蛋用鹌鹑的VIPR-1基因的多态性与早期生长性状的关联分析

doi:10.3969/j.issn.1004-1524.2021.08.06

浙江农业学报 ›› 2021, Vol. 33 ›› Issue (8): 1393-1401.DOI: 10.3969/j.issn.1004-1524.2021.08.06

蛋用鹌鹑的VIPR-1基因的多态性与早期生长性状的关联分析

董智豪¹(), 陈宇¹, 黄高想¹, 白俊艳¹^,²^,^*(), 李静云¹, 赵淑娟¹^,², 雷莹¹^,², 王新乐¹, 胡琦杭¹, 范征宇¹

1.河南科技大学动物科技学院,河南洛阳 471023
2.洛阳市动物遗传育种重点实验室,河南洛阳471023

收稿日期:2020-08-07 出版日期:2021-08-25 发布日期:2021-08-27
通讯作者: 白俊艳
作者简介:*白俊艳,E-mail: junyanbai@163.com
董智豪(1998—),男,安徽合肥人,硕士研究生,研究方向为动物遗传育种。E-mail: 18538564084@163.com
基金资助:
国家自然科学基金(31201777);河南省自然科学基金(202300410153)

Association analysis of VIPR-1 gene polymorphism and early growth traits in egg quail

DONG Zhihao¹(), CHEN Yu¹, HUANG Gaoxiang¹, BAI Junyan¹^,²^,^*(), LI Jingyun¹, ZHAO Shujuan¹^,², LEI Ying¹^,², WANG Xinle¹, HU Qihang¹, FAN Zhengyu¹

1. College of Animal Science and Technology, Henan University of Science and Technology, Luoyang 471023, China
2. Luoyang Key Laboratory of Animal Genetics and Breeding, Luoyang 471023,China

Received:2020-08-07 Online:2021-08-25 Published:2021-08-27
Contact: BAI Junyan

摘要/Abstract

摘要：

为分析VIPR-1基因是否能作为鹌鹑早期生长性状的相关分子标记或者候选基因,以中国黄羽鹌鹑、中国白羽鹌鹑、朝鲜鹌鹑3个蛋用鹌鹑品种作为实验对象,采用PCR-RFLP技术和测序技术检测VIPR-1基因的外显子6-7的多态性,并分析该基因多态性与蛋用鹌鹑早期生长性状的关联程度。结果表明,在3个蛋用鹌鹑品种中的VIPR-1基因外显子6-7区域共检测出15个SNP位点,分别为A94G、G97T、C201T、A204G、A233G、C260G、A299T、C354T、A355G、C378T、C407G、A425C、A543G、G585T、A586G。对HpyCH4IV位点(A355G)进行酶切分析,可以检测到3种基因型即AA(285 bp/811 bp)、AG(285 bp/811 bp/1 096 bp)和GG(1 096 bp)。中国黄羽鹌鹑和中国白羽鹌鹑的AA、AG、GG基因型频率分别为0.227、0.636、0.136和0.087、0.609、0.304。朝鲜鹌鹑AG和GG基因型频率分别为0.235和0.765。1~4周龄时,VIPR-1基因的HpyCH4IV位点与中国黄羽鹌鹑的日增重、体重、胫长、胸宽、胸深、胸骨长、胫围有显著关联性(P<0.05)。HpyCH4IV位点与中国白羽鹌鹑的胫围有显著关联性(P<0.05)。HpyCH4IV位点与朝鲜鹌鹑的体重、胸宽、胸深有显著关联性(P<0.05)。5~7周龄时,VIPR-1基因的HpyCH4IV位点与中国黄羽鹌鹑的体重、胸骨长、胫长、体长、胸宽、胸深、胫围、日增重和相对生长率均有显著的关联性(P<0.05)。HpyCH4IV位点与中国白羽鹌鹑的日增重和相对生长均有显著的关联性(P<0.05)。HpyCH4IV位点与朝鲜鹌鹑的体重有显著的关联性(P<0.05)。综上研究表明,VIPR-1基因外显子6-7的HpyCH4IV位点(A355G)对蛋用鹌鹑的早期生长性状具有一定影响。

关键词: 蛋用鹌鹑, VIPR-1基因, PCR-RFLP, 早期生长性状, 基因多态性

Abstract:

To analyze whether VIPR-1 gene can be used as a molecular marker or candidate gene for early growth traits of quail or not, in this study, three egg quails, namely Chinese yellow quail, Chinese white quail and Korean quail, were used as experimental materials. PCR-RFLP and sequencing were used to detect the polymorphism of exon 6-7 of VIPR-1 gene, and the correlation between the polymorphism and the early growth traits of egg quail was analyzed. The results showed that 15 SNP loci were detected in exon 6-7 of VIPR-1 gene in three egg quails, which were A94G, G97T, C201T, A204G, A233G, C260G, A299T, C354T, A355G, C378T, C407G, A425C, A543G, G585T, A586G. Three genotypes, AA (285 bp/811 bp), AG(285 bp/811 bp/1 096 bp) and GG(1 096 bp), were detected by restriction enzyme analysis of HpyCH4IV (A355G). The genotypic frequencies of AA, AG and GG were 0.227, 0.636, 0.136, 0.087, 0.609, 0.304, respectively. The frequencies of AG and GG genotypes in Korean quail were 0.235 and 0.765, respectively. At the age of 1-4 weeks, the HpyCH4IV locus of VIPR-1 gene was significantly correlated with the daily gain, body weight, tibial length, chest width, chest depth, sternal length and tibial circumference of Chinese yellow quails (P<0.05). There was a significant correlation between HpyCH4IV locus and tibial circumference of Chinese white quails (P<0.05). There was a significant correlation between HpyCH4IV locus and body weight, chest width and chest depth of Korean quail (P<0.05). At the age of 5-7 weeks, the HpyCH4IV locus of VIPR-1 gene was significantly correlated with the body weight, sternal length, tibial length, body length, chest width, chest depth, tibial circumference, daily gain and relative growth rate of Chinese yellow quails (P<0.05). There was a significant correlation between HpyCH4IV locus and daily gain and relative growth of Chinese white quails (P<0.05). There was a significant correlation between HpyCH4IV locus and body weight of Korean quail (P<0.05). In conclusion, the HpyCH4IV locus (A355G) in exon 6-7 of VIPR-1 gene has some influence on the early growth traits of quail.

Key words: egg quail, VIPR-1 gene, PCR-RFLP, early growth traits, gene polymorphism

中图分类号:

S837

董智豪, 陈宇, 黄高想, 白俊艳, 李静云, 赵淑娟, 雷莹, 王新乐, 胡琦杭, 范征宇. 蛋用鹌鹑的VIPR-1基因的多态性与早期生长性状的关联分析[J]. 浙江农业学报, 2021, 33(8): 1393-1401.

DONG Zhihao, CHEN Yu, HUANG Gaoxiang, BAI Junyan, LI Jingyun, ZHAO Shujuan, LEI Ying, WANG Xinle, HU Qihang, FAN Zhengyu. Association analysis of VIPR-1 gene polymorphism and early growth traits in egg quail[J]. Acta Agriculturae Zhejiangensis, 2021, 33(8): 1393-1401.

图/表 8

参考文献 26

[1]	陈清. 鹅核型分析和GH、GHR基因多态性与生长性状关联研究[D]. 扬州: 扬州大学, 2008.
	CHEN Q. Analysis on karyotype and polymorphism of GH and GHR gene and its relationship with growth traits in goose[D]. Yangzhou: Yangzhou University, 2008.(in Chinese with English abstract)
[2]	王庆. 鹌鹑GH、GHR基因多态性与生产性能相关性研究[D]. 哈尔滨: 东北农业大学, 2010.
	WANG Q. Study on relationships between GH, GHR gene polymorphism and performance in quail[D]. Harbin: Northeast Agricultural University, 2010.(in Chinese with English abstract)
[3]	MAZUROWSKI A, FRIESKE A, KOKOSZYNSKI D, et al. Examination of growth hormone (GH) gene polymorphism and its association with body weight and selected body dimensions in ducks[J]. Folia Biologica, 2015, 63(1):43-50. DOI URL
[4]	AYKUTA, ÖZENS, GÖKŞEND, et al. Melanocortin 4 receptor (MC4R) gene variants in children and adolescents having familial early-onset obesity: genetic and clinical characteristics[J]. European Journal of Pediatrics, 2020, 179:1445-1452. DOI URL
[5]	陶勇, 李国辉, 王金玉, 等. 京海黄鸡MC4R基因多态性及其与生长性能的关联分析[J]. 中国家禽, 2008, 30(5):21-23.
	TAO Y, LI G H, WANG J Y, et al. SNP of MC4R gene and its association with growth performance in Jinghai yellow chicken[J]. China Poultry, 2008, 30(5):21-23.(in Chinese with English abstract)
[6]	LI C Y, LI H. Association of MC4R gene polymorphisms with growth and body composition traits in chicken[J]. Asian-Australasian Journal of Animal Sciences, 2006, 19(6):763-768. DOI URL
[7]	王琼, 刘益平, 蒋小松, 等. MyoG基因多态性与优质肉鸡屠宰性状和肉质性状的相关性分析[J]. 遗传, 2007, 29(9):1089-1096.
	WANG Q, LIU Y P, JIANG X S, et al. Correlation analysis of relationships between polymorphisms of high quality chicken myogenin gene and slaughter and meat quality traits[J]. Hereditas(Beijing), 2007, 29(9):1089-1096.(in Chinese with English abstract)
[8]	YIN H D, ZHANG Z C, LAN X, et al. Association of MyF5, MyF6 and MyOG gene polymorphisms with carcass traits in Chinese meat type quality chicken populations[J]. Journal of Animal and Veterinary Advances, 2011, 10(6):704-708. DOI URL
[9]	白俊艳, 时坤鹏, 卢小宁, 等. 鹌鹑MyoG基因多态性与早期生长性能的关联分析[J]. 河南农业科学, 2020, 49(4):147-152.
	BAI J Y, SHI K P, LU X N, et al. Association analysis between MyoG gene polymorphism and early growth performance of quail[J]. Journal of Henan Agricultural Sciences, 2020, 49(4):147-152.(in Chinese with English abstract)
[10]	朱智, 徐宁迎, 吴登俊, 等. 鸡IGF-Ⅰ基因SNPs及其对屠体性状的遗传效应分析[J]. 畜牧兽医学报, 2007, 38(10):1021-1026.
	ZHU Z, XU N Y, WU D J, et al. SNPs of IGF-Ⅰgene and its genetic effects on carcass traits in chicken[J]. Chinese Journal of Animal and Veterinary Sciences, 2007, 38(10):1021-1026.(in Chinese with English abstract)
[11]	荣华, 豆腾飞, 张丽春, 等. 大围山微型鸡IGF-1基因表达量与生长性状的相关性分析[J]. 中国家禽, 2015, 37(4):5-8.
	RONG H, DOU T F, ZHANG L C, et al. Correlation analysis on IGF-1 gene expression and growth traits in Daweishan mini chicken[J]. China Poultry, 2015, 37(4):5-8.(in Chinese with English abstract)
[12]	彭琼. IGF1和MEF2A基因在蛋鸡、肉鸡胚胎期骨骼肌中的分子差异研究[D]. 雅安: 四川农业大学, 2018.
	PENG Q. Study on molecular differences of IGF1 and MEF2A genes in skeletal muscle of layers and Broilers[D]. Ya’an: Sichuan Agricultural University, 2018.(in Chinese with English abstract)
[13]	白俊艳, 卢军浩, 付学言, 等. 蛋用鹌鹑IGF-1R基因的多态性与体尺性状相关性分析[J]. 浙江农业学报, 2020, 32(3):398-405.
	BAI J Y, LU J H, FU X Y, et al. Analysis of correlation between polymorphism of IGF-1R gene and body size traits in egg quail[J]. Acta Agriculturae Zhejiangensis, 2020, 32(3):398-405.(in Chinese with English abstract)
[14]	WANG Y, LI J, WANG C Y, et al. Characterization of the receptors for chicken GHRH and GHRH-related peptides: Identification of a novel receptor for GHRH and the receptor for GHRH-LP (PRP)[J]. Domestic Animal Endocrinology, 2010, 38(1):13-31. DOI URL
[15]	LIANG Y, CUI J X, YANG G F, et al. Polymorphisms of 5' flanking region of chicken prolactin gene[J]. Domestic Animal Endocrinology, 2006, 30(1):1-16. DOI URL
[16]	ZHOU M, LEI M, RAO Y, et al. Polymorphisms of vasoactive intestinal peptide receptor-1 gene and their genetic effects on broodiness in chickens[J]. Poultry Science, 2008, 87(5):893-903. DOI URL
[17]	洪军, 王克华, 李东锋, 等. VIPR-1基因SNP位点与如皋黄鸡产蛋性能和蛋品质的关联分析[J]. 中国畜牧杂志, 2011, 47(23):1-5.
	HONG J, WANG K H, LI D F, et al. Association of SNP of VIPR-1 gene with egg production and egg quality traits in Rugao-yellow chicken[J]. Chinese Journal of Animal Science, 2011, 47(23):1-5.(in Chinese with English abstract)
[18]	周敏, 李莹, 沈栩, 等. 鹌鹑VIPR-1的克隆、序列特征和组织表达分析[J]. 中国农业科学, 2012, 45(3):529-539.
	ZHOU M, LI Y, SHEN X, et al. cDNA cloning, sequence analysis and tissue specific expression of vasoactive intestinal peptide type 1 receptor(VIPR-1) in quails[J]. Scientia Agricultura Sinica, 2012, 45(3):529-539.(in Chinese with English abstract)
[19]	PU Y J, WU Y, XU X J, et al. Association of VIPR-1 gene polymorphisms and haplotypes with egg production in laying quails[J]. Journal of Zhejiang University-SCIENCE B, 2016, 17(8):591-596. DOI URL
[20]	蒲跃进. 蛋用鹌鹑产蛋相关基因克隆、表达及其与性状的关联性研究[D]. 武汉: 华中农业大学, 2016.
	PU Y J. Molecular cloning and expression of genes related with laying quail reproduction and their associations with egg performances[D]. Wuhan: Huazhong Agricultural University, 2016.(in Chinese with English abstract)
[21]	周敏, 梁菲菲, 饶友生, 等. VIPR-1基因12个多态位点与鸡早期产蛋性状的相关性[J]. 畜牧兽医学报, 2008, 39(9):1147-1152.
	ZHOU M, LIANG F F, RAO Y S, et al. Association of twelve polymorphisms of the VIPR-1 gene with chicken early egg production traits[J]. Chinese Journal of Animal and Veterinary Sciences, 2008, 39(9):1147-1152.(in Chinese with English abstract)
[22]	周敏, 梁菲菲, 饶友生, 等. VIPR-1基因5'侧翼区2个SNP与鸡产蛋就巢的相关性[C]//中国畜牧兽医学会. 第十三届全国家禽学术讨论会论文汇编. 2007:513-516.
[23]	朱志明, 陈红萍, 杨武, 等. 河田鸡VIPR-1基因外显子2HpaⅡ位点多态性与产蛋性状的关联分析[J]. 畜牧与兽医, 2015, 47(3):46-48.
	ZHU Z M, CHEN H P, YANG W, et al. Association analysis of polymorphism of VIPR-1 gene exon-2 Hpa Ⅱ with laying traits in Hetian chickens[J]. Animal Husbandry & Veterinary Medicine, 2015, 47(3):46-48.
[24]	于海龙. 连成白鸭产蛋性能三个候选基因的相关研究[D]. 南京: 南京农业大学, 2011.
	YU H L. Correlation studies on three candidate genes affecting egg production in Liancheng white duck[D]. Nanjing: Nanjing Agricultural University, 2011.(in Chinese with English abstract)
[25]	周敏, 何丹林, 刘满清, 等. 清远麻鸡VIPR-1基因多态性及与生长性状的关联分析[J]. 养禽与禽病防治, 2009(7):2-4.
	ZHOU M, HE D L, LIU M Q, et al. Polymorphism of VIPR-1 gene and its association with growth traits in Qingyuan partridge chickens[J]. Poultry Husbandry and Disease Control, 2009(7):2-4.
[26]	周敏, 刘满清, 徐海平, 等. 血管活性肠肽Ⅰ型受体基因多态位点与鸡冠高度和体重的相关性[J]. 中国家禽, 2009, 31(20):17-20.
	ZHOU M, LIU M Q, XU H P, et al. Association of polymorphisms of VIPR-1 gene with chicken comb height and body weight[J]. China Poultry, 2009, 31(20):17-20.(in Chinese with English abstract)

编辑推荐

Metrics

阅读次数

全文

1701

HTML			PDF

最新录用	在线预览	正式出版	最新录用	在线预览	正式出版
0	0	8	0	0	1693

来源	本网站	其他网站

次数	1132	569
比例	67%	33%

摘要

1434

最新录用	在线预览	正式出版

0	0	1434

来源	本网站	其他网站

次数	1431	3
比例	100%	0%

品种 Species	基因型频率 Genotypic frequency			基因频率 Gene frequency		杂合度 Heterozy- gosity	有效等位基因数 Effective number of alleles	多态信息含量 Polymorphism information content	哈代温伯格平衡检验 Hardy-Weinberg equilibrium analysis
品种 Species	AA	AG	GG	A	G	杂合度 Heterozy- gosity	有效等位基因数 Effective number of alleles	多态信息含量 Polymorphism information content	哈代温伯格平衡检验 Hardy-Weinberg equilibrium analysis
中国黄羽鹌鹑	0.227	0.636	0.136	0.545	0.455	0.496	1.984	0.373	5.298(0.071)
Chinese yellow quail
中国白羽鹌鹑	0.087	0.609	0.304	0.391	0.609	0.476	1.910	0.363	5.324(0.070)
Chinese white quail
朝鲜鹌鹑	0	0.235	0.765	0.118	0.882	0.208	1.262	0.186	0.907(0.812)
Korean quail

品种 Species	基因型频率 Genotypic frequency			基因频率 Gene frequency		杂合度 Heterozy- gosity	有效等位基因数 Effective number of alleles	多态信息含量 Polymorphism information content	哈代温伯格平衡检验 Hardy-Weinberg equilibrium analysis
品种 Species	AA	AG	GG	A	G	杂合度 Heterozy- gosity	有效等位基因数 Effective number of alleles	多态信息含量 Polymorphism information content	哈代温伯格平衡检验 Hardy-Weinberg equilibrium analysis
中国黄羽鹌鹑	0.227	0.636	0.136	0.545	0.455	0.496	1.984	0.373	5.298(0.071)
Chinese yellow quail
中国白羽鹌鹑	0.087	0.609	0.304	0.391	0.609	0.476	1.910	0.363	5.324(0.070)
Chinese white quail
朝鲜鹌鹑	0	0.235	0.765	0.118	0.882	0.208	1.262	0.186	0.907(0.812)
Korean quail

品种 Species	基因型 Genotype	日增重 Daily gain/ (g·d^-1)	相对生长率 Relative growth rate/%	体重 Weight/g	胫长 Tibial length/cm	胸宽 Chest width/cm	胸深 Chest depth/cm	胸骨长 Sternal length/cm	体长 Body- length/cm	胫围 Tibial circum- ference/cm
中国黄羽鹌鹑 Chinese	AA	326.819 ±22.397 a	12.609 ±2.478 a	60.447 ±5.416 a	3.005 ±0.109 a	2.212 ±0.138 a	2.538 ±0.138 a	2.603 ±0.158 a	6.040 ±0.247 a	1.300 ±0.029 a
yellow quail	AG	275.510 ±15.992 ab	10.377 ±1.393 a	55.436 ±3.134 ab	2.928 ±0.059 ab	2.221 ±0.065 a	2.500 ±0.070 a	2.537 ±0.085 a	5.876 ±0.159 a	1.224 ±0.020 b
	GG	231.270 ±40.728 b	10.377 ±1.394 a	48.633 ±7.897 b	2.758 ±0.160 b	1.972 ±0.166 b	2.191 ±0.200 b	2.235 ±0.196 b	5.644 ±0.371 a	1.244 ±0.047 b
中国白羽鹌鹑 Chinese	AA	244.524 ±32.646 a	12.632 ±4.870 a	45.417 ±7.404 a	2.708 ±0.139 a	1.885 ±0.124 a	2.114 ±0.128 a	2.011 ±0.182 a	5.533 ±0.320 a	1.283 ±0.040 a
white quail	AG	255.340 ±15.759 a	12.582 ±1.512 a	44.812 ±3.086 a	2.766 ±0.059 a	1.881 ±0.058 a	2.195 ±0.060 a	2.191 ±0.084 a	5.724 ±0.148 a	1.198 ±0.023 b
	GG	210.476 ±19.422 a	11.228 ±2.470 a	40.971 ±3.648 a	2.657 ±0.082 a	1.827 ±0.086 a	2.151 ±0.090 a	2.063 ±0.137 a	5.652 ±0.190 a	1.157 ±0.026 b
朝鲜鹌鹑 Korean quail	AG	353.691 ±36.739 a	10.675 ±2.382 a	72.783 ±6.283 a	3.277 ±0.111 a	2.529 ±0.104 a	2.748 ±0.135 a	2.778 ±0.159 a	6.342 ±0.278 a	1.317 ±0.039 a
	GG	341.319 ±22.964 a	9.746 ±0.816 a	65.636 ±4.017 b	3.148 ±0.067 a	2.262 ±0.083 b	2.544 ±0.067 b	2.636 ±0.112 a	6.185 ±0.150 a	1.387 ±0.081 a

品种 Species	基因型 Genotype	日增重 Daily gain/ (g·d^-1)	相对生长率 Relative growth rate/%	体重 Weight/g	胫长 Tibial length/cm	胸宽 Chest width/cm	胸深 Chest depth/cm	胸骨长 Sternal length/cm	体长 Body- length/cm	胫围 Tibial circum- ference/cm
中国黄羽鹌鹑 Chinese	AA	326.819 ±22.397 a	12.609 ±2.478 a	60.447 ±5.416 a	3.005 ±0.109 a	2.212 ±0.138 a	2.538 ±0.138 a	2.603 ±0.158 a	6.040 ±0.247 a	1.300 ±0.029 a
yellow quail	AG	275.510 ±15.992 ab	10.377 ±1.393 a	55.436 ±3.134 ab	2.928 ±0.059 ab	2.221 ±0.065 a	2.500 ±0.070 a	2.537 ±0.085 a	5.876 ±0.159 a	1.224 ±0.020 b
	GG	231.270 ±40.728 b	10.377 ±1.394 a	48.633 ±7.897 b	2.758 ±0.160 b	1.972 ±0.166 b	2.191 ±0.200 b	2.235 ±0.196 b	5.644 ±0.371 a	1.244 ±0.047 b
中国白羽鹌鹑 Chinese	AA	244.524 ±32.646 a	12.632 ±4.870 a	45.417 ±7.404 a	2.708 ±0.139 a	1.885 ±0.124 a	2.114 ±0.128 a	2.011 ±0.182 a	5.533 ±0.320 a	1.283 ±0.040 a
white quail	AG	255.340 ±15.759 a	12.582 ±1.512 a	44.812 ±3.086 a	2.766 ±0.059 a	1.881 ±0.058 a	2.195 ±0.060 a	2.191 ±0.084 a	5.724 ±0.148 a	1.198 ±0.023 b
	GG	210.476 ±19.422 a	11.228 ±2.470 a	40.971 ±3.648 a	2.657 ±0.082 a	1.827 ±0.086 a	2.151 ±0.090 a	2.063 ±0.137 a	5.652 ±0.190 a	1.157 ±0.026 b
朝鲜鹌鹑 Korean quail	AG	353.691 ±36.739 a	10.675 ±2.382 a	72.783 ±6.283 a	3.277 ±0.111 a	2.529 ±0.104 a	2.748 ±0.135 a	2.778 ±0.159 a	6.342 ±0.278 a	1.317 ±0.039 a
	GG	341.319 ±22.964 a	9.746 ±0.816 a	65.636 ±4.017 b	3.148 ±0.067 a	2.262 ±0.083 b	2.544 ±0.067 b	2.636 ±0.112 a	6.185 ±0.150 a	1.387 ±0.081 a

品种 Species	基因型 Genotype	日增重 Daily gain/ (g·d^-1)	相对生长率 Relative growth rate/%	体重 Weight/g	胫长 Tibial length/cm	胸宽 Chest width/cm	胸深 Chest depth/cm	胸骨长 Sternal length/cm	体长 Body- length/cm	胫围 Tibial circum- ference/cm
中国黄羽鹌鹑 Chinese	AA	233.429 ±22.658 ab	2.407 ±0.266 ab	116.787 ±4.304 a	3.557 ±0.020 a	3.021 ±0.056 a	3.456 ±0.056 a	4.053 ±0.065 a	8.113 ±0.134 a	1.487 ±0.022 a
yellow quail	AG	175.442 ±15.250 b	2.161 ±0.217 b	99.514 ±3.046 b	3.437 ±0.029 ab	2.969 ±0.050 a	3.277 ±0.043 ab	3.796 ±0.064 b	7.783 ±0.102 ab	1.388 ±0.011 b
	GG	246.349 ±22.918 a	3.448 ±0.659 a	97.356 ±5.681 b	3.394 ±0.087 b	2.747 ±0.103 b	3.160 ±0.106 b	3.597 ±0.114 b	7.533 ±0.224 b	1.422 ±0.015 ab
中国白羽鹌鹑 Chinese	AA	157.857 ±23.453 b	2.252 ±0.358 b	86.283 ±7.724 a	3.375 ±0.092 a	2.636 ±0.124 a	3.000 ±0.127 a	3.267 ±0.247 a	7.100 ±0.369 a	1.383 ±0.040 a
white quail	AG	218.980 ±11.465 a	2.851 ±0.159 ab	94.424 ±3.635 a	3.359 ±0.023 a	2.693 ±0.049 a	3.247 ±0.061 a	3.436 ±0.064 a	7.483 ±0.102 a	1.355 ±0.024 a
	GG	213.129 ±13.816 ab	3.260 ±0.283 a	86.338 ±4.777 a	3.352 ±0.054 a	2.622 ±0.080 a	3.092 ±0.097 a	3.281 ±0.109 a	7.243 ±0.158 a	1.352 ±0.018 a
朝鲜鹌鹑 Korean quail	AG	236.190 ±46.561 a	2.193 ±0.491 a	133.875 ±5.576 a	3.848 ±0.061 a	3.249 ±0.062 a	3.798 ±0.057 a	4.233 ±0.087 a	8.783 ±0.109 a	1.492 ±0.023 a
	GG	214.908 ±18.464 a	2.137 ±0.215 a	126.803 ±2.867 b	3.769 ±0.019 a	3.172 ±0.057 a	3.617 ±0.057 a	4.177 ±0.061 a	8.615 ±0.100 a	1.492 ±0.011 a

蛋用鹌鹑的VIPR-1基因的多态性与早期生长性状的关联分析

Association analysis of VIPR-1 gene polymorphism and early growth traits in egg quail

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

图/表 8

参考文献 26

相关文章 4

编辑推荐

Metrics

本文评价

[1]	白俊艳, 卢军浩, 付学言, 武晓红, 杨又兵, 雷莹, 庞有志, 卢小宁, 巩慧荣, 胡陆星, 刘红涛, 樊红灯, 曹恒, 时坤鹏, 陈梦柯, 马永康. 蛋用鹌鹑IGF-1R基因的多态性与体尺性状相关性分析[J]. 浙江农业学报, 2020, 32(3): 398-405.
[2]	白俊艳, 曹恒, 王旭, 杨又兵, 樊红灯, 付学言, 时坤鹏, 董智豪, 卢小宁, 李新月, 郝伟光, 李子衡, 郑飞扬. 绵羊GH基因的Pvu Ⅱ 位点的多态性与其生长性状的关联分析[J]. 浙江农业学报, 2019, 31(9): 1416-1422.
[3]	母童, 王国梅, 杨启瑞, 金丽, 张海龙, 张丽, 田晓静, 刘丽霞. 烟台黑猪SLA-DQB基因外显子2多态性及其与仔猪腹泻的关联分析[J]. 浙江农业学报, 2016, 28(10): 1671-1677.
[4]	张磊;宋雪梅;姜俊芳;蒋永清*. 利用PCR-RFLP方法检测中国荷斯坦牛STAT4基因内含子20多态性[J]. , 2012, 24(5): 0-781.