Production of Germ Cell-Less Rainbow Trout by dead end Gene Knockout and their Use as Recipients for Germ Cell Transplantation.

In germ cell transplantation experiments, the use of sterile recipients that do not produce their own gametes is an important prerequisite. Triploidization and dnd gene knockdown (KD) methods have been widely used to produce sterile fish. However, triploidization does not produce complete sterility in some fish species, and gene KD is labor and time intensive since it requires microinjection into individual fertilized eggs. To overcome these problems, in this study, we generated homozygous mutants of the dead end (dnd) gene in rainbow trout (Oncorhynchus mykiss) using the clustered regulatory interspaced short palindromic repeats/CRISPR-associated protein 9 (CRISPR/Cas9) system, analyzed their reproductive capacity, and evaluated their suitability as recipients for germ cell transplantation. By crossing F1 heterozygous mutants produced from founders subjected to genome editing, an F2 generation consisting of approximately 1/4 homozygous knockout mutants (dnd KO) was obtained. The dnd KO hatchlings retained the same number of primordial germ cells (PGCs) as the wild-type (WT) individuals, after which the number gradually decreased. At 1 year of age, germ cells were completely absent in all analyzed individuals. To evaluate the dnd KO individuals as recipients for germ cell transplantation, germ cells prepared from donor individuals were transplanted into the abdominal cavity of dnd KO hatchlings. These cells migrated to the recipient gonads, where they initiated gametogenesis. The mature recipient individuals produced only donor-derived sperm and eggs in equivalent numbers to WT rainbow trout. These results indicate that dnd KO rainbow trout are suitable recipient candidates possessing a high capacity to nurse donor-derived germ cells.

Establishment of novel monoclonal antibodies for identification of type A spermatogonia in teleosts†.

We recently established a germ cell transplantation system in salmonids. Donor germ cells transplanted into the body cavity of recipient embryos migrate toward and are incorporated into the recipient gonad, where they undergo gametogenesis. Among the various types of testicular germ cells, only type A spermatogonia (A-SG) can be incorporated into the recipient gonads. Enriching for A-SG is therefore important for improving the efficiency of germ cell transplantation. To enrich for A-SG, an antibody against a cell surface marker is a convenient and powerful approach used in mammals; however, little is known about cell surface markers for A-SG in fish. To that end, we have produced novel monoclonal antibodies (mAbs) against cell-surface molecules of rainbow trout (Oncorhynchus mykiss) A-SG. We inoculated mice with living A-SG isolated from pvasa-GFP transgenic rainbow trout using GFP-dependent flow cytometry. By fusing lymph node cells of the inoculated mice with myeloma cells, we generated 576 hybridomas. To identify hybridomas that produce mAbs capable of labeling A-SG preferentially and effectively, we screened them using cell ELISA, fluorescence microscopy, and flow cytometry. We thereby identified two mAbs that can label A-SG. By using flow cytometry with these two antibodies, we could enrich for A-SG with transplantability to recipient gonads from amongst total testicular cells. Furthermore, one of these mAbs could also label zebrafish (Danio rerio) spermatogonia. Thus, we expect these monoclonal antibodies to be powerful tools for germ cell biology and biotechnology.

Germ Cell-Specific Excision of loxP-Flanked Transgenes in Rainbow Trout Oncorhynchus mykiss.

Cre/loxP-mediated DNA excision in germ cell lineages could contribute substantially to the study of germ cell biology in salmonids, which are emerging as a model species in this field. However, a cell type-specific Cre/loxPsystem has not been successfully developed for any salmonid species. Therefore, we examined the feasibility of Cre/loxP-mediated, germ cell-specific gene excision and transgene activation in rainbow trout. Double-transgenic (wTg) progeny were obtained by mating a transgenic male carryingcrewith a transgenic female carrying thehsc-LRLGgene;crewas driven by rainbow troutvasaregulatory regions and thehsc-LRLGgene was made up of the rainbow troutheat-shock-cognate71promoter, theDsRedgene flanked by twoloxPsites, and theEgfpgene. PCR analysis, fluorescence imaging, and histological analysis revealed that excision of theloxP-flanked sequence and activation ofEgfpoccurred only in germ cells of wTg fish. However, progeny tests revealed that the excision efficiency ofloxP-flanked sequence in germ cells was low (≤3.27%). In contrast, the other wTg fish derived from two differentcre-transgenic males frequently excised theloxP-flanked sequence in germ cells (≤89.25%). Thus, we showed for the first time successful germ cell-specific transgene manipulation via the Cre/loxPsystem in rainbow trout. We anticipate that this technology will be suitable for studies of cell function through cell targeting, cell-linage tracing, and generating cell type-specific conditional gene knockouts and separately for developing sterile rainbow trout in aquaculture.

Enrichment of spermatogonial stem cells using side population in teleost.

Spermatogenesis originates from a small population of spermatogonial stem cells; this population can maintain continuous sperm production throughout the life of fish via self-renewal and differentiation. Despite their biological importance, spermatogonial stem cells are not thoroughly characterized because they are difficult to distinguish from their progeny cells that become committed to differentiation. We previously established a novel technique for germ cell transplantation to identify spermatogonial stem cells based on their colonizing activity and their ability to initiate donor-derived gametogenesis in the rainbow trout (Oncorhynchus mykiss). Although spermatogonial stem cells can be retrospectively identified after transplantation, there is currently no technique to prospectively enrich for or purify spermatogonial stem cells. Here, we describe a method for spermatogonial stem cell enrichment using a side population. With optimized Hoechst 33342 staining conditions, we successfully identified side-population cells among type A spermatogonia. Side-population cells were transcriptomically and morphologically distinct from non-side-population cells. To functionally determine whether the transplantable spermatogonial stem cells were enriched in the side-population fraction, we compared the colonization activity of side-population cells with that of non-side-population cells. Colonization efficiency was significantly higher with side-population cells than with non-side-population cells or with total type A spermatogonia. In addition, side-population cells could produce billions of sperm in recipients. These results indicated that transplantable spermatogonial stem cells were enriched in the side-population fraction. This method will provide biological information that may advance our understanding of spermatogonial stem cells in teleosts. Additionally, this technique will increase the efficiency of germ cell transplantation used in surrogate broodstock technology.

Combining next-generation sequencing with microarray for transcriptome analysis in rainbow trout gonads.

Microarray technology is a powerful tool for studying genome-wide gene expression. As the genome of many fish has not yet been determined, however, cDNA microarrays can only be designed from limited expressed sequence tag data. In this study, we designed a microarray based on the sequencing data (337,466 reads) obtained by next-generation sequencing of RNA extracted from rainbow trout (Oncorhynchus mykiss) embryonic genital ridge, testis, and ovary. These data (307,264 reads) were assembled into 28,668 contigs; 3,298 reads could not be assembled and 26,904 reads were unique sequences that did not cluster with other reads. Based on this information, 55,928 microarray probes were designed for a microarray, which was validated by hybridization experiments with RNA extracted from type A spermatogonia (A-SG) and testicular somatic cells. Expression of known spermatogonial markers was confirmed to be higher in A-SG than in testicular somatic cells whereas supporting-cell markers were expressed at higher levels in testicular somatic cells. This microarray analysis revealed that 8,068 transcripts showed at least fourfold higher signal in A-SG than testicular somatic cells. Fourteen of 17 randomly selected transcripts were expressed at significantly higher-levels in A-SG than somatic cells, by quantitative RT-PCR. In addition, three transcripts analyzed with in situ hybridization showed A-SG-specific signals in immature trout testis, with one of them exhibiting a heterogeneous expression pattern in A-SG. The rainbow trout gonad microarray developed in this study therefore appears to be a useful tool to understand gametogenesis in rainbow trout.