三穗鸭<em>ITPR1</em>基因SNPs鉴定及其与蛋壳品质性状的关联性

doi:10.3969/j.issn.1674-7968.2020.03.008

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (3806 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要 1,4,5-三磷酸肌醇受体1 (inositol 1,4,5-trisphosphate receptor 1, ITPR1)是细胞内Ca²⁺释放通道蛋白,通过调控蛋壳腺钙离子的转运和释放而影响家禽的蛋壳矿化和蛋壳品质。本研究采用PCR产物直接测序法和序列比对技术对186只三穗鸭(Anas platyrhyncha domestica) ITPR1基因的遗传变异位点进行鉴定,分析SNP变异位点与蛋壳品质相关性。结果表明,在三穗鸭ITPR1基因功能结构域及部分内含子中共检测到14个SNPs突变位点,分别在第8内含子检测到g.46455T>C、g.46459C>A、g.46564A>G、g.46581A>T和g.46649T>G共5个突变位点,第15内含子检测到g.55537A>G、g.55610T>C、g.55620G>T、g.55664A>G、g.55680C>T和g.55709T>G共6个突变位点,第30内含子检测到g.72601T>G和g.72843A>G共2个突变位点,第42外显子检测出1个同义突变位点g.124036C>T;14个突变位点均产生3种基因型,且均为中度多态位点;卡方适应性检验结果显示,14个突变位点的基因型分布均符合Hardy-Weinberg平衡(P>0.05);连锁不平衡分析显示,g.46455T>C、g.46459C>A、g.46564A>G、g.46581A>T和g.46649T>G各位点两两之间存在强连锁不平衡,g.46581A>T、g.55537A>G、g.55620G>T、g.55664A>G、g.55680C>T和g.55709T>G各位点两两之间存在强连锁不平衡,g.72601T>G与g.72843A>G位点间存在强连锁不平衡;14个SNP位点共发现13种单倍型,H2 (CAGTGACTGTGGGC)和H11 (TCAATGCGAC)分别为优势单倍型和劣势单倍型,频率分别为0.131和0.060;关联性分析表明,除g.72843A>G位点外,其余13个SNPs与三穗鸭蛋壳厚度显著关联(P<0.05);g.46581A>T位点与蛋形指数显著关联(P<0.05);除g.55610T>C、g.55664A>G、g.72601T>G和g.72843A>G位点外,其余10个位点与蛋重均显著关联(P<0.05);g.46459C>A、g.55664A>G和g.124036C>T位点与蛋壳重显著关联(P<0.05);除g.124036C>T位点外,其余13个位点均与蛋壳强度显著关联(P<0.05)。综上所述,三穗鸭ITPR1基因主要功能结构域的DNA序列较保守,而内含子遗传变异丰富,且发现的14个SNPs至少与2个蛋壳品质指标显著关联,表明ITPR1基因的遗传变异可能影响鸭的蛋壳品质,可作为鸭蛋壳品质选择的遗传标记。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	李杰章
	谭光辉
	吴磊
	覃媛钰
	张依裕

关键词 ： 1, 4, 5-三磷酸肌醇受体1基因(ITPR1), SNP鉴定, 蛋壳品质, 三穗鸭

Abstract：Inositol 1,4,5-trisphosphate receptor 1 (ITPR1) is intracellular Ca²⁺ release channel protein, and could influence the mineralization and quality of eggshell in poultry by regulating the transport and release of calcium ions in the eggshell gland. In this study, the PCR product direct sequencing method and sequence alignment technology were used to identify the ITPR1 genetic variation sites of 186 Sansui duck (Anas platyrhyncha domestica), and the correlation between SNP mutation sites and eggshell quality was analyzed. The results showed that a total of 14 mutation sites were detected in the main functional domain and some introns of Sansui duck ITPR1 gene. There were 5 mutant sites, g.46455T>C, g.46459C>A, g.46564A>G, g.46581A>T, g.46649T>G, detected in the 8th intron. There were 6 mutant sites, g.55537A>G, g.55610T>C, g.55620G>T, g.55664A>G, g.55680C>T, g.55709T>G, detected in the 15th intron. There were 2 mutant sites, g.72601T>G and g.72843A>G, detected in the 30th intron. There was a synonymous mutation site g.124036C>T detected in the 42nd exon. All of the 14 mutation sites produced 3 genotypes, all of which were moderately polymorphic. The chi-square fitness test results showed that the genotype distribution of 14 mutation sites were consistent with the Hardy-Weinberg equilibrium (P>0.05). Based on linkage unbalance analysis,there were strong linkage imbalance between each two sites of g.46455T>C, g.46459C>A, g.46564A>G, g.46581A>T and g.46649T>G. There were strong linkage imbalance between each two sites of g.46581A>T, g.55537A>G, g.55620G>T, g.55664A>G, g.55680C>T and g.55709T>G. There was also strong linkage imbalance between g.72601T>G and g.72843A>G. A total of 13 kinds of haplotypes were found in 14 SNPs, of which H2 (CAGTGACTGTGGGC) was dominant haplotype with a frequency of 0.131, and H11 (TCAATGCGAC) was an inferior haplotype with a frequency of 0.060. The correlation analysis showed that 13 SNPs had significant correlation with eggshell thickness of Sansui duck except g.72843A>G site; Only g.46581A>T site had significant correlation with egg shape index (P<0.05); Except g.55610TC, g.55664AG, g.72601TG and g.72843AG, the other 10 sites had significant correlation on egg weight (P<0.05); g.46459C>A, g.55664A>G and g.124036C>T sites were significantly associated with eggshell weight (P<0.05); Except g.124036C>T site, the other 13 sites were significantly correlated with eggshell strength (P<0.05). In conclusion, the DNA sequence of the main functional domain of ITPR1 gene in the Sansui duck was relatively conservative, while intron genetic variation was abundant. Moreover, the 14 SNPs found in this study were significantly correlated with at least 2 eggshell quality indexes, indicating that the genetic variation of ITPR1 gene might affect eggshell quality and could be used as a genetic marker for the selection of eggshell quality of ducks.

Key words： Inositol 1,4,5-trisphosphate receptor 1 gene (ITPR1) SNP identification Eggshell quality Sansui duck

收稿日期: 2019-07-12

ZTFLH:

S834

基金资助:国家自然科学基金(31760663); 贵州省科技人才补助项目(黔科合平台人才[2017]5788); 贵州省千层次创新人才项目(701030174401)

通讯作者: *zyy8yyc@163.com

引用本文:

李杰章, 谭光辉, 吴磊, 覃媛钰, 张依裕. 三穗鸭ITPR1基因SNPs鉴定及其与蛋壳品质性状的关联性[J]. 农业生物技术学报, 2020, 28(3): 455-464.
LI Jie-Zhang, TAN Guang-Hui, WU Lei, QIN Yuan-Yu, ZHANG Yi-Yu. SNPs Identification of ITPR1 Gene and Its Correlation with Eggshell Quality Traits in Sansui Ducks (Anas platyrhyncha domestica). 农业生物技术学报, 2020, 28(3): 455-464.

链接本文:

http://journal05.magtech.org.cn/Jwk_ny/CN/10.3969/j.issn.1674-7968.2020.03.008 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2020/V28/I3/455

1 覃媛钰, 张依裕, 罗华伦, 等. 2019. SFRP5基因遗传变异对长顺绿壳蛋鸡胸肌肌肉品质的影响[J]. 农业生物技术学报, 27(04): 703-711.
(Qin Y Y, Zhang Y Y, Luo H L, et al.2019. Effect of genetic variation of SFRP5 gene on breast muscle quality of changshun blue-eggshell chicken (Gallus gallus domesticus)[J]. Journal of Agricultural Biotechnology, 27(04): 703-711.)
2 文禹粱, 王翔宇, 郭晓飞, 等. 2019. 不同产羔数小尾寒羊BMP4基因表达及其错义突变与产羔数关联分析[J]. 农业生物技术学报, 27(01): 80-88.
(Wen Y L, Wang X Y, Guo X X, et al.2019. BMP4 gene expression in Small Tail Han sheep (Ovis aries) with different litter size and association analysis between its missense mutation and litter size[J]. Journal of Agricultural Biotechnology, 27(01): 80-88.)
3 赵宪林, 曹少杰, 王俊全, 等. 2018. MC4R基因多态性及基因型组合与藏羊生长性状的关联分析[J]. 农业生物技术学报, 26(3): 429-436.
(Zhao X L, Cao S J, Wang J Q, et al.2018. Correlation analysis of polymorphism and genotype combination of MC4R gene and growth traits of Tibetan sheep (Ovis aries)[J]. Journal of Agricultural Biotechnology, 26(3): 429-436.)
4 Arias J, Mann K, Nys Y, et al.2008. Eggshell growth and matrix macromolecules[M]. Handbook of Biomineralization: Biological Aspects and Structure Formation,Wiley‐VCH Verlag GmbH, pp. 309-327.
5 Berridge M J, Taylor C W.1993. Inositol trisphosphate and calcium signaling[J]. Nature, 361(6410): 315-325.
6 Beauchamp N J, Daly M E, Makris M, et al.1998. A novel mutation in intron K of the PROS1 gene causes aberrant RNA splicing and is a common cause of protein S deficiency in a UK thrombophilia cohort[J]. Thromb Haemost, 79(6): 1086-1091.
7 Carrasco M A, Jaimovich E, Kemmerling U, et al.2004. Signal transduction and gene expression regulated by calcium release from internal stores in excitable cells[J]. Biological Research, 37(4): 701-712.
8 Choi J Y, Hwang C Y, Lee B, et al.2016. Age-associated repression of type 1 inositol 1, 4, 5-triphosphate receptor impairs muscle regeneration[J]. Aging, 8(9): 2062-2076.
9 Chang K C.2000. Critical regulatory domains in intron 2 of a porcine sarcomeric myosin heavy chain gene[J]. Journal of Muscle Research & Cell Motility, 21(5): 451-461.
10 Carneiro M, Hu D, Archer J, et al.2017. Dwarfism and altered craniofacial development in rabbits is caused by a 12.1 kb deletion at the HMGA2 locus[J]. Genetics, 205(2): 955-965.
11 Choi J Y, Jang H J, Park J W, et al.2018.Characterization of gene expression and genetic variation of horse ERBB receptor feedback inhibitor 1 in Thoroughbreds[J]. Asian-Australasian Journal of Animal Sciences, 31(3): 309-315.
12 Duan Z, Chen S, Sun C, et al.2015. Polymorphisms in ion transport genes are associated with eggshell mechanical property[J]. PLOS ONE, 10(6): e0130160.
13 Hamilton R, Hollands K, Voisey P, et al.1979. Relationship between egg shell quality and shell breakage and factors that affect shell breakage in the field-A review[J]. Worlds Poultry Science Journal, 35(3): 177-190.
14 Hir H L, Nott A, Moore M J.2003. How introns influence and enhance eukaryotic gene expression[J]. Trends in Biochemical Sciences, 28(4): 215-220.
15 Hirschey M D, Shimazu T, Goetzman E, et al.2010. SIRT3regulates mitochondrial fatty-acid oxidation by reversible enzyme deacetylation[J]. Nature, 464(7285): 121-125.
16 Huang L, Chardon J W, Carter M T, et al.2012. Missense mutations in ITPR1 cause autosomal dominant congenital nonprogressive spinocerebellar ataxia[J]. Orphanet Journal of Rare Diseases, 7(1): 1150-1172.
17 Jonchère V, Brionne A, Gautron J, et al.2012. Identification of uterine ion transporters for mineralisation precursors of the avian eggshell[J]. BMC Physiology, 12(1): 1472-6793.
18 Komar A A.2007. Silent SNPs: Impact on gene function and phenotype[J]. Pharmacogenomics, 8(8): 1075-1080.
19 Mikoshiba K.2007. IP3 receptor/Ca²+ channel: From discovery to new signaling concepts[J]. Journal of neurochemistry, 102(5): 1426-1446.
20 Moura G R, Pinheiro M, Freitas A, et al.2011. Species-specific codon context rules unveil non-neu-trality effects of synonymous mutations[J]. PLOS ONE, 6(10): e26817.
21 Maxwell T.2012. The eggshell: Structure, composition and mineralization[J]. Frontiers in Bioscience, 17(1): 1266-1280.
22 Narayanan D, Adebiyi A, Jaggar J H.2012. Inositol trisphosphate receptors in smooth muscle cells[J]. American Journal of Physiology-Heart and Circulatory Physiology, 302(11): H2190-H2210.
23 Nys Y, Guyot N.2011. Improving the safety and quality of eggs and egg products, Volume: Egg Chemistry, Production and Consumption[M]. Cambridge: Woodhead Publishing, pp. 83-132.
24 Nys Y, Gautron J, Garcia-Ruiz J M, et al.2004. Avian eggshell mineralization: Biochemical and functional characterization of matrix proteins[J]. Comptes Rendus-Palevol, 3(6-7): 560-562.
25 Rodriguez-Navarro A, Yebra A, Nys Y, et al.2007. Analysis of avian eggshell microstructure using X-ray area detectors[J]. European Journal of Mineralogy, 19(3): 391-398.
26 Parolin Schnekenberg R, Perkins E M, Miller J W, et al.2015. De novo point mutations in patients diagnosed with ataxic cerebral palsy[J]. Brain, 138(7): 1817-1832.
27 Soulsby M D, Wojcikiewicz R J.2005. The type Ⅲ inositol 1,4,5-trisphosphate receptor is phosphorylated by cAMP-dependent protein kinase at three sites[J]. Biochemical Journal, 392(3): 493-497.
28 Sauna Z E, Kinchi-Sarfaty C.2011. Understanding the contribution of synonymous mutations to human disease[J]. Nature Reviews Genetics, 12(10): 683-691.
29 Supek F, Minana B, Valcaler J, et al.2014. Synonymous mutations frequently act as driver mutations in human cancers[J]. Cell, 156(6): 1324-1335.
30 Sasaki M, Ohba C, Iai M, et al.2015. Sporadic infantile-onset spinocerebellar ataxia caused by missense mutations of the inositol 1,4,5-triphosphate receptor type 1 gene[J]. Journal of Neurology, 262(5): 1278-1284.
31 Santos C P, Aguiar A F, Giometti I C, et al.2018. High final energy of gallium arsenide laser increases MyoD gene expression during the intermediate phase of muscle regeneration after cryoinjury in rats[J]. Lasers in Medical Science, 33(4): 1-8.
32 Verkhratsky A.2004. Endoplasmic reticulum calcium signaling in nerve cells[J]. Biological Research, 37(4): 693-699.
33 Wu L J, Zhuo M.2009. Targeting the NMDA receptor subunit NR2B for the treatment of neuropathic pain[J]. Neurotherapeutics, 6(4): 693-702.
34 Weqierski T, Kuznicki J.2018. Neuronal calcium signaling via store-operated channels in health and disease[J]. Cell Calcium, 74(9): 102-111.
35 Wang J, Cui K, Yang Z, et al.2019. Transcriptome analysis of improved wool production in skin-specific transgenic sheep overexpressing ovine β-catenin[J]. International Journal of Molecular Sciences, 20(3): 620-622.
36 Xiang G H, Ren J L, Hal T, et al.2018. Editing porcine IGF2 regulatory element improved meat production in Chinese Bama pigs[J]. Cellular and Molecular Life Sciences, 75(24): 4619-4628.
37 Zhuo M.2009. Plasticity of NMDA receptor NR2B subunit in memory and chronic pain[J]. Molecular Brain, 2(4): 410-414.