Tetsuro Morita

Fish eggs as bioreactors: the production of bioactive luteinizing hormone in transgenic trout embryos

We demonstrated the production of goldfish luteinizing hormone (gfLH) by the use of 4-day-old rainbow trout embryos as novel bioreactors. This expression system has several advantages target proteins can be rapidly expressed at low cost, and recombinant proteins can be synthesized at low temperatures and can undergo complex post-translational modifications (PTMs). An expression vector containing gfLH cDNA was microinjected into fertilized trout eggs. After 4 days of incubation at 10°C, transgenic embryos were harvested and glycosylated recombinant gfLH was recovered, which stimulated testosterone production in testicular fragments from the goldfish. This is the first report on the successful production of bioactive recombinant gonadotropin originated from cyprinid. Further, these results demonstrate that trout-embryo bioreactors are a potentially powerful tool for the production of functional recombinant proteins.

Gene knock-down in rainbow trout embryos using antisense morpholino phosphorodiamidate oligonucleotides.

Gene knock-down technology using antisense molecules has many applications for studying gene function, disrupting undesirable genetic traits, as well as providing effective therapy for a number of viral diseases. Encouraged by these applications, we developed a gene knock-down technique to interfere with gene expression using transgenic rainbow trout expressing the green fluorescent protein (GFP) gene as a model. One of the antisense morpholino phosphorodiamidate oligonucleotides (AMOs) used in this study (AtGFP-1) was 25 nucleotides in length and localized against codons 2 to 8 of GFP messenger RNA. Microinjection of AtGFP-1 into the blastodisc of fertilized eggs decreased the level of GFP gene expression in a dose-dependent manner, A comparison of the effects of various doses of AtGFP-1 suggested that 10 ng of AtGFP-1 was the optimal concentration in that it interfered with specific gene expression without being strongly toxic to trout embryos. Conversely, morpholino phosphorodiamidate oligonucleotides with the inverted AtGFP-1 sequence, which cannot bind to the target mRNA, did not inhibit GFP gene expression. AtGFP-1 did not affect the expression of nontargeted genes such as the skeletal muscle actin and foreign lacZ genes. These results also indicate that AtGFP-1 interfered with the expression of only the targeted gene. Western blot and reverse transcriptase polymerase chain reaction analyses revealed that the amount of GFP protein drastically decreased whereas the mRNA level was not affected by AtGFP-1, suggesting that AtGFP-1 blocked specific gene function at the translational level. Further, this gene inhibition persisted until the hatching stage. Another AMO, which was localized against the junction region between the 5? untranslated region and the starting codon of GFP mRNA (AtGFP-2), also caused inhibition effects. Thus AMOs can have potent and specific gene knock-down effects in trout embryos. This technology may be useful for examining the roles of selected genes and disrupting their expression during embryonic development of salmonid fish.

Germ cell transplantation as a potential biotechnological approach to fish reproduction

Although the use of germ cell transplantation has been relatively well established in mammals, the technique has only been adapted for use in fish after entering the 2000s. During the last decade, several different approaches have been developed for germ cell transplantation in fish using recipients of various ages and life stages, such as blastula-stage embryos, newly hatched larvae and sexually mature specimens. As germ cells can develop into live organisms through maturation and fertilization processes, germ cell transplantation in fish has opened up new avenues of research in reproductive biotechnology and aquaculture. For instance, the use of xenotransplantation in fish has lead to advances in the conservation of endangered species and the production of commercially valuable fish using surrogated recipients. Further, this could also facilitate the engineering of transgenic fish. However, as is the case with mammals, knowledge regarding the basic biology and physiology of germline stem cells in fish remains incomplete, imposing a considerable limitation on the application of germ cell transplantation in fish. Furthering our understanding of germline stem cells would contribute significantly to advances regarding germ cell transplantation in fish.

Biological characteristics of fish germ cells and their application to developmental biotechnology.

We have revealed several unique characteristics of germ cell development using rainbow trout, including the fact that spermatogonia transplanted into the peritoneal cavity of newly hatched embryos migrate toward recipient gonads, that spermatogonia transplanted into female recipients start oogenesis and produce functional eggs and that diploid germ cells transplanted into triploid trout can complete gametogenesis. By combining these unique features of fish germ cells, we established allogeneic and xenogeneic transplantation systems for spermatogonia in several fish species. Spermatogonia isolated from the mature testes of vasa-green fluorescent protein (Gfp) transgenic rainbow trout were transplanted into the peritoneal cavity of triploid masu salmon newly hatched embryos. These spermatogonia migrated toward recipient salmon genital ridges with extending pseudopodia and were subsequently incorporated into them. We further confirmed that the donor-derived spermatogonia resumed gametogenesis and produced sperm and eggs in male and female salmon recipients, respectively. By inseminating the resulting eggs and sperm, we obtained only rainbow trout offspring in the F1 generation, suggesting that the triploid salmon recipients produced functional gametes derived only from donor trout. We further confirmed that this intra-peritoneal transplantation of germ cells is applicable to several marine fishes, which could be of benefit in the production of bluefin tuna that has a large broodstock (>100 kg) and is difficult to maintain in captivity. Gamete production of bluefin tuna could be more easily achieved by generating a surrogate species, such as mackerel, that can produce tuna gametes.

Characterization of lymphocyte antigen 75 (Ly75/CD205) as a potential cell-surface marker on spermatogonia in Pacific bluefin tuna Thunnus orientalis

In spermatogonial transplantation using Pacific bluefin tuna Thunnus orientalis as a donor, enrichment of spermatogonia (SG) is expected to facilitate high colonization efficiency. Although it is desirable to establish a bluefin tuna SG enrichment procedure using cell-surface markers, a germ cell-specific cell-surface marker has not been identified to date. We previously found that Ly75 is a mitotic germ cell-specific cell-surface marker in rainbow trout, and that its amino-acid sequences are highly conserved in various teleosts. Thus, the ly75 gene is an excellent candidate cell-surface marker of SG in bluefin tuna. In this study, the bluefin tuna ly75 homolog was cloned and characterized for further use as a germ cell-specific cell-surface marker. In adult tissues, high levels of ly75 transcripts were detected in the liver, pyloric caeca, and testis. In situ hybridization analyses showed that ly75 mRNA was predominantly localized in type-A spermatogonia (A-SG), including single A-SG that contain transplantable germ cells. In contrast, ly75 mRNA was not detected in spermatocytes, spermatids, or gonadal somatic cells in testis. The expression profiles of Ly75 protein were similar to those of the mRNA. Therefore, Ly75 is appropriate for use as a cell-surface marker of SG in bluefin tuna.

The Pacific bluefin tuna (Thunnus orientalis) dead end gene is suitable as a specific molecular marker of type A spermatogonia

We developed a spermatogonial transplantation technique to produce donor‐derived gametes in surrogate fish. Our ultimate aim is to establish surrogate broodstock that can produce bluefin tuna. We previously determined that only type A spermatogonia (ASG) could colonize recipient gonads in salmonids. Therefore, it is necessary to develop a precise molecular marker that can distinguish ASG in order to develop efficient spermatogonial transplantation methods. In this study, the Pacific bluefin tuna (Thunnus orientalis) dead end (BFTdnd) gene was identified as a specific marker for ASG. In situ hybridization and RT‐PCR analysis with various types of spermatogenic cell populations captured by laser microdissection revealed that localization of BFTdnd mRNA was restricted to ASG, and not detected in other differentiated spermatogenic cells. In order to determine if BFTdnd can be used as a molecular marker to identify germ cells with high transplantability, transplantation of dissociated testicular cells isolated from juvenile, immature, and mature Pacific bluefin tuna, which have different proportions of dnd‐positive ASG, were performed using chub mackerel as the surrogate recipient species. Colonization of transplanted donor germ cells was only successful with testicular cells from immature Pacific Bluefin tuna, which contained higher proportions of dnd‐positive ASG than juvenile and mature fish. Thus, BFTdnd is a useful tool for identifying highly transplantable ASG for spermatogonial transplantation. Mol. Reprod. Dev. 80: 871–880, 2013.

Production of recombinant goldfish gonadotropins by baculovirus in silkworm larvae

Recombinant gonadotropins (GTH), follicle-stimulating hormone (FSH) and luteinizing hormone (LH) of goldfish Carassius auratus were produced by baculovirus in silkworm larvae. Hemolymph containing recombinant FSH (rFSH) or LH (rLH) was collected from silkworm larvae, and its biological activity was examined in vivo using male goldfish and female bitterling Rhodeus ocellatus ocellatus. Injection of hemolymph containing rFSH or rLH induced milt production in male goldfish, whereas only rLH induced ovulation in female bitterling. These results suggest, that biologically active goldfish recombinant GTH could be applied for the induction of gonadal development in aquaculture fishes as a substitute of pituitary extract, if a method of large scale production is established.

Production of biologically-active recombinant goldfish gonadotropins in transgenic rainbow trout

The feasibility of using rainbow trout Oncorhynchus mykiss embryos as an expression system for proteins was investigated. For model proteins, we selected two goldfish gonadotropins (GTHs), follicle-stimulating hormone (FSH) and luteinizing hormone (LH). To produce single-chain goldfish FSH (scgfFSH) and LH (scgfLH), cDNAs encoding glycoprotein hormone (GP) α and FSHβ were fused in tandem, and cDNAs encoding GPα and LHβ were fused in tandem. The fused cDNAs were ligated with β-actin promoter, and microinjected into fertilized rainbow trout eggs. After 4-days incubation, the embryos were subjected to western blotting and in vitro bioassays. The recombinant proteins produced by the embryos were immunoreactive to antisera against goldfish GPα, N-glycosylated, and biologically active. We conclude that scgfFSH and scgfLH were successfully produced in transgenic rainbow trout.

Flow-cytometric enrichment of Pacific bluefin tuna type A spermatogonia based on light-scattering properties

We previously established surrogate broodstock in which the donor germ cells transplanted into the peritoneal cavities of xenogeneic recipients were capable of developing into functional eggs and sperm in teleost fish. In this transplantation system, only the undifferentiated germ cells such as type A spermatogonia (ASG) or a portion of the ASG population were capable of being incorporated into the genital ridges of the recipients and undergo gametogenesis. Therefore, the use of enriched ASGs can be expected to achieve efficient donor-cell incorporation. Here, we established a method of isolation and enrichment of the ASG of Pacific bluefin tuna using flow cytometry. Whole testicular cell suspensions were fractionated by forward and side scatter properties, following which ASGs were enriched in a fraction in which the forward scatter signal was relatively high and side scatter signal was relatively low. The diameter of sorted cells using the fraction was identical to the size of ASGs observed in histological analysis, and these cells also expressed the vasa gene. In addition, we succeeded in applying this method to several maturation stages of Pacific bluefin tuna. Since this method was based on light-scattering characteristics of ASGs, it can potentially be applied to various teleosts. We expect that this method can contribute to the production of seeds of Pacific bluefin tuna using surrogate broodstock.