Inherited XX sex reversal originating from wild medaka populations.

The teleost fish, medaka (Oryzias latipes), has an XX/XY sex-determining mechanism. A Y-linked DM domain gene, DMY, has been isolated by positional cloning as the sex-determining gene in this species. Previously, we conducted a field survey of genotypic sex and found that approximately 1% of wild medaka are sex-reversed (XX males and XY females). Here, we performed genetic analyses of nine spontaneous XX sex-reversed males to elucidate its genetic basis. In all cases, the F(1) progeny were all females, whereas XX males reappeared in the backcross (BC) progeny, suggesting that XX sex reversal is a recessive trait. Although the incidences of sex reversal in the BC progeny were mostly low, 40% were males derived from one XX male. We performed linkage analysis using 55 BC males and located a single major factor, sda-1 (sex-determining autosomal factor-1), controlling sex reversal in an autosomal linkage group. Thus, genes involved in the sex-determining pathway can be isolated from spontaneous mutants in wild populations.

Heritable artificial sex chromosomes in the medaka, Oryzias latipes.

Chromosomal sex determination is widely used by vertebrates, however, only two genes have been identified as master sex-determining genes: SRY/Sry in mammals and DMY in the teleost medaka. Transfer of both genes into genetically female (XX) individuals can induce male development. However, transgenic strains have not been established in both cases because of infertility of the transgenic founders in mammals and low germline transmission rates in medaka. In this study, we used a BAC clone containing DMY in a 117 kb genomic region and two types of fluorescent marker to establish two DMY-transgenic medaka strains. In these strains, exogenous DMY is completely linked to a male phenotype and early gonadal development is not different from that of the wild-type strain. Sex-linkage analysis showed that the exogenous DMY was located on linkage group (LG) 23 in one strain and on LG 5 in the other strain, whereas the sex chromosome in medaka is on LG 1. Real-time PCR analysis indicated that these strains have multiple copies of DMY and higher DMY expression levels than the wild-type strain. These results showed that LGs 23 and 5 function as sex chromosomes in the two strains, respectively. This is not only the first example of the artificial generation of heritable sex chromosomes in vertebrates but also the first evidence showing plasticity of homomorphic sex chromosomes. This plasticity appears to be a characteristic of lower vertebrates and the underlying cause of frequent sex chromosome switching, recently reported in several fish and frog species.

Sexual differentiation of germ cell deficient gonads in the medaka, Oryzias latipes.

To determine whether germ cells perform any function in gonadal sexual differentiation, development of gonads in the medaka, Oryzias latipes, after exposure to busulfan was investigated. Busulfan suppressed proliferation of early germ cells, thus significantly reducing the number of germ cells and generating regions without germ cells in the developing gonads. Globular structures were observed in the parenchyma in these regions. The structure was male specific, developed at the same time as acinus (seminiferous tubule precursor), surrounded by the basal lamina, and contained characteristic desmosomes. These results strongly suggest that these globular structures are the precursors of seminiferous tubules devoid of germ cells. In the ovary, no follicles were observed but a well-developed ovarian cavity was evident. From these results we conclude that differentiation of gonadal parenchyma cells, except for follicular ones, is not germ cell dependent, though morphological differentiation of the somatic cells seems to follow the differentiation of germ cells.

The vasa-like gene, olvas, identifies the migration path of primordial germ cells during embryonic body formation stage in the medaka, Oryzias latipes.

The medaka homolog of the Drosophila vasa gene, olvas (Oryzias latipes vas) was obtained using polymerase chain reaction of medaka cDNA from the testis and ovary. The spatio-temporal expression pattern of olvas transcripts was observed by in situ hybridization on gonads and embryos. The transcripts for olvas were exclusively detected in the cytoplasm of germ cells in the testis and ovary, not in gonadal somatic cells. In the early developmental stages, each blastomere possessed the maternal transcripts of olvas, which disappeared during gastrula stages. At the late gastrula stage, specific expression of olvas was observed only in germline cells located at the posterior shield. Embryos after the hybridization were examined histologically, and the distribution and migration path of primordial germ cells (PGC) during early stages of embryonic-body formation were revealed using the olvas gene as a germline cell marker. The PGC were translocated from the posterior shield to both sides of the embryonic body via the inner embryonic body in the medaka.

The role of annexin II tetramer in the activation of plasminogen.

Annexin II tetramer (AIIt) is a major Ca2+-binding protein of endothelial cells which has been shown to exist on both the intracellular and extracellular surfaces of the plasma membrane. In this report, we demonstrate that AIIt stimulates the activation of plasminogen by facilitating the tissue plasminogen activator (t-PA)-dependent conversion of plasminogen to plasmin. Fluid-phase AIIt stimulated the rate of activation of [Glu]plasminogen about 341-fold compared with an approximate 6-fold stimulation by annexin II. AIIt bound to [Glu]plasminogen(S741C-fluorescein) with a Kd of 1. 26 +/- 0.04 microM (mean +/- S.D., n = 3) and this interaction resulted in a large conformational change in [Glu]plasminogen. Kinetic analysis established that AIIt produces a large increase of about 190-fold in the kcat, app and a small increase in the Km,app which resulted in a 90-fold increase in the catalytic efficiency (kcat/Km) of t-PA for [Glu]plasminogen. AIIt also stimulated the t-PA-dependent activation of [Lys]plasminogen about 28-fold. Furthermore, other annexins such as annexin I, V, or VI did not produce comparable activation of t-PA-dependent conversion of [Glu]plasminogen to plasmin. The stimulation of the activation of [Glu]plasminogen by AIIt was Ca2+-independent and inhibited by epsilon-aminocaproic acid. AIIt bound to human 293 cells potentiated t-PA-dependent plasminogen activation. AIIt that was bound to phospholipid vesicles or heparin also stimulated the activation of [Glu]plasminogen 5- or 11-fold, respectively. Furthermore, immunofluorescence labeling of nonpermeabilized HUVEC revealed a punctated distribution of AIIt subunits on the cell surface. These results therefore identify AIIt as a potent in vitro activator of plasminogen.