黑龙江省大豆品种(品系)遗传特性的研究
摘要
本文运用RAPD技术,对黑龙江省10个大豆品种遗传特性进行了研究。计算了10
个品种之间的遗传年相似度和遗传距离,并进行了聚类分析,探讨了它们之间的亲缘关系。
RAPD技术分析结果表明:用13个随机引物对10个大豆品种的核DNA进行了RAPD
扩增,共检出93条扩增片断,多态性片断70条,占75.26%。反映了10个品种之间的
遗传变异;13个随机引物对10个品种分别扩增出11,12,5,4,7,8,3,7,2,5,
10,10,9条带,平均每个引物扩增7.15条带。并对所扩增的所有带确定了分子时范围;
10个大豆品种间的遗传相似度变异范围为0.6848-0.9019,遗传距离变异范围为
0.0981-0.3152,变异最大的是合丰27和90035,最小的是90035和9674。90035和9674
亲缘关系近;合丰27和90035亲缘关系最远。
蛋白质分析结果表明:10个大豆品种中的90035和90024之间的亲缘关系最近,遗
传变异最小。变异最大的是1330与绥4之间和1330与黑农39之间。
This work has researched the genetic characters of 10 soybean variety in Heilongjiang province by RAPD technique, calculated the genetic similar and genetic distance, made the cluster analysis, studied the genetic relationship among the 10 variety.
The results of RAPD analysis is found 93 amplification segments and 70 polymorphism segments, is 75.26% in all of, in the aberrance DNA among 10 soybean variety making RAPD amplification to utilized the 13 random primer. It is found the genetic variations among the 10 variety, there are :11, 12, 5, 4, 7, 8, 3, 7, 2, 5, 10, 10, 9 bands amplificated . from 10 variety with 13 random primer and the average 7.15 bands per primer. The genetic similar among the variety changed in 0.6848to 0.9019, the genetic distance changed in 0.0981 to 0.3152, and the breed change most is Heilongjiang 10 and 90035,the smallest is found in 90035 and 9674, the closed genetic relationship is between 90035 and 9674,and the farthest is between Heifeng 10 and 90035.
The results of Protein analysis is found that the closed genetic relationship is between 90035 and 90024,and the farthest is between 1330 and Sui 4, the farthest is between 1330 and Heinong 39.
个品种之间的遗传年相似度和遗传距离,并进行了聚类分析,探讨了它们之间的亲缘关系。
RAPD技术分析结果表明:用13个随机引物对10个大豆品种的核DNA进行了RAPD
扩增,共检出93条扩增片断,多态性片断70条,占75.26%。反映了10个品种之间的
遗传变异;13个随机引物对10个品种分别扩增出11,12,5,4,7,8,3,7,2,5,
10,10,9条带,平均每个引物扩增7.15条带。并对所扩增的所有带确定了分子时范围;
10个大豆品种间的遗传相似度变异范围为0.6848-0.9019,遗传距离变异范围为
0.0981-0.3152,变异最大的是合丰27和90035,最小的是90035和9674。90035和9674
亲缘关系近;合丰27和90035亲缘关系最远。
蛋白质分析结果表明:10个大豆品种中的90035和90024之间的亲缘关系最近,遗
传变异最小。变异最大的是1330与绥4之间和1330与黑农39之间。
This work has researched the genetic characters of 10 soybean variety in Heilongjiang province by RAPD technique, calculated the genetic similar and genetic distance, made the cluster analysis, studied the genetic relationship among the 10 variety.
The results of RAPD analysis is found 93 amplification segments and 70 polymorphism segments, is 75.26% in all of, in the aberrance DNA among 10 soybean variety making RAPD amplification to utilized the 13 random primer. It is found the genetic variations among the 10 variety, there are :11, 12, 5, 4, 7, 8, 3, 7, 2, 5, 10, 10, 9 bands amplificated . from 10 variety with 13 random primer and the average 7.15 bands per primer. The genetic similar among the variety changed in 0.6848to 0.9019, the genetic distance changed in 0.0981 to 0.3152, and the breed change most is Heilongjiang 10 and 90035,the smallest is found in 90035 and 9674, the closed genetic relationship is between 90035 and 9674,and the farthest is between Heifeng 10 and 90035.
The results of Protein analysis is found that the closed genetic relationship is between 90035 and 90024,and the farthest is between 1330 and Sui 4, the farthest is between 1330 and Heinong 39.
引文
1 白建荣、王秀荣、侯变英,分子标记的类型、特点及在育种中的应用,山西农业科学,1999,27(4):33—38
2 黑龙江省农科院主编,《黑龙江农作物品种志》,黑龙江人民出版社,1979。
3 吉林省农科院大豆研究所编,《中国大豆品种志》,北京农业出版社,1993。
4 陆朝福、朱立煌、植物育种中的分子标记辅助选择,生物工程进展,1995,15(4):11-7
5 李常保、宋建成,RAPD标记与作物改良,生物技术通报,1998,24(6):20-27
6 陆朝福,朱立煌,植物育种中的分子标记辅助选择,生物工程进展,1995,15(4):11-7
7 兰海燕,李立会,蛋向质凝胶电泳技术在农作物品种鉴定中的应用,中国农业科学,2002,35(8):916-920
8 刘润堂,贾炜珑,栽培大豆、野生大豆和半野生大豆脂酶同工酶的研究,山西农业大学学报,1995,15(30):235-237
9 沈法福,丁元杰,刘风珍,分子标记在植物遗传育种中的应用,山东农业大学学报,1997;28(1):83-91
10 许守民,苗以农等,野生大豆种子蛋白含量差异生理及结构基础的探讨,植物学报,1994,36(5):380-384
11 晏月明,大豆品种的聚丙稀酰胺凝胶电泳鉴定研究,西南农业大学学报,1997,19(1):59-61
12 张忠廷、李松涛、王斌,遗传学报,1994,21(5):373—378
13 张志永,栽培大豆品种间RAPD标记的多态性分析及聚类分析,大豆科学,1995,17(1):4—8
14 张立异等,贵农21与p38的SDS-PAGE蛋白质图谱及RAPD分析,麦业作物学报,2000,20(3):89—91
15 Demeke T, R P Adams. PCR Techmology 1994.
16 Landry, B.S. et al., Genetics, 1987, 116, 331-337.
17 Phiuips RL, Vasil IK. DNA-Based Markers in Plants. Khuwer Academic Printed in the Nelheds, 1994.
2 黑龙江省农科院主编,《黑龙江农作物品种志》,黑龙江人民出版社,1979。
3 吉林省农科院大豆研究所编,《中国大豆品种志》,北京农业出版社,1993。
4 陆朝福、朱立煌、植物育种中的分子标记辅助选择,生物工程进展,1995,15(4):11-7
5 李常保、宋建成,RAPD标记与作物改良,生物技术通报,1998,24(6):20-27
6 陆朝福,朱立煌,植物育种中的分子标记辅助选择,生物工程进展,1995,15(4):11-7
7 兰海燕,李立会,蛋向质凝胶电泳技术在农作物品种鉴定中的应用,中国农业科学,2002,35(8):916-920
8 刘润堂,贾炜珑,栽培大豆、野生大豆和半野生大豆脂酶同工酶的研究,山西农业大学学报,1995,15(30):235-237
9 沈法福,丁元杰,刘风珍,分子标记在植物遗传育种中的应用,山东农业大学学报,1997;28(1):83-91
10 许守民,苗以农等,野生大豆种子蛋白含量差异生理及结构基础的探讨,植物学报,1994,36(5):380-384
11 晏月明,大豆品种的聚丙稀酰胺凝胶电泳鉴定研究,西南农业大学学报,1997,19(1):59-61
12 张忠廷、李松涛、王斌,遗传学报,1994,21(5):373—378
13 张志永,栽培大豆品种间RAPD标记的多态性分析及聚类分析,大豆科学,1995,17(1):4—8
14 张立异等,贵农21与p38的SDS-PAGE蛋白质图谱及RAPD分析,麦业作物学报,2000,20(3):89—91
15 Demeke T, R P Adams. PCR Techmology 1994.
16 Landry, B.S. et al., Genetics, 1987, 116, 331-337.
17 Phiuips RL, Vasil IK. DNA-Based Markers in Plants. Khuwer Academic Printed in the Nelheds, 1994.