Formation of spicules by sclerocytes from the freshwater sponge Ephydatia muelleri in short-term cultures in vitro.

Cells from the freshwater sponge Ephydatia muelleri were isolated by dissociating hatching gemmules. During the first 24 h the cells reaggregated, but the aggregates progressively disintegrated again to single cells, among which the spicule-forming sclerocytes were recognized. Such cultures were used to study spicule (megascleres) formation in vitro. The isolated sclerocytes formed the organic central axial filament onto which they deposited inorganic silicon. The size of the spicules (200 to 350 microns in length) as well as the rate of spicule formation (1 to 10 microns/h) under in vitro conditions were similar to the values measured in vivo. Immediately after completion of spicule formation, or even before, the sclerocyte could start formation of a new spicule; 5% of the cells were in the process of forming two spicules simultaneously. Cultivation of sclerocytes in the absence of silicon resulted in the formation of the axial filament only. We succeeded in maintaining the sclerocytes in a proliferating and spicule-forming state for up to 3 mo. These results demonstrate that the establishment of short-term cell cultures from E. muelleri is possible; however, future studies must be undertaken to identify the growth factors required for a permanent culture of sponge cells.

Unusual presence and intranuclear storage of silica crystals in the freshwater sponges Ephydatia muelleri and Spongilla lacustris (Porifera: Spongillidae).

Crystal structures have been identified in nuclei of cells from the freshwater sponges Ephydatia muelleri and Spongilla lacustris. Their length is approximately 5 microns and their diameter varies from 0.8 to 1 micron. They occur in several different cell types, among them pinacocytes, cystencytes (E. muelleri) and granulocytes as well as differentiating archaeocytes (S. lacustris). In contrast to earlier reports it is now shown that the crystals are geometrically periodic and anisotropic structures composed of silica. We assume that the crystals play a functional role during differentiation of the cells.

Preparation and karyotype analysis of mitotic chromosomes of the freshwater sponge Spongilla lacustris.

The present study documents for the first time the karyotype and mitotic chromosomes of a sponge. For the studies the freshwater sponge Spongilla lacustris (Lin. 1758) was used. Its karyotype comprises nine different chromosome pairs ranging in size from 2.1 to < or = 0.7 microns. Changes in size and shape of the chromosomes during the progression of mitosis are documented both light and electron microscopically. The data reveal that the lowest multicellular eukaryotes, the sponges, have already reached a high level of evolution of the mitotic mechanism.

Evolution of cell adhesion systems: evidence for Arg-Gly-Asp-mediated adhesion in the protozoan Neoparamoeba aestuarina.

Developmental processes in multicellular organisms require structural elements, such as adhesion molecules, to stabilize cells at functional positions. In vertebrates, a series of extracellular matrix proteins, e.g. fibronectin and laminin, are involved in cell adhesion. These proteins contain Arg-Gly-Asp [RGD] at their binding sites. Here we show that at concentrations above 2 mM the peptide GRGDSPK, comprising the tripeptide RGD (Arg-Gly-Asp), prevents the adhesiveness of cells of the marine amoeba Neoparamoeba aestuarina. In addition, elevated levels of GRGDSPK cause cells to alter their shapes from those with digitiform subpseudopodia to rounded cells with small lobed pseudopodia. These cells detach from the substratum. These results are specific for the RGD sequence, because incubation in GRGESPK solution at the same concentrations had no effect on cell attachment or structure. From these data we suggest that the structural adhesion molecules identified in vertebrates show amino acid homologies with those found in unicellular protozoa.

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 chromosomes in the diploid state. The size of the chromosomes was between 0.25 and 1.0 micron. No pronounced banding pattern was visible.

Expression of P-glycoprotein gene in marine sponges. Identification and characterization of the 125 kDa drug-binding glycoprotein.

In the present paper it is shown that the marine sponges Geodia cydonium and Verongia aerophoba contain the gene coding for P-glycoprotein P170, also known as a multidrug-resistance gene. Western blot studies revealed that polyclonal antibodies raised against hamster P170 cross-react with the sponge polypeptide of Mr 125,000. After endoglycosidase F treatment, the sponge P125 is converted to a polypeptide of Mr 105,000. Northern blot studies, using the human P170 cDNA probe, revealed a size of 4.2 kb for the sponge P125 transcript. The level of this transcript does not change in response to incubation with the aggregation factor. Confocal laser scanning microscopy showed that P125 is a cell membrane bound protein. In addition, sponge membrane vesicles possess a potential to bind in vitro 2-acetylamino-fluorene, vincristine and daunomycin. This process is Verapamil-sensitive, a characteristic known also for the mammalian vesicle associated P170. The data reported demonstrate that the classical multidrug resistance mechanism, described in drug-resistant tumor cell lines, functions also in sponges and may explain the relative resistance of these animals to pollution.