Identification of promoter elements responsible for gonad-specific expression of zebrafish Deadend and its application to ovarian germ cell derivation.

We discovered that a 150-bp region of zebrafish deadend (dnd) spanning the translation start codon, exon 1 and part of intron 1 is required to direct heterologous neomycin-resistance gene (neo) expression specifically in the gonad, similar to endogenous dnd. Using an 8.3-kb dnd promoter that contains this 150-bp region, we generated Tg(dnd:neo-dnd) transgenic zebrafish in which the expression of Neo was detected specifically in ovarian germ cells. The transgenic fish were used to initiate primary ovarian germ cell cultures with antibiotic G418 to select ovarian germ cells and eliminate ovarian somatic cells. RT-PCR results demonstrated that the drug-selected ovarian germ cells continued to express germ-cell markers nanos3, vasa and dnd. Growth assays demonstrated that recombinant zebrafish Lif had a significant mitogenic effect on the ovarian germ cells. When long-term ovarian germ cell cultures were transplanted into two-week-old infertile larvae, they successfully colonized and directed the formation of a truncated gonad in the recipient adult fish. Histological examination of the recipient adult fish revealed that 9 out of 34 individuals (26%) possessed donor-derived cells in their gonads. The identification of zebrafish dnd promoter and the use of this promoter to generate Tg(dnd:neo-dnd) led to the success of germ cell isolation through drug selection to generate homogenous germ cells that can be used to study zebrafish germ cell biology and may lead to a cell-mediated gene transfer strategy.

Dorsomorphin promotes survival and germline competence of zebrafish spermatogonial stem cells in culture.

Zebrafish spermatogonial cell cultures were established from Tg(piwil1:neo);Tg(piwil1:DsRed) transgenic fish using a zebrafish ovarian feeder cell line (OFC3) that was engineered to express zebrafish Lif, Fgf2 and Gdnf. Primary cultures, initiated from testes, were treated with G418 to eliminate the somatic cells and select for the piwil1:neo expressing spermatogonia. Addition of dorsomorphin, a Bmp type I receptor inhibitor, prolonged spermatogonial stem cell (SSC) survival in culture and enhanced germline transmission of the SSCs following transplantation into recipient larvae. In contrast, dorsomorphin inhibited the growth and survival of zebrafish female germline stem cells (FGSCs) in culture. In the presence of dorsomorphin, the spermatogonia continued to express the germ-cell markers dazl, dnd, nanos3, vasa and piwil1 and the spermatogonial markers plzf and sox17 for at least six weeks in culture. Transplantation experiments revealed that 6 week-old spermatogonial cell cultures maintained in the presence of dorsomorphin were able to successfully colonize the gonad in 18% of recipient larvae and produce functional gametes in the resulting adult chimeric fish. Germline transmission was not successful when the spermatogonia were cultured 6 weeks in the absence of dorsomorphin before transplantation. The results indicate that Bmp signaling is detrimental to SSCs but required for the survival of zebrafish FGSCs in culture. Manipulation of Bmp signaling could provide a strategy to optimize culture conditions of germline stem cells from other species.

Inducible Sterilization of Zebrafish by Disruption of Primordial Germ Cell Migration.

During zebrafish development, a gradient of stromal-derived factor 1a (Sdf1a) provides the directional cue that guides the migration of the primordial germ cells (PGCs) to the gonadal tissue. Here we describe a method to produce large numbers of infertile fish by inducing ubiquitous expression of Sdf1a in zebrafish embryos resulting in disruption of the normal PGC migration pattern. A transgenic line of zebrafish, Tg(hsp70:sdf1a-nanos3, EGFP), was generated that expresses Sdf1a under the control of the heat-shock protein 70 (hsp70) promoter and nanos3 3?UTR. To better visualize the PGCs, the Tg(hsp70:sdf1a-nanos3, EGFP) fish were crossed with another transgenic line, Tg(kop:DsRed-nanos3), that expresses DsRed driven by the PGC-specific kop promoter. Heat treatment of the transgenic embryos caused an induction of Sdf1a expression throughout the embryo resulting in the disruption of their normal migration. Optimal embryo survival and disruption of PGC migration was achieved when transgenic embryos at the 4- to 8-cell stage were incubated at 34.5°C for 18 hours. Under these conditions, disruption of PGC migration was observed in 100% of the embryos. Sixty-four adult fish were developed from three separate batches of heat-treated embryos and all were found to be infertile males. When each male was paired with a wild-type female, only unfertilized eggs were produced and histological examination revealed that each of the adult male fish possessed severely under-developed gonads that lacked gametes. The results demonstrate that inducible Sdf1a expression is an efficient and reliable strategy to produce infertile fish. This approach makes it convenient to generate large numbers of infertile adult fish while also providing the capability to maintain a fertile brood stock.

Production of zebrafish offspring from cultured female germline stem cells.

Zebrafish female germline stem cell (FGSC) cultures were generated from a transgenic line of fish that expresses Neo and DsRed under the control of the germ cell specific promoter, ziwi [Tg(ziwi:neo);Tg(ziwi:DsRed)]. Homogeneous FGSC cultures were established by G418 selection and continued to express ziwi for more than 6 weeks along with the germ cell markers nanos3, dnd, dazl and vasa. A key component of the cell culture system was the use of a feeder cell line that was initiated from ovaries of a transgenic line of fish [Tg(gsdf:neo)] that expresses Neo controlled by the zebrafish gonadal soma derived factor (gsdf) promoter. The feeder cell line was selected in G418 and engineered to express zebrafish leukemia inhibitory factor (Lif), basic fibroblast growth factor (Fgf2) and glial-cell-line derived neurotrophic factor (Gdnf). These factors were shown to significantly enhance FGSC growth, survival and germline competency in culture. Results from cell transplantation experiments revealed that the cultured FGSCs were able to successfully colonize the gonad of sterile recipient fish and generate functional gametes. Up to 20% of surviving recipient fish that were injected with the cultured FGSCs were fertile and generated multiple batches of normal offspring for at least 6 months. The FGSC cultures will provide an in vitro system for studies of zebrafish germ cell growth and differentiation and their high frequency of germline transmission following transplantation could form the basis of a stem cell-mediated strategy for gene transfer and manipulation of the zebrafish genome.

Effects of specific and prolonged expression of zebrafish growth factors, Fgf2 and Lif in primordial germ cells in vivo.

Primordial germ cells (PGCs), specified early in development, proliferate and migrate to the developing gonad before sexual differentiation occurs in the embryo and eventually give rise to spermatogonia or oogonia. In this study, we discovered that nanos3 3'UTR, a common method used to label PGCs, not only directed PGC-specific expression of DsRed but also prolonged this expression up to 26 days post fertilization (dpf) when DsRed-nanos3 3'UTR hybrid mRNAs were introduced into 1- to 2-cell-stage embryos. As such, we employed this knowledge to express zebrafish leukemia inhibitory factor (Lif), basic fibroblast growth factor (Fgf2) and bone morphogenetic protein 4 (Bmp4) in the PGCs and evaluate their effects on PGC development in vivo for over a period of 3 weeks. The results show that expression of Fgf2 significantly increased PGC number at 14- and 21-dpf while Bmp4 resulted in severe ventralization and death of the embryos by 3 days. Expression of Lif resulted in a significant disruption of PGC migration. Mopholino knockdown experiments indicated that Lif illicited its effect on PGC migration through Lif receptor a (Lifra) but not Lifrb. The general approach described in this study could be used to achieve prolonged PGC-specific expression of other proteins to investigate their roles in germ cell and gonad development. The results also indicate that zebrafish PGCs have a mechanism to stabilize and prolong the expression of mRNA that carries nanos3 3'UTR. Understanding this mechanism may make it possible to achieve prolonged RNA expression in other cell types.

Zebrafish germline chimeras produced by transplantation of ovarian germ cells into sterile host larvae.

High frequency production of zebrafish germline chimeras was achieved by transplanting ovarian germ cells into sterile Danio hybrid recipients. Ovarian germ cells were obtained from 3-mo-old adult Tg(vasa:DsRed2-vasa);Tg(bactin:EGFP) double transgenic zebrafish by discontinuous Percoll gradient centrifugation. An average of 755 ± 108 DsRed-positive germ cells was recovered from each female. For transplantations, a total of approximately 620 ± 242 EGFP-positive cells of which 12 ± 4.7 were DsRed-positive germ cells were introduced into the abdominal cavity under the swim bladder of 2-wk-old sterile hybrid larvae. Six weeks after transplantation, a total of 10 recipients, obtained from 2 different transplantations, were examined, and 2 individuals (20%) were identified that possessed a large number of DsRed- and EGFP-positive cells in the gonadal region. The transplanted ovarian germ cells successfully colonized the gonads and differentiated into sperm in the male hybrid recipients. Of 67 adult recipients, 12 (18%) male chimeric fish reproduced and generated normal offspring when paired with wild-type zebrafish females. The fertilization efficiency ranged from 23% to 56%. Although the fertile male chimeras were generated by transplantation of ovarian germ cells, the F1 generation produced by the male chimeras contained both male and female progeny, indicating that male sex determination in zebrafish is not controlled by sex chromosome heterogamy. Our findings indicate that a population of ovarian germ cells that are present in the ovary of adult zebrafish can function as germline stem cells, able to proliferate and differentiate into testicular germ cells and functional sperm in male recipients. The high frequency of germline chimera formation achieved with the ovarian germ cells and the convenience of identifying the chimeras in the sterile host background should make this transplantation system useful for performing genetic manipulations in zebrafish.

A zebrafish cell culture assay for the identification of microRNA targets.

MicroRNAs (miRNAs) are endogenous small noncoding RNAs that regulate gene expression at the posttranscriptional level. Studies have shown that zebrafish miRNAs play a key role in embryo development, tissue fate establishment, and differentiation by interacting with specific targets, usually in the 3'UTR of the mRNA. Identification of the target sequence is fundamental to elucidating miRNA function. Since bioinformatics can predict hundreds of potential targets for each miRNA, experimental validation of the actual target site is required. Although recent studies have employed the HEK293 cell line to investigate mammalian miRNA targets, our results have shown that the cell line is not suitable for studies of zebrafish miR-430b miRNA. In this article we describe a convenient in vitro assay system that involves the use of zebrafish cell cultures and a luciferase reporter construct to evaluate miR-430b target sites. The cell culture-based assay could be used to validate target sequences of other zebrafish miRNAs.

Zebrafish dead end possesses ATPase activity that is required for primordial germ cell development.

Zebrafish dead end (dnd) mRNA is specifically expressed in primordial germ cells (PGCs) and is required for PGC migration and survival. Previous studies have shown that zebrafish Dnd functions by protecting the 3'UTRs of nanos1 and TDRD7 from miR-430b-mediated RNA deadenylation. In this work, we demonstrate that zebrafish Dnd protein possesses Mg(2+)-dependent ATPase activity that is required for PGC formation. Michaelis-Menten analysis revealed that the ATPase has a k(cat) of 0.632 +/- 0.036/min under optimal conditions, and mapping studies using Dnd truncates showed that ATPase resides in the last 91 aa of the Dnd C terminus. Internal deletion and point mutagenesis analysis of this region were used to identify key amino acids required for ATPase activity. Rescue experiments conducted by injecting mRNAs encoding the Dnd ATPase mutants into embryos in which the endogenous dnd expression was inhibited demonstrated that the ATPase activity is required for normal zebrafish PGC survival. Real-time PCR analysis showed that the expression of PGC markers nanos1 and TDRD7 but not vasa were down-regulated when dnd mutant proteins lacking ATPase were expressed in the rescued embryos, indicating that the Dnd ATPase is involved in protecting nanos1 and TDRD7 transcripts.

Zebrafish primordial germ cell cultures derived from vasa::RFP transgenic embryos.

Although embryonic germ (EG) cell-mediated gene transfer has been successful in the mouse for more than a decade, this approach is limited in other species due to the difficulty of isolating the small numbers of progenitors of germ cell lineage (PGCs) from early-stage embryos and the lack of information on the in vitro culture requirements of the cells. In this study, methods were established for the culture of PGCs obtained from zebrafish embryos. Transgenic embryos that express the red fluorescent protein (RFP) under the control of the PGC-specific vasa promoter were used, making it possible to isolate pure populations of PGCs by fluorescence-activated cell sorting (FACS) and to optimize the culture conditions by counting the number of fluorescent PGC colonies produced in different media. Cultures initiated from 26-somite-stage embryos contained the highest percentage of PGCs that proliferated in vitro to generate colonies. The effect of growth factors, including Kit ligand a and b (Kitlga and Kitlgb) and stromal cell-derived factor 1a and 1b (Sdf-1a and Sdf-1b), on PGC proliferation was studied. Optimal in vitro growth and survival of the zebrafish PGCs was achieved when recombinant Kitlga and Sdf-1b were added to the culture medium through transfected feeder cells, resulting in a doubling of the number of PGC colonies. Results from RT-PCR and in situ hybridization analysis demonstrated that PGCs maintained in culture expressed the kita receptor, even though receptor expression was not detected in PGCs isolated by FACS directly from dissociated embryos. In optimal growth conditions, the PGCs continued to proliferate for at least 4 months in culture. The capacity to establish long-term PGC cultures from zebrafish will make it possible to conduct in vitro studies of germ cell differentiation and EG cell pluripotency in this model species and may be valuable for the development of a cell-mediated gene transfer approach.

Initiation of a zebrafish blastula cell line on rainbow trout stromal cells and subsequent development under feeder-free conditions into a cell line, ZEB2J.

A continuous cell line, ZEB2, was developed from zebrafish blastula-stage embryos expressing enhanced green fluorescent protein (GFP). Originally the rainbow trout spleen cell line, RTS34st, was used as feeders to initiate and maintain the cells through several passages. ZEB2 was then grown for 2 years without feeders in L-15 with 15% fetal bovine serum (FBS) for 120 population doublings. This new cell line, ZEB2J, was heteroploid, had detectable telomerase activity, and was adherent. After growing into monolayers, some cells continued to grow into mounds. Cultures expressed Pou-2 mRNA and contained many alkaline phosphatase and a few stage-specific embryonic antigen-1-positive cells. In dishes coated with a phospholipid polymer (2-methacryloxyloxyethyl phosphorylcholine, MPC), ZEB2J formed spherical aggregates. Aggregates attached to conventional culture plastic, and most cells that emerged from aggregates had typical epithelial-like shapes of ZEB2J, which suggests that ZEB2J had limited differentiation potential, despite expressing some stem cell properties. The fluorescence of ZEB2J allowed relationships with feeder cells to be studied. In MPC dishes, ZEB2J formed mixed spheroids with RTS34st. In adherent cocultures, RTS34st and other fish cell lines strongly stimulated the ZEB2J growth, which could be quantified specifically because ZEB2J expressed GFP. ZEB2J should be useful for optimizing culture conditions for zebrafish embryonic stem cells.

Zebrafish embryonic stem cells.

Methods are presented for the derivation of zebrafish embryonic stem (ES) cell cultures that are initiated from blastula and gastrula stage embryos. To maintain pluripotency, the ES cells are cocultured with rainbow trout spleen cells from the RTS34st cell line. ES cells maintained for multiple passages on a feeder layer of growth-arrested RTS34st exhibit in vitro characteristics of pluripotency and produce viable germ cells following transplantation into a host embryo. The ES cells are able to undergo targeted plasmid insertion by homologous recombination, and methods are described for the introduction of a targeting vector by electroporation. Two strategies are described for the efficient isolation of homologous recombinants using a visual marker screen and positive-negative selection.

Homologous recombination in zebrafish ES cells.

Targeted insertion of a plasmid by homologous recombination was demonstrated in zebrafish ES cell cultures. Two selection strategies were used to isolate ES cell colonies that contained targeted plasmid insertions in either the no tail or myostatin I gene. One selection strategy involved the manual isolation of targeted cell colonies that were identified by the loss of fluorescent protein gene expression. A second strategy used the diphtheria toxin A-chain gene in a positive-negative selection approach. Homologous recombination was confirmed by PCR, sequence and Southern blot analysis and colonies isolated using both selection methods were expanded and maintained for multiple passages. The results demonstrate that zebrafish ES cells have potential for use in a cell-mediated gene targeting approach.

The isolation, characterization, and expression of a novel GDF11 gene and a second myostatin form in zebrafish, Danio rerio.

In the current study, the first non-mammalian growth/differentiation factor (GDF) 11-like homolog was cloned from zebrafish. At the nucleotide level, zebrafish GDF11 is most similar to human GDF11 (79%), while the peptide is most similar to mouse GDF11 (78%). Phylogenetic analysis showed that the zebrafish GDF11 clusters with mammalian GDF11s. This study also cloned a second MSTN form in zebrafish most similar to Salmonid MSTN2 forms. Based on real time PCR, GDF11 is expressed in multiple adult tissues, with levels highest in whole heads and gonads, and expression is less ubiquitous when compared to MSTN expression. During embryonic development, real time PCR demonstrated increasing GDF11 mRNA levels 10 h post-fertilization (hpf), while MSTN mRNA levels remain low until 48 hpf. This is the first report of a transforming growth factor (TGF)-beta superfamily member in a non-mammalian species that is more closely related to GDF11 than MSTN, and also a second form of MSTN in zebrafish; suggesting that a more complex TGF-beta superfamily array exists in primitive vertebrates than previously thought.

Identification and characterization of a second fibronectin gene in zebrafish.

Fibronectin (FN) is a highly conserved extracellular matrix protein that plays crucial roles in vertebrate embryogenesis. Previously, it was reported that zebrafish possess a single FN gene (fn1a). Here we report the presence of a second zebrafish FN gene (fn1b) that encodes a protein with a predicted primary structure that is similar to FNs identified in other vertebrates possessing 12 type I, 2 type II and 17 type III repeats including two alternative splice sites (EIIIA and EIIIB) and a variable region (V). Zebrafish FN1b exhibits 62.0% amino acid identity with zebrafish FN1a, 54% with human and 55% with Xenopus laevis FNs respectively. Employing RT-PCR analysis, we demonstrate that EIIIB- and V- isoforms are produced by alternative splicing of a single fn1b transcript. The FN1b EIIIA- isoform was not detected in zebrafish embryos or adult tissues nor were EIIIA, EIIIB or V region splice variants of fn1a found. FN1b mRNA was detected by RT-PCR in embryos at the gastrula-stage (8hpf) through 72hpf and in various adult tissues. EIIIB- and V+ are the predominant forms of FN1b present in the zebrafish embryo. Unlike FN1a, which is present at a relatively high amount at the embryonic stages before gastrulation, the FN1b isoforms are present at very low amounts at the early cleavage stage. The presence of multiple isoforms of FN1b along with a different pattern of expression compared to FN1a indicates that the two fn genes have separate roles in zebrafish development.

Improved phytate phosphorus utilization by Japanese medaka transgenic for the Aspergillus niger phytase gene.

The inefficient digestion of phytate phosphorus by fish has created environmental concerns associated with phosphorus pollution from aquaculture production facilities. To further complicate this situation, phytate is known to chelate minerals and proteins, making them nutritionally unavailable. The enzyme phytase degrades phytate into inorganic phosphorus, which can be directly utilized by fish. As a model to examine the feasibility and efficacy of producing fish capable of degrading phytate, Japanese medaka (Oryzias latipes) transgenic for an Aspergillus niger phytase gene were produced and their ability to utilize phytate phosphorus tested. Cell culture techniques, including transfection, RT-PCR, Northern blot, Western blot, and enzyme activity analysis demonstrated that the protein was expressed, active, and secreted. Survival of transgenic fish was significantly greater on all examined diets than their nontransgenic siblings and up to six-fold higher on a diet with phytate as the main phosphorus source. Similar results were obtained with nontransgenic fish when fed the same diet supplemented with phytase, suggesting that phytase, whether ingested or produced by the fish, is effective in degrading phytate and overcoming many of the known antinutritional factors.

Development of cell cultures with competency for contributing to the zebrafish germ line.

The zebrafish is an established model for the genetic analysis of vertebrate development. Forward-genetic screens have generated thousands of mutations, and antisense-based methods have been used to transiently knockdown gene expression during embryogenesis. Although these methods have made the zebrafish a valuable system for the identification and functional characterization of developmentally important genes, one deficiency of the zebrafish model is the absence of methods to introduce targeted mutations to generate knockout lines of fish. Application of gene-targeting methods has been limited in nonmurine species due to the absence of germ-line competent embryonic stem (ES) cell lines. Recently, progress was made in addressing this problem by the derivation of zebrafish embryo cell lines that remain pluripotent and germ-line competent for multiple passages in culture. Zebrafish germ-line chimeras were generated using cultures derived from embryos at two different developmental stages, and targeted insertion of vector DNA by homologous recombination was demonstrated in both cultures. Several strategies are being used to optimize the production and identification of germ-line chimeras. The zebrafish embryo cell culture system should provide the basis of a gene-targeting approach that will complement other genetic strategies and improve the utility of the zebrafish model for studies of development and disease.