Toshinobu Tokumoto

Induction and inhibition of oocyte maturation by EDCs in zebrafish

BackgroundOocyte maturation in lower vertebrates is triggered by maturation-inducing hormone (MIH), which acts on unidentified receptors on the oocyte surface and induces the activation of maturation-promoting factor (MPF) in the oocyte cytoplasm. We previously described the induction of oocyte maturation in fish by an endocrine-disrupting chemical (EDC), diethylstilbestrol (DES), a nonsteroidal estrogen.MethodsIn this study, stimulatory and inhibitory effects of EDCs and natural steroids on oocyte maturation were examined in zebrafish. For effective agents, some details about the mechanism in induction or inhibition of maturation were examined. Possible groups of DES interacting with the MIH receptor are discussed based on relative potency of steroids to induce maturation.ResultsAmong agents tested, tamoxifen (TAM) and its metabolite 4-hydroxytamoxifen (4-OHT) showed stimulatory activity similar to DES. The time courses of the change in germinal vesicle breakdown and an intracellular molecular event (the synthesis of cyclin B) induced by TAM were indistinguishable from those induced by MIH. In contrast, pentachlorophenol (PCP) had a potent inhibitory effect on MIH-induced oocyte maturation. PCP inhibited not only MIH-induced maturation but also DES- and TAM-induced maturation. Methoxychlor also inhibited maturation when oocytes were pre-treated with this agent.ConclusionThese results suggest that EDCs act as agonists or antagonists in the induction of oocyte maturation in fish.

Progesterone Is a Sperm-Releasing Factor from the Sperm-Storage Tubules in Birds

Because of the presence of sperm-storage tubules (SST) in the utero-vaginal junction (UVJ) in the oviduct, once ejaculated sperm have entered the female reproductive tract, they can survive for a prolonged time in domestic birds, although the specific mechanisms involved in the sperm uptake into, maintenance within, and controlled release from the SST remain to be elucidated. In this report, we provide evidence that progesterone triggers the release of the resident sperm from the SST in the UVJ. The ultrastructural observation of the SST indicated that the resident sperm are released from the SST around 20 h after oviposition. When laying birds were injected with progesterone, most of the sperm were released from the SST within 1 h of injection. In situ hybridization analyses demonstrated the presence of the transcripts of membrane progestin receptor α in the UVJ, and the translated proteins were detected in the UVJ extracts by Western blotting. Moreover, the number of secretory granules in the SST epithelial cells fluctuates during the ovulatory cycle, and the progesterone administration mimics this phenomena. A binding assay using [(3)H]-progesterone indicated the presence of a high affinity, limited capacity, saturable and single binding site for [(3)H]-progesterone in the membrane fraction of the UVJ, and this receptor did not interact with the synthetic antiprogestin RU486. These results demonstrated for the first time that the progesterone stimulates the release of the resident sperm from the SST and that the release of the sperm might occur via membrane progestin receptor α-mediating signal transduction.

Nature and role of proteasomes in maturation of fish oocytes.

The proteasome is an essential component of the proteolytic pathway in eukaryotic cells and is responsible for the degradation of most cellular proteins. Proteasomes are sorted into two types, 20S and 26S. The 20S proteasome forms the catalytic core of the 26S proteasome. The 26S proteasome is involved in the ubiquitin-dependent protein degradation pathway. Cyclins and cdk inhibitors or c-mos products, proteins critical to the regulation of the cell cycle, are known to be degraded by the ubiquitin pathway. Thus the 26S proteasome is thought to be involved in the regulation of cell cycle events. This review focuses on advances in the study of the biochemical properties and functions of the 20S and 26S proteasomes in the fish meiotic cell cycle.

Possible Function of Caudal Nuclear Pocket Degradation of Nucleoproteins by Ubiquitin-Proteasome System in Rat Spermatids and Human Sperm

Many temporarily functioning proteins are generated during the replacement of nucleoproteins in the nuclei of late spermatids and seem to be degraded in the nucleus. This study was designed to clarify the involvement of the ubiquitin-proteasome degradation system in the nucleus of rat developing spermatids. Thus, we studied the nuclear distribution of polyubiquitinated proteins (pUP) and proteasome in spermiogenic cells and sperm using postembedding immunoelectron microscopy. We divided the nuclear area of late spermatids into two regions: (1) a dense area composed of condensed chromatin and (2) a nuclear pocket in the neck region. The latter was located in the caudal nuclear region and was surrounded by redundant nuclear envelope. We demonstrated the presence of pUP in the dense area and nuclear pocket, proteasome in the nuclear pocket, and clear spots in the dense area of rat spermatids. Using quantitative analysis of immunogold labeling, we found that fluctuation of pUP and proteasome levels in late spermatogenesis was mostly synchronized with disappearance of histones and transitional proteins reported previously. In the nuclei of human sperm, pUP was detected in the dense area, whereas proteasome was in the nuclear vacuoles and clear spots. These results strongly suggest that pUP occur in the dense nuclear area of developing spermatids and that the ubiquitin-proteasome system is more actively operational in the nuclear pocket than dense area. Thus, the nuclear pocket might be the degradation site for temporarily functioning proteins generating during condensation of chromatin in late spermatids.

Sperm proteasome degrades egg envelope glycoprotein ZP1 during fertilization of Japanese quail (Coturnix japonica).

At the time of fertilization, the extracellular matrix surrounding avian oocytes, termed the perivitelline membrane (pvm), is hydrolyzed by a sperm-borne protease, although the actual protease that is responsible for the digestion of the pvm remains to be identified. Here, we show evidence that the ubiquitin-proteasome system is functional in the fertilization of Japanese quail. The activities for the induction of the acrosome reaction and binding to ZP3 as revealed by ligand blotting of purified serum ZP1 are similar to those of pvm ZP1. Western blot analysis of purified ZP1 and ZP3 by the use of the anti-ubiquitin antibody showed that only pvm ZP1 was reactive to the antibody. In vitro penetration assay of the sperm on the pvm indicated that fragments of ZP1 and intact ZP3 were released from the pvm. Western blot analysis using the anti-20S proteasome antibody and ultrastructural analysis showed that immunoreactive proteasome was localized in the acrosomal region of the sperm. Inclusion of specific proteasome inhibitor MG132 in the incubation mixture, or depletion of extracellular ATP by the addition of apyrase, efficiently suppressed the sperm perforation of the pvm. These results demonstrate for the first time that the sperm proteasome is important for fertilization in birds and that the extracellular ubiquitination of ZP1 might occur during its transport via blood circulation.

Identification of the Xenopus 20S proteasome α4 subunit which is modified in the meiotic cell cycle

The proteasomes are large, multi-subunit particles that act as the proteolytic machinery for most of the regulated intracellular protein degradation in eukaryotic cells. To investigate the regulatory mechanism for the 26S proteasome in cell-cycle events, we purified this proteasome from immature and mature oocytes, and compared its subunits. Immunoblot analysis of 26S proteasomes showed a difference in the subunit of the 20S proteasome. A monoclonal antibody, GC3beta, cross-reacted with two bands in the 26S proteasome from immature oocytes (in G2-phase); however, the upper band was absent in the 26S proteasome from mature oocytes (in M-phase). These results suggest that changes in the subunits of 26S proteasomes are involved in the regulation of the meiotic cell cycle. Here we describe the molecular cloning of one of the alpha subunits of the 20S proteasome from a Xenopus ovarian cDNA library using an anti-GC3beta monoclonal antibody. From the screening, two types of cDNA are obtained, one 856bp, the other 984bp long. The deduced amino-acid sequences comprise 247 and 248 residues, respectively. These deduced amino-acid sequences are highly homologous to those of alpha4 subunits of other vertebrates. Phosphatase treatment of 26S proteasome revealed the upper band to be a phosphorylated form of the lower band. These results suggest that a part of the alpha4 subunit of the Xenopus 20S proteasome, alpha4_xl, is phosphorylated in G2-phase and dephosphorylated in M-phase.

Induction of ovulation in Xenopus without hCG injection: the effect of adding steroids into the aquatic environment

BackgroundThe African clawed frog, Xenopus laevis, is widely used in studies of oogenesis, meiotic cell cycle and early embryonic development. However, in order to perform such studies, eggs are normally collected after the injection of hCG into the dorsal lymph sac of fully-grown female frogs following pre-injection of PMSF. Although this protocol is established and used as standard laboratory approach, there are some concerns over whether the injections could cause the transmission of deleterious microorganisms. Moreover, these injection protocols require a competent skilled worker to carry out the procedure efficiently.MethodsRecently, we established a novel method to induce fish ovulation by simply adding the natural maturation-inducing hormone of teleosts, 17 alpha, 20 beta-dihydroxy-4-pregnen-3-one (17,20 beta-DHP), into the surrounding water. In the present study, we demonstrate how we can induce ovulation in frogs using the same methodology.ResultsIn frogs, progesterone was effective in the induction of oocyte maturation in vitro. We then examined the ability of progesterone to induce ovulation in frogs. However treatment of frogs with progesterone alone only occasionally induced ovulation in vivo. The number of oocytes and the frequency of ovulation were significantly lower than that induced by hCG-injection. Thus, conditions were improved by using a combination of progesterone with estradiol and by pre-treating frogs with low concentrations of progesterone or estradiol. Finally, we established an efficient means of inducing ovulation in frogs which involved pre-treatment of frogs with salt solution followed by a mixture of estradiol and progesterone at high concentration. The frequency and numbers of oocytes obtained were identical to those resulting from PMSG-hCG induction. Fertilization rate of eggs ovulated by the new treatment method was comparable to eggs obtained by hCG-injection and juveniles developed normally.ConclusionsTo conclude, we have successfully developed a novel method to induce ovulation in frogs but without the need for a potentially harmful injection strategy.

A major substrate for MPF: cDNA cloning and expression of polypeptide chain elongation factor 1γ from goldfish (Carassius auratus)

One of the eukaryotic polypeptide chain elongation factors, EF-1 g n i complex, is involved in polypeptide chain elongation via the GDP/GTP exchange activity of EF-1 f. In the complex, EF-1 n has been reported to be a major substrate for maturation promoting factor (MPF). Here, we present the cloning, sequencing and expression analysis of goldfish, Carassius auratus, EF-1 n from the goldfish ovary. The cloned cDNA was 1490 u bp in length and encoded 442 amino acids. The deduced amino acid sequence was highly homologous to EF-1 n from other species. Although, the phosphorylation site identified in Xenopus EF-1 n was not conserved in the goldfish homologue, phosphorylation analysis showed that the goldfish EF-1 n was phosphorylated by MPF. We concluded that EF-1 n is a substrate for MPF during oocyte maturation in goldfish.

Regulated interaction between polypeptide chain elongation factor-1 complex with the 26S proteasome during Xenopus oocyte maturation

BackgroundDuring Xenopus oocyte maturation, the amount of a 48 kDa protein detected in the 26S proteasome fraction (p48) decreased markedly during oocyte maturation to the low levels seen in unfertilized eggs. The results indicate that the interaction of at least one protein with the 26S proteasome changes during oocyte maturation and early development. An alteration in proteasome function may be important for the regulation of developmental events, such as the rapid cell cycle, in the early embryo. In this study, we identified p48.Resultsp48 was purified by conventional column chromatography. The resulting purified fraction contained two other proteins with molecular masses of 30 (p30) and 37 (p37) kDa. cDNAs encode elongation factor-1γ and δ were obtained by an immuno-screening method using polyclonal antibodies against purified p48 complex, which recognized p48 and p37. N-terminal amino acid sequence analysis of p30 revealed that it was identical to EF-1β. To identify the p48 complex bound to the 26S proteasome as EF-1βγδ, antibodies were raised against the components of purified p48 complex. Recombinant EF-1 β,γ and δ were expressed in Escherichia coli, and an antibody was raised against purified recombinant EF-1γ. Cross-reactivity of the antibodies toward the p48 complex and recombinant proteins showed it to be specific for each component. These results indicate that the p48 complex bound to the 26S proteasome is the EF-1 complex. MPF phosphorylated EF-1γ was shown to bind to the 26S proteasome. When EF-1γ is phosphorylated by MPF, the association is stabilized.Conclusionp48 bound to the 26S proteasome is identified as the EF-1γ. EF-1 complex is associated with the 26S proteasome in Xenopus oocytes and the interaction is stabilized by MPF-mediated phosphorylation.

Molecular Cloning of cDNA Encoding a 20S Proteasome α2 Subunit from Goldfish (Carassius auratus) and Its Expression Analysis

Abstract Proteasomes are large, multisubunit particles that act as the proteolytic machinery for most regulated intracellular protein breakdown in eukaryotic cells. The core proteinase of this complex, the 20S proteasome, is comprised of four stacked rings with seven subunits each. The outer two rings are made up of seven, distinct α-type subunits, while the two inner rings are composed of seven, different β-type subunits. Here we present the cloning, sequencing and expression analysis of Carassius auratus, α2_ca, which encodes one of the proteasome α subunits from goldfish ovary. The cloned cDNA is 838 bp long and encodes 234 amino acids. The deduced amino acid sequence is highly homologous to α2 subunits from other vertebrates. The expression of mRNA for α2_ca occurs at very high levels in ovary and muscle and moderately high levels in testis, brain and gill. It was also shown that protein content was different from mRNA expression levels.