杨属派间5个种特异性InDel引物及在派间杂交子代鉴别中的应用

doi:10.11707/j.1001-7488.LYKX20230225

摘要/Abstract

摘要： 目的远缘杂交可以实现有利基因的聚合，是种质创新的重要手段。杨属有些派间杂交困难，且杂交子代从形态学难以区分，本研究开发杨属不同派间的特异性引物，为派间杂交创制新种质的真实性鉴定提供技术支撑。方法利用在美洲黑杨和小叶杨中种特异性InDel位点设计引物，并利用SeqHunter2依次比对胡杨、山杨、小叶杨和大叶杨基因组，再用杨属5个派的自然群体材料进行种内保守及种间多态引物的试验验证，筛选出杨属不同派的特异性引物序列，对杨属不同派间杂交子代进行真实性鉴别。结果将从美洲黑杨基因组设计的5 000对InDel引物依次分别比对胡杨、山杨、小叶杨和大叶杨基因组，最后筛选出341对引物在上述5个种中是通用的。从不同染色体上共选取48对引物并合成，利用5个树种各1个DNA检测得到43对引物是通用的，其中19对引物在不同种中扩增条带单一且存在差异。利用自然群体混合DNA对试验验证的19对通用引物进行种间多态性和种内保守性检测，初步获得4对多态性引物。最后再用自然群体DNA对这4对引物进行扩增检测，发现引物Chr12_4341229和 Chr13_10582756在美洲黑杨、小叶杨、山杨、大叶杨和胡杨中均只能扩增出一个位点，引物Chr12_4341229扩增条带分别为148、152、113、152和159 bp，引物Chr13_10582756扩增条带分别为140、144、116、140和159 bp。利用上述2对引物对小胡杨2号、黑胡杨和黑小杨进行鉴定，发现所有杂交子代个体均能检测它们2个亲本的特征带。引物Chr12_4341229和Chr13_10582756一起使用，可以用于美洲黑杨、小叶杨、山杨、大叶杨和胡杨任意组合杂交子代的真实性鉴别。结论本研究获得了杨属5个派间的5个种的特异性InDel引物2对，可以有效地进行杨属不同派5个种之间任意组合种间杂交子代的真实性鉴别，为进一步开展杨树派间杂交创制新种质提供了技术支持。

关键词: 杨属, 远缘杂交, 物种特异性引物, 种间杂交分子鉴别

Abstract: Objective Distant hybridization is an important way for germplasm innovation which can achieve the aggregation of favorable genes. Cross-incompatibility often occurs in some of Populus sects, and interspecific hybrids are difficult to distinguish from its morphology. In this study, species-specific InDel markers were developed to identify the interspecific hybrids from different sects of Populus, so as to lay a foundation for the new germplasm innovation in poplar. Method The primers were developed from species-specific InDel sites in P. deltoides and P. simonii and were used to blast sequentially the genomes of P. euphratica, P. davidiana, P. simonii and P. lasiocarpa using SeqHunter2. Natural individuals from different sects were used to verify the species-specific primers in intra species conservation and inter species polymorphism by PCR amplification test, and the identified species-specific primer sequences for different sects of Populus were screened, and the authenticity of interspecies hybrid progenies among any combinations from the five species in different Populus sects was identified.Result Five thousands of InDel primers were designed from the genome of P. deltoides and used to blast sequentially the genomes of P. euphratica, P. davidiana, P. simonii and P. lasiocarpa. A total of 341 primer pairs were detected as universal markers among the five species. A total of 48 primer pairs from different chromosome were selected and synthesized, and 43 were identified as universal in five species from different sects, of which 19 primer pairs were conservative within individual species and produced length polymorphism of amplified bands in different species. The mixed DNA from natural population was used to test the 19 pairs of universal primers for interspecific polymorphism and intraspecific conservation by PCR amplification, and 4 pairs of polymorphic primers were preliminarily obtained. Finally, natural population DNA was used to amplify and detect these 4 pairs of primers, and it was found that primer pairs of Chr12_4341229 and Chr13_10582756 were species-specific, and could be used to amplify clear and unique bands in P. deltoides, P. simonii, P. davidiana, P. lasiocarpa and P. euphratica. Primer pairs of Chr12_4341229 could be used to amplify the bands with length of 148, 152, 113, 152 and 159 bp, and primer pairs of Chr13_10582756 could be used to amplify the bands with length of 140, 144, 116, 140 and 159 bp separately in the species of P. deltoides, P. simonii, P. davidiana, P. lasiocarpa and P. euphratica. Primers Chr12_4341229 and Chr13_10582756 were used to identify the inter-specific hybrids of P. simonii × P. euphratica, P. deltoides × P. euphratica, and P. deltoides × P. simonii, showing that all the three inter-specific hybrids could amplify two bands which were inherited from the parents used for hybridization. The above two primers were able to be used for verifying the authenticity of progenies from any combination of the five species in different Populus sects.Conclusion In this study, two pairs of species-specific InDel markers have been identified conservative within species and with length polymorphism in the five species from different Populus sects, and can be used to identify inter-specific hybrids from any combination among the five species in Populus. The development of the two species-specific InDel markers will provide technical support for the further germplasm innovation by distant hybridization in Populus.

Key words: Populus, distant hybridization, species-specific primers, molecular identification of hybrids

中图分类号:

戴晓港, 韩峭子, 尹佟明. 杨属派间5个种特异性InDel引物及在派间杂交子代鉴别中的应用[J]. 林业科学, 2024, 60(2): 78-86.

Dai Xiaogang, Han Qiaozi, Yin Tongming. Species-Specific Indel Markers in Five Species from Different Poplar Sects and Their Application in Identification of Inter-Specific Hybrids[J]. Scientia Silvae Sinicae, 2024, 60(2): 78-86.

参考文献

陈赢男, 胡传景, 诸葛强, 等. 2022. 杨树农杆菌遗传转化研究30年. 林业科学, 58(12): 114-129.
Chen Y N, Hu C J, Zhuge Q, et al. 2022. Thirty years of Agrobacterium-mediated genetic transformation of Populus. Scientia Silvae Sinicae, 58(12): 114-129. ［in Chinese］
戴晓港, 陈晨, 薛良交, 等. 2021. 基于物种特异性InDel标记鉴别美洲黑杨与小叶杨的杂交子代. 林业科学, 57(11): 79-84.
Dai X G, Chen C, Xue L J, et al. 2021. Identification of interspecific hybrids between Populus deltoides and P. simonii by using species-specific InDel marker. Scientia Silvae Sinicae, 57(11): 79-84. ［in Chinese］
董天慈. 1980. 小叶杨与胡杨亚属间有性杂交. 遗传, 2(1): 25-28.
Dong T C. 1980. Cross breeding of P. simonii and sub Sect. Turanga. Hereditas, 2(1): 25-28. ［in Chinese］
国家林业和草原局. 2019. 中国森林资源报告(2014-2018). 北京: 中国林业出版社.
National Forestry and Grassland Administration. 2019. China forest resources report (2014-2018). Beijing: China Forestry Publishing House. ［in Chinese］
黄承玲, 姚刚, 田晓玲, 等. 2021. 基于RAD高通量测序的贵州百里杜鹃保护区杜鹃花属分类. 林业科学, 57(2): 72-81.
Huang C L, Yao G, Tian X L, et al. 2021. Phylogenomic analysis of Rhododendron species in Guizhou Baili Rhododendron reserve based on RAD sequencing. Scientia Silvae Sinicae, 57(2): 72-81. ［in Chinese］
贾会霞, 姬慧娟, 胡建军, 等. 2015. 杨树新品种的SSR指纹图谱构建和倍性检测. 林业科学, 51(2): 69-79.
Jia H X, Ji H J, Hu J J, et al. 2015. Fingerprints of SSR markers and ploidy detection for new Populus varieties. Scientia Silvae Sinicae, 51(2): 69-79. ［in Chinese］
贾婕, 冯源恒, 杨章旗, 等. 2014. 松属EST-SSR引物开发及马尾松-湿地松种间特异性鉴别引物筛选. 分子植物育种, 12(5): 963-968.
Jia J, Feng Y H, Yang Z Q, et al. 2014. EST-SSR Primer Development for Pinus and Primers Selection for Interspecies-specific Identification between P. massoniana and P. elliottii. Molecular Plant Breeding, 12(5): 963-968. ［in Chinese］
江锡兵, 张志毅, 龚榜初. 2013. 美洲黑杨与大青杨杂种无性系分子鉴定. 生物技术通报, (3): 102-106.
Jiang X B, Zhang Z Y, Gong B C. 2013. Molecular identification of hybrid clones between Populus deltoides Bartr. and P. ussuriensis Kom. Biotechnology Bulletin, (3): 102-106. ［in Chinese］
李善文, 张志毅, 何承忠, 等. 2004. 中国杨树杂交育种研究进展. 世界林业研究, 17(2): 37-41.
Li S W, Zhang Z Y, He C Z, et al. 2004. Progress on hybridization breeding of poplar in China. World Forestry Research, 17(2): 37-41. ［in Chinese］
李晓宇, 梁德军, 纪纯阳, 等. 2019. 银白杨×N001杨杂交子代及亲本的AFLP分析. 湖南林业科技, 46(3): 38-43.
Li X Y, Liang D J, Ji C Y, et al. 2019. AFLP analysis of hybrid progenies and parents of Populus alba L.×Populus deltoides ‘N001’. Hunan Forestry Science & Technology, 46(3): 38-43. ［in Chinese］
李毅, 刘榕, 孙雪新. 2002. 箭杆杨×胡毛杨良种选育及测定. 林业实用技术, (2): 7-8.
Li Y, Liu R, Sun X X. 2002. Breeding and determination of the elite species of P. nigra var. thevestina×P. euphratica. Practical Forestry Technology, (2): 7-8. ［in Chinese］
彭儒胜. 2018. 美洲黑杨与山杨远缘杂交技术的研究. 四川林业科技, 39(3): 40- 43.
Peng R S. 2018. Technology of intersectional crossing between Populus deltoides and P. davidiana. Journal of Sichuan Forestry Science and Technology , 39(3): 40-43. ［in Chinese］
彭儒胜, 赵鑫闻, 王胜东, 等. 2013. 美洲黑杨与胡杨杂交及其杂种子代亲子鉴定. 辽宁林业科技, (5): 1-4, 27.
Peng R S, Zhao X W, Wang S D, et al. 2013. Paternity identification of hybrids between Populus deltoides and P. euphratica. Liaoning Forestry Science and Technology, (5): 1-4, 27. ［in Chinese］
徐纬英. 1958. 三个杨树新品种培育成功. 林业实用技术, (9): 5.
Xu W Y. 1958. Three new varieties of poplars have been successfully cultivated. Forest Science and Technology, (9): 5. ［in Chinese］
张红莲, 李火根, 胥猛, 等. 2010. 鹅掌楸属种及杂种的SSR分子鉴定. 林业科学, 46(1): 36-39.
Zhang H L, Li H G, Xu M, et al. 2010. Identification of Liriodendron tulipifera, Liriodendron chinense and hybrid Liriodendron using species-specific SSR markers. Scientia Silvae Sinicae, 46(1): 36-39. ［in Chinese］
张金凤, 朱之悌. 2007. 杨树分派的分子系统学与派间杂交研究进展. 安徽农学通报, 13(1): 48-51.
Zhang J F, Zhu Z T. 2007. Advances of researches on molecular phylogeny and intersectional hybridization of Populus sections, Anhui Agriculture Science Bulletin, 13(1): 48-51. ［in Chinese］
张玉平, 鲁绍伟, 李少宁, 等. 2015. RAPD标记鉴定银白杨×新疆杨杂交后代. 西部林业科学, 44(4): 25-29, 42.
Zhang Y P, Lu S W, Li S N, et al. 2015. Identification of Populus alba×Populus alba var. pyramidalis and their hybrids by RAPD. Journal of West China Forestry Science, 44(4): 25-29, 42. ［in Chinese］
DiFazio S P, Slavov G T, Joshi C P. 2011. Populus: a premier pioneer system for plant genomics. Lebanon: Science Publishers, Inc. 1-28.
Eckenwalder J E. 1996. Systematics and evolution of Populus//Stettler R F, Bradshaw Jr. H D, Heilman P E. eds. Biology of Populus and its implications for management and conservation. Ottawa: NRC Research Press, 7-32.
Ma T, Wang J Y, Zhou G K, et al. 2014. Genomic insights into salt adaptation in a desert poplar. Nature Communications, 4(1): 2797.
Ye W W, Dou D L, Wang Y C. 2012. SeqHunter2: a bioinformatics software for genome sequence analysis. https://sourceforge.net/projects/seqhunter2/
Zhang D F, Zhang Z Y, Zhu Z T. 2005. Cross breeding of Populus and its hybrids for cold resistance. Forestry Studies in China, 7(3): 70-76.

[1]	戴晓港,陈晨,薛良交,吴怀通,尹佟明. 基于物种特异性InDel标记鉴别美洲黑杨与小叶杨的杂交子代[J]. 林业科学, 2021, 57(11): 79-84.
[2]	宋红竹张绮纹周春江. 杨树部分种的AFLP遗传多样性分析[J]. 林业科学, 2007, 43(12): 64-69.
[3]	李善文张有慧张志毅安新民何承忠李百炼;. 杨属部分种及杂种的AFLP分析[J]. 林业科学, 2007, 43(1): 35-41.