期刊文献+

中国地方黄牛GH基因遗传多态性研究 被引量:15

Genetic Polymorphisms of GH Genes in Chinese Yellow Cattle
下载PDF
导出
摘要 以鲁西牛、南阳牛为试验动物,利用PCR-SSCP和PCR-RFLP技术研究了以上2个地方黄牛品种生长激素(GH)基因第3内含子、第4内含子、第5外显子、3′端和5′端位点的遗传多态性。检测结果表明:GH基因第3内含子1 547 bp处发生碱基C→T的替换;GH基因第4内含子位点多态的产生是由于1 947 bp处发生碱基T→G的替换;GH基因第5外显子2 141 bp处碱基C→G的突变,使得亮氨酸变成缬氨酸,造成氨基酸发生变化。GH基因3′端的PCR-RFLP结果表明:由于2 639 bp处碱基GCC→GGC的突变造成HaeⅢ酶增加1个酶切位点;GH基因5′端位点多态的产生是由303 bp处碱基C→T的突变造成。 Nanyang and Luxi cattle were used as experimental population; the genetic variations of GH genes were researched by PCR-SSCP and PCR-RFLP method. The results were as follows. The polymorphic PCR-SSCP sites in the 3^rd , 4^th intron, the 5^th exon, and 5' flanking region and the polymorphic HaeⅢ site in the 3' flanking region of the bovine growth hormone (GH) were examined in two breeds. The polymorphisms of the 3^rd intron were caused by C→T transition at 1 547 bp position. The polymorphisms of the 4^th intron were tested by T→G transition at 1 947 bp position in Nanyang, Luxi cattle. The polymorphisms of the 5^th exon were caused by C→G transition at 2 141 bp position, which resulted amino acid translation, leucine to valine. And the polymorphic HaeⅢ site in the 3' flanking region were caused by GCC→GGC transition at 2 639 bp position, and C→T transition at 303 bp resulted the polymorphisms of 5' flanking region.
出处 《畜牧兽医学报》 CAS CSCD 北大核心 2005年第10期991-995,共5页 ACTA VETERINARIA ET ZOOTECHNICA SINICA
基金 国家"863"计划(2002AA242011)
关键词 黄牛 GH 遗传多态 生长性状 Yellow cattle GH gene genetic variations growth traits
  • 相关文献

参考文献10

  • 1Yao J, Samuel E, David Z, et al. Sequence variation in the bovine growth hormone gene characterized by SSCP analysis and their association with milk production traits in Holsteins [J]. Genetics, 1996, 144:1 809-1 816.
  • 2Wallis M . Mechanism of action of growth hormone[M]. In: Hormones and their actions (Ed. Cooke B A, R J King B Vander Molen H J). Elsevier Science Publishers, BV Part Ⅱ, 1988. 265-290.
  • 3Gordon D F, Quick D P, Erwin C R, et al. Nucleotide sequence of the bovine growth hormone chromosomal gene [J]. Mol Cell Endocrinol, 1983, 33(1):81-95.
  • 4Hediger R, Johnson S E, Barendse W, et al. Assignment of the growth hormone gene locus 19q26-qter in cattle and to 11q25-qter in sheep by in-situ hybridization [J]. Genomics, 1990, 8(1): 171-174.
  • 5Woychik R P, Camper S A, Lyons R H, et al. Cloning and nucleotide sequencing of the bovine growth hormone gene[J]. Nucleic Acids Res,1982, 10.7 197-7 210.
  • 6Cowan C M, Dentine M R, Ax R L. Restriction fragment length polymorphisms associated with growth hormone and prolaetin genes in Holstein bulls: evidence for a novel growth hormone allele[J]. Animal Genetics, 1989, 20: 157-165.
  • 7Hilbert D M, Cancro M P, Scherle P A,et al. cell derived IL-6 is differentially required for antigen-specific antibody secretion by primary and secondary B cells[J]. Immunol,1989, 143:4 019 -4 024.
  • 8Lucy M C, Hauser S D, Eppard P J, et al. Variants of somatropin in cattle: gene frequencies in major dairy breeds and associated milk production[J]. Dom Anim Endocrinol, 1993, 10: 325-333.
  • 9Zhang H M, Brown D R, Denise S K, et al. Nucleotide sequence deter mutation of a bovine somatropin allele [J]. Animal Genetics, 1992, 23(6): 578.
  • 10Unanian M M, De Nise S K, Zhang H M, et al. Rapid communication: chain reaction restriction fragment length polymorphism in the bovine growth hormone gene [J]. Animal Sci, 1994, 72: 2 203.

同被引文献181

引证文献15

二级引证文献45

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部