Enhancement of FGF-1 release along with cytosolic proteins from rat astrocytes by hydrogen peroxide.

We previously observed that the production and release of fibroblast growth factor (FGF-1) are increased in rat astrocytes during in vitro long-term culture, that FGF-1 enhances the generation of apoE-containing high density lipoproteins (apoE/HDL), and that the wound healing of brain cryoinjury delays in apoE-deficient mouse. The detail mechanism underlying these phenomena remains unknown. In this study, we examined effects of oxidative stress on release of FGF-1 from cultured rat astrocytes. The treatment of rat astrocytes with 100µM hydrogen peroxide (H2O2) for 10min enhanced FGF-1 release without inducing apoptosis. The conditioned medium prepared from the cells cultured in a fresh medium after the treatment with H2O2 had the FGF-1-like activities, which enhanced cholesterol synthesis, signalings to phosphorylate Akt and ERK, and apoE secretion. The oxidative stress induced by H2O2 enhanced the release of cytosolic proteins such as HSP70 and HSP90 in addition to FGF-1. Antioxidants such as ascorbic acid and ebselen suppressed the release of cytosolic proteins induced by H2O2 treatment. The addition of lipoproteins such as low density lipoproteins (LDL), furthermore, canceled H2O2-induced release of FGF-1 and cytosolic proteins. Proteolysis of cytosolic proteins in the H2O2-treated rat astrocytes was enhanced in the presence of exogenous trypsin, which was attenuated by the pretreatment with LDL, suggesting that H2O2 increases the permeability of the membrane of cells, which was prevented by the addition of lipoproteins. These findings suggest that oxidative stress is one of the candidates which triggers FGF-1 release from astrocytes in the brain, and that the lipid homeostasis in the cell membrane may regulate H2O2-induced release of FGF-1.

Identification of novel isoforms of vitellogenin expressed in ascidian eggs.

Vitellogenin is a precursor of yolk protein that is necessary for embryonic development. This protein is a large multi-domain protein consisting of a signal peptide, a heavy-chain lipovitellin, a phosvitin, a light-chain lipovitellin, a von Willebrand factor type D domain (vWF-D), and a C-terminal coding region (CT), which are processed to respective domains after uptake into oocytes. It is currently believed that only lipovitellin and phosvitin domains are necessary for nutrient supply to oocytes. Thus, molecular species of vitellogenin lacking these domains are not known. Here, we show that two novel isoforms of vitellogenin, both of which possess vWF-D and CT domains but not a lipovitellin or phosvitin domain, are expressed in the gonad of the ascidian Halocynthia roretzi. In situ hybridization revealed that mRNAs of these proteins are specifically expressed in oocytes and test cells, accessory cells in the perivitelline space of ascidian eggs. Immunohistochemistry showed that these proteins are localized around the surface of test cells in immature oocytes. Immunoelectron microscopy revealed that vitellogenin associates with vesicles located beneath the vitelline coat (VC) before fertilization but that it dissociates from the VC after fertilization. These results, together with our previous results showing that vWF-D and CT domains are capable of binding to the two sperm proteases HrProacrosin and HrSpermosin, led us to propose that novel isoforms of vitellogenin, which are expressed in oocytes and test cells and released to the perivitelline space during oocyte maturation, may participate in gamete interaction upon fertilization.

Characterization of O-GlcNAcylation in starfish (Asterina pectinifera) development from fertilization to bipinnaria larva.

Though O-linked ß-N-acetylglucosaminylation (O-GlcNAcylation) of nucleocytoplasmic proteins has been found in many multicellular organisms, its presence or absence in Echinodermata is unknown. Here we report the occurrence of O-GlcNAcylation in starfish (Asterina pectinifera) oocytes and the apparent O-GlcNAcylation pattern in starfish early development. O-GlcNAcylation might participate in the regulation of starfish development at the mid-blastula stage and thereafter.

Localization and copy number of the protein-coding genes actin, alpha-tubulin, and HSP90 in the nucleus of a primitive dinoflagellate, Oxyrrhis marina.

Chromosomes of the dinoflagellate Oxyrrhis marina are composed of thin parallel filaments running longitudinally and lack the arched structure common to the dinochromosome. The physicochemical and molecular organization of these chromosomes, including the localization and arrangement of genes, is still unknown. We investigated the locations of three protein-coding genes, actin (AF482402), alpha-tubulin (AF482403), and HSP90 (AY391258), on these chromosomes using fluorescence in-situ hybridization (FISH). Primers for these three genes were designated according to known partial sequences. PCR products amplified from total DNA were labeled with digoxigenin (DIG) by random priming and used as probes. After in-situ hybridization, DIG signals were amplified and visualized with anti-DIG-FITC. The number of signals was 3 +/- 1.3 (n = 90) for actin, 4.1 +/- 1.4 (n = 70) for alpha-tubulin, and 5.5 +/- 1.7 (n = 80) for HSP90. This study is the first to locate protein-coding genes in the nucleus of a dinoflagellate, although the chromosomes were greatly damaged during the FISH process. The copy number of each gene per cell was estimated using real time PCR. Resulting copy numbers of actin, alpha-tubulin and HSP90 were, 33.7, 10.4 and 5.4, respectively.

Serum amyloid A generates high density lipoprotein with cellular lipid in an ABCA1- or ABCA7-dependent manner.

Serum amyloid A (SAA) is an amphiphilic helical protein that is found associated with plasma HDL in various pathological conditions, such as acute or chronic inflammation. Cellular lipid release and generation of HDL by this protein were investigated, in comparison with the reactions by apolipoprotein A-I (apoA-I) and several types of cells that appear with various specific profiles of cholesterol and phospholipid release. SAA mediated cellular lipid release from these cells with the same profile as apoA-I. Upregulation of cellular ABCA1 protein by liver X receptor/retinoid X receptor agonists resulted in an increase of cellular lipid release by apoA-I and SAA. SAA reacted with the HEK293-derived clones that stably express human ABCA1 (293/2c) or ABCA7 (293/6c) to generate cholesterol-containing HDL in a similar manner to apoA-I. Dibutyryl cyclic AMP and phorbol 12-myristate 13-acetate, which differentiate apoA-I-mediated cellular lipid release between 293/2c and 293/6c, also exhibited the same differential effects on the SAA-mediated reactions. No evidence was found for the ABCA1/ABCA7-independent lipid release by SAA. Characterization of physicochemical properties of the HDL revealed that SAA-generated HDL particles had higher density, larger diameter, and slower electrophoretic mobility than those generated by apoA-I. These results demonstrate that SAA generates cholesterol-containing HDL directly with cellular lipid and that the reaction is mediated by ABCA1 and ABCA7.

Role of microtubules and centrosomes in the eccentric relocation of the germinal vesicle upon meiosis reinitiation in sea-cucumber oocytes.

In the oocytes of many animals, the germinal vesicle (GV) relocates from the center to the periphery of the oocyte upon meiosis reinitiation, which is a prerequisite to the formation of meiotic spindles beneath the cell surface in order for meiosis to succeed. In the present study, we have investigated nuclear positioning using sea-cucumber oocytes. Upon meiosis reinitiation, the GV relocates to the cell periphery beneath a surface protuberance. After GV breakdown, polar bodies were extruded from the top of the protuberance, which we therefore called the animal pole process. The GV relocation was inhibited by nocodazole but not by cytochalasin. Immunofluorescent staining and electron microscopy of microtubular arrays revealed that: (i) in immature oocytes, two centrosomes were situated beneath the animal pole process far apart from the GV, anchoring to the cortex via astral microtubules; (ii) upon meiosis reinitiation, microtubular bundles were newly formed between the centrosomes and the GV; and (iii) the microtubular bundles became short as GV migration proceeded. These observations suggest that microtubules and centrosomes participate in GV relocation. A very large mass of annulate lamellae, having a 20-microm diameter, was found in the vegetal pole of the oocytes.

'Nectosome': a novel cytoplasmic vesicle containing nectin in the egg of the sea urchin, Temnopleurus hardwickii.

Localization of an extracellular matrix protein, Th-nectin, in the eggs and embryos of the sea urchin Temnopleurus hardwickii was examined by both immunofluorescence and immunoelectron microscopy. The protein is associated with a tubular structure packaged in rod-shaped vesicles that were designated as 'nectosomes'. In unfertilized eggs, nectosomes are distributed uniformly throughout the cytoplasm, but after fertilization, they gradually translocate to the cortical zone where they are arranged perpendicular to the plasma membrane. The migration of the nectosomes was strongly inhibited by cytochalasin B, which suggested that microfilaments play an important role in this process. Immunocytochemical and immunoblotting analyses both ascertained that nectin is secreted into the hyaline layer. Some nectosomes remain in the apical cytoplasm of dermal cells until the gastrula stage. Ultrastructural examination revealed that the accumulation of nectosomes in the oocyte cytoplasm begins quite early in oogenesis, concomitant with the accumulation of cortical vesicles.

The protozoa dinoflagellate Oxyrrhis marina contains selenoproteins and the relevant translation apparatus.

In the phylogenetic tree, selenoproteins and the corresponding translation machinery are found in Archaea, Eubacteria, and animals, but not in fungi and higher plants. As very little is known about Protozoa, we searched for the presence of selenoproteins in the primitive dinoflagellate Oxyrrhis marina, belonging to the Protoctista kingdom. Four selenoproteins could be obtained from O. marina cells cultured in the presence of 75Se. Using O. marina or bovine liver cytosolic extracts, we could serylate and selenylate in vitro total O. marina tRNAs. Moreover, the existence of a tRNA(Sec) could be deduced from in vivo experiments. Lastly, an anti-serum against the specialized mammalian translation elongation factor mSelB reacted with a protein of 48-kDa molecular mass. Altogether, our data showed that O. marina contains selenoproteins and suggests that the corresponding translation machinery is related to that found in animals.

Nonequivalence of maternal centrosomes/centrioles in starfish oocytes: selective casting-off of reproductive centrioles into polar bodies.

It is believed that in most animals only the paternal centrosome provides the division poles for mitosis in zygotes. This paternal inheritance of the centrosomes depends on the selective loss of the maternal centrosome. In order to understand the mechanism of centrosome inheritance, the behavior of all maternal centrosomes/centrioles was investigated throughout the meiotic and mitotic cycles by using starfish eggs that had polar body (PB) formation suppressed. In starfish oocytes, the centrioles do not duplicate during meiosis II. Hence, each centrosome of the meiosis II spindle has only one centriole, whereas in meiosis I, each has a pair of centrioles. When two pairs of meiosis I centrioles were retained in the cytoplasm of oocytes by complete suppression of PB extrusion, they separated into four single centrioles in meiosis II. However, after completion of the meiotic process, only two of the four single centrioles were found in addition to the pronucleus. When the two single centrioles of a meiosis II spindle were retained in the oocyte cytoplasm by suppressing the extrusion of the second PB, only one centriole was found with the pronucleus after the completion of the meiotic process. When these PB-suppressed eggs were artificially activated to drive the mitotic cycles, all the surviving single centrioles duplicated repeatedly to form pairs of centrioles, which could organize mitotic spindles. These results indicate that the maternal centrioles are not equivalent in their intrinsic stability and reproductive capacity. The centrosomes with the reproductive centrioles are selectively cast off into the PBs, resulting in the mature egg inheriting a nonreproductive centriole, which would degrade shortly after the completion of meiosis.

Ultrastructural Studies on the Behavior of Centrioles during Meiosis of Starfish Oocytes: (oocyte/meiosis/centriole/starfish).

The behavior of centrioles and ultrastructural changes of the nucleus were observed in maturing oocytes of the starfishes, Asterina pectinifera and Asterias amurensis. Observations were focused on the number and behavior of centrioles during two successive meiotic divisions. Examination of serial sections revealed that in meiosis I each division pole has a pair of centrioles, whereas in meiosis II each has only one centriole, confirming the observations by Sluder et al. (1989) on oocytes of Pisaster ocraceus and Asterias forbesi. The first polar body had two centrioles and the second polar body had only one. These results indicate that no duplication of centrioles occurs during the two successive meiotic divisions, and that the egg inherits one centriole from a primary oocyte.

Fusion of Spermatozoa with Embryonic Cells and Somatic Cells in the Sea Urchin: (fertilization/re-fertilization/acrosome reaction/sea urchin).

Spermatozoa can enter the separated blastomeres of 8- and 16-cell stage embryos, the cells of blastulae and even somatic cells of the oesophagus wall of an adult sea urchin, under certain conditions. In the presence of egg jelly solution, the rate of entrance of spermatozoa is remarkably increased. In the case of the blastomere of 8-cell stage embryos, characteristic cytoplasmic protrusions are formed at the sites of sperm entry, in succession to the formation of the cytoplasmic bulge. These protrusions elongate until 4 min after insemination, and then they retract gradually. The nucleus of penetrated sperm swells and decondenses to form a pronucleus. In most cases, the pronucleus seems to fuse with the preexisting diploid nucleus of the blastomere. When the dissociated oesophagus cells were inseminated, a certain type of the cells was found to fuse with spermatozoa, although the percentage of fused cells was very low.

Induction of the Acrosome Reaction of Sea Urchin Spermatozoa by Means of Urea: (acrosome reaction/spermatozoa/urea/sea urchin).

Urea is an effective reagent for inducing the acrosome reaction of spermatozoa in sea urchins. Urea-treated spermatozoa are capable of fertilizing eggs in Ca-deficient sea water. The pH of the urea solution is an important factor affecting the induction of the acrosome reaction. The reaction occurs at a high percentage in urea Solution at pH's higher than 7.8, while the reaction is almost completely suppressed at pH 7.2. Ca++ is also an important factor for the induction of the reaction, although the minimum concentration required is very low. The acrosomal filament formed in urea solution is similar in shape to that formed in egg-water, when fixed after 10 seconds' urea-treatment. The acrosome granule material is found around the basal portion of the acrosomal filament.

RELATION BETWEEN THE ACROSOME REACTION AND FERTILIZATION IN THE SEA URCHIN. II. FERTILIZATION IN ACIDIFIED SEA WATER WITH EGG-WATER-TREATED SPERMATOZOA.

Fertilization of sea urchin eggs fails to occur at a pH lower than 6.5. Analytical studies on this problem were made with Hemicentrotus pulcherrimus, Anthocidaris crassispina and Pseudocentrotus depressus. If the spermatozoa have been pretreated with egg water, eggs can be fertilized even at pH 6.5 and 6.0. The acrosome reaction is inhibited at a pH lower than 6.5. Intact spermatozoa fail to adhere to the fixed eggs in acidified sea water, whereas egg-water-treated spermatozoa adhere even at pH 6.5 and 6.0. From these results we infer that the failure of fertilization at pH 6.5-6.0 is caused by non-occurrence of the acrosome reaction, and that fertilization reactions other than the acrosome reaction, such as the binding and fusion of the gametes, are not inhibited in this range of pH. At pH 5.5, the spermatozoa become inert and fertilization is inhibited or suppressed, even though egg-water-treated spermatozoa are employed.

SPECIES-SPECIFIC ADHESION OF SPERMATOZOA TO THE SURFACE OF FIXED EGGS IN SEA URCHINS.

When the spermatozoa of sea urchins are added to eggs which have been fixed with glutaraldehyde and washed thoroughly, the spermatozoa swarm around the eggs and adhere to the egg surface. The mode of sperm adhesion to the fixed egg is assumed, on the evidence of electron-microscopical studies, to be the same as that of adhesion to the intact egg at the initial stage of normal fertilization. The spermatozoa and fixed eggs of five species of sea urchins were combined and heterologous crosses were studied. Species-specific adhesion of sperm to fixed eggs was clearly demonstrated. There is a direct relationship between the cross-fertilization of living gametes and the binding capacity of spermatozoa and fixed eggs in so far as the employed five species are concerned.