基于荧光SSR构建中国糜子核心种质DNA分子身份证

doi:10.3864/j.issn.0578-1752.2023.12.002

中国农业科学 ›› 2023, Vol. 56 ›› Issue (12): 2249-2261.doi: 10.3864/j.issn.0578-1752.2023.12.002

• 作物遗传育种·种质资源·分子遗传学 • 上一篇下一篇

基于荧光SSR构建中国糜子核心种质DNA分子身份证

薛亚鹏¹(), 丁艺冰¹, 王宇卓¹, 王晓丹¹, 曹晓宁², SANTRA Dipak K³, 陈凌², 乔治军²(), 王瑞云¹^,²()

¹ 山西农业大学农学院，中国山西太谷030801
² 山西农业大学农业基因资源研究中心/农业农村部黄土高原作物基因资源与种质创制重点实验室/杂粮种质资源发掘与遗传改良山西省重点实验室，中国山西太原 030031
³ 内布拉斯加大学林肯分校农艺系小宗粮豆研究与推广中心，美国内布拉斯加州斯克茨布拉夫 69361

收稿日期:2023-02-01 接受日期:2023-04-01 出版日期:2023-06-16 发布日期:2023-06-27
通信作者: 王瑞云，E-mail：wry925@126.com。乔治军，E-mail：nkypzs@126.com
联系方式: 薛亚鹏，E-mail：745703453@qq.com。
基金资助:
国家自然科学基金(31271791); 现代农业产业技术体系建设专项资金(CARS-06-13.5-A16); 山西省现代农业产业技术体系建设专项资金(2023CYJSTX03-12); 山西省重点研发项目(2022ZDYF110)

Construction of DNA Molecular Identity Card of Core Germplasm of Broomcorn Millet in China Based on Fluorescence SSR

XUE YaPeng¹(), DING YiBing¹, WANG YuZhuo¹, WANG XiaoDan¹, CAO XiaoNing², SANTRA Dipak K³, CHEN Ling², QIAO ZhiJun²(), WANG RuiYun¹^,²()

¹ College of Agronomy, Shanxi Agricultural University, Taigu 030801, Shanxi, China
² Center for Agricultural Genetic Resources Research, Shanxi Agricultural University/Key Laboratory of Crop Gene Resources and Germplasm Enhancement on Loess Plateau, Ministry of Agriculture and Rural Affairs/Shanxi Key Laboratory of Genetic Resources and Genetic Improvement of Minor Crops, Taiyuan 030031, Shanxi, China
³ Panhandle Research & Extension Center, Department of Agronomy and Horticulture, University of Nebraska-Lincoln, Scottsbluff, 69361, Nebraska, USA

Received:2023-02-01 Accepted:2023-04-01 Published:2023-06-16 Online:2023-06-27

摘要/Abstract

摘要：

【目的】糜子（Panicum miliaceum L.）作为一种古老的粟类作物，种质丰富，基于荧光SSR标记构建其DNA分子身份证可为资源的数字化管理提供理论依据和分子检测工具。【方法】以235份中国糜子核心种质为试验材料，对山西农业大学农学院糜子作物分子育种课题组前期开发的糜子特异性SSR标记进行多次PCR筛选和优化后获取核心引物。基于糜子参考基因组信息，经过BLAST序列比对后将核心标记进行染色体定位。在SSR引物的5′端标注荧光（FAM/HEX），利用毛细管电泳给出材料的基因型，采用“0，1”二进制编码方式记录扩增条带的有无，使用ID Analysis 4.0检测材料的区分程度。采用十进制（0—9）统计扩增片段大小以获得材料的字符串分子身份证。使用Popgene、Powermarker、MEGA、NTSYS进行遗传多样性、遗传聚类和主成分分析。利用二维码在线软件（https://cli.im/）给出材料的二维码DNA分子身份证。【结果】PCR扩增结果发现，7个荧光SSR（RYW3、RYW6、RYW11、RYW18、RYW37、RYW43和RYW125）组合在一起可以将235份材料全部区分开。BLAST结果表明，RYW18、RYW37分布在第2染色体，分别位于0.60和0.80 cM处；RYW125位于第4染色体，定位在10.40 cM处；RYW43、RYW6分布在第5染色体，分别位于52.80和53.00 cM处；RYW11和RYW3定位在第6染色体，分别位于2.10和20.70 cM处。遗传多样性分析结果表明，235份材料在7个位点共检出87个等位变异，每个位点检出3（RYW11）—25（RYW6）个，平均为12.4286；检出Shannon多样性指数（I）变幅为0.2055（RYW18）—2.0587（RYW6），平均1.1398；观测杂合度（Ho）为0.0086（RYW11）—0.9455（RYW18）；期望观测杂合度（He）为0.0795（RYW18）—0.7452（RYW6）；Nei’s基因多样性指数（Nei）为0.0793（RYW18）—0.7452（RYW6）；多态性信息含量（PIC）为0.0334（RYW11）—0.8071（RYW6），平均为0.5185。聚类分析和主成分分析均将材料划归8个类群。将电泳条带进行数字编码，利用7个标记组合，构建了全部材料的字符串和二维码DNA分子身份证。【结论】以235份中国糜子核心种质为试验材料，利用PCR扩增和毛细管电泳筛选到7个糜子荧光SSR核心标记。基于糜子参考基因组信息将上述标记定位在4条染色体上。利用上述标记扩增供试材料，给出遗传多样性衡量参数，基于遗传距离将材料聚为8个类群，主成分分析解决了聚类结果中出现的偏差。依照最少引物区分最多种质的原则，利用十进制编码方式给出材料的字符串DNA分子身份证，结合表型数据，利用二维码在线软件构建了全部材料的二维码DNA分子身份证。

关键词: 糜子, 毛细管电泳, 荧光SSR, DNA分子身份证

Abstract:

【Objective】As an ancient minor grain crop, broomcorn millet ( Panicum miliaceum L. ) is abundant in germplasm. The construction of their DNA molecular identity based on fluorescent SSR markers would provide theoretical basis and molecular detection tool for digital management of resources. 【Method】Two hundred and thirty five broomcorn millet core accessions from China were used as experimental material, polymerase chain reaction were conducted several times using the broomcorn millet specific SSR markers which developed previously by the Broomcorn Millet Crop Molecular Breeding Research Group of the Agronomy College in Shanxi Agricultural University, core markers were obtained. With the given reference genome information of broomcorn millet, the core markers were mapped on chromosomes through BLAST sequence alignment. Fluorescence (FAM/HEX) was labeled on the 5' end of the SSR primer, the genotype of the material was given by capillary electrophoresis. Using binary coding means of expression, “0, 1” was written representing the presence or absence of amplified bands, and the discrimination of the material was detected by the software ID Analysis 4.0. Decimal (0-9) coding methods were used to calculate the size of the amplified fragments so as to obtain the character string molecular identity card of the accession. Genetic diversity, genetic clustering and principal component analysis were performed using the softwares Popgene, Powermarker, MEGA and NTSYS. The two-dimensional code DNA molecular identity card of the accession was given using the two-dimensional code online software (https://cli.im/). 【Result】PCR amplification results showed that all the 235 accessions could be separated by 7 fluorescent SSR markers (RYW3, RYW6, RYW11, RYW18, RYW37, RYW43 and RYW125) combined together. BLAST results showed that RYW18 and RYW37 were distributed on Chromosome 2, located at 0.60 cM and 0.80 cM, respectively. RYW125 is located on Chromosome 4 at 10.40 cM. RYW43 and RYW6 were distributed on Chromosome 5, located at 52.80 cM and 53.00 cM, respectively. RYW11 and RYW3 were located on Chromosome 6 at 2.10 cM and 20.70 cM, respectively. Genetic diversity analysis showed that 87 alleles were detected at 7 loci among all accessions, 3 (RYW11)-25 (RYW6) alleles were detected at each locus, with an average of 12.4286. Shannon diversity index (I) was detected and ranged from 0.2055 (RYW18) to 2.0587 (RYW6), with an average of 1.1398. The observed heterozygosity (Ho) was 0.0086 (RYW11)-0.9455 (RYW18). The expected observed heterozygosity (He) was 0.0795 (RYW18)-0.7469 (RYW11). Nei’s gene diversity index (Nei) was 0.0793 (RYW18)-0.7452 (RYW6). The polymorphism information content (PIC) was 0.0334 (RYW11)-0.8071 (RYW6), with an average of 0.5185. The results of cluster analysis and principal component analysis showed that 235 accessions were classified into 8 groups. The electrophoretic bands were number coding, and 7 marker combinations were used to construct the character string and two-dimensional code DNA molecular ID of all the accessions.【Conclusion】Two hundred and thirty five broomcorn millet core germplasms from China were used as material, polymerase chain reaction and capillary electrophoresis were conducted, 7 core SSR markers were screened. With the given reference genome information of broomcorn millet, the above markers were mapped on 4 chromosomes. Used the above SSR markers, genetic diversity analysis of all accessions was conducted and genetic diversity parameters were obtained. Based on Cluster analysis, all accessions were classified into 8 groups. Principal component analysis result resolved the deviation occured in Cluster analysis. According to the principle of most accessions were tell apart using the least markers, decimal (0-9) coding methods were used to calculate the size of the amplified fragments so as to obtain the character string molecular identity card of the accession. Combined the phenotype data with the above character string, two-dimensional code DNA molecular ID of all the accessions were developed.

Key words: broomcorn millet, capillary electrophoresis, fluorescent SSR, DNA molecular identification

薛亚鹏, 丁艺冰, 王宇卓, 王晓丹, 曹晓宁, SANTRA Dipak K, 陈凌, 乔治军, 王瑞云. 基于荧光SSR构建中国糜子核心种质DNA分子身份证[J]. 中国农业科学, 2023, 56(12): 2249-2261.

XUE YaPeng, DING YiBing, WANG YuZhuo, WANG XiaoDan, CAO XiaoNing, SANTRA Dipak K, CHEN Ling, QIAO ZhiJun, WANG RuiYun. Construction of DNA Molecular Identity Card of Core Germplasm of Broomcorn Millet in China Based on Fluorescence SSR[J]. Scientia Agricultura Sinica, 2023, 56(12): 2249-2261.

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链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2023.12.002

https://www.chinaagrisci.com/CN/Y2023/V56/I12/2249

图/表 10

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7对核心引物毛细管电泳结果及带型编码"

引物 Primer	荧光基团 Fluorescent group	电泳条带数目 Polymorphism bands	电泳片段长度及编码 Length and code of electrophoresis fragments (bp)
RYW3	6-羧基荧光素 FAM (blue)	19	149(01),440(02),132/149(03),132/149/156(04),138/149/178(05),143/149/156(06),143/149(07),143/149/178(08),143/149/216(09),149/156(10),149/156/216(11),149/169/198(12),149/178(13),149/211/216(14),149/216(15),156/169(16),272/344/440/474(17),440/474(18),143/149/184(19)
RYW6	6-羧基荧光素 FAM (blue)	38	242(01),255(02),262(03),300(04),308(05),323(06),333(07),387(08),444(09),452(10),174/195/242/372(11),187/195/242/372(12),195/202/242(13),195/202/242/372(14),195/242(15),195/242/267/372(16),195/242/347/372(17),195/242/372(18),195/242/387(19),195/242/401(20),202/333(21),211/242/372(22),211/333(23),242/323(24),242/333(25),242/387(26),242/425(27),252/257(28),255/267(29),296/308(30),300/308(31),323/328(32),323/333(33),323/338(34),328/333(35),333/338(36),387/425(37),444/452(38)
RYW11	6-羧基荧光素FAM (blue)	3	180(01),222(02),213/222(03)
RYW18	6-羧基荧光素FAM (blue)	5	376(01),369/381(02),376/381(03),381/386(04),381(05)
RYW37	6-羧基荧光素 FAM (blue)	6	203(01),209(02),196/203(03),196/203/209(04),196/203/209/216(05),203/209(06)
RYW125	6-羧基荧光素 FAM (blue)	24	196(01),202(02),207(03),292(04),333(05),105/202/323(06),122/211/292(07),130/151/202/333(08),130/202/219/339(09),130/202/323/333(10),130/323(11),141/259/292/372(12),141/299/323(13),196/202(14),196/219(15),202/207(16),202/211(17),202/227(18),219/223(19),259/323/333/393(20),292/333(21),299/339(22),323/339(23),323/402(24)
RYW43	六氯-6-甲基荧光素 HEX (green)	30	109(01),120(02),128(03),181(04),204(05),109/115(06),109/115/181(07),109/120/128/147(08),109/128/181/204(09),109/128(10),109/128/181(11),109/138(12),109/138/181(13),109/155/181(14),109/181(15),109/181/204(16),109/181/226/293(17),109/181/293(18),109/181/293/405 (19),109/226/293(20),109/226/293/491(21),109/226/483(22),109/226/491(23),109/293(24),128/181(25),138/181(26),170/181(27),181/204(28),103/109/181/204(29),109/204(30)

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材料编号 Serial number	统一编号 Unicode	名称 Name	来源 Source	备注 Remark
1	00000082	黄糜子Huangmeizi	中国黑龙江Heilongjiang, China	地方品种Landrace
2	00000840	六十天小红黍60-day Xiaohongshu	中国山西Shanxi, China	地方品种Landrace
3	00000710	皋兰鸭蛋青Gaolanyadanqing	中国甘肃Gansu, China	地方品种Landrace
4	00003117	黄糜Huangmei	中国新疆Xinjiang, China	地方品种Landrace
5	00006438	乌克兰黍Ukraine shu	中国内蒙古Inner Mongolia, China	地方品种Landrace
6	00004198	金守黍Jinshoushu	中国广东Guangdong, China	地方品种Landrace
7	00007131	白黍子Baishuzi	中国河北Hebei, China	地方品种Landrace
8	00006681	札达糜Zhadamei	中国西藏Tibet, China	地方品种Landrace
9	00007258	黄糜子Huangmeizi	中国辽宁Liaoning, China	地方品种Landrace
10	00007375	790035	印度India	地方品种Landrace
11	00005191	塞盖德斯Saigaidesi	中国山东Shandong, China	地方品种Landrace
12	00005671	扶余白糜子Fuyubaimeizi	中国吉林Jilin, China	地方品种Landrace
13	00005452	夯糜子Hangmeizi	中国陕西Shaanxi, China	地方品种Landrace
14	00002641	西吉小黄糜Xijixiaohuangmei	中国宁夏Ningxia, China	地方品种Landrace

位点 Locus	正向引物 Forward primer (5′-3′)	反向引物 Reverse primer (5′-3′)	5′端修饰 5′ end modification	重复序列 Repeated motif	退火温度 Tm (℃)
RYW3	GGAGGCGTGACAATAAAAC	GGCGTGAGGTGTTGTTTTT	5′6-FAM	(CTGCAA)₅	48.90
RYW5	GACGATGCTCTTGACCTTGT	CACCGTGAAATGTCTCTGCT	5′6-FAM	(CCTTT)₅	51.80
RYW6	AGCCGATTTGCTGTGGAGT	CTGCCTCCGATGAGTTGGT	5′6-FAM	(ACACC)₅	52.15
RYW11	TGCTCGTCTTCTCGCTTCG	AGTAGTCCTCCACCGCCATCT	5′6-FAM	(GGTA)₅	54.75
RYW14	CGCACAACGACCACAAGAG	ATACACCAGAGGAGCACGC	5′6-FAM	(GGCC)₅	57.35
RYW18	CTCCCTCTTTGTCCTCGTT	GCTGCCTCTTCGCTATCTT	5′6-FAM	(AGTT)₆	51.10
RYW20	ACCTCTTGCCGCACACTAC	TTCTACATCCCCGAACCAC	5′6-FAM	(TTGG)₆	52.15
RYW35	ATTAGCATCCCCCTCCAC	ATCCGCTTTCCCAACCAC	5′6-FAM	(CGTGC)₅(GGA)₆	50.30
RYW37	CATTCCGTTCCTTGTCTTCC	CAGTCTCACTCCTGCGATGT	5′6-FAM	(GCGAT)₅	52.80
RYW40	TGCTCTTCGGCTCTTCTCC	ATCAGCTCATCGTGACCCC	5′6-FAM	(CAGC)₆	53.20
RYW43	GGAGATGCTTGCTTGGTTG	CAGGAATCGCAAGGAACAG	5′HEX	(GGAG)₅	54.00
RYW54	GCACTTGCTCCTGCTTCTC	GACCTTGCCGATGTTGTTG	5′HEX	(CCTC)₅	55.65
RYW124	CCACAAAGCGAAAGAACC	GAGTCCAAGCCCTCATCC	5′6-FAM	(TCG)₆	53.65
RYW125	TTGACGACGACTGTGTGC	TGTTGGTGGAGTTGAGGAC	5′6-FAM	(GGC)₅	55.10
RYW146	TGATGCTTCTTGGGTTCG	CGCCGTCCACTTCTGTAT	5′6-FAM	(GCG)₆	53.60

引物 Primer	观测等位变异 Observed number of alleles (Na)	Shannon 多样性指数 Shannon’s diversity index(I)	观测杂合度 Observed heterozygosity (Ho)	期望杂合度 Expected heterozygosity (He)	Nei’s 基因多样性指数 Nei's expected heterozygosity (Nei)	多态性信息含量Polymorphism information content (PIC)
RYW3	15.0000	0.9874	0.8136	0.4114	0.4105	0.5073
RYW6	25.0000	2.0587	0.5238	0.7469	0.7452	0.8071
RYW11	3.0000	0.7178	0.0086	0.5053	0.5043	0.0334
RYW18	4.0000	0.2055	0.9455	0.0795	0.0793	0.2103
RYW37	4.0000	1.1777	0.3376	0.6700	0.6686	0.6495
RYW125	16.0000	1.6084	0.4414	0.6940	0.6916	0.7681
RYW43	20.0000	1.2230	0.5399	0.5161	0.5149	0.6540
合计Total	87.0000	-	-	-	-	-
平均Mean	12.4286	1.1398	0.5158	0.5176	0.5163	0.5185

引物/组合 Primer/Combination	区分种质数 No. of germplasm distinguished	区分率 Rate of discrimination (%)
RYW3	10	4.26
RYW6	17	7.23
RYW11	2	0.85
RYW18	0	0.00
RYW37	2	0.85
RYW43	16	6.81
RYW125	16	6.81
RYW3+RYW6	46	19.57
RYW3+RYW6+RYW11	48	20.42
RYW3+RYW6+RYW11+RYW18	62	26.38
RYW3+RYW6+RYW11+RYW18+RYW37	88	37.45
RYW3+RYW6+RYW11+RYW18+RYW37+RYW43	161	68.51
RYW3+RYW6+RYW11+RYW18+RYW37+RYW43+RYW125	235	100.00

基于荧光SSR构建中国糜子核心种质DNA分子身份证

Construction of DNA Molecular Identity Card of Core Germplasm of Broomcorn Millet in China Based on Fluorescence SSR

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