Evidence for a centrosome-attracting body like structure in germ-soma segregation during early development, in the urochordate Oikopleura dioica.

BACKGROUND: Germ cell formation has been investigated in sessile forms of tunicates. This process involves the release of a subset of maternal transcripts from the centrosome-attracting body (CAB) in the progenitor cells of the germ line. When germ-soma segregation is completed, CAB structures are missing from the newly formed primordial germ cells (PGCs). In free-swimming tunicates, knowledge about germ cell formation is lacking. In this investigation, comparative gene expression and electron microscopy studies were used to address germ cell formation in Oikopleura dioica (O. dioica). RESULTS: We found that the RNA localization pattern of pumilio (pum1) is similar to the pattern described for a subset of maternal transcripts marking the posterior end of ascidian embryos. Transcripts marking the posterior end are called postplasmic or posterior-end mark (PEM) transcripts. We found no localization of vasa (vas) transcripts to any sub-region within the germ-line precursor cells. Expression of vas4 was detected in the newly formed PGCs. Electron microscopy studies confirmed the presence of structures with similar morphology to CAB. In the same cytoplasmic compartment, we also identified pum1 transcripts and an epitope recognized by an antibody to histone H3 phosphorylated on serine 28. CONCLUSIONS: Our findings support that a CAB-like structure participates in the segregation of maternal pum1 transcripts during germ-soma separation in O. dioica.

Plasticity of animal genome architecture unmasked by rapid evolution of a pelagic tunicate.

Genomes of animals as different as sponges and humans show conservation of global architecture. Here we show that multiple genomic features including transposon diversity, developmental gene repertoire, physical gene order, and intron-exon organization are shattered in the tunicate Oikopleura, belonging to the sister group of vertebrates and retaining chordate morphology. Ancestral architecture of animal genomes can be deeply modified and may therefore be largely nonadaptive. This rapidly evolving animal lineage thus offers unique perspectives on the level of genome plasticity. It also illuminates issues as fundamental as the mechanisms of intron gain.

Regeneration of spermatogenesis and production of functional sperm by grafting of testicular cell aggregates in Zebrafish (Danio rerio).

The self-renewal and differentiation of spermatogonial stem cells (SSCs) is essential for the continuous production of sperm throughout life in male vertebrates. The development of a functional assay to analyze these properties in isolated SSCs remains necessary. In our current study, we have developed a transplantation method for testicular cell aggregates in zebrafish (Danio rerio) in which allogeneic SSCs can undergo self-renewal and differentiation. The immature testes from juveniles are dissociated, aggregated by cultivation, and then transplanted under the abdominal skin of the recipient fish. The grafted aggregates reconstitute the appropriate testicular structures, including the lobule structure, consisting of basement membrane and interstitial steroid-producing cells on the outside, and the cysts, which comprise germ cell clusters and surrounding Sertoli cells. Bromodeoxyuridine incorporation analysis indicated that continuous spermatogenesis is maintained for at least 6 mo in the reconstituted testis. Moreover, when the sperm generated from the aggregates at 3 mo postgrafting were used for artificial insemination, fertilized eggs were obtained that developed sexually mature fish. These results suggest that self-renewal of SSCs takes place in reconstituted testes under the abdominal skin and that their differentiating progeny can develop into functional sperm. Furthermore, allogeneic spermatogonia were also found to proliferate and differentiate into sperm in these grafts. Our method of grafting testicular cell aggregates should thus prove useful not only analyzing the stem cell ability of an individual SSC but also for the production of progeny from cultured SSCs or SSCs of sterile mutants with somatic cell defects.

Sexual dimorphic expression pattern of a splice variant of zebrafish vasa during gonadal development.

In Drosophila, the RNA helicase VASA (VAS) is required for both germ line formation and oocyte differentiation. While the murine VAS homologue is required for spermatogenesis, it is dispensable for germ line formation. The molecular basis for this apparently dual role of VAS in germ line ontogeny is, however, unclear. Recent evidence indicates that fish, like flies, employs VAS both in early and late stages of the germ line development and that there is a sex-linked differential expression of splice variants. We show here that the longer of two splice variants of zebrafish vas is transiently downregulated in the germ line around the time when the germ cells reach the developing gonad. Using transgenic vas::EGFP fish lines, which allow us to distinguish between male and female individuals, we show that the long splice variant reappears in both sexes at around day 25 and is subsequently downregulated during male gonadal development. Our data further suggest that there is a switch from maternal to zygotic expression of the long splice variant of vas as sexual dimorphic development commences.

Linker histone H1M transcripts mark the developing germ line in zebrafish.

Maternally synthesised factors contribute to the establishment of the germ cell lineage in lower vertebrates. In zebrafish, germ-soma segregation appears to be completed by the late blastula stage of development. To search for new germ cell factors in the zebrafish, we have used subtractive cDNA cloning. Here we report that linker histone H1M transcripts mark the germ line from the early gastrulation up to 18 h post-fertilisation.

Expression of a vas::EGFP transgene in primordial germ cells of the zebrafish.

In zebrafish, maternally produced vasa (vas) transcripts become targeted to the cleavage planes of early embryos and subsequently incorporated into the primordial germ cells (PGCs). Zygotic vas transcription occurs from the onset of gastrulation. Here, we report on the characterisation of the zebrafish vas locus. The gene consists of 27 exons, spans about 25kb, and contains two CpG-rich regions. We have used vas regulatory regions to establish transgenic zebrafish lines expressing enhanced green fluorescent protein (EGFP) in their PGCs. Maternally encoded vas::EGFP transcripts and VAS::EGFP protein segregate with the PGCs during embryogenesis. We find that the maternally deposited vas::EGFP transcripts are stable during embryogensis at least up to 50h of development. Vas::EGFP transcripts could not be detected in embryos that inherit the transgene from males, most likely due to the lack of one or more regulatory elements required for early zygotic expression. We show that vas::EGFP transcripts become enriched to the cleavage planes in early embryos, a finding that supported an RNA localisation signal localised within the vas region of these transcripts.