Control of L5178y cell growth by the galactose-specific lectin from Geodia cydonium

The galactose-specific lectin from the sponge Geodia cydonium was determined to cause an increase of the growth rate of L5178y mouse lymphoma cells. The lectin interacts with cell surface components which were solubilized and enriched by affinity chromatography; their Mr's were 170,000, 140,000 and 88,000. Results from Ouchterlony diffusion studies suggest that the cell surface ligand is monovalent. Given to cells in suspension, the lectin causes cell agglutination. This process could be abolished by coincubation with the soluble cell surface ligand. Plating the cells onto substrate-attached lectin resulted in a stimulation of cell spreading. Scatchard analyses revealed that L5178y cells contained 6.3 X 10(7) lectin binding sites with an affinity (Ka) of 1.7 X 10(7) M-1. The binding of the Geodia lectin to the cell surface can be prevented by addition of horse serum. The blocking serum components were isolated by affinity chromatography and determined to consist of six protein species.     

Further characterization of a lectin and its in vivo receptor from Geodia cydonium

From the results of two-dimensional isoelectric focusing, SDS-gel electrophoresis and from immunochemical data it became evident that lectin I and lectin II (corresponding to fractions Geodia I and Geodia II isolated on immobilized lactose) from the sponge Geodia cydonium are apparently identical mixtures of several isolectins, the pI values of their subunits ranging, in contrast to our previous report, from 4.8–7.5. The hypothetical concept of sugar-mediated, specific lectin-lectin interactions (self-recognition) could not be verified by binding of FITC-labelled isolectins (Geodia I) to the lectin subunits, which had been purified by SDS-polyacrylamide gel electrophoresis and blotted onto nitrocellulose membranes. The concept should also be dismissed on the basis of carbohydrate analyses revealing in contradiction with previous results the exclusive presence of alkali-labile bound tetraglucose on the purified isolectins (1 mol/mol lectin protein). The combining site of the isolectins was shown by a quantitative microprecipitation inhibition assay to be most complementar to oligosaccharides of the β-galactoside series and to interact specifically with particular structural elements of the subterminal sugar(s). Carbohydrates of the anti aggregation receptor, which are assumed to represent the functional ligand of the Geodia-isolectins in vivo, could be demonstrated to have a high affinity for the lectin combining site, exceeding that of the best disaccharide inhibitor, lactose, by five orders of magnitude. A preliminary chemical characterization of the receptor carbohydrate revealed that D-galactose and D-glucose (each approx. 200 mol/mol receptor) are organized in an oligosaccharide, which could be cleaved from the protein by trifluoroacetolysis.     

Chromatin structure from the marine sponge Geodia cydonium

The histones isolated from the siliceous sponge Geodia cydonium have been separated using two electrophoretic techniques. A comparison of their mobilities with those of calf thymus and rat liver show that some Geodia histone species (H3, H1 and H1(0) exhibit electrophoretic variance. The results show, that as in other eukaryotic systems the sponge chromatin contains the core histones (H2A, H2B, H3 and H4) and the linker histone (H1). ADP-ribosylation of Geodia histones and separation of the individual histones by electrophoresis resulted in four histones being radiolabeled. Digestion of Geodia chromatin with endogenous endonuclease is shown to result in the formation of nucleosome particles containing approximately 200 base pairs of DNA. A major product of endogenous endonuclease digestion is a relatively stable 110 base pair intermediate. Incubation of chromatin with DNase II and separation of the products under denaturing conditions reveals 20 bands migrating at 10 base intervals.     

Directed migration of cells from the sponge Geodia cydonium

The migration behavior of cells from the sponge Geodia cydonium was studied in vitro, applying the 'Tissue Culture Slide Chamber' technique. The homologous lectin caused a directed cell migration with a maximal locomotory rate of 1.6 mum/min. Competition experiments using the solubilized lectin receptor (= antiaggregation receptor) revealed that the chemotactic ligand (= lectin) interacts directly with the lectin receptor which-in consequence-functions as the chemotactic receptor. The ability of the lectin to promote cell migration is abolished by coincubation with purified leucine aminopeptidase. Biochemical and immunochemical data revealed that this enzyme is present also on the surface of sponge cells. Furthermore, we present evidence that the chemotactic receptor (= anti-aggregation receptor) on the cell surface is, in an hitherto unknown manner, coupled with the intracellularly present actin filaments. From these data we conclude that the directed migration of Geodia cells is mediated by the interaction between the lectin (= chemotactic ligand) and the lectin receptor (= chemotactic receptor); it is very likely that also intracellular structural elements operate simultaneously and coordinately during cell migration.     

Heat-stable protease from the marine sponge Geodia cydonium.

A protease from the marine sponge Geodia cydonium was purified from an aqueous extract by gel filtration and anion-exchange chromatography. A 200-kDa proteolytically active band was obtained when the enzyme was analyzed in gelatin-copolymerized zymograms. The enzyme was also able to degrade casein, bovine collagen, and the synthetic substrate alpha-N-benzoyl-D-arginine p-nitroanilide (BAPNA). Optimal conditions for proteolytic activity were achieved in the presence of 10 mM CaCl2 and within the pH range 7.0 to 8.5. The protease showed an extraordinary heat resistance. The enzyme activity was inhibited by phenylmethylsulphonyl fluoride (PMSF) and N-tosyl-lysine chloromethyl ketone (TLCK), suggesting that the enzyme belongs to the group of serine-type proteases. We propose that the protease is involved in sponge collagen catabolism.     

An intron-less betagamma-crystallin-type gene from the sponge Geodia cydonium

We report the cloning of a gene encoding a betagamma-crystallin-type protein from a porifera, the Geodia cydonium sponge. The data provide direct, conclusive evidence of the existence of such a gene in the genome of an early diverged metazoan. The cloned gene is found to contain no introns, while proto-splice sites are identified in the nucleotide sequence at positions where introns are located in homologous, very recently diverged vertebrate genes. These findings are discussed in the light of the debate between the introns-late and introns-early theories.     

Protein synthesis of the sponge Geodia cydonium: characterization of the system

The ribosomal population of the sponge Geodia cydonium has been examined. The monosomes have a sedimentation constant of 80 S, the sizes of the subunits are approximately 60 S and 45 S respectively. The polyribosomes contain up to 40 ribosomal units. Cell free protein synthesizing systems (cell homogenate as well as reconstituted system) have been prepared and characterized with respect to Mg²⁺, KCI and ATP concentrations, temperature, pH and time course of the reaction. In the cell-free system and in the cellular system the protein biosynthesis is inhibited by chloramphenicol. It is not affected by cycloheximide.     

S-type lectins occur also in invertebrates: High conservation of the carbohydrate recognition domain in the lectin genes from the marine sponge Geodia cydonium

The marine sponge Geodia cydonium contains several lectins.The main component, called lectin-1, is composed of three tofour identical subunits. The subunits of the lectins were clonedfrom a cDNA library; two clones were obtained. From the deducedaa sequence of one clone, LECT-1, a mol. wt of 15 313 Da iscalculated; this value is in good agreement with mass spectrometricanalysis of 15 453 25 Da. The sequence of another clone, LECT-2,was analysed and the aa sequence was deduced (15 433 Da). Thetwo subunits have a framework sequence of 38 conserved aa whichare characteristic for the carbohydrate-binding site of vertebrateS-type lectins. Clustering of lectin sequences of various speciesfollowing their pairwise comparison establishes a dendrogram,which reveals that the sponge lectin could be considered asthe ancestor for vertebrate S-type lectins. Geodia cydonium lectin sponges S-type lectin     

Histochemical reactivity of the Geodia cydonium agglutinin (GCA) in human tissues

We applied a peroxidase-antiperoxidase technique to study the distribution pattern and binding characteristics of the lectin from the marine sponge Geodia cydonium (Geodia cydonium agglutinin; GCA) in various human tissues. This lectin has been shown to possess a broad reactivity, but there was a distinct distribution of binding sites within the different organs. In the histochemical system GCA displayed no blood group specificity and labeled red blood cells, the vascular endothelium, and epithelial cells showing blood group antigen expression independent of the ABH blood group status. However, inhibition of GCA reactivity by simple sugars and complex carbohydrates demonstrated tissue-specific differences of lectin binding related to the ABH blood group status of the tissue and revealed information on the structural requirements of the histological lectin binding site. Tissues that totally lacked blood group antigens or that expressed only the H-antigen disclosed a GCA reactivity which was completely inhibited by lactose. In contrast, tissues that expressed blood group A- or blood group B-antigen exhibited a lactose-resistant lectin binding which was inhibited only by water-soluble blood group substance A from peptone A and by bovine glycophorin but not by other complex carbohydrates, including human glycophorin and human asialoglycophorin. Competitive inhibition studies in situ revealed that GCA binding was not inhibited by blood group type I/II carbohydrate sequence-specific lectins or by lectins with other sugar specificities. Inhibition by lactose of GCA binding to some histological sites indicates that the binding site consists of a beta-linked galactose-containing disaccharide. However, periodate oxidation of tissue sections had no effect on lectin binding, pointing to a subterminal location of the relevant sequence. The results obtained from inhibition studies with simple saccharides and complex carbohydrates in relation to the expression of ABH blood group antigens suggest a complex lectin combining site(s) in histological specimens. The lectin may possess either one binding site with a range of affinities for different carbohydrates (besides beta-linked disaccharides the GCA binding site accommodates to carbohydrate determinants carrying the blood group A or blood group B determinant), or may possess two different binding sites. Besides an acceptor site for beta-linked disaccharides, an additional binding site may exist accommodating to extended carbohydrate sequences related to A or B blood group structures. In conclusion, GCA represents a blood group-nonspecific lectin whose binding affinities are determined by the ABH blood group status of the tissue.     

Genome size and chromosomes in marine sponges [Suberites domuncula,Geodia cydonium]

The genome size of the marine sponges Suberites domuncula and Geodia cydonium has been determined by flow cytofluorometric analysis using diamidino-phenylindole [DAPI]. Using human lymphocytes as reference the amount of DNA in cells from S. domuncula has been determined to be 3.7 pg and that of G. cydonium 3.3 pg. While no chromosomes could be identified in G. cydonium, the karyotype of the Suberites domuncula is 32 chromsomes in the diploid state. The size of the chromosomes was between 0.25 and 1.0 μm. No pronounced banding pattern was visible.     

Epibiontic and endobiontic polychaetes of Geodia cydonium (Porifera,Demospongiae) from the Mediterranean Sea

Polychaete assemblages associated to the sponge Geodia cydonium were investigated at two sampling sites in the Mediterranean Sea: Porto Cesareo Basin (Apulia) and Marsala Lagoon (Sicily), both characterized by sheltered hydrodynamic conditions. Samples were seasonally performed during 1997, in order to compare the assemblages coming from the two localities studied, considering separately the internal and external tissues of the sponge, and with the aim of evaluating the influence of sponge size on polychaete colonization. The examined sponge is characterized by a peculiar stratification of its tissues: an external thick and hard layer, the cortex, and an internal softer one, the choanosome. Statistical analysis showed that this was the main factor controlling polychaete assemblage, with the internal tissue, less rich and diversified, appearing impoverished with respect to the external layer. A similarity in species composition was observed between sites, even though some differences were evidenced in the abundance of some species, mainly reflecting differences in local environmental conditions. Species richness and density increased with the increasing sponge size. Such a situation is particularly evident at Porto Cesareo, where sponges are covered by an algal layer which is particularly rich on the largest specimens, thus suggesting that most of the species of polychaetes were linked more to the neighbouring environment than to the sponge itself.     

Expression and characterization of recombinant 2',5'-oligoadenylate synthetase from the marine sponge Geodia cydonium

2',5'-oligoadenylate (2-5A) synthetases are known as components of the interferon-induced cellular defence mechanism in mammals. The existence of 2-5A synthetases in the evolutionarily lowest multicellular animals, the marine sponges, has been demonstrated and the respective candidate genes from Geodia cydonium and Suberites domuncula have been identified. In the present study, the putative 2-5A synthetase cDNA from G. cydonium was expressed in an Escherichia coli expression system to characterize the enzymatic activity of the recombinant polypeptide. Our studies reveal that, unlike the porcine recombinant 2-5A synthetase, the sponge recombinant protein associates strongly with RNA from E. coli, forming a heterogeneous set of complexes. No complete dissociation of the complex occurs during purification of the recombinant protein and the RNA constituent is partially protected from RNase degradation. We demonstrate that the sponge recombinant 2-5A synthetase in complex with E. coli RNA catalyzes the synthesis of 2',5'-phosphodiester-linked 5'-triphosphorylated oligoadenylates from ATP, although with a low specific activity. Poly(I).poly(C), an efficient artificial activator of the mammalian 2-5A synthetases, has only a minimal effect (an approximate two-fold increase) on the sponge recombinant 2-5A synthetase/bacterial RNA complex activity.     

Tetranectin, a trimeric plasminogen-binding C-type lectin.

Tetranectin, a plasminogen-binding protein belonging to the family of C-type lectins, was expressed in E. coli and converted to its native form by in vitro refolding and proteolytic processing. Recombinant tetranectin-as well as natural tetranectin from human plasma-was shown by chemical cross-linking analysis and SDS-PAGE to be a homo-trimer in solution as are other known members of the collectin family of C-type lectins. Biochemical evidence is presented showing that an N-terminal domain encoded within exons 1 and 2 of the tetranectin gene is necessary and sufficient to govern subunit trimerization.     

Demonstration of an endocrine signaling circuit for insulin in the sponge Geodia cydonium.

The existence of an insulin-mediated cell-to-cell signaling in the sponge Geodia cydonium is demonstrated in this study by molecular biological and immunological techniques. The sequence of a sponge cDNA clone encoding preproinsulin was analyzed for the first time and determined to comprise a high homology to human preproinsulin (60-80% homology). The predicted polypeptide of preproinsulin from sponge contains two disulfide bridges which link the A- to the B-chain. The intra-A chain disulfide bridge is absent. Applying immunological and electron microscopical techniques it is shown that insulin is produced in specialized cells (spherulous cells). Experimental evidence is presented which indicates that the sponge preproinsulin (predicted Mr 11,850) is processed to insulin (Mr 5600; B-chain, Mr 3700 and A-chain, Mr 1900). Plasma membranes of sponge cells are shown to be provided with an insulin-binding receptor composed of two molecules (Mr 104,000 and Mr 98,000). Heterologous insulin (from bovine pancreas) was found to stimulate gene expression in G. cydonium cells. It is concluded that sponges are provided with an endocrine signaling circuit: signaling cells (spherulous cells), hormone (insulin), and hormone receptor bearing target cells which respond to the hormone stimulus.     

Phylogenetic relationship of ubiquitin repeats in the polyubiquitin gene from the marine sponge Geodia cydonium

Ubiquitin is a 76-residue protein which is highly conserved among eukaryotes. Sponge (Porifera) ubiquitin, isolated from Geodia cydonium, is encoded by a gene (termed GCUBI) with six repeats, GCUBI-1 to GCUBI-6. All repeat units encode the same protein (with one exception: GCUBI-4 encodes ubiquitin with a change of Leu to Val at position 71). On the nt level the sequences of the six repeats differ considerably. All changes (except in GCUBI-4) are silent substitutions, which do not affect the protein structure. However, there is one major difference between the repeats: Codons from both codon families (TCN and AGPy) are simultaneously used for the serine at position 65. Using this characteristic the repeats were divided into two groups: Group I: GCUBI-1,3 (TCT codon) and GCUBI-5 (TCC); Group II: GCUBI-2,4,6 (AGC codon). Mutational analysis suggests that the sponge polyubiquitin gene evolved from an ancestral monoubiquitin gene by gene duplication and successive tandem duplications. The ancestral monoubiquitin gene most probably coded for threonine (ACC) at position 65. The first event, duplication of the monoubiquitin gene, happened some 110 million years ago. Since sponges from the genus Geodia are known from the Cretaceous (145 million) to recent time, it is very likely that all events in the evolution of polyubiquitin gene occurred in the same genus. Alignment data of the consensus ubiquitin nt sequences of different animals (man to protozoa) reflect very well the established phylogenetic relationships of the chosen organisms and show that the sponge ubiquitin gene branched off first from the multicellular organisms.Correspondence to: W.E.G. Müller     

Regulated expression and phosphorylation of the 23-26-kDa ras protein in the sponge Geodia cydonium

We have cloned, sequenced and examined the sponge Geodia cydonium cDNA encoding a protein homologous to ras proteins. The sponge ras protein has a more conserved N-terminal region and a less conserved C-terminal region, especially in comparison to Dictyostelium discoideum; the similarity to human c-Ha-ras-1 and to Saccharomyces cerevisiae is less pronounced. The sponge ras cDNA comprises five TAG triplets; at the translational level these UAG termination codons are suppressed by a Gln-tRNA. The sponge ras protein was isolated and partially purified (23-26 kDa) and found to undergo phosphorylation at a threonine moiety, when dissociated cells were incubated in the presence of a homologous aggregation factor and insulin. Insulin-mediated phosphorylation of the ras protein resulted in a decrease in its Kd with GTP from 2 microM to 80 nM. The activated ras protein displayed high GTPase activity if the partially purified protein was incubated with homologous lectin and lectin receptor molecules. These results suggest that in the sponge, ras is activated by the insulin/insulin(insulin-like)-receptor system. This transition enables the ras protein to interact with the lectin-receptor/lectin complex, a process which may ultimately lead to an initiation of an intracellular signal-transduction chain.     

Multiple Ig-like featuring genes divergent within and among individuals of the marine sponge Geodia cydonium

The receptor tyrosine kinase of the marine sponge Geodia cydonium features two extracellular Ig-like domains in which we recently documented RT-PCR polymorphism among individuals. Genomic-PCR analysis presented here revealed 14 unique sequences from four sponges, differing predominantly in the sequence of an intron which splits the Ig-like domains. Nevertheless, analysis of putative coding regions in 19 distinct clones (156–159 aa) from seven sponges revealed 69 positions of nucleotide substitutions, 67.6% of them non-synonymous, translating into 43 positions of divergent residues. Excluding aa deletions, these 19 sequences share pairwise aa identities of 89–99%. In three sponges, four or five unique Ig-like coding regions were scored. PCR amplification across this intron revealed multiple bands, polymorphic among five of six sponges. Further substantiated by Southern and Northern blots, it is evident that the genome of G. cydonium harbors multicopies of moderately divergent Ig-like domains. Presently, this only appears paralleled by the human KIR multigene family of NK cells MHC class I-specific receptors, which consist of two or three moderately divergent extracellular Ig-like domains.     

Comparative sequence analysis of bacterial symbionts from the marine sponges Geodia cydonium and Ircinia muscarum

Marine sponges (Porifera) live in a symbiotic relationship with microorganisms, primarily bacteria. Recently, several studiesindicated that sponges are the most prolific source of biologically-active compounds produced by symbiotic microorganisms ratherthan by the sponges themselves. In the present study we characterized the bacterial symbionts from two Demospongiae, Irciniamuscarum and Geodia cydonium. We amplified 16S rRNA by PCR, using specific bacterial-primers. The phylogenetic analysisrevealed the presence of nine bacterial clones from I. muscarum and ten from G. cydonium. In particular, I. muscarum resultedenriched in Bacillus species and G. cydonium in Proteobacterium species. Since these bacteria were able to produce secondarymetabolites with potential biotechnological and biopharmaceutical applications, we hypothesized that I. muscarum and G. cydoniumcould be a considered as a “gold mine” of natural products.     

Partial purification and properties of a chromatin bound endonuclease from the marine sponge Geodia cydonium

A chromatin bound endonuclease (Mr:107,000) has been extracted and partially purified from the siliceous sponge Geodia cydonium. Disc gel electrophoresis showed that only one enzyme was present in the partially purified preparation which was able to degrade DNA and poly(A). The enzyme liberates oligonucleotides on incubation with poly(A), which are further degraded to yield the 5'-mononucleotide, which has a pI of 6.5 and a pH optimum of 7.5-8.0. Cations are not required for enzymic activity and EDTA does not inhibit the enzyme. Only iodosobenzoic acid was found to completely inhibit the enzyme. The enzyme hydrolysed poly(A), poly(U), poly(C), DNA, poly[d(A-T)], poly[d(G-C)], but not poly (dA) or poly(G).