Mammalian arylsulfatase A functions as a novel component of the extracellular matrix.

Inherited deficiency for arylsulfatase (Ars) leads to lysosomal storage of sulfated compounds and to serious diseases such as growth retardation, heart failure, and demyelination in the central nervous system. Ars has been regarded as a lysosomal enzyme because of its hydrolytic activity on synthetic aromatic substrates and the lysosomal localization of its enzymatic activity. We previously demonstrated that a large portion of the mammalian arylsulfatase A (ArsA) protein exists on the cell surface of vascular endothelial cells, suggesting that ArsA plays a role in the components of the extracellular matrix. Here we show that ArsA functions as a substrate on which cells adhere and form protrusions. Coating culture plates with recombinant mouse ArsA (rmArsA) stimulates adhesion of human microvascular endothelial cells to the plate followed by the formation of cell protrusions as well as lamellipodia. rmArsA affects the architecture of the cytoskeleton, with a high density of actin filaments localized to peripheral regions of the cells and the extension of bundles of microtubules into the tips of cellular protrusions. rmArsA also affects the distribution pattern of the cell adhesion-associated proteins, integrin α2ß1, and paxillin. rmArsA seems to modulate signaling of basic fibroblast growth factor (bFGF) stimulating cytoskeletal rearrangement. We also show that rmArsA tightly binds to sulfated polysaccharides. We suggest that mammalian ArsA plays a role as a novel component of the extracellular matrix. This viewpoint of Ars could be very useful for clarifying the mechanisms underpinning syndromes caused by the deficiency of the function of Ars genes.

Sea urchin arylsulfatase, an extracellular matrix component, is involved in gastrulation during embryogenesis.

Arylsulfatases (Arses) have been regarded as lysosomal enzymes because of their hydrolytic activities on synthetic aromatic substrates and their lysosomal localization of their enzymatic activities. Using sea urchin embryos, we previously demonstrated that the bulk of Hemicentrotus Ars (HpArs) does not exhibit enzyme activity and is located on the apical surface of the epithelial cells co-localizing with sulfated polysaccharides. Here we show that HpArs strongly binds to sulfated polysaccharides and that repression of the synthesis by HpArs-morpholino results in retardation of gastrulation in the sea urchin embryo. Accumulation of HpArs protein and sulfated polysaccharides on the apical surface of the epithelial cells in sea urchin larvae is repressed by treatment with beta-aminopropionitrile (BAPN), suggesting that deposition of HpArs and sulfated polysaccharides is dependent on the crosslinking of proteins such as collagen-like molecules. We suggest that HpArs functions by binding to components of the extracellular matrix.

Developmental expression of HpNanos, the Hemicentrotus pulcherrimus homologue of nanos.

The Hemicentrotus pulcherrimus homologue of nanos (HpNanos), that encodes a protein containing two CCHC zinc finger motifs, was isolated from a gastrula cDNA library. The accumulation of HpNanos mRNA during embryonic development and the spatial expression pattern are reported. Developmental northern blot analysis revealed that HpNanos mRNA markedly accumulated during the blastula stages, and then decreased in abundance at the mesenchyme blastula stage. The second phase of HpNanos mRNA expression occurred during gastrulation, after which the expression returned to a low level. Whole-mount in situ hybridization showed that the HpNanos was exclusively expressed in four to six small micromere-descendant cells at the blastula stage. The expression of HpNanos was restricted to the coelomic pouch, which gives rise to the mesoderm of the ventral surface of the adult rudiment, at the prism stage. These results suggest that HpNanos expression will be instrumental for future analyses of the function of small micromere-descendant cells and of the origin of germ cells during sea urchin development.

Unichrom, a novel nuclear matrix protein, binds to the Ars insulator and canonical MARs.

Eukaryotic genomic DNA is organized into loop structures by attachments to the nuclear matrix. These attachments to the nuclear matrix have been supposed to form the boundaries of chromosomal DNA. Insulators or boundary elements are defined by two characteristics: they interrupt promoter-enhancer communications when inserted between them, and they suppress the silencing of transgenes stably integrated into inactive chromosomal domains. We recently identified an insulator element in the upstream region of the sea urchin arylsulfatase (HpArs) gene that shows both enhancer blocking and suppression of position effects. Here, we report that Unichrom, originally identified by its G-stretch DNA binding capability, is a nuclear matrix protein that binds to the Ars insulator and canonical nuclear matrix attachment regions (MARs). We also show that Unichrom recognizes the minor groove of the AT-rich region within the Ars insulator, which may have a base-unpairing property, as well as the G-stretch DNA. Furthermore, Unichrom selectively interacts with poly(dG).poly(dC), poly(dA).poly(dT) and poly(dAT).poly(dAT), but not with poly(dGC).poly(dGC). Unichrom also shows high affinity for single-stranded G- and C-stretches. We discuss the DNA binding motif of Unichrom and the function of Unichrom in the nuclear matrix.

Change in the Activity of Na1 , K+ -ATPase in Embryos of the Sea Urchin, Hemicentrotus pulcherrimus, during Early Development: (sea urchin embryo/Na+ , K+ -ATPase/RNA synthesis/ectodermal cell/actinomycin D).

The activity of ouabain-sensitive Na+ , K+ -ATPase in sea urchin embryos at the morula and the swimming blastula stage was practically the same to that in unfertilized eggs. The activity increased during the period between the mesenchyme blastula and the late gastrula stages. In embryo-wall cell fraction, which contained presumptive ectodermal cells as well as those of other cell lineages at the pre-gastrula stage and ectodermal cells at the late gastrula stage, the Na+ , K+ -ATPase activity increased in this developmental period more largely than in another cell fraction, containing mesenchyme cells and archenteron cells. Cycloheximide did not only block the activity increase in this period but also caused evident decrease in the activity in embryos at all examined stages. The activity increase in this period was strongly blocked by the treatment with actinomycin D, starting before the mesenchyme blastula stage, and was not seriously inhibited by the treatment starting at the mesenchyme blastula stage. The treatment starting at the initiation of gastrulation only slightly blocked further increase in the activity. Probably, an accumulation of mRNA encoding Na+ , K+ -ATPase occurs mainly in ectodermal cells and is completed up to the early gastrula stage.

Changes in Insulin-Binding Capacity of the Plasma Membrane Fraction during Culture in vitro of Cells Derived from Micromeres of 16-Cell-Stage Sea Urchin Embryos: (sea urchin/development/micromere/insulin/insulin receptor).

In cultured cells derived from isolated micromeres of 16-cell stage sea urchin embryos, which undergo insulin-induced pseudopodial cable growth, specific and reversible insulin binding by a 52-kDa protein, probably an insulin receptor in the plasma membrane, is augmented during 5 h of culture without any change in the dissociation constant (Kuno et al : 1994). The increase in insulin-binding capacity in micromere-derived cells was only minimally blocked by actinomycin D and cycloheximide, which inhibited [U-3 H]uridine incorporation into RNA and [35 S]methionine incorporation into protein, respectively. Insulin binding capacity was found in the plasma membrane fraction and the microsome fraction of isolated micromeres. The capacity in the plasma membrane fraction increased, accompanied by its decrease in the microsome fraction, during 5 h of culture of micromere-derived cells. The insulin receptor is probably accumulated in microsomes of presumptive micromeres prior to the 16-cell stage and transferred to the plasma membrane, resulting in an increase in the insulin binding capacity of micromere-derived cells during 5 h of culture.

Several Cell Responses to Insulin of Cultured Cells Derived from Micromeres, Isolated from Sea Urchin Embryos at the 16 Cell Stage: (Sea urchin/development/morphogenesis/insulin/micromere).

In micromere-derived cells of sea urchin embryos, treatment with insulin started for up to 24 h during culture at 20°C resulted in augmentation of 32 P incorporation into protein (protein phosphorylation) followed by activation of 32 P incorporation into RNA (RNA synthesis) and then induced pseudopodial cable growth, accompanied by considerable decreases in the rates of protein phosphorylation and RNA synthesis. This augmentation of RNA synthesis and cable growth induced by insulin were blocked by H-7, which inhibited protein phosphorylation, and were also inhibited by actinomycin D without any inhibition of protein phosphorylation. Similar results were obtained on treatment with horse serum, found to contain insulin-like compounds. In cells treated with horse serum treated cells, high rates of protein phosphorylation and RNA synthesis were maintained even after the initiation of cable growth and about 5 h later, spicule rods were produced. Insulin treatment did not induce spicule rod formation. In cells treated with horse serum, actinomycin D treatment started at the time of initiation of cable growth, cables were formed but formation of spicule rods was blocked. These results suggest that horse serum contains some other substance besides insulin-like ones, which induces expression of genes that are indispensable for spicule rod formation.

Expression of Na+ , K+ -ATPase α-Subunit in Animalized and Vegetalized Embryos of the Sea Urchin, Hemicentrotus pulcherrimus.

A marked increase in the Na+ , K+ -ATPase activity of sea urchin embryos occurred following an elevation of its mRNA level, revealed by Northern blotting analysis, in developmental period between the swimming blastula and the late gastrula stage. cDNA clone of Na+ , K+ -ATPase α-subunit, obtained from γgt10 cDNA library of sea urchin gastrulae, was digested with EcoRl ad Hindlll. The obtained 268 bp cDNA fragment, hybridized to a 4.6 Kb RNA, was used as probe for Northern blotting analysis. The level of Na+ , K+ -ATPase mRNA was higher in embryo-wall cell fraction isolated from late gastrulae (ectoderm cells) than the level in the bag fraction, containing mesenchyme cells (mesoderm cells) and archenteron (endoderm cells). The activity of Na+ , K+ -ATPase and the level of its mRNA were higher in animalized embryos obtained by pulse treatment with A23187 for 3 hr, starting at the 8-16 cell stage and were considerably lower in vegetalized embryos induced by 3 hr treatment with Li+ than that in normal embryos at the post gastrula corresponidng stage. Augmentation of Na+ , K+ -ATPase gene expression can be regarded as a marker for ectoderm cell differentiation at the post gastrula stage, which results from determination of cell fate in prehatching period.

Novel structure of hepatic extracellular matrices containing arylsulfatase A.

Arylsulfatase A (ArsA) has been regarded as a lysosomal enzyme involved in the degradation of sulfolipids. We previously reported the colocalization of non-enzymatic ArsA with heparan sulfate proteoglycan on cell surfaces in the mouse liver using tissues processed with phosphate-buffered saline containing Ca2+ and Mg2+. In vitro analysis also revealed the tight binding of ArsA to heparin. These results suggest that ArsA functions as a component of the extracellular matrix (ECM). To characterize ArsA as a component of ECMs, we extended our comparison to the distribution patterns of ArsA and the major hepatic ECM components (types I, III, IV and V collagen, fibronectin, and laminin) in the mouse liver at the ultrastructural level under the same conditions that allow the detection of ArsA. Here, we show that ArsA is distributed not only on the cell surfaces of endothelial cells and hepatocytes, but also on the collagen fibrils in the space of Disse. ArsA is additionally colocalized with these major hepatic ECM components on both the luminal and abluminal sides of sinusoidal endothelial cells as well as in the space of Disse. These findings reveal a novel structure of hepatic ECMs containing ArsA.

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.

The micro1 gene is necessary and sufficient for micromere differentiation and mid/hindgut-inducing activity in the sea urchin embryo.

In the sea urchin embryo, micromeres have two distinct functions: they differentiate cell autonomously into the skeletogenic mesenchyme cells and act as an organizing center that induces endomesoderm formation. We demonstrated that micro1 controls micromere specification as a transcriptional repressor. Because micro1 is a multicopy gene with at least six polymorphic loci, it has been difficult to consistently block micro1 function by morpholino-mediated knockdown. Here, to block micro1 function, we used an active activator of micro1 consisting of a fusion protein of the VP16 activation domain and the micro1 homeodomain. Embryos injected with mRNA encoding the fusion protein exhibited a phenotype similar to that of micromere-less embryos. To evaluate micro1 function in the micromere, we constructed chimeric embryos composed of animal cap mesomeres and a micromere quartet from embryos injected with the fusion protein mRNA. The chimeras developed into dauerblastulae with no vegetal structures, in which the micromere progeny constituted the blastula wall. We also analyzed the phenotype of chimeras composed of an animal cap and a mesomere expressing micro1. These chimeras developed into pluteus larvae, in which the mesomere descendants ingressed as primary mesenchyme cells and formed a complete set of skeletal rods. The hindgut and a part of the midgut were also generated from host mesomeres. However, the foregut and nonskeletogenic mesoderm were not formed in the larvae. From these observations, we conclude that micro1 is necessary and sufficient for both micromere differentiation and mid/hindgut-inducing activity, and we also suggest that micro1 may not fulfill all micromere functions.

The Otx binding site is required for the activation of HpOtxL mRNA expression in the sea urchin, Hemicentrotus pulcherrimus.

Two distinct types of orthodenticle-related (HpOtxE and HpOtxL) mRNA are transcribed from a single HpOtx gene by altering the transcription start site and by alternative splicing, and their expressions are differentially regulated during early development of the sea urchin Hemicentrotus pulcherrimus. To understand the mechanism of this regulation, we screened for the enhancer element involved in the stage-specific expression of HpOtxL mRNA. Different portions of the HpOtx gene, including the 5'-flanking region and the first intron, were ligated to the minimal HpOtxL promoter driving a luciferase gene, and their constructs were introduced into fertilized eggs using a particle gun. The enhancer element responsible for proper expression consistent with that of the endogenous HpOtxL was found in the first intron of the HpOtx gene. External and internal deletion analyses showed that the 334 bp region (from +8838 bp to +9171 bp) was required for enhancer activity. In addition, deletion of an Otx binding site within the 334 bp region markedly reduced reporter expression. These results suggest that the Otx binding site within the HpOtxL enhancer is required for the activation of HpOtxL mRNA expression. The promoter preference of the HpOtxL enhancer is also discussed.

Utilization of a particle gun DNA introduction system for the analysis of cis-regulatory elements controlling the spatial expression pattern of the arylsulfatase gene (HpArs) in sea urchin embryos.

We applied a particle gun method to introduce DNA into fertilized sea urchin eggs for the analysis of cis-regulatory elements responsible for spatial gene expression during development. We introduced HpArs (sea urchin arylsulfatase gene) -GFP and HpArs-LacZfusion constructs into the fertilized eggs and obtained high expression levels of the fusion genes. Using this assay system, we demonstrated that a fragment of HpArs (-3,484 to +4,636) is sufficient for aboral ectoderm-specific expression, and that the region in the first intron from +406 to +1,993 contains the control elements responsible for the repression of the HpArs promoter activity in secondary mesenchyme cells.

A new G-stretch-DNA-binding protein, Unichrom, displays cell-cycle-dependent expression in sea urchin embryos.

We report the identification and characterization of Unichrom, a gene encoding a new G-stretch-DNA-binding protein in the sea urchin embryo. The derived amino acid sequence of Unichrom contains plant homeodomain (PHD) finger and high mobility group (HMG) motifs as well as motifs required for cell-cycle-dependent degradation. The expression of a Unichrom-green fluorescent protein (GFP) fusion protein in sea urchin embryonic cells indicates that Unichrom protein accumulates in nuclei during interphase and disperses into the cytoplasm at mitosis. Overexpression of dominant negative Unichrom, which contains the DNA binding domain lacking the motif for cell-cycle-dependent degradation, causes impairment of chromosome segregation. These results suggest that Unichrom binds to genome DNA at G-stretch and that degradation of Unichrom is required for segregation of chromosomes.

T-brain homologue (HpTb) is involved in the archenteron induction signals of micromere descendant cells in the sea urchin embryo.

Signals from micromere descendants play a crucial role in sea urchin development. In this study, we demonstrate that these micromere descendants express HpTb, a T-brain homolog of Hemicentrotus pulcherrimus. HpTb is expressed transiently from the hatched blastula stage through the mesenchyme blastula stage to the gastrula stage. By a combination of embryo microsurgery and antisense morpholino experiments, we show that HpTb is involved in the production of archenteron induction signals. However, HpTb is not involved in the production of signals responsible for the specification of secondary mesenchyme cells, the initial specification of primary mesenchyme cells, or the specification of endoderm. HpTb expression is controlled by nuclear localization of beta-catenin, suggesting that HpTb is in a downstream component of the Wnt signaling cascade. We also propose the possibility that HpTb is involved in the cascade responsible for the production of signals required for the spicule formation as well as signals from the vegetal hemisphere required for the differentiation of aboral ectoderm.