甘肃金鳟遗传资源评价及其与日本金鳟和道氏虹鳟遗传分化研究
GENETIC RESOURCES EVALUATION OF GANSU GOLDEN TROUT AND GENETIC DIFFERENTIATION OF DONALDSON RAINBOW TROUT AND ALBINO RAINBOW TROUT BASED ON MICROSATELLITE DNA MARKERS
-
摘要: 为分析甘肃金鳟遗传资源状况, 研究利用18 个微卫星DNA 标记, 对甘肃金鳟、日本金鳟和道氏虹鳟3 群体各50 尾个体进行了遗传分析, 以评价甘肃金鳟遗传资源状况并研究其与日本金鳟和道氏虹鳟遗传分化情况。结果表明甘肃金鳟具有较丰富的遗传变异, 15 个微卫星DNA 座位共获得了51 个等位基因, 有效等位基因数(Ne)为1.13, 多态信息含量(PIC)为0.440, 平均观察杂合度(Ho)和期望杂合度(He)分别为0.430 和0.498。在Hardy-Weinberg 平衡条件下, 进行了P 检验, 发现3 个群体均有位点发生了显著偏离; 对3 个群体进行了Fst 值计算, 表明群体间存在着一定程度的遗传分化, 但遗传变异绝大部分存在于品种内。综合分析,认为甘肃金鳟遗传性状基本稳定, 遗传变异度较高, 遗传多样性相对丰富, 具有较大的遗传潜力, 与道氏虹鳟和日本金鳟群体间分化明显, 人工选育对群体的遗传变异产生了一定的影响。研究结果对甘肃金鳟的保种、选育及其合理的推广应用具有一定的指导作用。Abstract: Oncorhynchus mykis is an important reared freshwater species, which has been cultured for more than thirty years in Gansu Province, China. Due to the ecological conditions, different feeding manners, the various breeding goals and some native breeds had been formed in the past years, such as Gansu golden trout, which had past the National Aquaculture Species Identification Committee identifying and was recommend as the species reared in the northwestern areas. However, the genetic differentiation and the genetic variability are still unknown. In order to get insight into the genetic variability in its population and provide the genetic background and guidance for its conservation and utilization, 20 microsatellite DNA markers were applied to analyze genetic diversity and genetic differentiation.Genome DNA was extracted from each 50 individuals in Donaldson rainbow trout, Albino rainbow trout and Gansu golden trout in total 150 individuals. Each fish was extracted from ethanol-preserved caudal fin by using phenol-chloroform method. The PCR was performed in a 25 μL reaction and the products were isolated by electrophoresis on 10% polyacrylamide gel and visualized by silver staining. The data were calculated and analyzed by statistic method. 18 microsatellite primers were successfully amplified, 13 loci with reasonable polymorphism in the three populations. And there were a large range of genetic variation existing in Gansu golden trout. The number of alleles in these loci ranged from 2 to 7. 51 alleles was obtained; the mean number of alleles was 3.00; the value of mean polymorphism information content (PIC) was 0.440, the PIC value was more than 0.5 in locus AF346692, AF375011, AF352739, AF352746, AF352747, AF352751, AF352756, AF352763 and AF352765; the PIC value was more than 0.25 and less than 0.5 in locus AF352767 and AF352762; the PIC value was less than 0.25 in locus AF352750 and AF352749. The observed heterozygosity (Ho) and the expected heterozygosity (He) were calculated based on frequencies of genotypes and alleles of each microsatellite locus, the value of average observed heterozygosity (Ho) and expected heterozygosity (He) were 0.498,0.498 respectively, which showed that Gansu golden trout had relatively abundant genetic diversity.Genetic distance analysis showed that the largest distance was between Donaldson rainbow trout and Gansu golden trout and the smallest distance was between Albino rainbow trout and Gansu golden trout. Furthermore, it was found that some microsatellite loci of the three breeds deviated from Hardy-Weinberg equilibrium, where the majority of the variance in the Oncorhynchus mykiss was within populations (80.7%), and small proportion was among populations (19.3%). The medium level of overall genetic diversity and medium Fixation Index (Fst=0.193) indicated that the Oncorhynchus mykis reared in Gansu had relatively medium genetic variation. Obviously, the genetic characteristics and the genetic status of Gansu golden trout are getting stable. The genetic differentiation was significant among the three breeds, and selective breeding impacted genetic variations on the breeds. The results provided the guidance for its breeding, spreading, conservation and utilization.
-
Keywords:
- Gansu golden trout /
- Microsatellite /
- Genetic differentiation /
- Genetic diversity
-
-
[1] Liang S X, Sun X W, Bai J J, et al. Genetic analysis for culturedLargemouth bass (Micropterus salmoides) in Chinawith microsatellites [J]. Acta Hydrobiologica Sinica, 2008,32(5): 694—700 [梁素娴, 孙效文, 白俊杰, 等. 微卫星标记对中国引进加州鲈养殖群体遗传多样性的分析. 水生生物学报, 2008, 32(5): 694—700].
[2] Robert D Ward, Knut E Jorstad, Greg B Maguire. Microsatellitediversity in rainbow trout (Oncorhynchus mykiss) introducedto Western Australia [J]. Aquaculture, 2003, 219:169—179.
[3] Riho Gross, Priit Lulla, Tiit Paaver. Genetic variability anddifferentiation of rainbow trout (Oncorhynchus mykiss)strains in northern and Eastern European [J]. Aquaculture,2007, 272(S1): S139—S146.
[4] Zhao Y Y, Zhu X C, Sun X W. Genetic diversity of the culturedpopulations of six Rainbow Trout (Oncorhynchusmykiss) by microsatellite [J]. Hereditas, 2006, 28(8): 956—962 [赵莹莹, 朱晓琛, 孙效文. 虹鳟6 个养殖群体遗传多样性的微卫星分析. 遗传, 2006, 28(8): 956—962].
[5] Yu D M, Ma H T, Sun X W. Genetic diversity in three RainbowTrout populations as revealed by microsatellite markers[J]. Chinese Journal of Zoology, 2007, 42(4): 8—14 [于冬梅,马海涛, 孙效文. 三个虹鳟养殖群体遗传结构的微卫星分析. 动物学杂志, 2007, 42(4): 8—14].
[6] Zhang Y P, Wang H F, Su J H, et al. Studies on genetic diversityof 3 cultivated populations of Oncorhynchus mykissby RAPD technique [J]. Journal of Gansu Agricultural University,2008, 43(3): 37—41 [张艳萍, 王海芳, 苏军虎, 等.甘肃金鳟、日本金鳟和道氏虹鳟的随机扩增多态DNA 分析. 甘肃农业大学学报, 2008, 43(3): 37—41].
[7] Botstein D, White R L, Sckolnick M, et al. Construction of agenetic linkage map in man using restriction fragment lengthpolymorphism [J]. Am J Hum Genetic, 1980, 32(3): 314—331.
[8] Nei M. Genetic distance between populations [J]. Am Nat,1972, 106: 283—292.
[9] Crow A J, Kimura M. Evolution in sexual and asexual population[J]. Am Nat, 1965, 99: 439—450.
[10] Kanno M, Li Q, Kijima A. Isolation and characterization oftwenty microsatellite loci in Japanese sea cucumber (Stichopusjaponicus) [J]. Mar Biotechnol, 2005, 7(3): 179—183.
[11] Ardren W R, Borer S. Inheritance of 12 microsatellite loci inOncorhynchus mykiss [J]. J Hered, 1999, 90(5): 529—536.
[12] Zhan A B, Bao Z M, Hui M, et al. Inheritance pattern of EST—SSRs in self—fertilized larvae of the bay scallop Argopectenirradians [J]. Ann Zool Fennici, 2007, 44: 259—268.
[13] Lehoczky I, Magyary I, Hancz C, et al. Preliminary studieson the genetic variability of six Hungarian common carpstrains using microsatellite DNA markers [J]. Hydrobiogia,2005, 533: 223—228.
[14] Liang J, Li D J, Lu L Q. Microsatellite variation of Japaneseeel (Anguilla Japonica) and European eel (A. arzgailla) [J].Oceanologiaet Limnologia Sinica, 2003, 34(4): 414—451[梁俊, 李道季, 卢莉琼. 日本鳗鲡 (Anguilla japorzira)和欧洲鳗鲡 (A. arzgailla) 的微卫星差异. 海洋与湖沼,2003, 34(4): 414—451].
[15] Zhang T S, Wang Q Y, Liu P, et al. Genetic diversity analysison selected populations of shrimp Fenneropenaeus chinensisby microsatellites [J]. Oceanologia Etlimnologia Sinica,2005, 36(1): 72—81 [张天时, 王清印, 刘萍, 等. 中国对虾(Fenneropenaeus chinensis)人工选育群体不同世代的微卫星分析. 海洋与湖沼, 2005, 36(1): 72—81].
[16] Ball A O, Leonard S, Chapman R W. Characterization of(GT), microsatellites from native white shrimp Penaeussetiferus[J]. Mol Ecol, 1998, 7: 1251—1253.
[17] Barker J S, Moore F, Hetzel S S, et al. Genetic diversity ofAsia water buffalo (Bualus bubalis) microsatellite variationand a comparison with Protein-coding loci [J]. Animal Genetics,1997, 28(2): 103—115.
[18] Allendorf F W, Phelps S R. Loss of genetic variation in ahatcherystock of cut throat trout [J]. Translations Am FishSociety, 1980, 109: 537—543.
[19] Wang B Q, Jia Z H, Xu L W, et al. A comparison study onperformance among albino rainbow trout and donaldsonrainbow trout and their filial generation [J]. Chinese Journalof Fisheries, 2005, 18(1): 38—42 [王丙乾, 贾钟贺, 徐连伟, 等. 日本金鳟(Oncorhyncus mykiss)和道氏虹鳟及其杂交后代生产性能的比较研究. 水产学杂志, 2005, 18(1):38—42].
[20] Kincaid H L. Effects of inbreeding on rainbow trout populations[J]. Transactions of the American Fisheries Society,1976, 2: 273—280.
-
期刊类型引用(13)
1. 宋玉芳,黄进强,李永娟,吴深基,赵璐,孙同振,张东强. 虹鳟Gch1基因的克隆、序列分析与表达研究. 海洋渔业. 2024(06): 657-668 . 
百度学术
2. 杨顺文,杨濯羽,苏子郡,焦文龙,卡伟,史小宁. 基于微卫星标记探究5个虹鳟和金鳟养殖群体的遗传多样性. 青海畜牧兽医杂志. 2023(04): 47-52+63 . 百度学术
3. 刘立龙,姬翔. 道氏虹鳟和日本金鳟生长激素(GH)基因多态性比较研究. 畜牧兽医杂志. 2020(05): 11-13+17 . 百度学术
4. 李谨. 鱼生长激素(GH)基因多态性分析. 农家参谋. 2020(22): 135-136 . 百度学术
5. 杨濯羽,张艳萍,娄忠玉,焦文龙,王太. 基于微卫星标记的22个道氏虹鳟选育家系的遗传多样性研究. 淡水渔业. 2016(03): 3-9 . 百度学术
6. 王伟伟,刘青,魏琳琳. 基于mtDNA控制区序列的我国养殖鲑亚科鱼类系统关系. 淡水渔业. 2015(05): 24-28 . 百度学术
7. 虎永彪,张艳萍,杜岩岩,娄忠玉,焦文龙. 甘肃金鳟生长激素基因多态性与生长性状的相关分析. 淡水渔业. 2014(05): 100-103 . 百度学术
8. 杨娟,刘山东,施海娜,胡丹丹,王建福,宋超,张久盘,刘哲. 基于MHC-DAB基因内含子序列的3种虹鳟养殖群体遗传结构分析. 中国农业科技导报. 2013(06): 135-141 . 百度学术
9. 苏军虎,张艳萍,娄忠玉,刘焕章,焦文龙,魏彦明. 黄河上游极边扁咽齿鱼种群遗传结构. 动物分类学报. 2012(01): 29-35 . 百度学术
10. 杨建宝,张艳萍,苏军虎,娄忠玉,焦文龙,王太,魏彦明. 引进美洲红点鲑群体遗传多样性微卫星的分析. 四川动物. 2012(03): 348-352 . 百度学术
11. 苏军虎,张艳萍,娄忠玉,刘焕章,焦文龙,杨建宝,魏彦明. 基于线粒体控制区序列的黄河上游厚唇裸重唇鱼种群遗传结构. 生态学报. 2012(13): 4191-4198 . 百度学术
12. 崔海玉,马洪雨,马春艳,乔振国,马群群,亓磊,沈盎绿,马凌波. 利用微卫星标记比较分析拟穴青蟹不同家系的遗传多样性. 海洋渔业. 2011(03): 274-281 . 百度学术
13. 苏军虎,张艳萍,娄忠玉,焦文龙,王太,杨建宝,吴建平,魏彦明. 甘肃金鳟AFLP体系建立及应用. 中国农学通报. 2011(07): 400-404 . 百度学术
其他类型引用(4)
计量
- 文章访问数: 1138
- HTML全文浏览量: 1
- PDF下载量: 588
- 被引次数: 17
下载: