玉米Suwan种质改良过程中的关键基因组区段发掘

doi:10.3724/SP.J.1006.2019.83052

作物学报 ›› 2019, Vol. 45 ›› Issue (4): 568-577.doi: 10.3724/SP.J.1006.2019.83052

• 作物遗传育种·种质资源·分子遗传学 • 上一篇下一篇

玉米Suwan种质改良过程中的关键基因组区段发掘

李秀诗,吴迅,吴文强,刘鹏飞,郭向阳,王安贵,祝云芳,陈泽辉()

贵州省农业科学院旱粮研究所, 贵州贵阳 550006

收稿日期:2018-06-26 接受日期:2018-12-24 出版日期:2019-04-12 网络出版日期:2019-01-04
通讯作者: 陈泽辉
基金资助:
本研究由国家“七大作物育种”专项(2016YFD0101206-4)(2016YFD0101206);黔农科院自主创新科研专项字(2014)006(Special Character of Independent Innovation of Guizhou Academy of Agriculture [2014]006);国家自然科学基金项目(31760387);黔科合支撑([2016]2605, [2016]2549, [2017]2507, [2018]2296);黔科合基础资助([2017]1413)

Excavation of main candidate genome regions in Suwan germplasm improvement process of maize

LI Xiu-Shi,WU Xun,WU Wen-Qiang,LIU Peng-Fei,GUO Xiang-Yang,WANG An-Gui,ZHU Yun-Fang,CHEN Ze-Hui()

Upland Crops Institute, Guizhou Academy of Agricultural Sciences, Guiyang 550006, Guizhou, China

Received:2018-06-26 Accepted:2018-12-24 Published:2019-04-12 Published online:2019-01-04
Contact: Ze-Hui CHEN
Supported by:
This study was supported by the National Key Research and Development Program of China(2016YFD0101206);Innovation Program of QAAS(Special Character of Independent Innovation of Guizhou Academy of Agriculture [2014]006);National Natural Science Foundation of China(31760387);Science and Technology Support Project of Guizhou Province (Qiankehe support([2016]2605, [2016]2549, [2017]2507, [2018]2296);Science and Technology Project of Guizhou Province (Qiankehe Foundation)([2017]1413)

摘要/Abstract

摘要：

玉米Suwan种质抗性好、适应性强、籽粒品质优, 在现代育种尤其是南方玉米育种中具有不可替代的作用。明确Suwan种质优良特性在改良过程中的遗传机制对我国南方玉米生态区的玉米生产具有重要意义。本研究以Suwan 1 (Suwan 1C₁₀)及其衍生群体(苏兰1号C₀)不同改良世代为材料, 利用包含5.6万个SNP标记的MaizeSNP50芯片对供试群体进行基因型鉴定。遗传分析发现: Suwan 1群体不同改良世代间的基因组差异片段较少, 仅出现5个, 其中4个出现在第11轮改良世代(Suwan 1 C₁₁), 1个出现在第15轮改良世代(Suwan 1 C₁₅); 苏兰1号不同改良世代间的基因组差异片段相对较多, 共有18个, 其中8个在不同改良世代间稳定遗传; Suwan种质改良形成苏兰1号群体的过程中, 共获得43个Lancaster特异性遗传片段, 其中35个在苏兰1号不同改良世代间稳定遗传。全基因组关联分析共鉴定出16个与穗行数显著关联的QTN, 分别位于第2、第3、第5、第6、第7、第8、第9染色体上, 其中SYN25713和SYN36577位于苏兰1号群体的Lancaster特异性遗传片段内; 共检测到13个控制穗长相关的QTN, 分别位于第1、第2、第5、第7、第8、第9染色体上, 其中PZE-105143697位于苏兰1号群体的Lancaster特异性遗传片段内。该结果为后续全基因组关联研究和分子标记辅助选择等提供了重要的理论依据。

关键词: 玉米, 群体改良, 基因组特征, 全基因组关联分析, 遗传位点

Abstract:

Suwan germplasm with good resistance, strong adaptability and excellent grain quality has played an irreplaceable role in modern breeding, especially in the southern of China. It is important to clarify the genetic mechanism of Suwan germplasm. In this study, modified generations of Suwan 1 (Suwan 1 C₁₀) and its derived population (Suwan-Lancaster 1 C₀) were used to be genotyped by using MaizeSNP50 chips containing about 56,000 SNP markers. There was a smaller genome differences among different improved generations for Suwan 1 population, with only five different inherited fragments identified, among which four appeared only in the 11th improved generation (Suwan 1 C₁₁), one appeared only in the 15th improved generation (Suwan 1 C₁₅). For Suwan-Lancaster1 population, among 18 different genetic fragments eight were stably inherited in different improved generations. A total of 43 specific genetic segments of Lancaster germplasm were obtained, among them 35 were stably inherited in different improved generations. Genome-wide association studies (GWAS) showed that 16 QTNs significantly associated with kernel row number were located on chromosomes 2, 3, 5, 6, 7, 8, and 9, respectively, among them SYN25713 and SYN36577 were located in the Lancaster specific genetic fragment of the Suwan-Lancaster 1 population. A total of 13 QTNs related to ear length were located on chromosomes 1, 2, 5, 7, 8, and 9, respectively, among them PZE-105143697 was located in the Lancaster specific genetic fragment. These results provide an important theoretical basis for the subsequent genome-wide association study and molecular marker assisted selection.

Key words: maize, population improvement, genome characteristics, genome-wide association study, genetic loci

李秀诗,吴迅,吴文强,刘鹏飞,郭向阳,王安贵,祝云芳,陈泽辉. 玉米Suwan种质改良过程中的关键基因组区段发掘[J]. 作物学报, 2019, 45(4): 568-577.

LI Xiu-Shi,WU Xun,WU Wen-Qiang,LIU Peng-Fei,GUO Xiang-Yang,WANG An-Gui,ZHU Yun-Fang,CHEN Ze-Hui. Excavation of main candidate genome regions in Suwan germplasm improvement process of maize[J]. Acta Agronomica Sinica, 2019, 45(4): 568-577.

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序号 No.	材料 Accession	系谱 Pedigree	类群 Group
1	Suwan 1 (Suwan 1 C₁₀)	Suwan 1 C₉	Suwan
2	Suwan 1 C₁₁	Suwan 1 C₁₀	Suwan
3	Suwan 1 C₁₂	Suwan 1 C₁₁	Suwan
4	Suwan 1 C₁₃	Suwan 1 C₁₂	Suwan
5	Suwan 1 C₁₅	Suwan 1 C₁₄	Suwan
6	苏兰1号C₀ SL1C₀	Suwan, Lancaster及78599选系 Synthetic populations of Suwan, Lancaster and 78599 selected lines	Suwan-Lancaster
7	苏兰1号C₁ SL1C₁	苏兰1号C₀ SL1C₀	Suwan-Lancaster
8	苏兰1号C₂ SL1C₂	苏兰1号C₁ SL1C₁	Suwan-Lancaster
9	苏兰1号C₃ SL1C₃	苏兰1号C₂ SL1C₂	Suwan-Lancaster

材料 Accession	穗长 Ear length				穗行数 Kernel row number
材料 Accession	贵阳 Guiyang	大方 Dafang	罗平 Luoping	平均值 Mean	贵阳 Guiyang	大方 Dafang	罗平 Luoping	平均值 Mean
苏兰1号C₀SL1C₀	17.67	18.77	17.40	17.94	15.47	14.53	14.67	14.89
苏兰1号C₁SL1C₁	18.13	19.33	17.17	18.21	15.33	14.73	14.27	14.78
苏兰1号C₂SL1C₂	17.87	18.97	18.20	18.34	14.27	14.27	14.47	14.33
苏兰1号C₃SL1C₃	18.27	19.57	17.73	18.52	15.00	15.53	15.20	15.24
Suwan 1 (Suwan 1 C₁₀)	17.47	18.33	16.43	17.41	15.00	14.93	14.00	14.64
Suwan 1 C₁₁	17.67	18.23	17.03	17.64	15.40	14.93	14.13	14.82
Suwan 1 C₁₂	16.87	17.97	16.33	17.06	15.13	15.87	14.60	15.20
Suwan 1 C₁₃	16.53	18.17	16.20	16.97	15.40	14.93	14.20	14.84
Suwan 1 C₁₅	17.60	18.53	17.03	17.72	14.60	14.60	14.53	14.58
平均值Mean	17.56	18.65	17.06	17.76	15.07	14.93	14.45	14.81
标准差Standard deviation	1.09	0.73	0.84	1.11	0.67	0.57	0.65	0.68
变异系数Coefficient of variation (%)	6.21	3.91	4.92	6.25	4.45	3.82	4.50	4.59

SNP	染色体 Chr.	物理位置 Position	SNP	染色体 Chr.	物理位置 Position
SYN450	1	35968064	PZE-106016986	6	32497838
PZE-103104159	3	164159285	PZE-106016987	6	32498979
PZE-106016953	6	32495316	PZE-106017115	6	32905813
PZE-106016962	6	32495710	PZE-106017122	6	32908494
PZE-106016971	6	32496071	PZE-106099248	6	152896893
PZA00540.3	6	32496071	PZE-108113902	8	163858777

SNP	染色体 Chr.	物理位置 Position	SNP	染色体 Chr.	物理位置 Position
PZE-101205609	1	253344590	PZE-102156731	2	203902578
PZE-101205965	1	253895960	SYN15645	3	182660027
SYN6838	1	297376850	PZE-105016506	4	7204051
PZE-103008521	2	4666469	PZE-106033525	5	76988770
PZE-102060229	2	38551101	SYN25006	6	8192709
PZE-102060230	2	39031517	PZE-107126153	7	163083361
PZE-102061400	2	39748797	PZE-109019803	7	20222259
SYN26925	2	200353907	PZE-109051268	9	85880947
SYN26929	2	200359094	PZE-109051619	9	86414796
SYN10568	2	200723525	PZE-109052137	9	86974491
SYN35589	2	201246108

SNP	染色体 Chr.	物理位置 Position	SNP	染色体 Chr.	物理位置 Position
SYN11491	1	3683507	PZE-104127854	4	212788677
PZE-101054452	1	38617583	PZE-104127855	4	212788991
PZE-101178005	1	222370910	PZE-104152999	4	243521349
PZE-101192090	1	237838603	SYN28825	5	7319620
PZE-101192133	1	237900682	PZE-105051178	5	43960922
PZE-101192647	1	238680213	PZE-105051179	5	43961044
PZE-101195574	1	242361972	PZE-105051200	5	43966297
PZE-101195592	1	242398910	PZE-105099516	5	146942464
PZE-101196147	1	243255282	PZE-105101687	5	152095801
PZE-101196704	1	244083020	PZE-105102557	5	154315332
PZE-101196940	1	244512792	PZE-105144984	5	197943057
PZE-101197050	1	244678601	PZB02424.1	5	199531408
SYN12881	1	245242156	SYN30468	5	199531778
PZE-101197856	1	245308899	PZA00540.3	6	32496071
SYN15061	1	261370341	PZE-106016971	6	32496071
PZE-102060229	2	38551101	PZE-106017115	6	32905813
PZE-102060230	2	39031517	PZE-106017122	6	32908494
SYN26925	2	200353907	SYN25006	7	8192709
SYN26929	2	200359094	PZE-107018281	7	15776884
SYN35589	2	201246108	PZE-107126153	7	163083361
PZE-103025362	3	17738644	SYN34213	8	5090046
PZE-103056619	3	68433447	PZE-108010963	8	11645850
PZE-103068285	3	108233400	PUT-163a-78089347-4225	8	169951365
PZE-103076844	3	123683053	PUT-163a-78089347-4224	8	169951478
PZE-103083872	3	135004208	PZE-109008703	9	9247324
SYN34685	4	202660380	SYN36362	9	9247324
PZE-104126691	4	210495187	PZE-109051619	9	86414796
PZE-104127248	4	211708774	PZE-109101971	9	141650742
PZE-104127853	4	212785374	PZE-110080467	10	134211006

玉米Suwan种质改良过程中的关键基因组区段发掘

Excavation of main candidate genome regions in Suwan germplasm improvement process of maize

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SNP	染色体 Chr.	物理位置 Position	P值 P-value (×10^-4)	最小等位基因频率 Minimum allele frequency
PZE-102049428	2	27586143	0.83	0.22
SYN29936	3	214728752	0.79	0.53
SYN25713	4	218657640	0.50	0.39
PZE-104012465	4	10671690	0.95	0.39
PZE-105068275	5	70167652	0.38	0.50
SYN35408	5	64502995	0.64	0.53
ZM013904-0312	5	64757602	0.64	0.53
PZE-105060180	5	58448124	0.80	0.44
PZE-106105143	6	155807238	0.29	0.42
PUT-163a-60355888-2779	6	30864359	0.32	0.61
PUT-163a-60355888-2773	6	30864423	0.32	0.61
SYN36577	7	9216854	0.53	0.67
SYN36527	8	166695438	0.72	0.17
SYN36532	8	166695690	0.72	0.83
PZE-108065598	8	115805296	0.89	0.33
PZE-109004718	9	5289730	0.54	0.31

SNP	染色体 Chr.	物理位置 Position	P值 P-value (×10^-4)	最小等位基因频率 Minimum allele frequency
SYN28790	1	198085193	3.55	0.56
PZE-102089207	2	89322082	3.55	0.83
PZE-102089216	2	89350485	7.42	0.17
PZE-102094273	2	103594813	7.42	0.28
PZE-103146876	3	199472604	5.85	0.64
PZE-105143697	5	196993540	6.06	0.22
SYN2938	5	212502760	2.47	0.44
PZE-105181391	5	215066204	8.77	0.22
SYN19052	7	125475003	6.64	0.78
SYN10053	8	1816317	7.98	0.39
PZA-000908002	8	99959553	2.84	0.44
PZE-108076469	8	130589109	3.55	0.83
PZE-109008801	9	9401106	7.42	0.44

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