木槿ISSR-PCR反应体系的建立及优化
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摘要
建立木槿ISSR-PCR反应体系,为木槿种质资源的创新与鉴定提供理论基础。采用正交试验法,对影响PCR结果的Taq酶用量、Mg~(2+)浓度、dNTPs浓度、模板DNA用量及引物浓度5个因素进行分析,采用单因素试验对退火温度进行筛选,并利用最佳体系对24个木槿品种进行扩增验证。结果表明,最优反应体系(25μL)中,含10×buffer(Mg~(2+) free) 2.5μL、Taq酶0.75 U、Mg~(2+) 2.0 mmol/L、dNTPs 0.10 mmol/L、模板DNA 100 ng、引物0.5μmol/L。PCR反应程序为94℃预变性2 min;94℃变性30 s,50℃退火30 s,72℃延伸1 min,34个循环;72℃延伸6 min,4℃保温。建立的体系对24个木槿品种能够扩增出清晰稳定、无拖带、多态性高的条带。
The ISSR-PCR reaction system of Hibiscus syriacus was established to provide theoretical basis for the Hibiscus germplasm resources innovation and identification.Orthogonal test was used to analyze five factors affecting the results of PCR:Taq enzyme dosage,Mg~(2+),dNTPs concentration,template DNA dosage and primer concentration.Single factor design was used to screen annealing temperature,and 24 Hibiscus species were amplified and validated by this system.The results showed that the optimal reaction system(25 μL) contained 10×buffer(Mg~(2+) free) 2.5 μL,Taq enzyme 0.75 U,Mg~(2+) 2.0 mmol/L,dNTPs 0.10 mmol/L,template DNA 100 ng,and primers 0.5 μmol/L.The procedure of PCR was 94 ℃ 2 min;94 ℃ 30 s,50 ℃ 30 s,72 ℃ 1 min,34 cycles;72 ℃ 6 min,4 ℃ for holding.Using this system,24 Hibiscus species could amplify clear and stable bands with high polymorphism without towing.
The ISSR-PCR reaction system of Hibiscus syriacus was established to provide theoretical basis for the Hibiscus germplasm resources innovation and identification.Orthogonal test was used to analyze five factors affecting the results of PCR:Taq enzyme dosage,Mg~(2+),dNTPs concentration,template DNA dosage and primer concentration.Single factor design was used to screen annealing temperature,and 24 Hibiscus species were amplified and validated by this system.The results showed that the optimal reaction system(25 μL) contained 10×buffer(Mg~(2+) free) 2.5 μL,Taq enzyme 0.75 U,Mg~(2+) 2.0 mmol/L,dNTPs 0.10 mmol/L,template DNA 100 ng,and primers 0.5 μmol/L.The procedure of PCR was 94 ℃ 2 min;94 ℃ 30 s,50 ℃ 30 s,72 ℃ 1 min,34 cycles;72 ℃ 6 min,4 ℃ for holding.Using this system,24 Hibiscus species could amplify clear and stable bands with high polymorphism without towing.
引文
[1] 王向东,马艳芝,客绍英.11种荆芥种质资源ISSR分析[J].浙江农业学报,2018,30(4):614-621.
[2] 马艳芝,客绍英.不同柴胡种质资源的ISSR和ITS序列分析[J].西北农林科技大学学报(自然科学版),2015,43(1):193-200.
[3] 王庆军,马丽,郝兆祥,等.观赏石榴种质资源遗传多样性的ISSR分析[J].浙江农业学报,2018,30(2):236-241.
[4] 孙雪梅,赵才美,李友勇,等.云南茶树地方品种与野生茶遗传多样性的ISSR分析[J].西南农业学报,2018,31(5):30-35.
[5] 李义良,赵奋成,李福明,等.湿地松×洪都拉斯加勒比松遗传多样性的ISSR分析[J].广西植物,2018,38(6):812-817.
[6] 于恒秀,王淼,梁国华,等.ISSR引物鉴定芍药栽培品种之间亲缘关系的初步研究[J].植物生理学报,2006,42(2):271-274.
[7] 钟丽凡,吕长平,许文婷,等.湖南本土牡丹遗传多样性与亲缘关系的ISSR分析[J].江苏农业科学,2018,46(10):34-37.
[8] 张富民,赖呈纯,黄贤贵,等.196份福建葡萄品种资源亲缘关系的ISSR分析[J].福建农业学报,2018,33(3):263-268.
[9] 沈永宝,施季森,赵洪亮.利用ISSR DNA标记鉴定主要银杏栽培品种[J].林业科学,2005,41(1):202-204.
[10] 王伟丽,何立平,余敏芬,等.12个北美冬青品种的ISSR亲缘关系分析[J].浙江农林大学学报,2018,35(4):612-617.
[11] 孙淑霞,李靖,陈栋,等.ISSR分子标记技术在桃品种鉴定中的应用[J].中国农学通报,2011,27(4):173-177.
[12] 向巧彦,黄夕洋,李虹,等.利用ISSR分子标记检测空间诱导罗汉果DNA突变[J].广西植物,2017,37(5):581-586.
[13] 郑改笑,李夏,熊冬金,等.寒兰离体化学诱变效果的ISSR分析[J].南昌大学学报(理科版),2017,41(3):255-258.
[14] 刘平平,叶开玉,龚弘娟,等.猕猴桃60Co-γ射线辐射诱变植株变异的ISSR分子标记研究[J].西南农业学报,2016,29(10):2457-2462.
[15] 尤根彪,刘伟,王敏彪,等.木槿扦插繁殖技术研究[J].安徽农业科学,2017,45(7):143-144.
[16] 王晓红,任雪羽,刘佳,等.影响木槿扦插生根的因素分析[J].中南林业科技大学学报,2018,38(4):6-9,15.
[17] KWACK B H,KIM S B,LEE C H,et al.Effects of different extent of desiccation on rooting cuttings of Hibiscus syriacus L.when treated with NAA[J].Research Reports of the College of Agriculture Korea University,1988,10(28):81-86.
[18] KWACK B H,YOON B H.A survey on cold injuries of Hibiscus syriacus L.in the central regions of Korea[J] Research Reports of the College of Agriculture Korea University,1986,12(26):25-29.
[19] Tiange产品.DP320:新型植物基因组提取试剂盒[EB/OL].[2015-09-06].http://www.tiangen.com/?productShow/t1/1/id/19.html.
[20] 曹嵩晓.广藿香无菌苗的秋水仙素和EMS诱变及突变体植株遗传多样性的ISSR分析[D].海口:海南大学,2011.
[21] 盖钧锰.试验统计方法[M].北京:中国农业出版社,2003.
[2] 马艳芝,客绍英.不同柴胡种质资源的ISSR和ITS序列分析[J].西北农林科技大学学报(自然科学版),2015,43(1):193-200.
[3] 王庆军,马丽,郝兆祥,等.观赏石榴种质资源遗传多样性的ISSR分析[J].浙江农业学报,2018,30(2):236-241.
[4] 孙雪梅,赵才美,李友勇,等.云南茶树地方品种与野生茶遗传多样性的ISSR分析[J].西南农业学报,2018,31(5):30-35.
[5] 李义良,赵奋成,李福明,等.湿地松×洪都拉斯加勒比松遗传多样性的ISSR分析[J].广西植物,2018,38(6):812-817.
[6] 于恒秀,王淼,梁国华,等.ISSR引物鉴定芍药栽培品种之间亲缘关系的初步研究[J].植物生理学报,2006,42(2):271-274.
[7] 钟丽凡,吕长平,许文婷,等.湖南本土牡丹遗传多样性与亲缘关系的ISSR分析[J].江苏农业科学,2018,46(10):34-37.
[8] 张富民,赖呈纯,黄贤贵,等.196份福建葡萄品种资源亲缘关系的ISSR分析[J].福建农业学报,2018,33(3):263-268.
[9] 沈永宝,施季森,赵洪亮.利用ISSR DNA标记鉴定主要银杏栽培品种[J].林业科学,2005,41(1):202-204.
[10] 王伟丽,何立平,余敏芬,等.12个北美冬青品种的ISSR亲缘关系分析[J].浙江农林大学学报,2018,35(4):612-617.
[11] 孙淑霞,李靖,陈栋,等.ISSR分子标记技术在桃品种鉴定中的应用[J].中国农学通报,2011,27(4):173-177.
[12] 向巧彦,黄夕洋,李虹,等.利用ISSR分子标记检测空间诱导罗汉果DNA突变[J].广西植物,2017,37(5):581-586.
[13] 郑改笑,李夏,熊冬金,等.寒兰离体化学诱变效果的ISSR分析[J].南昌大学学报(理科版),2017,41(3):255-258.
[14] 刘平平,叶开玉,龚弘娟,等.猕猴桃60Co-γ射线辐射诱变植株变异的ISSR分子标记研究[J].西南农业学报,2016,29(10):2457-2462.
[15] 尤根彪,刘伟,王敏彪,等.木槿扦插繁殖技术研究[J].安徽农业科学,2017,45(7):143-144.
[16] 王晓红,任雪羽,刘佳,等.影响木槿扦插生根的因素分析[J].中南林业科技大学学报,2018,38(4):6-9,15.
[17] KWACK B H,KIM S B,LEE C H,et al.Effects of different extent of desiccation on rooting cuttings of Hibiscus syriacus L.when treated with NAA[J].Research Reports of the College of Agriculture Korea University,1988,10(28):81-86.
[18] KWACK B H,YOON B H.A survey on cold injuries of Hibiscus syriacus L.in the central regions of Korea[J] Research Reports of the College of Agriculture Korea University,1986,12(26):25-29.
[19] Tiange产品.DP320:新型植物基因组提取试剂盒[EB/OL].[2015-09-06].http://www.tiangen.com/?productShow/t1/1/id/19.html.
[20] 曹嵩晓.广藿香无菌苗的秋水仙素和EMS诱变及突变体植株遗传多样性的ISSR分析[D].海口:海南大学,2011.
[21] 盖钧锰.试验统计方法[M].北京:中国农业出版社,2003.
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