The prototype of sex chromosomes found in Korean populations of Rana rugosa

The seventh largest chromosome in Japanese populations of the frog Rana rugosa morphologically evolved as a sex chromosome. The sex chromosome is XX/XY type in one geographic form and ZZ/ZW type in another. In contrast, the seventh chromosomes are still homomorphic between the sexes in the other two geographic forms: they are more subtelocentric in the Kanto form and subtelocentric in the western Japanese form. To identify a prototype of the sex chromosomes, we extended our investigation in this study to the Korean form, which is supposed to be close to the phylogenetic origin of this species. The karyotype, a sex-linked gene sequence, and mechanisms of sex determination and gonadal differentiation were all examined. In addition, phylogenetic analyses were performed based on mitochondrial gene sequences and the results of crossings between the Korean and Japanese forms. As a consequence, the more subtelocentric seventh chromosome, shared by the Korean and Japanese Kanto forms, was concluded to be the prototype of the sex chromosomes. Starting at the prototype, a whole process of morphological sex chromosome evolution was reconstructed.     

Alteration of the sex determining system resulting from structural change of the sex chromosomes in the frog Rana rugosa

Rana rugosa in Japan is divided into four geographical races on the basis of the karyotype of the sex chromosomes: one in which heteromorphic sex chromosomes occur in the female sex (ZW/ZZ-system), another in which they are present in males (XX/XY-system), and the remaining two in which no heteromorphism is seen in either sex. The last two inherit the XX/XY sex determining system. Y and Z chromosomes in the former two are of the same karyotype as the no. 7 chromosomes seen in one of the latter two, whereas X and W are caused by two inversions that occurred in the original Xs (no. 7). In this study, we first attempted to detect the structural difference between the resulting X and W by examining their chiasma formation. The chiasma distribution between X and W was closely similar to that between two Xs, suggesting that the W and X are identical in structure. Regarding the change from XX/XY- to ZW/ZZ-system, the simplest explanation is that the putative female-determining gene(s) on the W grew functionally stronger by inversions. Next, we examined the sex of triploids having two Xs and one Z. The data showed that the triploids with two original Xs and a Z were all male, whereas most of those with two resulting Xs and a Z developed into females as expected. We speculated that the female-determining gene(s) on the resulting X grew mildly stronger functionally by position effect, whereas those on the W grew much stronger for some other reason (e.g., duplication). J. Exp. Zool. 286:313-319, 2000.     

Maternal control of sex ratio in Rana rugosa: evidence from DNA sexing

Parental control of primary sex ratio has been reported in a mammal (red deer), some birds, and a snake. However, it remains uncertain whether other vertebrates including Amphibia can control sex ratio. In this paper, we examined the possibility in a wild population of the Japanese frog Rana rugosa which has female heterogamety. Sex ratios of their eggs were determined using DNA markers. The eggs were sampled in the field from May to August in 1998. Each egg was then sexed by polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) using a sex-specific DNA marker. The result showed a male bias early in the season which changed to a female bias later, suggesting that females of R. rugosa can control the primary sex ratio.     

Expression profiles for six zebrafish genes during gonadal sex differentiation

Background  

The mechanism of sex determination in zebrafish is largely unknown and neither sex chromosomes nor a sex-determining gene have been identified. This indicates that sex determination in zebrafish is mediated by genetic signals from autosomal genes. The aim of this study was to determine the precise timing of expression of six genes previously suggested to be associated with sex differentiation in zebrafish. The current study investigates the expression of all six genes in the same individual fish with extensive sampling dates during sex determination and -differentiation.     

辽宁产粗皮蛙的染色体组型研究(图版Ⅳ,下)

用骨髓细胞制片法分析了粗皮蛙的染色体组型 ,结果表明其二倍体染色体数为 2 6 ,可配成 13对 ,有5对大型染色体 (相对长度 >9)和 8对小型染色体 (相对长度 <6 5 ) ,其中 ,第 1、 5、 6、 7、 8对为中部着丝点染色体 ,第 12对为端部着丝点染色体 ,第 2、 3、 4、 9、 10、 11、 13对为亚中部着丝点染色体 ,第 4对为性染色体 ,属XY型 ,X染色体为亚中部着丝点 (相对长度为 10 70 ,臂比指数为 1 72 ) ,Y染色体为亚中部着丝点(相对长度为 12 83,臂比指数为 2 0 2 )。     

鸟类性别决定候选基因在性反转鸡胚中的表达

DMRT1、PKCIW和FET1是鸟类性别决定过程中重要的候选基因。以芳香化酶抑制剂处理的鸡胚为实验材料, 对这3个基因的表达变化进行了研究。结果表明, 在整个性别决定关键时期(E4.5 ~ E10.5), DMRT1在雄性的表达量显著高于雌性, 并且在ZW性反转鸡胚中表达大幅上升, 表明DMRT1的上调表达是与睾丸形成相关的。PKCIW基因在雌性特异表达并在性反转鸡胚表达上升, 这可能与其特殊作用模式有关, 即使性反转鸡胚PKCIW代偿性的表达升高, 却也未能阻止睾丸的形成。此外, FET1为雌性特异表达, 但在性反转鸡胚中表达无变化。综上, 实验结果支持了DMRT1是鸟类睾丸发育决定因子的假说。     

Evidence for two successive pericentric inversions in sex lampbrush chromosomes of Rana rugosa (Anura: Ranidae)

The objective of this study was to clarify the course of inversions by which a ZW sex chromosome dimorphism has become established in Rana rugosa. Fortunately, R. rugosa preserves three different forms of sex chromosomes in the several isolated populations. In both males and females, the homomorphic sex chromosomes from Hiroshima were closely similar to Z, while those from Isehara were slightly different from the Z. Females from Hirosaki demonstrated heteromorphic sex chromosomes. In this study, the configuration and pairing behavior of sex lampbrush chromosomes were examined in the female offspring produced from a cross between a female from Hiroshima and a male from Isehara, as well as the female offspring of a female from Hirosaki and the male from Isehara. For the sex lampbrush chromosomes from Hiroshima and Isehara, chiasmata were exclusively formed between the distal regions of the long arms of one sex chromosome and the terminal regions of the short arms of the other. As a result, landmarks arranged in reverse order were observed in the achiasmatic regions of these chromosomes. For the sex lampbrush chromosomes from Isehara and Hirosaki, on the other hand, chiasma formation was mainly confined to the lower half of the chromosomes corresponding to the long arms, and the landmarks in the achiasmatic regions of these chromosomes were disposed in the opposite direction to each other. These results seem to indicate that in the primitive sex chromosomes of the Hiroshima type two pericentric inversions occurred, leading to the differentiation of the W chromosomes. This is the first report to substantiate the process of sex chromosome differentiation experimentally. Received: 10 November 1996; in revised form: 22 April 1997 / Accepted: 24 April 1997     

Hypocalcemic factor in the ultimobranchial gland of the frog,Rana rugosa

• 1.1. The hypocalcemic activity of the ultimobranchial gland of the frog, Rana rugosa, was estimated using a rat bioassay method.
• 2.2. Extracts of the ultimobranchial gland showed a very high hypocalcmic activity. The value corresponded to 6,340 mU (MRC)/kg b.w.
• 3.3. Serum inorganic phosphorus values of rats received the extract decreased in proportion to the dose, although no changes were found in serum sodium concentration.

     

Role of aromatase and androgen receptor expression in gonadal sex differentiation of ZW/ZZ-type frogs,Rana rugosa

To elucidate the mechanisms of amphibian gonadal sex differentiation, we examined the expression of aromatase and androgen receptor (AR) mRNAs for days 17-31 after fertilization. The effects of inhibitors and sex steroid hormones were also examined. In ZZ males, expression of AR decreased after day 19, while aromatase expression was low throughout the sampling period. Males treated with 17beta-estradiol (E2) showed increasing aromatase expression after day 21, and formed ovaries. AR antagonist treatment also induced high-level aromatase expression and ovarian differentiation. In males co-treated with an aromatase inhibitor and E2, the undifferentiated gonads developed into testes despite high-level aromatase expression. Males treated with androgen and E2 before and during an estrogen sensitive period, respectively, also formed testes. In ZW females, AR expression persisted at a low-level, while aromatase expression increased after day 18. Short-term treatment with an aromatase inhibitor was ineffective in preventing ovarian differentiation, whereas long-term treatment resulted in testes developing from ovarian structure. Compared with the ZZ males and ZW females, WW females did not exhibit detectable expression of AR, suggesting that the active AR gene(s) itself, or a putative gene regulating AR gene expression, is located on Z chromosomes. From the time lag of aromatase expression between ZW females and ZZ males treated with E2 and the effect of AR antagonist, it was found that in males elevated AR expression suppresses aromatase expression directly or indirectly. Consequently, endogenous androgens, accumulated by blocking estrogen biosynthesis, induced testicular differentiation. The gonadogenesis of males is dependent on sex hormone, whereas that of females has evolved to hormone-independence.     

DMRT1/Dmrt1, the sex determining or sex differentiating gene in Vertebrata

Although the phenomenon of sexual dimorphism is widespread in vertebrates, the molecular mechanism of sex-determination is not the same across animal phyla, in contrast to other areas of developmental biology. Recent extensive studies, however, have given proof of evolutionarily conserved function in genes which share a novel DNA binding DM domain, primarily identified in two invertebrate sex regulatory genes: doublesex of Drosophila melanogaster and mab-3 of Caenorhabditis elegans. Their mammalian autosomal homologue, DMRT1, first isolated in humans, was further discovered in genomes of various vertebrate species and appears to be involved in similar aspects of sexual development. Its precise role is still speculated, thus identification of sex reversal mutations, functional studies as well as determination of the sex-specific expression profile during embryogenesis are still being undertaken. Is this a sex determining rather than a sex differentiating gene? Is it involved in a dosage-sensitive mechanism? On what level does it function in the hierarchy of the sexual regulatory gene cascade? Recent results are discussed in this paper.