Koji Akasaka

RSF Governs Silent Chromatin Formation via Histone H2Av Replacement

Human remodeling and spacing factor (RSF) consists of a heterodimer of Rsf-1 and hSNF2H, a counterpart of Drosophila ISWI. RSF possesses not only chromatin remodeling activity but also chromatin assembly activity in vitro. While no other single factor can execute the same activities as RSF, the biological significance of RSF remained unknown. To investigate the in vivo function of RSF, we generated a mutant allele of Drosophila Rsf-1 (dRsf-1). The dRsf-1 mutant behaved as a dominant suppressor of position effect variegation. In dRsf-1 mutant, the levels of histone H3K9 dimethylation and histone H2A variant H2Av were significantly reduced in an euchromatic region juxtaposed with heterochromatin. Furthermore, using both genetic and biochemical approaches, we demonstrate that dRsf-1 interacts with H2Av and the H2Av-exchanging machinery Tip60 complex. These results suggest that RSF contributes to histone H2Av replacement in the pathway of silent chromatin formation.

Sea urchin insulator protects lentiviral vector from silencing by maintaining active chromatin structure.

Suppressed expression of transgenes in vivo is the major obstacle in the gene therapy. For the long-term expression, we utilized a chromatin insulator from sea urchin arylsulfatase (Ars) gene locus (Ars insulator, ArsI), which has been shown to epigenetically regulate gene expression across species. ArsI was able to prevent silencing of the transgene in a myeloid cell line, HL-60, and a murine embryonic stem cell line, CCE, in an orientation-dependent manner, but not in Huh-7, K562 and MCF-7 cells, indicating that the effect of ArsI on gene silencing was cell type dependent. Although anti-silencing effect of ArsI was almost equivalent to that of chicken β-globin insulator, incorporation of ArsI into lentiviral vector had little effect on the virus titer compared with chicken β-globin insulator. Clonal analysis of transduced HL-60 cells revealed that ArsI protects the lentiviral vector from position effects regardless of its orientation. Furthermore, chromatin immunoprecipitation assays revealed that a high acetylation level was observed in the promoter of the insulated vector, whereas that of ArsI was independent of its anti-silencing capacity. In addition to it having little deteriorative effect on the virus titer, the identified anti-silencing effect of ArsI suggested its possibility for application in gene therapy.

Expression patterns of Hox genes in larvae of the sea lily Metacrinus rotundus

We cloned eight Hox genes (MrHox1, MrHox2, MrHox4, MrHox5, MrHox7, MrHox8, MrHox9/10, and MrHox11/13c) from the sea lily Metacrinus rotundus, a member of the most basal group of the extant echinoderms. At the auricularia stage, before the formation of the pentaradial rudiment, four MrHox genes were expressed sequentially along the anteroposterior (AP) axis in the straightened mesodermal somatocoels in the order MrHox5, MrHox7, MrHox8, and MrHox9/10. The expression of MrHox7 and MrHox8 was detected as early as the hatching stage in the presumptive somatocoel region of the archenteral sac. MrHox5 was expressed in the anteriormost region of the somatocoels, where a stalk-related structure (the chambered organ) forms later. In addition to the mesodermal somatocoels, MrHox7 was expressed in the oral hood ectoderm, which gives rise to the adhesive pit. The expression of four other MrHox genes (MrHox1, MrHox2, MrHox4, and MrHox11/13c) was not detected in any of the larval stages we examined. In comparison with the mesodermal sea urchin Hox genes, the MrHox genes are expressed more posteriorly along the AP (oral–anal) axis than the sea urchin orthologs, implying that the evolution of the eleutherozoans was accompanied by a posteriorization of the larval body. Our study illuminates the possible body plan and Hox expression patterns of the ancestral echinoderm and sheds light on the larval body plan of the last common ancestor of the echinoderms and chordates.

Carbonic anhydrase activity in developing sea urchin embryos with special reference to calcification of spicules

Eggs and embryos of the sea urchins Anthocidaris crassispina and Hemicentrotus pulcherrimus did not exhibit significant changes in carbonic anhydrase activity during early development. Acetazolamide inhibited enzyme activity in homogenates of embryos and inhibited the formation of calcified spicules in a culture of micromeres at concentrations between 40 and 100 microM. Acetazolamide allowed intact embryos to develop to quasi-normal plutei but inhibited calcium deposition in the spicules. It is suggested that carbonic anhydrase contributes to CaCO3 deposition in the spicule.

Phylogenomic Analyses of Echinodermata Support the Sister Groups of Asterozoa and Echinozoa

Echinoderms (sea urchins, sea stars, brittle stars, sea lilies and sea cucumbers) are a group of diverse organisms, second in number within deuterostome species to only the chordates. Echinoderms serve as excellent model systems for developmental biology due to their diverse developmental mechanisms, tractable laboratory use, and close phylogenetic distance to chordates. In addition, echinoderms are very well represented in the fossil record, including some larval features, making echinoderms a valuable system for studying evolutionary development. The internal relationships of Echinodermata have not been consistently supported across phylogenetic analyses, however, and this has hindered the study of other aspects of their biology. In order to test echinoderm phylogenetic relationships, we sequenced 23 de novo transcriptomes from all five clades of echinoderms. Using multiple phylogenetic methods at a variety of sampling depths we have constructed a well-supported phylogenetic tree of Echinodermata, including support for the sister groups of Asterozoa (sea stars and brittle stars) and Echinozoa (sea urchins and sea cucumbers). These results will help inform developmental and evolutionary studies specifically in echinoderms and deuterostomes in general.

Sulfated glycan present in the EDTA extract of Hemicentrotus embryos (mid-gastrula)

Light microscopical observations of the Alcian blue-stained gastrulae of Hemicentrotus pulcherrimus together with the scanning electron microscopical observations of the embryos revealed the presence of highly acidic glycans in the invaginating archenteron (inside surface), the surrounding of secondary mesenchyme cells (pseudopodial protrusions and filamentous structures) and the hyaline layer. In the embryos grown in sulfate-free sea water and thus with arrested gastrulation it was found that the dye stainability in the above regions was markedly reduced. The glycosaminoglycan fraction prepared from the whole embryos (mid-gastrulae) was found to contain various kinds of acidic glycans as analysed by chromatography on DEAE-cellulose. Among these glycan components, the F component was mainly recovered in the EDTA extract of the embryos, and was shown to be specifically deleted in the embryos grown in sulfate-free sea water, suggesting that the F component may be related to the Alcian blue-stainable material in Hemicentrotus embryos. The component F was found to consist of sulfated fucan and acid mucopolysaccharide (unidentified) chains, which are probably linked to a common peptide core, forming macromolecules with larger than 10(6) molecular weights.

Cell-surface arylsulfatase A and B on sinusoidal endothelial cells, hepatocytes, and Kupffer cells in mammalian livers

Arylsulfatase A (ARSA) and B (ARSB) have been regarded as lysosomal enzymes because of their hydrolytic activity on synthetic aromatic substrates and the lysosomal localization of their enzymatic activity. Using sea urchin embryos, we previously demonstrated that the bulk of ARS is located on the cell surface of the epithelium, colocalizing with sulfated polysaccharides, and that it does not exhibit enzymatic activity. To examine whether ARSA and ARSB exist on the cell surface in mammalian tissues, we raised antibodies against ARSA and ARSB and examined immunohistochemically their localization in the liver using light and electron microscopy. Here we show that mammalian ARSA and ARSB exist on the cell surface of sinusoidal endothelial cells, hepatocytes, and sinusoidal macrophages (Kupffer cells), as well as in the lysosome. They are also colocalized with heparan sulfate proteoglycan. These results suggest that ARSA and ARSB also may function in the cell surface of mammals. This is the first report to show cell-surface localization of ARS in mammalian somatic cells. The extracellular localization of ARS will provide new insight for human ARS deficiency disorders, such as metachromatic leukodystrophy and mucopolysaccharidosis VI.

HpSulf, a heparan sulfate 6-O-endosulfatase, is involved in the regulation of VEGF signaling during sea urchin development.

Cell surface heparan sulfate proteoglycans (HSPGs) play significant roles in the regulation of developmental signaling, including vascular endothelial growth factor (VEGF), fibroblast growth factor, Wnt and bone morphogenetic protein signaling, through modification of their sulfation patterns. Recent studies have revealed that one of the functions of heparan sulfate 6-O-endosulfatase (Sulf) is to remove the sulfate from the 6-O position of HSPGs at the cell surface, thereby regulating the binding activities of heparan sulfate (HS) chains to numerous ligands and receptors in animal species. In this study, we focused on the sea urchin Hemicentrotus pulcherrimus homolog of Sulf (HpSulf), and analyzed its expression pattern and functions during development. HpSulf protein was present throughout development and localized at cell surface of all blastomeres. In addition, the HS-specific epitope 10E4 was detected at the cell surface and partially colocalized with HpSulf. Knockdown of HpSulf using morpholino antisense oligonucleotides (MO) caused abnormal morphogenesis, and the development of MO-injected embryos was arrested before the hatched blastula stage, indicating that HpSulf is necessary for the early developmental process of sea urchin embryos. Furthermore, we found that injection of HpSulf mRNA suppressed the abnormal skeleton induced by overexpression of HpVEGF mRNA, whereas injection of an inactive form of HpSulf mRNA, containing mutated cysteines in the sulfatase domain, did not have this effect. Taken together, these results suggest that HpSulf is involved in the regulation of various signal transductions, including VEGF signaling, during sea urchin development.

GENERAL PATTERN, 35SO4‐INCORPORATION AND INTRACELLULAR LOCALIZATION OF GLYCANS IN DEVELOPING SEA URCHIN (ANTHOCIDARIS) EMBRYOS

Glycosaminoglycan (GAG) prepared from sea urchin embryos (Anthocidaris crassispina) at various stages with or without pulse 35SO4‐labelling was separated into various fractions by chromatography on DEAE‐cellulose with a linear NaCl concentration gradient: fraction “P” (nonacidic) and fractions “A” through “F” (of increasing acidities). The 35SO4‐radioactivity was negligible in “P” and “A”, largest in “B” and “C”, and decreased in the other fractions three alphabetical order. During development (hatched blastulae to gastrulae) the glycans in fractions “P” and “A” decreased in amount, whereas those in “E” and “F” increased. “E” contained heparin‐like (AMPS‐1) and dermatanpolysulfate‐like (AMPS‐2) GAG in addition to a sulfated fucogalactan‐like (E1) glycan. Another sulfated fucogalactan‐like (F1) glycan was found in “F”. A sulfated polysialic acid‐like (S1) glycan was found in “C”. An EDTA‐extract of gastrulae gave AMPS‐2, E1 and F1. The mitochondria‐rich fraction gave AMPS‐1, whereas the yolk granule‐rich fraction gave S1. Most of the other still unidentified components in “B”, “C”, and “D” appeared to be derived from glycoproteins and were mainly located in the crude yolk‐mitochondrial and cytosol fractions.

Organ-Specific and Age-Dependent Expression of Insulin-like Growth Factor-I (IGF-I) mRNA Variants: IGF-IA and IB mRNAs in the Mouse

Abstract Insulin-like growth factor-I (IGF-I) gene generates several IGF-I mRNA variants by alternative splicing. Two promoters are present in mouse IGF-I gene. Each promoter encodes two IGF-I mRNA variants (IGF-IA and IGF-IB mRNAs). Variants differ by the presence (IGF-IB) or absence (IGF-IA) of a 52-bp insert in the E domain-coding region. Functional differences among IGF-I mRNAs, and regulatory mechanisms for alternative splicing of IGF-I mRNA are not yet known. We analyzed the expression of mouse IGF-IA and IGF-IB mRNAs using SYBR Green real-time RT-PCR. In the liver, IGF-I mRNA expression increased from 10 days of age to 45 days. In the uterus and ovary, IGF-I mRNA expression increased from 21 days of age, and then decreased at 45 days. In the kidney, IGF-I mRNA expression decreased from 10 days of age. IGF-IA mRNA levels were higher than IGF-IB mRNA levels in all organs examined. Estradiol-17β (E2) treatment in ovariectomized mice increased uterine IGF-IA and IGF-IB mRNA levels from 3 hr after injection, and highest levels for both mRNAs were detected at 6 hr, and relative increase was greater for IGF-IB mRNA than for IGF-IA mRNA. These results suggest that expression of IGF-I mRNA variants is regulated in organ-specific and age-dependent manners, and estrogen is involved in the change of IGF-I mRNA variant expression.