Sexually dimorphic dynamics of the microtubule network in medaka (Oryzias latipes) germ cells.

Gametogenesis is the process through which germ cells differentiate into sexually dimorphic gametes, eggs and sperm. In the teleost fish medaka (Oryzias latipes), a germ cell-intrinsic sex determinant, foxl3, triggers germline feminization by activating two genetic pathways that regulate folliculogenesis and meiosis. Here, we identified a pathway involving a dome-shaped microtubule structure that may be the basis of oocyte polarity. This structure was first established in primordial germ cells in both sexes, but was maintained only during oogenesis and was destabilized in differentiating spermatogonia under the influence of Sertoli cells expressing dmrt1. Although foxl3 was dispensable for this pathway, dazl was involved in the persistence of the microtubule dome at the time of gonocyte development. In addition, disruption of the microtubule dome caused dispersal of bucky ball RNA, suggesting the structure may be prerequisite for the Balbiani body. Collectively, the present findings provide mechanistic insight into the establishment of sex-specific polarity through the formation of a microtubule structure in germ cells, as well as clarifying the genetic pathways implementing oocyte-specific characteristics.

Generation, characterization, and differentiation of induced pluripotent stem-like cells in the domestic cat.

Induced pluripotent stem (iPS) cells are generated from somatic cells and can differentiate into various cell types. Therefore, these cells are expected to be a powerful tool for modeling diseases and transplantation therapy. Generation of domestic cat iPS cells depending on leukemia inhibitory factor has been reported; however, this strategy may not be optimized. Considering that domestic cats are excellent models for studying spontaneous diseases, iPS cell generation is crucial. In this study, we aimed to derive iPS cells from cat embryonic fibroblasts retrovirally transfected with mouse Oct3/4, Klf4, Sox2, and c-Myc. After transfection, embryonic fibroblasts were reseeded onto inactivated SNL 76/7 and cultured in a medium supplemented with basic fibroblast growth factor. Flat, compact, primary colonies resembling human iPS colonies were observed. Additionally, primary colonies were more frequently observed in the KnockOut Serum Replacement medium than in the fetal bovine serum (FBS) medium. However, enhanced maintenance and proliferation of iPS-like cells occurred in the FBS medium. These iPS-like cells expressed embryonic stem cell markers, had normal karyotypes, proliferated beyond 45 passages, and differentiated into all three germ layers in vitro. Notably, expression of exogenous Oct3/4, Klf4, and Sox2 was silenced in these cells. However, the iPS-like cells failed to form teratomas. In conclusion, this is the first study to establish and characterize cat iPS-like cells, which can differentiate into different cell types depending on the basic fibroblast growth factor.

foxl3, a sexual switch in germ cells, initiates two independent molecular pathways for commitment to oogenesis in medaka.

Germ cells have the ability to differentiate into eggs and sperm and must determine their sexual fate. In vertebrates, the mechanism of commitment to oogenesis following the sexual fate decision in germ cells remains unknown. Forkhead-box protein L3 (foxl3) is a switch gene involved in the germline sexual fate decision in the teleost fish medaka (Oryzias latipes). Here, we show that foxl3 organizes two independent pathways of oogenesis regulated by REC8 meiotic recombination protein a (rec8a), a cohesin component, and F-box protein (FBP) 47 (fbxo47), a subunit of E3 ubiquitin ligase. In mutants of either gene, germ cells failed to undergo oogenesis but developed normally into sperm in testes. Disruption of rec8a resulted in arrest at a meiotic pachytenelike stage specifically in females, revealing a sexual difference in meiotic progression. Analyses of fbxo47 mutants showed that this gene regulates transcription factors that facilitate folliculogenesis: LIM homeobox 8 (lhx8b), factor in the germline α (figla), and newborn ovary homeobox (nobox). Interestingly, we found that the fbxo47 pathway ensures that germ cells do not deviate from an oogenic pathway until they reach diplotene stage. The mutant phenotypes together with the timing of their expression imply that germline feminization is established during early meiotic prophase I.

Seasonal changes in NRF2 antioxidant pathway regulates winter depression-like behavior.

Seasonal changes in the environment lead to depression-like behaviors in humans and animals. The underlying mechanisms, however, are unknown. We observed decreased sociability and increased anxiety-like behavior in medaka fish exposed to winter-like conditions. Whole brain metabolomic analysis revealed seasonal changes in 68 metabolites, including neurotransmitters and antioxidants associated with depression. Transcriptome analysis identified 3,306 differentially expressed transcripts, including inflammatory markers, melanopsins, and circadian clock genes. Further analyses revealed seasonal changes in multiple signaling pathways implicated in depression, including the nuclear factor erythroid-derived 2-like 2 (NRF2) antioxidant pathway. A broad-spectrum chemical screen revealed that celastrol (a traditional Chinese medicine) uniquely reversed winter behavior. NRF2 is a celastrol target expressed in the habenula (HB), known to play a critical role in the pathophysiology of depression. Another NRF2 chemical activator phenocopied these effects, and an NRF2 mutant showed decreased sociability. Our study provides important insights into winter depression and offers potential therapeutic targets involving NRF2.

Zygotic nanos3 Mutant Medaka (Oryzias latipes) Displays Gradual Loss of Germ Cells and Precocious Spermatogenesis During Gonadal Development.

Nanos is one of the components of germ plasm and is evolutionarily conserved from flies to mammals. In medaka (Oryzias latipes), maternally provided nanos3 is essential for maintenance of primordial germ cells (PGCs). Here, we generated nanos3 loss-of-function mutants by using transcription activator-like effector nuclease (TALEN) and examined the function of zygotic nanos3 in medaka. Zygotic nanos3 homozygous (-/-) mutants derived from nanos3 heterozygous mothers formed germ cells. However, after hatching, the number of germ cells decreased considerably, resulting in infertility of both nanos3-/- females and males. Surprisingly, both nanos3-/- XX and XY mutants underwent precocious spermatogenesis during early gonadal development, as seen in loss-of-function mutants of foxl3, the germline sex-determination gene, in medaka. Therefore, in addition to the maintenance of germ cells, these results suggest that zygotic nanos3 affects the proper regulation of germline sex in XX medaka.

Dynamics of Spermatogenesis and Change in Testicular Morphology under 'Mating' and 'Non-Mating' Conditions in Medaka (Oryzias latipes).

Here, we report that the gross morphology of the testes changes under 'non-mating' or 'mating' conditions in medaka (Oryzias latipes). During these conditions, an efferent duct expands and a histological unit of spermatogenesis, the lobule, increases its number under 'non-mating' conditions. Based on BrdU labeling experiments, lower mitotic activity occurs in gonial cells under 'non-mating' conditions, which is consistent with the reduced number of germ cell cysts. Interestingly, the total number of type A spermatogonia was maintained, regardless of the mating conditions. In addition, the transition from mitosis to meiosis may have been retarded under the 'non-mating' conditions. The minimum time required for germ cells to become sperm, from the onset of commitment to spermatogenesis, was approximately 14 days in vivo. The time was not found to significantly differ between 'non-mating' and 'mating' conditions. The collective data suggest the presence of a mechanism wherein the homeostasis of spermatogenesis is altered in response to the mating conditions.

Germ cells in the teleost fish medaka have an inherent feminizing effect.

AUTHOR SUMMARY: Germ cells are the only cells that can transfer genetic materials to the next generation via the sperm or egg. However, recent analyses in teleosts revealed another essential role of germ cells: feminizing the gonads. In our study, medaka mutants in which gametogenesis was blocked at specific stages provides the novel view that the feminizing effect of germ cells occurs in parallel with other reproductive elements, such as meiosis, the sexual fate decision of germ cells, and gametogenesis. Germ cells in medaka may have a potential to feminize gonads at the moment they have developed.

Novel components of germline sex determination acting downstream of foxl3 in medaka.

Germline sex determination is an essential process for the production of sexually dimorphic gametes. In medaka, Forkhead box L3 (foxl3) was previously identified as a germ cell-intrinsic regulator of sex determination that suppresses the initiation of spermatogenesis in female germ cells. To reveal the molecular mechanism of germline sex determination by foxl3, we conducted the following four analyses: Comparison of transcriptomes between wild-type and foxl3-mutant germ cells; epistatic analysis; identification of the FOXL3-binding motif; and ChIP-qPCR assay using a FOXL3-monoclonal antibody. We identified two candidate genes acting downstream of foxl3: Rec8a and fbxo47. It has been known that Rec8 regulates sister chromatid cohesion and Fbxo47 acts as a ubiquitin E3 ligase. These functions have not been, however, associated with sexual differentiation in germ cells. Our results uncover novel components acting downstream of foxl3, providing insights into the mechanism of germline sex determination.

Periaortic Abdominal Fat Area as a Predictor of Surgical Difficulties during Extraperitoneal Laparoscopic Para-aortic Lymphadenectomy.

STUDY OBJECTIVE: To evaluate whether obesity is a marker of surgical difficulty during extraperitoneal para-aortic lymphadenectomy. DESIGN: Retrospective observational cohort study. SETTING: Tertiary medical center in the Kanazawa area of Japan. PATIENTS: Eighty-four patients with primary endometrial cancer who underwent extraperitoneal laparoscopic para-aortic lymphadenectomy (LPAND) between January 2005 and December 2017 were included. INTERVENTIONS: We investigated the correlation between operative times and body mass indexes, visceral fat areas, and periabdominal artery fat areas (PAFAs). The number of lymph nodes harvested was used as an indicator of the degree of surgical completion. MEASUREMENTS AND MAIN RESULTS: There was no correlation between the operative time and body mass index. Significant correlations were observed between operative time and visceral fat area (p = .026; r = 0.243) and between operative time and PAFA (p = .007; r = 0.293). A multivariate analysis showed that PAFA was a significant independent marker that could be used to predict prolonged operative times for extraperitoneal LPAND (p = .045; odds ratio, 3.05). The number of para-aortic lymph nodes harvested was not significant in the high- and low-PAFA groups (22 and 25, respectively; p = .525). CONCLUSION: PAFA is an adequate marker of prolonged operative time for extraperitoneal LPAND among patients with endometrial cancer.

Analysis of a novel gene, Sdgc, reveals sex chromosome-dependent differences of medaka germ cells prior to gonad formation.

In vertebrates that have been examined to date, the sexual identity of germ cells is determined by the sex of gonadal somatic cells. In the teleost fish medaka, a sex-determination gene on the Y chromosome, DMY/dmrt1bY, is expressed in gonadal somatic cells and regulates the sexual identity of germ cells. Here, we report a novel mechanism by which sex chromosomes cell-autonomously confer sexually different characters upon germ cells prior to gonad formation in a genetically sex-determined species. We have identified a novel gene, Sdgc (sex chromosome-dependent differential expression in germ cells), whose transcripts are highly enriched in early XY germ cells. Chimeric analysis revealed that sexually different expression of Sdgc is controlled in a germ cell-autonomous manner by the number of Y chromosomes. Unexpectedly, DMY/dmrt1bY was expressed in germ cells prior to gonad formation, but knockdown and overexpression of DMY/dmrt1bY did not affect Sdgc expression. We also found that XX and XY germ cells isolated before the onset of DMY/dmrt1bY expression in gonadal somatic cells behaved differently in vitro and were affected by Sdgc. Sdgc maps close to the sex-determination locus, and recombination around the two loci appears to be repressed. Our results provide important insights into the acquisition and plasticity of sexual differences at the cellular level even prior to the developmental stage of sex determination.

Feeder-independent canine induced pluripotent stem cells maintained under serum-free conditions.

Canine induced pluripotent stem cells (ciPSCs) are an attractive source for regenerative veterinary medicine, and may also serve as a disease model for human regenerative medicine. Extending the application of ciPSCs from bench to bedside, however, requires resolving many issues. We generated ciPSCs expressing doxycycline-inducible murine Oct3/4 (Pou5f1), Sox2, Klf4, and c-Myc, which were introduced using lentiviral vectors. The resultant ciPSCs required doxycycline to proliferate in the undifferentiated state. Those ciPSC colonies exhibiting basic fibroblast growth factor (bFGF)-dependent proliferation were dissociated into single cells for passaging, and were maintained on a Matrigel-coated dish without feeder cells in a serum-free medium. The established ciPSCs had the ability to differentiate into three germ layers, via formation of embryoid bodies, as well as into cells expressing the same markers as mesenchymal stem cells. These ciPSCs may thus serve as a suitable source of pluripotent stem cell lines for regenerative veterinary medicine, with fewer concerns of contamination from unknown animal components.

The Mechanism of Germline Sex Determination in Vertebrates.

Germ cells are the common cells of origin for the two different types of gametes, sperm and eggs. In vertebrates so far examined, the sex of germ cells is determined by gonadal somatic cells. However, influenced by the somatic cells, how germ cells adopt their sexual fates by intrinsic factors has long been unclear in vertebrates. We recently identified forkhead box L3 (FOXL3) as a germ cell-intrinsic factor involved in the sperm-egg fate decision in the teleost fish medaka (Oryzias latipes). On the basis of the results obtained by the analysis of foxl3/FOXL3 expression and loss-of-function mutants, we review when and how germ cell sex is regulated non-cell-autonomously and cell-autonomously. We then discuss the fact that the germline sex determination pathway is genetically distinct from other essential gametogenic pathways such as meiotic entry and the establishment of germline stem cells. Another extraordinary finding in the foxl3 mutant is that functional sperm can be produced in the ovary, which provides a new notion that gametogenesis can proceed regardless of the sex of the surrounding somatic cells once the sexual identity of germ cells is established in medaka.

Hyperproliferation of mitotically active germ cells due to defective anti-Müllerian hormone signaling mediates sex reversal in medaka.

The function of AMH (Anti-Müllerian hormone), a phylogenetically ancient member of the TGFß family of proteins, in lower vertebrates is largely unknown. Previously, we have shown that the gene encoding the type II anti-Müllerian hormone receptor, amhrII, is responsible for excessive germ cell proliferation and male-to-female sex reversal in the medaka hotei mutant. In this study, functional analyses in cultured cells and of other amhrII mutant alleles indicate that lack of AMH signaling causes the hotei phenotype. BrdU incorporation experiments identified the existence of both quiescent and mitotically active germ cells among the self-renewing, type I population of germ cells in the developing gonad. AMH signaling acts in supporting cells to promote the proliferation of mitotically active germ cells but does not trigger quiescent germ cells to proliferate in the developing gonad. Furthermore, we show that the male-to-female sex reversal phenotype in hotei mutants is not a direct consequence of AMH signaling in supporting cells, but is instead mediated by germ cells. Our data demonstrate that interfollicular AMH signaling regulates proliferation at a specific stage of germ cell development, and that this regulation is crucial for the proper manifestation of gonadal sex directed by sex determination genes.

Synthetic human gonadal tissues for toxicology.

The process of mammalian reproduction involves the development of fertile germ cells in the testis and ovary, supported by the surrounders. Fertilization leads to embryo development and ultimately the birth of offspring inheriting parental genome information. Any disruption in this process can result in disorders such as infertility and cancer. Chemical toxicity affecting the reproductive system and embryogenesis can impact birth rates, overall health, and fertility, highlighting the need for animal toxicity studies during drug development. However, the translation of animal data to human health remains challenging due to interspecies differences. In vitro culture systems offer a promising solution to bridge this gap, allowing the study of mammalian cells in an environment that mimics the physiology of the human body. Current advances on in vitro culture systems, such as organoids, enable the development of biomaterials that recapitulate the physiological state of reproductive organs. Application of these technologies to human gonadal cells would provide effective tools for drug screening and toxicity testing, and these models would be a powerful tool to study reproductive biology and pathology. This review focuses on the 2D/3D culture systems of human primary testicular and ovarian cells, highlighting the novel approaches for in vitro study of human reproductive toxicology, specifically in the context of testis and ovary.

Ran-GTP assembles a specialized spindle structure for accurate chromosome segregation in medaka early embryos.

Despite drastic cellular changes during cleavage, a mitotic spindle assembles in each blastomere to accurately segregate duplicated chromosomes. Mechanisms of mitotic spindle assembly have been extensively studied using small somatic cells. However, mechanisms of spindle assembly in large vertebrate embryos remain little understood. Here, we establish functional assay systems in medaka (Oryzias latipes) embryos by combining CRISPR knock-in with auxin-inducible degron technology. Live imaging reveals several unexpected features of microtubule organization and centrosome positioning that achieve rapid, accurate cleavage. Importantly, Ran-GTP assembles a dense microtubule network at the metaphase spindle center that is essential for chromosome segregation in early embryos. This unique spindle structure is remodeled into a typical short, somatic-like spindle after blastula stages, when Ran-GTP becomes dispensable for chromosome segregation. We propose that despite the presence of centrosomes, the chromosome-derived Ran-GTP pathway has essential roles in functional spindle assembly in large, rapidly dividing vertebrate early embryos, similar to acentrosomal spindle assembly in oocytes.

Disentangling cell-intrinsic and extrinsic factors underlying gene expression evolution.

Chimeras have played a foundational role in biology, for example by enabling the classification of developmental processes into those driven intrinsically by individual cells versus those driven extrinsically by their extracellular environment. Here, we extend this framework to decompose evolutionary divergence in gene expression and other quantitative traits into cell-intrinsic, extrinsic, and intrinsic-extrinsic interaction components. Applying this framework to reciprocal rat-mouse chimeras, we found that the majority of gene expression divergence is attributable to cell-intrinsic factors, though extrinsic factors also play an integral role. For example, a rat-like extracellular environment extrinsically up-regulates the expression of a key transcriptional regulator of the endoplasmic reticulum (ER) stress response in some but not all cell types, which in turn strongly predicts extrinsic up-regulation of its target genes and of the ER stress response pathway as a whole. This effect is also seen at the protein level, suggesting propagation through multiple regulatory levels. We also demonstrate that our framework is applicable to a cellular trait, neuronal differentiation, and estimated the intrinsic and extrinsic contributions to its divergence. Finally, we show that imprinted genes are dramatically mis-expressed in species-mismatched environments, suggesting that mismatch between rapidly evolving intrinsic and extrinsic mechanisms controlling gene imprinting may contribute to barriers to interspecies chimerism. Overall, our conceptual framework opens new avenues to investigate the mechanistic basis of evolutionary divergence in gene expression and other quantitative traits in any multicellular organism.

Genome engineering with Cas9 and AAV repair templates generates frequent concatemeric insertions of viral vectors.

CRISPR-Cas9 paired with adeno-associated virus serotype 6 (AAV6) is among the most efficient tools for producing targeted gene knockins. Here, we report that this system can lead to frequent concatemeric insertions of the viral vector genome at the target site that are difficult to detect. Such errors can cause adverse and unreliable phenotypes that are antithetical to the goal of precision genome engineering. The concatemeric knockins occurred regardless of locus, vector concentration, cell line or cell type, including human pluripotent and hematopoietic stem cells. Although these highly abundant errors were found in more than half of the edited cells, they could not be readily detected by common analytical methods. We describe strategies to detect and thoroughly characterize the concatemeric viral vector insertions, and we highlight analytical pitfalls that mask their prevalence. We then describe strategies to prevent the concatemeric inserts by cutting the vector genome after transduction. This approach is compatible with established gene editing pipelines, enabling robust genetic knockins that are safer, more reliable and more reproducible.

Sexual dimorphism of gonadal structure and gene expression in germ cell-deficient loach, a teleost fish.

Germ cell-deficient fish usually develop as phenotypic males. Thus, the presence of germ cells is generally considered to be essential for female gonadal differentiation or the maintenance of ovarian structure. However, little is known of the role of germ cells in the determination of the sexual fate of gonadal somatic cells. We have established an inducible germ cell deficiency system in the loach (Misgurnus anguillicaudatus, Cypriniformes: Cobitidae), a small freshwater fish, using knockdown of the dead end gene with a morpholino antisense oligonucleotide. Interestingly, loach lacking germ cells could develop as either phenotypic males or females, as characterized morphologically by the presence or absence of bony plates in the pectoral fins, respectively. The phenotypic males and females had testicular and ovarian structures, respectively, but lacked germ cells. Gene expression patterns in these male and female germ cell-deficient gonads were essentially the same as those in gonads of normal fish. Our observations indicate that sexually dimorphic gonads can develop in germ cell-deficient loach. In contrast to the situation in other model fish species, the gonadal somatic cells in phenotypic females autonomously differentiated into ovarian tissues and also played a role in the maintenance of gonadal structure. On the basis of our observations, we propose two possible models to explain the role of germ cells in sex determination in fish.

In Vitro Storage of Functional Sperm at Room Temperature in Zebrafish and Medaka.

The longevity of sperm in teleost such as zebrafish and medaka is short when isolated even in saline-balanced solution at a physiological temperature. In contrast, some internal fertilizers exhibit the long-term storage of sperm, >10 months, in the female reproductive tract. This evidence implies that sperm in teleost possesses the ability to survive for a long time under suitable conditions; however, these conditions are not well understood. In this study, we show that the sperm of zebrafish can survive and maintain fertility in L-15-based storage medium supplemented with bovine serum albumin, fetal bovine serum, glucose, and lactic acid for 28 days at room temperature. The fertilized embryos developed to normal fertile adults. This storage medium was effective in medaka sperm stored for 7 days at room temperature. These results suggest that sperm from external fertilizer zebrafish and medaka has the ability to survive for at least 4 and 1 week, respectively, in the body fluid-like medium at a physiological temperature. This sperm storage method allows researchers to ship sperm by low-cost methods and to investigate key factors for motility and fertile ability in those sperm.

Generation of Self-Fertilizing Hermaphroditic Fish from Gonochoristic Fish, Medaka (Oryzias latipes).

INTRODUCTION: Hermaphroditism is a mode of reproduction involving an individual animal that possesses both a testis and an ovary either sequentially or simultaneously. The mechanism creating hermaphrodites remains unknown. Previously, we identified foxl3 as the germline sex determination gene in a gonochoristic fish, medaka (Oryzias latipes). foxl3 loss-of-function (foxl3-/-) females produce functional sperm as well as eggs in the ovary. However, these two gametes are not self-fertilizing because of the histological separation of each gamete production. In this study, we attempted to generate self-fertilizing medaka from female medaka by modifying germline sex using foxl3-/- mutants and by using exogenous androgen to induce partial sex reversal of somatic cells. METHODS: foxl3-/- XX females were treated with 11-ketotestosterone (11-KT), a potent teleost fish androgen, at the sexually mature stage for 30 days (90-120 dph). Then, the fish were kept under normal conditions until they were either being dissected or crossed with infertile males. RESULTS AND DISCUSSION: We showed that the foxl3-/- XX female medaka can be transformed into a self-fertilizing hermaphrodite by inducing the formation of a male-like structure with exogenous 11-KT. Self-fertilization occurs in either the ovarian cavity, the oviduct, or both where sperm is released from a tubule-like structure which is likely derived from germinal epithelium, suggesting that timely modification of 2 independent mechanisms, regulation of germline sex and partial sex reversal of somatic cells, are critical to change the reproduction mode. Our results will provide insights in developmental and evolutional occurrence of hermaphrodite vertebrates, facilitate an innovative technique to improve the efficient selection of fish with desirable traits, and contribute to the rescue of endangered species.