The active stem cell specific expression of sponge Musashi homolog EflMsiA suggests its involvement in maintaining the stem cell state.

A hallmark of stem cells is the ability to sustainably generate stem cells themselves (self-renew) as well as differentiated cells. Although a full understanding of this ability will require clarifying underlying the primordial molecular and cellular mechanisms, how stem cells maintain their stem state and their population in the evolutionarily oldest extant multicellular organisms, sponges, is poorly understood. Here, we report the identification of the first stem cell-specific gene in demosponges, a homolog of Musashi (an evolutionarily conserved RNA binding protein that regulates the stem cell state in various organisms). EflMsiA, a Musashi paralog, is specifically expressed in stem cells (archeocytes) in the freshwater sponge Ephydatia fluviatilis. EflMsiA protein is localized predominantly in the nucleus, with a small fraction in the cytoplasm, in archeocytes. When archeocytes enter M-phase, EflMsiA protein diffuses into the cytoplasm, probably because of the breakdown of the nuclear membrane. In the present study, the existence of two types of M-phase archeocytes [(M)-archeocytes] was revealed by a precise analysis of the expression levels of EflMsiA mRNA and protein. In Type I (M)-archeocytes, presumably archeocytes undergoing self-renewal, the expression levels of EflMsiA mRNA and protein were high. In Type II (M)-archeocytes, presumably archeocytes committed to differentiate (committed archeocytes), the expression levels of EflMsiA mRNA and protein were about 60% and 30% lower than those in Type I (M)-archeocytes. From these results, archeocytes can be molecularly defined for the first time as EflMsiA-mRNA-expressing cells. Furthermore, these findings shed light on the mode of cell division of archeocytes and suggest that archeocytes divide symmetrically for both self-renewal and differentiation.

Piwi expression in archeocytes and choanocytes in demosponges: insights into the stem cell system in demosponges.

Little is known about the stem cells of organisms early in metazoan evolution. To characterize the stem cell system in demosponges, we identified Piwi homologs of a freshwater sponge, Ephydatia fluviatilis, as candidate stem cell (archeocyte) markers. EfPiwiA mRNA was expressed in cells with archeocyte cell morphological features. We demonstrated that these EfPiwiA-expressing cells were indeed stem cells by showing their ability to proliferate, as indicated by BrdU-incorporation, and to differentiate, as indicated by the coexpression of EfPiwiA with cell-lineage-specific genes in presumptive committed archeocytes. EfPiwiA mRNA expression was maintained in mature choanocytes forming chambers, in contrast to the transition of gene expression from EfPiwiA to cell-lineage-specific markers during archeocyte differentiation into other cell types. Choanocytes are food-entrapping cells with morphological features similar to those of choanoflagellates (microvillus collar and a flagellum). Their known abilities to transform into archeocytes under specific circumstances and to give rise to gametes (mostly sperm) indicate that even when they are fully differentiated, choanocytes maintain pluripotent stem cell-like potential. Based on the specific expression of EfPiwiA in archeocytes and choanocytes, combined with previous studies, we propose that both archeocytes and choanocytes are components of the demosponge stem cell system. We discuss the possibility that choanocytes might represent the ancestral stem cells, whereas archeocytes might represent stem cells that further evolved in ancestral multicellular organisms.

Toward understanding the morphogenesis of siliceous spicules in freshwater sponge: differential mRNA expression of spicule-type-specific silicatein genes in Ephydatia fluviatilis.

Siliceous spicules of sponges are morphologically diverse and provide good models for understanding the morphogenesis of biomineralized products. The silica deposition enzyme silicatein is a component of siliceous spicules of sponges and is thought to be the key molecule determining the morphology of spicules. Here, we focused on the silicateins of the freshwater sponge Ephydatia fluviatilis, which has two types of morphologically and functionally different spicules, called megascleres and gemmoscleres. We isolated six isoforms of silicateins and examined their mRNA expression in the cells producing megascleres and gemmoscleres. The spicule-type-specific mRNA expression of these isoforms and differential expression during spicule development suggest that the characteristic morphology of spicules is due to the specific properties and combinatory functions of silicatein isoforms.

Isolation of Ef silicatein and Ef lectin as molecular markers for sclerocytes and cells involved in innate immunity in the freshwater sponge Ephydatia fluviatilis.

Sponges (phylum Porifera) have remarkable regenerative and reconstitutive abilities and represent evolutionarily the oldest metazoans. To investigate sponge stem cell differentiation, we have focused on the asexual reproductive system in the freshwater sponge Ephydatia fluviatilis. During germination, thousands of stem cells proliferate and differentiate to form a fully functional sponge. As an initial step of our investigation of stem cell (archeocyte) differentiation, we isolated molecular markers for two differentiated cell types: spicule-making sclerocyte cells, and cells involved in innate immunity. Sclerocyte lineage-specific Ef silicatein shares 45% to 62% identity with other sponge silicateins. As in situ hybridization of Ef silicatein specifically detects archeocytes possibly committed to sclerocytes, as well as sclerocytes with an immature or mature spicule, therefore covering all the developmental stages, we conclude that Ef silicatein is a suitable sclerocyte lineage marker. Ef lectin, a marker for the cell type involved in innate immunity, shares 59% to 65% identity with the marine sponge Suberites domuncula galactose-binding protein (Sd GBP) and horseshoe crab Tachypleus tridentatus tachylectin1/lectinL6. Since Sd GBP and tachylectin1 are known to bind to bacterial lipopolysaccharides and inhibit the growth of bacteria, Ef lectin may have a similar function and be expressed in a specialized type of cell involved in defense against invading bacteria. Ef lectin mRNA and protein are not expressed in early stages of development, but are detected in late stages. Therefore, Ef lectin may be specifically expressed in differentiating and/or differentiated cells. We suggest Ef lectin as a marker for cells that assume innate immunity in freshwater sponges.

Isolation of the choanocyte in the fresh water sponge, Ephydatia fluviatilis and its lineage marker, Ef annexin.

In order to investigate the cellular system of the freshwater sponge, Ephydatia fluviatilis, we isolated a molecular marker for the most prominent cell type, the choanocyte. After feeding sponge with fluorescent beads, fluorescent-labeled choanocytes were collected by fluorescence activated cell sorting (FACS). By protein profiling choanocyte and archeocyte (stem cell)-rich fractions, proteins characteristic of choanocyte were identified. The partial amino-acid sequence of one of the proteins characteristic of choanocyte matches the deduced amino-acid sequence of sponge expression tag (EST) clones and mouse annexin VII. These EST clones overlap and encode a protein, designated Ef annexin, which includes four annexin domains. Whole mount in situ hybridization shows Ef annexin expression in chamber-forming choanocytes in 7-day-old sponge, leading us to conclude that Ef annexin can be used as a choanocyte marker. In the early development stage, Ef annexin expression can be detected in both large single cells, characteristic of archeocytes, and cells forming 2-, 4- and multiple-cell clusters. These results indicate that Ef annexin is initially expressed in the choanocyte-committed archeocyte which then undergoes several mitotic cell divisions to form a choanocyte chamber. This suggests that the single choanocyte chamber essentially originates from a single archeocyte.

[The molecular genetics of rheumatoid arthritis disease gene].

Rheumatoid arthritis(RA) is a chronic polyarthritis of unknown etiology affecting approximately 1% of the population worldwide. Previous studies have shown that the ratio of the risk for siblings of patients with the disease versus the prevalence of that disease in the general population (lambda s) is much greater in RA, suggesting that genetic factors may be involved in familial clustering. Using microsatellite marker analysis and sib-pair linkage study, we have identified three chromosome regions D1S214/253, D8S556 and DXS1232/984 as candidate loci for RA disease genes. In this article, we review the molecular genetic findings on the RA disease genes located respectively at each of the above chromosome regions. We show that the death receptor 3(DR3) gene, a Fas family member, containing nucleotide polymorphism is the candidate disease gene located at D1S214/253. We also identify the mutant forms of angiopoietin-1(Ang-1) and Dbl proto-oncogenes respectively as the candidate genes located at D8S556 and DXS1232/984. We surmise that these mutations are responsible for the impairment of apoptosis induction, angiogenesis and leukocyte function in the patients, which may predispose to autoimmunity.