Your search keyword '"Kunieda Tetsuo"' showing total 8 results

1. Positional Cloning of the Gene LIMBIN Responsible for Bovine Chondrodysplastic Dwarfism

Author

Takeda, Haruko, Takami, Marika, Oguni, Tomoko, Tsuji, Takehito, Yoneda, Kazuhiro, Sato, Hiroaki, Ihara, Naoya, Itoh, Tomohito, Kata, Srinivas R., Mishina, Yuji, Womack, James E., Moritomo, Yasuo, Sugimoto, Yoshikazu, and Kunieda, Tetsuo

Published

2002

2. Skeletal Analysis of the Long Bone Abnormality ( lbab/ lbab) Mouse, A Novel Chondrodysplastic C-Type Natriuretic Peptide Mutant.

Author

Kondo, Eri, Yasoda, Akihiro, Tsuji, Takehito, Fujii, Toshihito, Miura, Masako, Kanamoto, Naotestu, Tamura, Naohisa, Arai, Hiroshi, Kunieda, Tetsuo, and Nakao, Kazuwa

Subjects

SKELETAL muscle, BONE abnormalities, LABORATORY mice, NATRIURETIC peptides, GENETIC mutation, ENDOCHONDRAL ossification

Abstract

Long bone abnormality ( lbab/lbab) is a strain of dwarf mice. Recent studies revealed that the phenotype is caused by a spontaneous mutation in the Nppc gene, which encodes mouse C-type natriuretic peptide (CNP). In this study, we analyzed the chondrodysplastic skeletal phenotype of lbab/lbab mice. At birth, lbab/lbab mice are only slightly shorter than their wild-type littermates. Nevertheless, lbab/lbab mice do not undergo a growth spurt, and their final body and bone lengths are only ~60% of those of wild-type mice. Histological analysis revealed that the growth plate in lbab/lbab mice, especially the hypertrophic chondrocyte layer, was significantly thinner than in wild-type mice. Overexpression of CNP in the cartilage of lbab/lbab mice restored their thinned growth plate, followed by the complete rescue of their impaired endochondral bone growth. Furthermore, the bone volume in lbab/lbab mouse was severely decreased and was recovered by CNP overexpression. On the other hand, the thickness of the growth plate of lbab/+ mice was not different from that of wild-type mice; accordingly, impaired endochondral bone growth was not observed in lbab/+ mice. In organ culture experiments, tibial explants from fetal lbab/lbab mice were significantly shorter than those from lbab/+ mice and elongated by addition of 10 M CNP to the same extent as lbab/+ tibiae treated with the same dose of CNP. These results demonstrate that lbab/lbab is a novel mouse model of chondrodysplasia caused by insufficient CNP action on endochondral ossification. [ABSTRACT FROM AUTHOR]

Published

2012

3. Characterization of the dwg mutations: dwg and dwg Bayer are new mutant alleles of the Ggt1 gene.

Author

Tsuji, Takehito, Yamada, Kaoru, and Kunieda, Tetsuo

Subjects

GENETIC mutation, GENE frequency, GENETICS, PHENOTYPES, GLUTATHIONE, MESSENGER RNA

Abstract

The dwg and dwg Bayer are allelic mutations of the mouse that are characterized by dwarfism, cataracts, and coat color change in homozygotes. The Ggt1 gene encodes γ-glutamyltransferase 1 (GGT1), an extracellular membrane-bound enzyme that is critical for glutathione homeostasis. Both the dwg locus and Ggt1 gene are localized on mouse chromosome 10, and the phenotypes of GGT1-deficient mice with targeted disruption of the Ggt1 gene show remarkable similarities with those of dwg/ dwg and dwg Bayer/ dwg Bayer mice. This evidence led us to hypothesize that the Ggt1 gene is responsible for dwg and dwg Bayer mutations. In this study we characterized dwg mutations by investigating their association with the Ggt1 gene. Histological analysis revealed reduced numbers of proliferative and hypertrophic chondrocytes in the growth plate of dwg/ dwg mice, which are characteristic abnormalities observed in GGT1-deficient mice. To identify the causative mutations of dwg mutations, we analyzed the Ggt1 gene in dwg/ dwg and dwg Bayer/ dwg Bayer mice. In dwg/ dwg mice, 13 nucleotides on exon 7 of the Ggt1 gene were deleted, resulting in the generation of aberrant transcripts due to disrupted pre-mRNA splicing. Furthermore, dwg Bayer/ dwg Bayer mice had a 46.7-kb deletion containing complete coding sequences of Ggt1 and AI646023 genes and the first exon of the Ggt5 gene, which is closely related to the Ggt1 gene as a member of the GGT gene family. These results indicate that both dwg and dwg Bayer have defective mutations of the Ggt1 gene. Thus, we concluded that mutations in the Ggt1 gene are responsible for the phenotypes of dwg/ dwg and dwg Bayer/ dwg Bayer mice. [ABSTRACT FROM AUTHOR]

Published

2009

4. Short-Limbed Dwarfism: slw Is a New Allele of Npr2 Causing Chondrodysplasia.

Author

Sogawa, Chizuru, Tsuji, Takehito, Shinkai, Yusuke, Katayama, Kentaro, and Kunieda, Tetsuo

Subjects

DWARFISM, PHENOTYPES, EXTREMITIES (Anatomy), GENETIC mutation, LABORATORY mice

Abstract

Short-limbed dwarfism (SLW) is a new mutant mouse characterized by a dwarf phenotype with markedly short body, limbs, and tail. In the present study, we investigated the skeletal phenotypes of the SLW mouse and determined the chromosomal localization to identify the gene responsible for the phenotypes (slw). Skeletal preparations stained with alcian blue and alizarin red revealed that longitudinal growth of the extremities of the affected (slw/slw) mice was significantly reduced in comparison with that of normal mice, whereas the positions and numbers of skeletal elements were normal. Histological examination of tibial growth plates of the affected mice showed that the numbers of proliferating and hypertrophic chondrocytes were obviously diminished. These phenotypes resembled to those of human chondrodysplasias caused by defective chondrocyte proliferation and differentiation. We mapped the slw locus on an 11.7-cM interval of the proximal region of mouse chromosome 4 by linkage analysis. Furthermore, allelism test using Npr2cn locus, a mutant allele of Npr2 gene encoding a natriuretic peptide receptor B, revealed that slw locus is an allele of the Npr2 gene. These results suggest that the dwarf phenotype of the SLW mouse is caused by the disturbed endochondral ossification, and a mutation in the Npr2 gene is expected to be responsible for the phenotypes of the SLW mouse. [ABSTRACT FROM AUTHOR]

Published

2007

5. Characterization of chromosomal inversion of the mouse hairy ears ( Eh) mutation associated with cleft palate.

Author

Katayama, Kentaro, Furuno, Aki, Akiyama, Kouyou, Tsuji, Takehito, and Kunieda, Tetsuo

Subjects

CHROMOSOME inversions, NEUTRON irradiation, LABORATORY mice, CLEFT palate, GENETIC mutation, GENETICS

Abstract

The hairy ears ( Eh) mutation in the mouse originated from neutron irradiation experiments and is associated with chromosomal inversion on chromosome 15. Eh/+ mice have small pinna and extra hairs on the pinna but the phenotypic features of Eh/Eh mice are unclear. In this study we found that Eh/Eh mice died shortly after birth and had a cleft palate caused by impaired growth of palate shelves. Because genes located on the breakpoints of inversion are likely to be responsible for the defects associated with chromosomal inversions, we determined the breakpoints of the Eh inversion. We used a new genetic method that uses recombinant chromosomes resulting from crossing over between two overlapping inversions to determine the breakpoints. Koa is a mouse mutation associated with inversion of chromosome 15, which partially overlaps with the Eh inversion. We made Eh +/+ Koa double heterozygotes and obtained the recombinant chromosomes possessing deletion and duplication of the regions flanked by the breakpoints of both inversions, which were generated by crossing over within the overlapped region of these inversions. By defining the deleted regions we identified the breakpoints of the Eh inversion. We then examined the expression of genes in the vicinities of the breakpoints and found ectopic expression of the Hoxc5 gene and a transcript with unknown function in the developing palate of Eh/Eh mice, which is likely to be responsible for the cleft palate. [ABSTRACT FROM AUTHOR]

Published

2007

6. An insertion mutation of the bovine F11 gene is responsible for factor XI deficiency in Japanese black cattle.

Author

Kunieda, Masaki, Tsuji, Takehito, Abbasi, Abdol Rahim, Khalaj, Maryam, Ikeda, Miho, Miyadera, Keiko, Ogawa, Hiroyuki, and Kunieda, Tetsuo

Subjects

GENETIC mutation, CATTLE, GENETICS, BOS, LIVESTOCK, HEREDITY, NUCLEOTIDE sequence, NUCLEOTIDE analysis, EXONS (Genetics), SPLIT genes

Abstract

Factor XI deficiency in Japanese black cattle is an hereditary mild bleeding disorder with an autosomal recessive mode of inheritance. To characterize the molecular lesion causing factor XI deficiency in cattle, we isolated an entire coding region of the bovine F11 gene, which comprises 15 exons and 14 introns, and determined its nucleotide sequences. Comparison of the nucleotide sequences of the F11 gene between affected and unaffected animals revealed an insertion of 15 nucleotides in exon 9 of the affected animals. The insertion results in a substitution of one amino acid with six amino acids in a highly conserved amino acid sequence in the fourth apple domain of factor XI protein. Genotyping of the F11 gene in 109 Japanese black cattle revealed that the insertion clearly corresponded to the factor XI activities of the animals. We therefore concluded that the insertion of 15 nucleotides in the F11 gene is the causative mutation for factor XI deficiency in Japanese black cattle. Genotyping of the F11gene by detecting the insertion will be an effective DNA-based diagnostic system to prevent incidence of the disease. [ABSTRACT FROM AUTHOR]

Published

2005

7. A Loss-of-Function Mutation in Natriuretic Peptide Receptor 2 (Npr2) Gene Is Responsible for Disproportionate Dwarfism in cn/cn Mouse.

Author

Tsuji, Takehito and Kunieda, Tetsuo

Subjects

*DWARFISM, *PEPTIDES, *GENETIC mutation, *GROWTH disorders, *GENETICS, *GENOTYPE-environment interaction, *CELL nuclei, *AMINO acids, *CARTILAGE cells, *GENETIC transformation

Abstract

The achondroplastic mouse is a spontaneous mutant characterized by disproportionate dwarfism with short limbs and tail due to disturbed chondrogenesis during endochondral ossification. These abnormal phenotypes are controlled by an autosomal recessive gene (cn). In this study, linkage analysis using 115 affected mice of F2 progeny mapped the cn locus on an ∼0.8-cM region of chromosome 4, and natriuretic peptide receptor 2 (Npr2) gene was identified as the most potent candidate for the cn mutant in this region. This gene encodes a receptor for C-type natriuretic peptide (CNP) that positively regulates longitudinal bone growth by producing cGMP in response to CNP binding to the extracellular domain. Sequence analyses of the Npr2 gene in cn/cn mice revealed a T to G transversion leading to the amino acid substitution of highly conserved Leu with Arg in the guanylyl cyclase domain. In cultured chondrocytes of cn/cn mice, stimulus with CNP did not significantly increase intracellular cGMP concentration, whereas it increased in +/+ mice. Transfection of the mutant Npr2 gene into COS-7 cells also showed similar results, indicating that the missense mutation of the Npr2 gene in cn/cn mice resulted in disruption of the guanylyl cyclase activity of the receptor. We therefore concluded that the dwarf phenotype of cn/cn mouse is caused by a loss-offunction mutation of the Npr2 gene, and cn/cn mouse will be a useful model to further study the molecular mechanism regulating endochondral ossification by CNP/natriuretic peptide receptor B signal. [ABSTRACT FROM AUTHOR]

Published

2005

8. Hypomorphic mutation in mouse Nppc gene causes retarded bone growth due to impaired endochondral ossification

Author

Tsuji, Takehito, Kondo, Eri, Yasoda, Akihiro, Inamoto, Masataka, Kiyosu, Chiyo, Nakao, Kazuwa, and Kunieda, Tetsuo

Subjects

*GENES, *CARTILAGE cells, *BONE growth, *GENETIC mutation, *ENDOCHONDRAL ossification

Abstract

Abstract: Long bone abnormality (lbab/lbab) is a spontaneous mutant mouse characterized by dwarfism with shorter long bones. A missense mutation was reported in the Nppc gene, which encodes C-type natriuretic peptide (CNP), but it has not been confirmed whether this mutation is responsible for the dwarf phenotype. To verify that the mutation causes the dwarfism of lbab/lbab mice, we first investigated the effect of CNP in lbab/lbab mice. By transgenic rescue with chondrocyte-specific expression of CNP, the dwarf phenotype in lbab/lbab mice was completely compensated. Next, we revealed that CNP derived from the lbab allele retained only slight activity to induce cGMP production through its receptor. Histological analysis showed that both proliferative and hypertrophic zones of chondrocytes in the growth plate of lbab/lbab mice were markedly reduced. Our results demonstrate that lbab/lbab mice have a hypomorphic mutation in the Nppc gene that is responsible for dwarfism caused by impaired endochondral ossification. [Copyright &y& Elsevier]

Published

2008