Stimulation of protein (collagen) synthesis in sponge cells by a cardiac myotrophin‐related molecule from Suberites domuncula

Schröder, Heinz C.; Krasko, Anatoli; Batel, Renato; Skorokhod, Alexander; Pahler, Sabine; Kruse, Michael; Müller, Isabel M.; Müller, Werner

doi:10.1096/fj.00-0043com

Cited by 74 publications

(40 citation statements)

References 50 publications

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“…The data presented above demonstrate that at suitable concentrations silicate induces the genes encoding collagen, silicatein and myotrophin. However, the gene induction of silicatein appears to be a complex process, since the morphogen myotrophin induces only the collagen, but not the silicatein gene Schröder et al 2000). This finding supports earlier observations indicating that the formation of collagen fibrils can proceed independently of spicule formation as well as closely connected with this process (reviewed in: Simpson 1984).…”

Section: Proposed Pathway For Spicule Formationsupporting

confidence: 88%

Molecular Mechanism of Spicule Formation in the Demosponge Suberites domuncula: Silicatein-Collagen-Myotrophin

Müller¹,

Krasko²,

Pennec³

et al. 2003

Silicon Biomineralization

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Section: Proposed Pathway For Spicule Formationsupporting

confidence: 88%

Molecular Mechanism of Spicule Formation in the Demosponge Suberites domuncula: Silicatein-Collagen-Myotrophin

Müller¹,

Krasko²,

Pennec³

et al. 2003

Silicon Biomineralization

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“…Three segments can be distinguished: (i) the N-terminal non-collagen region (aa 1 to aa 26 ); (ii) the region comprising the characteristic G-X-Y collagen triple helix repeats (in COLL3_SUBDO 37 triples; aa 27-136 ); and finally (iii) the non-collagen C-terminal part (aa ). This arrangement has been described also for the other collagen proteins from S. domuncula (15,37). Data bank searches revealed that COLL3_SUBDO shares highest sequence similarity to the fibrillar collagen from Haliotis discus (BAA75668 (38)) with E ϭ 8e Ϫ39 and from…”

Section: Co-expression Of Silicatein With Galectin and Collagensupporting

confidence: 62%

“…Until now, only genes encoding non-fibrillar collagens had been described in sponges, e.g. as for Ephydatia muelleri (40) or S. domuncula (37). The newly discovered S. domuncula collagen displays the typical structure for fibrillar collagens: the N-peptide, the triple helix segment, and the C-peptide.…”

Section: Discussionmentioning

confidence: 99%

Co-expression and Functional Interaction of Silicatein with Galectin

Schröder

Boreiko

Korzhev

et al. 2006

Journal of Biological Chemistry

128

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Sponges (phylum Porifera) of the class of Demospongiae are stabilized by a siliceous skeleton. It is composed of silica needles (spicules), which provide the morphogenetic scaffold of these metazoans. In the center of the spicules there is an axial filament that consists predominantly of silicatein, an enzyme that catalyzes the synthesis of biosilica. By differential display of transcripts we identified additional proteins involved in silica formation. Two genes were isolated from the marine demosponge Suberites domuncula; one codes for a galectin and the other for a fibrillar collagen. The galectin forms aggregates to which silicatein molecules bind. The extent of the silicatein-mediated silica formation strongly increased if associated with the galectin. By applying a new and mild extraction procedure that avoids hydrogen fluoride treatment, native axial filaments were extracted from spicules of S. domuncula. These filaments contained, in addition to silicatein, the galectin and a few other proteins. Immunogold electron microscopic studies underscored the role of these additional proteins, in particular that of galectin, in spiculogenesis. Galectin, in addition to silicatein, presumably forms in the axial canal as well as on the surface of the spicules an organized net-like matrix. In the extraspicular space most of these complexes are arranged concentrically around the spicules. Taken together, these additional proteins, working together with silicatein, may also be relevant for potential (nano)-biotechnological applications of silicatein in the formation of surface coatings. Finally, we propose a scheme that outlines the matrix (galectin/silicatein)-guided appositional growth of spicules through centripetal and centrifugal synthesis and deposition of biosilica.The members of the phylum Porifera (sponges) are grouped according to their mineral skeleton into three classes: Hexactinellida and Demospongiae, which comprise a siliceous skeleton, and Calcarea, with calcareous skeletal materials (1). The elements constituting these skeletons are termed spicules; they are used as systematic characters for a given sponge species (2). Given the comprehensive studies of Bütschli (3) and Minchin (4), a descriptive view of the formation of the siliceous spicules has been well established. In demosponges, where most studies have been performed with Suberites domuncula, spicules are initially formed within specialized cells called sclerocytes (5). S. domuncula has the advantage of containing only macroscleres (tylostyles/oxeas), whereas most other sponges, e.g. Tethya aurantium, contain macroscleres (oxeas) as well as microscleres (spherasters) (6). Spicules have in their center a 1-2-m-wide axial canal (7), which contains the axial filament. In demosponges first siliceous deposits are arranged around this axial filament. When spicules reach lengths of about 10 m they are extruded from the cells. The spicules are completed extracellularly in the mesohyl (8), where they reach final sizes of 10 m (microscleres) and 200 m (mac...

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“…This cDNA was used for expression in Escherichia coli as described. 53,69 The cDNA was inserted into the bacterial oligohistidine expression vector pQE-32 (Quiagen). E. coli (XL1-blue) were transformed with this plasmid and expression of fusion protein was induced with isopropyl 1-thio-b-Dgalactopyranoside (IPTG).…”

Section: Northern Blot Analysismentioning

confidence: 99%

Sponge Bcl-2 homologous protein (BHP2-GC) confers distinct stress resistance to human HEK-293 cells

2001

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It is established that sponges, the phylogenetically oldest still extant phylum of Metazoa, possess key molecules of the apoptotic pathways, that is members from the Bcl-2 family and a pro-apoptotic molecule with death domains. Here we report on transfection studies of human cells with a sponge gene, GCBHP2. Sponge tissue was exposed to heat shock and tributyltin, which caused an upregulation of gene expression of GCBHP2. The cDNA GCBHP2 was introduced into human HEK-293 cells and mouse NIH-3T3 cells; the stable transfection was confirmed by the identification of the transcripts, by Western blotting as well as by immunofluorescence using antibodies raised against the recombinant polypeptide. HEK-293 cells, transfected with GCBHP2, showed high resistance to serum starvation and tributyltin treatment, compared to mock-transfected cells. In contrast to mock-transfected cells, GCBHP2-transfected cells activated caspase-3 to a lower extent. Thus, sponges contain gene(s) involved in apoptotic pathway(s) displaying their function also in human cells. Cell Death and Differentiation (2001) 8, 887 ± 898.

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Stimulation of protein (collagen) synthesis in sponge cells by a cardiac myotrophin‐related molecule from Suberites domuncula

Cited by 74 publications

References 50 publications

Molecular Mechanism of Spicule Formation in the Demosponge Suberites domuncula: Silicatein-Collagen-Myotrophin

Molecular Mechanism of Spicule Formation in the Demosponge Suberites domuncula: Silicatein-Collagen-Myotrophin

Co-expression and Functional Interaction of Silicatein with Galectin

Sponge Bcl-2 homologous protein (BHP2-GC) confers distinct stress resistance to human HEK-293 cells

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