molecules, initial light and electron microscopic immunocytochemical studies indicated the presence of type IV collagen, laminin, heparan sulfate proteoglycan, and fibronectin immunoreactive components in Hydra mesoglea. These immunocytochemical observations were in part supported by biochemical analyses of isolated Hydra mesoglea which indicated the presence of fibronectin and laminin based on Western blot analysis. Amino acid analysis of total mesoglea and some of its isolated components confirmed the presence of collagen molecules in mesoglea. Additional studies indicated the presence of (1) a gelatin binding protein in Hydra which was immunoreactive with antibodies raised to human plasma fibronectin and (2) a noncollagen fragment extracted from mesoglea which was immunoreactive to antibodies raised to the NC1 domain (alpha 1 subunit) of bovine glomerular basement membrane type IV collagen. These observations indicate that Hydra mesoglea is evolutionarily a primitive basement membrane that has retained some properties of interstitial ECM.     

Inotropic response elicited by nematocyst contents of Hydra oligactis (Coelenterata: Hydrozoa)

1. Intact, isolated nematocysts from the non-toxic, freshwater coelenterate Hydra oligactis contain soluble material(s) capable of producing a sustained increase in the rate of developed force in the vertebrate myocardium. 2. The positive inotropic effects of this material(s) appear grossly comparable to those described for Anthopleurin-A (AP-A) and Toxin II (ATX-II) from sea anemones. 3. The effects of the nematocyst material are distinct from those of known vasoactive peptides reported to occur in Hydra.     

Antistasin, an inhibitor of coagulation and metastasis, binds to sulfatide (Gal(3-SO4) beta 1-1Cer) and has a sequence homology with other proteins that bind sulfated glycoconjugates

Antistasin, a 15-kDa salivary protein from the Mexican leech Haementeria officinalis, inhibits both blood coagulation and the metastasis of tumors (Tuszynski, G. P., Gasic, T. B., and Gasic, G. J. (1987) J. Biol. Chem. 262, 9718-9723). Antistasin binds to heparin-agarose, suggesting the protein interacts with sulfated glycoconjugates. The specificity of the interaction between antistasin and heparin was tested by measuring the binding of antistasin to various lipids and by comparing the ability of several charged glycoconjugates to inhibit binding. Of the lipids tested, antistasin binds with high affinity only to sulfatide (Gal(3-SO4)beta 1-1Cer) and does not bind to comparable levels of phospholipids, neutral glycosphingolipids, gangliosides, or cholesterol-3-SO4. The binding of antistasin to sulfatide is inhibited by dextran sulfate, fucoidan, and heparin, with I50 values of 1.5, 9.2, and 16 micrograms/ml, respectively. Comparable levels of chondroitin sulfates A, B, C, keratan sulfate, or hyaluronic acid do not inhibit binding. Comparisons of the amino acid sequences of antistasin and other sulfatide or heparin-binding proteins revealed a region of homology, based around the sequence Cys-Ser-Val-Thr-Cys-Gly-X-Gly-X-X-X-Arg-X-Arg, which may be a sulfated glycoconjugate binding domain. In addition, homologies were found with the alternate complement pathway protein properdin and coat proteins from malaria circumsporozoites and Herpes simplex I.     

Nucleotide sequence of an actin-encoding gene from Hydra attenuata: structural characteristics and evolutionary implications

We have determined the complete nucleotide sequence of an actin-encoding gene from Hydra attenuata as well as partial sequences of cDNA clones from two additional actin-encoding genes. The gene from the genomic clone contains a single intron, and has promoter and polyadenylation signals similar to those found in other species. The hydra genome has a very A + T-rich base composition (71%). This is reflected in the codon usage of the actin-encoding genes, which is strongly biased towards codons having A or T in the third position. The hydra actin-encoding gene family consists of three or more transcribed genes, two of which are very closely related to each other and probably arose by a recent gene duplication. Hydra actin, like other invertebrate actins, is more similar to the non-muscle isotypes of vertebrates than to the vertebrate muscle actins. Hydra actin is more similar to animal actins than to those of plants or fungi, which is consistent with the view that all metazoans arose from a single protist ancestor.     

中国水螅属一新种(水螅纲,水螅科)

报道采自广东省肇庆市的淡水水螅1新种,多形水螅Hydra polymorphus sp.nov.,研究标本均来自1只水螅的单系繁殖群体,测量数据经生物统计学处理。新种的钩刺丝囊外形及内部刺丝盘旋均有多种形态,故新种名以此命名。所有研究标本保存于深圳大学生命科学学院。     

Structural model of an antistasin/notch-like fusion protein from the cocoon wall of the aquatic leech, Theromyzon tessulatum

The aquatic leech, Theromyzon tessulatum, secretes a proteinaceous cocoon with extraordinary physical properties (e.g., proteolytic, thermal resiliency). The deduced amino acid sequence of a major protein (Tcp—Theromyzon cocoon protein) from the T. tessulatum cocoon wall has been used to model the endogenous structure of the Tcp protein. The Tcp protein sequence comprises six internal repeats, each containing 12 ordered Cys residues. Amino acid alignments suggest that the region Cys1→6 is homologous to antistasin, a leech anticoagulant, and Cys7→12 is homologous to an epidermal growth factor-like domain found in notch-class proteins, which play critical roles in development, signaling, and adhesion throughout the Animalia. Modeling of individual domains (i.e., antistasin and notch) positions multiple hydrophobic and charged residues on the surface. When the antistasin and notch domains were fused, hydrophobic pockets appeared that may facilitate a polymerization mechanism. Collectively, the predicted features of our Tcp model are consistent with the physical properties of the leech cocoon wall.      

The head organizer in Hydra

Organizers and organizing centers play critical roles in axis formation and patterning during the early stages of embryogenesis in many bilaterians. The presence and activity of an organizer was first described in adult Hydra about 100 years ago, and in the following decades organizer regions were identified in a number of bilaterian embryos. In an adult Hydra, the cells of the body column are constantly in the mitotic cycle resulting in continuous displacement of the tissue to the extremities where it is sloughed. In this context, the head organizer located in the hypostome is continuously active sending out signals to maintain the structure and morphology of the head, body column and foot of the animal. The molecular basis of the head organizer involves the canonical Wnt pathway, which acts in a self-renewing manner to maintain itself in the context of the tissue dynamics of Hydra. During bud formation, Hydra's mode of asexual reproduction, a head organizer based on the canonical Wnt pathway is set up to initiate and control the development of a new Hydra. As this pathway plays a central role in vertebrate embryonic organizers, its presence and activity in Hydra indicate that the molecular basis of the organizer arose early in metazoan evolution.     

X-ray structure of antistasin at 1.9 A resolution and its modelled complex with blood coagulation factor Xa.

The three-dimensional structure of antistasin, a potent inhibitor of blood coagulation factor Xa, from the Mexican leech Haementeria officinalis was determined at 1.9 A resolution by X-ray crystallography. The structure reveals a novel protein fold composed of two homologous domains, each resembling the structure of hirustasin, a related 55-residue protease inhibitor. However, hirustasin has a different overall shape than the individual antistasin domains, it contains four rather than two beta-strands, and does not inhibit factor Xa. The two antistasin domains can be subdivided into two similarly sized subdomains with different relative orientations. Consequently, the domain shapes are different, the N-terminal domain being wedge-shaped and the C-terminal domain flat. Docking studies suggest that differences in domain shape enable the N-terminal, but not C-terminal, domain of antistasin to bind and inhibit factor Xa, even though both have a very similar reactive site. Furthermore, a putative exosite binding region could be defined in the N-terminal domain of antistasin, comprising residues 15-17, which is likely to interact with a cluster of positively charged residues on the factor Xa surface (Arg222/Lys223/Lys224). This exosite binding region explains the specificity and inhibitory potency of antistasin towards factor Xa. In the C-terminal domain of antistasin, these exosite interactions are prevented due to the different overall shape of this domain.     

The Hydra genome: insights, puzzles and opportunities for developmental biologists

The sequencing of a Hydra genome marked the beginning of a new era in the use of Hydra as a developmental model. Analysis of the genome sequence has led to a number of interesting findings, has required revisiting of previous work, and most importantly presents new opportunities for understanding the developmental biology of Hydra. This review will de-scribe the history of the Hydra genome project, a selection of results from it that are relevant to developmental biologists, and some future research opportunities provided by Hydra genomics.     

Demonstration that [A103,106,108] antistasin 93-119 inhibits the specific binding of antistasin to sulfatide [Gal(3-SO4)beta 1-1Cer

Antistasin is a 119 amino acid heparin-binding protein from the leech Haementaria officinalis which has anticoagulant and antimetastatic properties. A series of peptides representing the basic amino acid-rich domains of the amino- and carboxyl-terminal regions of the inhibitor were synthesized by solid-phase peptide chemistry and their ability to bind sulfated glycolipids was investigated. The findings show that [A103,106,108] antistasin 93-119 has high affinity for sulfatide and inhibits the specific interaction of whole antistasin with [Gal(3-SO4)beta 1-1Cer]. We conclude that the 93-119 region is a critical domain that mediates the interaction of antistasin with sulfated glycolipids.     

Specific inhibition of binding of antistasin and [A103,106,108] antistasin 93-119 to sulfatide (Gal(3-SO4)beta 1-1Cer) by glycosaminoglycans.

Leech-derived antistasin is a potent anticoagulant and antimetastatic protein that binds sulfatide (Gal(3-SO4)beta 1-1Cer) and sulfated polysaccharides. In this study, the synthetic fragment [A103,106,108] antistasin 93-119, which corresponds to the carboxyl terminus, showed specific and saturable binding to sulfatide. Binding was competitively blocked by glycosaminoglycans (GAGs) in the order: dextran sulfate 5000 congruent to dextran sulfate 500,000 greater than heparin greater than dermatan sulfate much greater than chondroitin sulfates A and C. This rank order of inhibitory potency was identical to that observed with whole antistasin. We suggest that residues 93-119 of antistasin represent a critical domain for binding GAGs and sulfated glycolipids.     

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.     

Evolution of Vertebrate Immunity: Sequence and Functional Analysis of the SEFIR Domain Family Member Act1

SEF/IL-17R/CIKS/ACT1 homology (SEFIR) domain containing proteins, which include the IL-17 receptors and an adaptor protein Act1, have essential roles in vertebrate immunity. However, the molecular mechanisms of Act1 function remain largely unexplored. In this article, we employed an evolutionary analysis to discover novel structural and functional properties of Act1. Firstly, we have found that the previously identified helix-loop-helix and Ufd2-box domains in human Act1 have relatively recent evolutionary origins in higher vertebrates. Zebrafish Act1, which lacks these domains, is unable to induce JNK phosphorylation and activate cytokine expression when expressed in human cells. Secondly, we have established that Act1-like proteins contain DEATH-domains in basal animals, such as Hydra and primitive chordates, but lack this domain in vertebrates. Finally, we have shown that Act1-TRAF6 interactions are conserved throughout vertebrate evolution: Act1 derived from zebrafish can bind to TRAF6 and activate NF-κB in human cells. Moreover, we have identified a novel highly conserved motif at the amino-terminus of Act1, which is critical for binding to TRAF6 and activating NF-κB-dependent gene expression. We propose a model of evolutionary changes in Act1-mediated signalling, which contributes to a better understanding of evolution of the vertebrate immunity.