Your search keyword '"O. Ninagi"' showing total 2 results

1. Isolation and characterization of sex chromosome rearrangements generating male muscle dystrophy and female abnormal oogenesis in the silkworm, Bombyx mori.

Author

Fujii T, Yokoyama T, Ninagi O, Kakehashi K, Obara Y, Nenoi M, Ishikawa T, Mita K, Shimada T, and Abe H

Subjects

Animals, Chromosome Mapping, Female, Gene Deletion, Genetic Markers, Male, Models, Genetic, Muscular Dystrophies genetics, Oogenesis, Sex Factors, Translocation, Genetic, Bombyx genetics, Chromosome Aberrations, Sex Chromosomes

Abstract

In deletion-mapping of W-specific RAPD (W-RAPD) markers and putative female determinant gene (Fem), we used X-ray irradiation to break the translocation-carrying W chromosome (W( Ze )). We succeeded in obtaining a fragment of the W( Ze ) chromosome designated as Ze (W), having 3 of 12 W-RAPD markers (W-Bonsai, W-Yukemuri-S, W-Yukemuri-L). Inheritance of the Ze (W) fragment by males indicates that it does not include the Fem gene. On the basis of these results, we determined the relative positions of W-Yukemuri-S and W-Yukemuri-L, and we narrowed down the region where Fem gene is located. In addition to the Ze (W) fragment, the Z chromosome was also broken into a large fragment (Z(1)) having the +( sch ) (1-21.5) and a small fragment (Z(2)) having the +( od ) (1-49.6). Moreover, a new chromosomal fragment (Ze (W)Z(2)) was generated by a fusion event between the Ze (W) and the Z(2) fragments. We analyzed the genetic behavior of the Z(1) fragment and the Ze (W)Z(2) fragment during male (Z/Z(1) Ze (W)Z(2)) and female (Z(1) Ze (W)Z(2)/W) meiosis using phenotypic markers. It was observed that the Z(1) fragment and the Z or the W chromosomes separate without fail. On the other hand, non-disjunction between the Ze (W)Z(2) fragment and the Z chromosome and also between the Ze (W)Z(2) fragment and the W chromosome occurred. Furthermore, the females (2A: Z/Ze (W)Z(2)/W) and males (2A: Z/Z(1)) resulting from non-disjunction between the Ze (W)Z(2) fragment and the W chromosome had phenotypic defects: namely, females exhibited abnormal oogenesis and males were flapless due to abnormal indirect flight muscle structure. These results suggest that Z(2) region of the Z chromosome contains dose-sensitive gene(s), which are involved in oogenesis and indirect flight muscle development.

Published

2007

2. The effect of W chromosome origin on sex-chromosome pairing in ZZWW tetraploid females of the domesticated silkworm, Bombyx mori, and the congenic wild silkworm, Bombyx mandarina.

Author

Tanaka N, Yokoyama T, Abe H, Ninagi O, and Oshiki T

Subjects

Animals, Animals, Congenic, Chromosome Pairing, Cold Temperature, Evolution, Molecular, Female, Meiosis, Oocytes cytology, Sex Ratio, Bombyx genetics, Polyploidy, Sex Chromosomes

Abstract

To analyze the degree of pairing of the Z and W chromosomes in ZZWW tetraploid female silkworms that have the W chromosomes of the domesticated silkworm, Bombyx mori, and those of the wild silkworm, Bobyx mandarina, we induced two types of ZZWW tetraploid female silkworms (Cr4n, Wr4n) through cold treatment of the eggs. The Wr4n female is congenic to the Cr4n female for W chromosomes; namely, the W chromosomes of the Wr4n female are derived from those of B. mandarina. Each of the sex ratios (female/male) in filial triploids from the Cr4n females was shown to be in the range of 3.9-5.3 (4.6 as an average of six cases). On the other hand, each of the sex ratios (female/male) in filial triploids from the Wr4n females was shown to be in the range of 6.2-9.0 (6.9 as an average of nine cases). The results of a t-test indicated that the difference in sex ratios in the two groups is highly significant (at the 0.1% level). These results suggest that, in the meiosis of the ZZWW tetraploid female, the frequency of pairing of the W chromosome of B. mandarina and the Z chromosome of B. mori is lower than that of the pairing of the W and Z chromosomes of B. mori. Furthermore, the t-test results are evidence that the W chromosomes have undergone significant evolutional change.

Published

2002