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

doi:10.11707/j.1001-7488.20211108

摘要/Abstract

摘要：

目的: 针对杨树种间杂交子代苗期形态不易区分的问题，利用美洲黑杨和小叶杨物种特异性InDel位点开发标记对种间杂交子代进行快速鉴别，为黑杨派和青杨派种间杂交子代鉴定、分子标记辅助育种等研究提供重要的参考技术。方法: 以美洲黑杨、小叶杨及其杂交子代为试验材料，根据美洲黑杨和小叶杨重测序结果分析物种特异性InDel位点并设计引物，采用非变性聚丙烯酰胺凝胶电泳对引物进行通用性和物种特异性检测，用筛选出的物种特异的引物，对种间杂交子代的真实性进行鉴别。结果: 分别将10个个体的美洲黑杨和小叶杨重测序序列比对到美洲黑杨基因组，共获得长度差异大于5 bp的InDel位点359 733个，其中种内特异、种间存在差异的InDel位点18 418个。采用Primer3在美洲黑杨基因组中的17 956个位点成功设计引物。在不同染色体共选取10对引物，采用SeqHunter2将引物序列比对到小叶杨基因组，共有6对引物在小叶杨中是通用的。采用非变性聚丙烯酰胺凝胶电泳检测，发现引物Psi2-1和Psi13-14在美洲黑杨和小叶杨中存在差异。利用美洲黑杨和小叶杨自然群体各50个个体对上述2个引物进行检测，发现引物Psi2-1在美洲黑杨中扩增出128 bp的特异性产物，在小叶杨中扩增出139 bp的特异性产物，在真实的种间杂交子代中扩增出128 bp和139 bp 2条产物；引物Psi13-14在美洲黑杨中扩增出132 bp的特异性产物，在小叶杨中扩增出144 bp的特异性产物，在真实的种间杂交子代中扩增出132 bp和144 bp 2条产物。2对引物对美洲黑杨与小叶杨种间杂交子代鉴别准确率达100%。结论: 获得了美洲黑杨和小叶杨物种特异性InDel标记2对，上述标记可以有效地用于美洲黑杨与小叶杨种间杂交子代的真实性鉴别。

关键词: 美洲黑杨, 小叶杨, 种间杂交, 物种特异性引物, 分子鉴别

Abstract:

Objective: The identification of interspecific poplar hybrids at seedling stage is challenging because of the morphological similarity. Here, we developed species-specific InDel markers to identify the interspecific hybrids between Populus deltoides and P. simonii, in order to lay a foundation for the identification of hybrids and molecular marker-assisted breeding in poplar. Method: Ten individuals of each P. deltoides and P. simonii were resequenced to screen species-specific InDels, which were further applied for primer designing. The resulted primers were tested for their versatility and specificity using 8% non-denature polyacrylamide gel electrophoresis. The selected species-specific polymorphic primers were used to identify interspecific hybrid progeny between P. deltoides and P. simonii. Result: Resequencing reads from each ten individuals of P. deltoides and P. simonii were mapped onto the genome of P. deltoides for comparisons, and a total of 359 733 InDel sites with a length difference larger than 5 bp were obtained, of which 18 418 sites are conserved within species but different between species. Based on the genome sequence of P. deltoides, 17 956 primer pairs were successfully designed using Primer3. Ten primer pairs from different chromosomes were selected and tested for their versatile in P. simonii by SeqHunter2 software. A total of six primer pairs were versatile between P. deltoides and P. simonii. The electrophoresis with 8% non-denature polyacrylamide gel showed that primers Psi2-1 and Psi13-14 were polymorphic between P. deltoides and P. simonii. Both primer pairs were then screened in natural population of P. deltoides and P. simonii each with fifty clones separately. The primers Psi2-1 amplified specific bands of 128 bp and 139 bp respectively in P. deltoides and P. simonii. And both of these bands were amplified in interspecific hybrids. Primers Psi13-14 amplified specific bands of 132 bp and 144 bp respectively in P. deltoides and P. simonii. And both of these two bands were successfully amplified in the interspecific hybrids. The two pairs of primers can be used to identify the hybrids between P. deltoides and P. simonii with an accuracy of 100%. Conclusion: This study confirmed that species-specific InDel markers can be used for the identification of interspecific hybrids of P. deltoides and P. simonii, which is of great significance for the identification of interspecific hybrid and breeding of new varieties of poplar.

Key words: Populus deltoides, Populus simonii, interspecific-cross, species-specific marker, molecular identification

中图分类号:

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.

Xiaogang Dai,Chen Chen,Liangjiao Xue,Huaitong Wu,Tongming Yin. Identification of Interspecific Hybrids between Populus deltoides and P. simonii by Using Species-Specific InDel Marker[J]. Scientia Silvae Sinicae, 2021, 57(11): 79-84.

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参考文献 0

	陈洪伟, 康向阳, 张正海, 等. 小青杨与胡杨杂交及其杂种后代分子鉴定. 北京林业大学学报, 2009, 31 (2): 86- 91. doi: 10.3321/j.issn:1000-1522.2009.02.013
	Chen H W , Kang X Y , Zhang Z H , et al. Production and molecular identification of hybrids between Populus pseudo-simonii Kitag. and P. euphratica Oliv. Journal of Beijing Forestry University, 2009, 31 (2): 86- 91. doi: 10.3321/j.issn:1000-1522.2009.02.013
	冯芳君, 罗利军, 李荧, 等. 水稻InDel和SSR标记多态性的比较分析. 分子植物育种, 2005, 3 (5): 725- 730. doi: 10.3969/j.issn.1672-416X.2005.05.024
	Feng F J , Luo L J , Li Y , et al. Comparative analysis of polymorphism of InDel and SSR markers in rice. Molecular Plant Breeding, 2005, 3 (5): 725- 730. doi: 10.3969/j.issn.1672-416X.2005.05.024
	符毓秦, 刘玉媛, 李均安, 等. 美洲黑杨杂种无性系-陕林3、4号杨的选育. 陕西林业科技, 1990, (3): 1- 9, 13.
	Fu Y Q , Liu Y Y , Li J A , et al. Cotton wood hybrided clones selection of Shaanlin No. 3 and No. 4. Shaanxi Forest Science and Technology, 1990, (3): 1- 9, 13.
	李善文, 张志毅, 何承忠, 等. 中国杨树杂交育种研究进展. 世界林业研究, 2004, 17 (2): 37- 41. doi: 10.3969/j.issn.1001-4241.2004.02.010
	Li S W , Zhang Z Y , He C Z , et al. Progress on hybridization breeding of poplar in China. World Forestry Research, 2004, 17 (2): 37- 41. doi: 10.3969/j.issn.1001-4241.2004.02.010
	李晓宇, 梁德军, 纪纯阳, 等. 银白杨×N001杨杂交子代及亲本的AFLP分析. 湖南林业科技, 2019, 46 (3): 38- 43. doi: 10.3969/j.issn.1003-5710.2019.03.007
	Li X Y , Liang D J , Ji C Y , et al. AFLP analysis of hybrid progenies and parents of Populus alba L. ×Populus deltoides 'N001'. Hunan Forestry Science & Technology, 2019, 46 (3): 38- 43. doi: 10.3969/j.issn.1003-5710.2019.03.007
	李毅, 刘榕, 孙雪新. 箭杆杨×胡杨良种选育及测定. 林业实用技术, 2002, (2): 7- 8.
	Li Y , Liu R , Sun X X . Breeding and determination of the good species of P. nigra var. thevestina×P. euphratica. Practical Forestry Technology, 2002, (2): 7- 8.
	吕文, 杨自湘, 王燕, 等. 中国北方小叶杨资源与发展. 防护林科技, 2001, (4): 33- 36. doi: 10.3969/j.issn.1005-5215.2001.04.012
	Lü W , Yang Z X , Wang Y , et al. Populus simonii resources and development in northern China. Protection Forest Science and Technology, 2001, (4): 33- 36. doi: 10.3969/j.issn.1005-5215.2001.04.012
	马常耕. 我国杨树杂交育种的现状和发展对策. 林业科学, 1995, 31 (1): 60- 68.
	Ma C G . Status and development strategies of poplar hybrid breeding in China. Scientia Silvae Sinicae, 1995, 31 (1): 60- 68.
	彭儒胜, 赵鑫闻, 王胜东, 等. 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, 2013, (5): 1- 4. doi: 10.3969/j.issn.1001-1714.2013.05.001
	Peng R S , Zhao X W , Wang S D , et al. Paternity identification of hybrids between Populus deltoides and P. euphratica. Liaoning Forestry Science and Technology, 2013, (5): 1- 4. doi: 10.3969/j.issn.1001-1714.2013.05.001
	苏晓华, 黄秦军, 张冰玉, 等. 中国杨树良种选育成就及发展对策. 世界林业研究, 2004, 17 (1): 46- 49. doi: 10.3969/j.issn.1001-4241.2004.01.010
	Su X H , Huang Q J , Zhang B Y , et al. Achievements and development strategies of improved poplar breeding in China. World Forestry Research, 2004, 17 (1): 46- 49. doi: 10.3969/j.issn.1001-4241.2004.01.010
	王明庥, 黄敏仁, 吕士行, 等. 1987. 黑杨派新无性系研究Ⅰ: 苗期测定. 南京林业大学学报: 自然科学版, (2): 1-12.
	Wang M X, Huang M R, Lü S X, et al. Study of new clones of the Aigeiros poplar I: Nursery testing. Journal of Nanjing Forestry University: Natural Sciences Edition, (2): 1-12. [in Chinese]
	徐纬英. 三个杨树新品种培育成功. 林业实用技术, 1958, (9): 5.
	Xu W Y . Three new varieties of poplars have been successfully cultivated. Forest Science and Technology, 1958, (9): 5.
	张红莲, 李火根, 胥猛, 等. 鹅掌楸属种及杂种的SSR分子鉴定. 林业科学, 2010, 46 (1): 36- 39. doi: 10.3969/j.issn.1672-8246.2010.01.007
	Zhang H L , Li H G , Xu M , et al. Identification of Liriodendron tulipifera, Liriodendron chinense and hybrid Liriodendron using species-specific SSR markers. Scientia Silvae Sinicae, 2010, 46 (1): 36- 39. doi: 10.3969/j.issn.1672-8246.2010.01.007
	张玉平, 鲁绍伟, 李少宁, 等. RAPD标记鉴定银白杨×新疆杨杂交后代. 西部林业科学, 2015, 44 (4): 25- 29.
	Zhang Y P , Lu S W , Li S N , et al. Identification of Populus alba×Populus alba var. pyramidalis and their hybrids by RAPD. Journal of West China Forestry Science, 2015, 44 (4): 25- 29.
	Cros D , Teissier E . Breeding strategies with poplars in Europe. Forest Ecology & Management, 1984, 8 (1): 23- 39.
	Garrison E, Marth G. 2012. Haplotype-based variant detection from short-read sequencing. arXiv, https://arxiv.org/abs/1207.3907.
	Li H , Durbin R . Fast and accurate long-read alignment with Burrows-Wheeler transform. Bioinformatics, 2010, 26 (5): 589- 595. doi: 10.1093/bioinformatics/btp698
	Li H , Handsaker B , Wysoker A , et al. Genome Project Data Processing S: The Sequence Alignment/Map format and SAMtools. Bioinformatics, 2009, 25 (16): 2078- 2079. doi: 10.1093/bioinformatics/btp352
	Väli V , Brandström M , Johansson M , et al. Insertion-deletion polymorphisms(indels) as genetic markers in natural populations. BMC Genetics, 2008, 9 (1): 8.
	Ye W W, Dou D L, Wang Y C. 2012. SeqHunter2: a bioinformatics software for genome sequence analysis. https://sourceforge.net/projects/seqhunter2/files/.

序号	引物名称 Primer name		染色体位置 Chromosome position/bp		引物序列 Primer sequence(5′—3′)	SeqHunter2检测通用性 Transferability analyzed by SeqHunter2
1	Psi2-1	F	ChrⅡ	6 011 070	TTGTGCCTTTTTGTTTCACG	√
1	Psi2-1	R	ChrⅡ	6 011 070	TGAACAAAAGCCACCATAGC	√
2	Psi10-2	F	ChrⅩ	828 530	AATGGGGTAGGCAAAGGTCT	√
2	Psi10-2	R	ChrⅩ	828 530	TCGCATGAACCGGCTATAAT	√
3	Psi11-5	F	ChrⅪ	705 972	GAACGCAACACTGTCTTCCC	×
3	Psi11-5	R	ChrⅪ	705 972	ACGATCCATGGGATTCTTCA	×
4	Psi11-6	F	ChrⅪ	781 192	CCTTAAGTTTTTGTTCCCCG	×
4	Psi11-6	R	ChrⅪ	781 192	TGGGATTTGCACCTGATATG	×
5	Psi11-7	F	ChrⅪ	1 251 475	GGCCTTCCTTCACATCAAGA	√
5	Psi11-7	R	ChrⅪ	1 251 475	CAGGTAATCGGAAGGGCTTT	√
6	Psi11-8	F	ChrⅪ	137 601	ATCCGAGCTGTGTTGCTCTT	√
6	Psi11-8	R	ChrⅪ	137 601	GTCATGGGGACAACTTTGCT	√
7	Psi12-11	F	ChrⅫ	375 716	GAGACGATCCCGATCTACCA	×
7	Psi12-11	R	ChrⅫ	375 716	AAAGGAATCCTCGGGACAGT	×
8	Psi12-12	F	ChrⅫ	370 456	TCTCAACACCCCAGATGAAA	√
8	Psi12-12	R	ChrⅫ	370 456	CCAACAAAAGGCGAACAAGT	√
9	Psi13-14	F	ChrⅩⅢ	65 102	GGTGACCTTCATCGTGAAAAA	√
9	Psi13-14	R	ChrⅩⅢ	65 102	AGCCCCACATGTGCATACTT	√
10	Psi13-15	F	ChrⅩⅢ	84 912	TGGATTGCAAGCTTTCTCAA	×
10	Psi13-15	R	ChrⅩⅢ	84 912	AGCATGCAATTGAAGACCAA	×

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[14]	潘惠新刘晓宇唐进根严敖金谢寅峰黄敏仁. 美洲黑杨叶片主要化学物质差异及其对杨四瘿螨的抗性[J]. 林业科学, 2008, 44(10): 76-81.
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