夏玉米根系构型与抗根倒性能间的关系

doi:10.3724/SP.J.1006.2023.23004

Abstract

Abstract:

To screen out the summer maize varieties with high root-lodging resistance and provide theoretical basis for the breeding of root-toppling resistance maize varieties to achieve resistant to lodging and high and stable yields in summer maize, the relationship between root architecture and root-lodging resistance was studied. In this experiment, to analyze the relationship between root morphology and root lodging resistance, 104 summer maize varieties widely planted in Yellow-Huaihe-Haihe Rivers region were used as materials, and the root pulling force and root related characters of different maize varieties were measured at flowering stage, and were evaluated by principal component analysis and cluster analysis. The results showed that the root pulling force of 104 varieties conformed to normal distribution with a range of 862-1092 N. There was a significant positive correlation between root pulling force and root angle, root numbers, total root number, root length, root dry weight, and yields. Based on the comprehensive root traits of different maize varieties, the experimental varieties were group into six groups according to the root lodging resistance from strong to weak. Among them, the varieties with strong root resistance were as follows: Lianyan 155, Dika 517, Qiminyu 6, Jinhai 13, Laiyu 721, Fengle 365, Liangxing 579, Denghai 605, Denghai 518, and Dedan 179. This group of maize varieties had the characteristics of higher root dry weight, root number, total root number, root angle, root length, and grain yield.

Key words: maize, resistance to root lodging, root morphology, root pulling force

ZHANG Jing, WANG Hong-Zhang, REN Hao, YIN Fu-Wei, WU Hong-Yan, ZHAO Bin, ZHANG Ji-Wang, REN Bai-Zhao, DAI Ai-Bin, LIU Peng. Relationship between root architecture and root pulling force of summer maize[J].Acta Agronomica Sinica, 2023, 49(1): 188-199.

Figures/Tables 13

Table 1

Hybrid varieties used in this study"

序号 Number	品种名称 Hybrid name	序号 Number	品种名称 Hybrid name
1	博信212 Boxin 212	53	迪卡517 Dika 517
2	道吉158 Daoji 158	54	农华5号 Nonghua 5
3	鑫研156 Xinyan 156	55	桓丰601 Huanfeng 601
4	中天303 Zhongtian 303	56	道吉1+1 Daoji 1+1
5	九圣禾2468 Jiushenghe 2468	57	好日子738 Haorizi 738
6	鲍玉3号 Baoyu 3	58	宁研519 Ningyan 519
7	鲁单9169 Ludan 9169	59	连胜253 Liansheng 253
8	京农科736 Jinnongke 736	60	中农大688 Zhongnongda 688
9	登海1717 Denghai 1717	61	天泰619 Tiantai 619
10	强盛339 Qiangsheng 339	62	鲁单9088 Ludan 9088
11	裕丰620 Yufeng 620	63	鑫瑞57 Xinrui 57
12	郑单958 Zhengdan 958	64	天泰366 Tiantai 366
13	登海371 Denghai 371	65	大京九4703 Dajingjiu 4703
14	中天308 Zhongtian 308	66	中天301 Zhongtian 301
15	邦玉519 Bangyu 519	67	登海6188 Denghai 6188
16	鑫瑞76 Xinrui 76	68	鑫瑞37 Xinrui 37
17	莱农14 Lainong 14	69	登海606 Denghai 606
18	德单179 Dedan 179	70	京科999 Jingke 999
19	丰乐37 Fengle 37	71	NK815
20	登海518 Denghai 518	72	C1210
21	金海2010 Jinhai 2010	73	C9256
22	胶玉1号 Jiaoyu 1	74	登海682 Denghai 682
23	九玉Y02 Jiuyu Y02	75	宇玉268 Yuyu 268
24	齐单805 Qidan 805	76	来玉1819 Laiyu 1819
25	NK818	77	齐民玉6号 Qimingyu 6
26	安玉706 Anyu 706	78	德发718 Defa718
27	金海13 Jinhai 13	79	登海511Denghai 511
28	济玉519 Jiyu 519	80	鑫玉518 Xinyu 518
29	鑫星321 Xinxing 321	81	登海533 Denghai 533
30	MC121	82	登海653 Denghai 653
31	郑原玉432 Zhengyuanyu 432	83	丰乐235 Fengle 235
32	MC278	84	豫禾269 Yuhe 269
33	源丰008 Yuanfeng 008	85	登海605 Denghai 605
34	来玉317 Laiyu 317	86	鲁单1号 Ludan 1
35	强盛198 Qiangsheng 198	87	宁研503 Ningyan 503
36	鑫瑞25 Xinrui 25	88	德发705 Defa 705
37	京农玉658 Jinnongyu 658	89	金来705 Jinlai 705
38	丰度191 Fengdu 191	90	德单5号Dedan 5
39	金海1911 Jinhai 1911	91	万盛69 Wansheng 69
40	金海1908 Jinhai 1908	92	农华221 Nonghua 221
41	丰乐365 Fengle 365	93	德瑞88 Derui 88
42	登海710 Denghai 710	94	齐单109 Qidan 109
43	来玉721 Laiyu 721	95	京科927 Jingke 927
44	来玉238 Laiyu 238	96	联研155 Lianyan 155
45	新单68 Xindan 68	97	宁研678 Ningyan 678
46	MC812	98	桓丰107 Huanfeng 107
47	德发106 Defa 106	99	登海1996 Denghai 1996
48	胜风1号 Shengfeng 1	100	立原296 Liyuan 296
49	金海188 Jinhai 188	101	硕秋702 Shuoqiu 702
50	德单123 Dedan 123	102	良星579 Liangxing 579
51	明天695 Mingtian 695	103	鑫研218 Xinyan 218
52	登海111 Denghai 111	104	禾硕818 Heshuo 818

Table 1

Fig. 1

Fig. 2

Table 2

Table 3

Fig. 3

Table 4

Fig. 4

Table 5

Fig. 5

Table 6

Table 7

Fig. 6

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指标 Index	根拔力 RPF	第1层 1st floor	第2层 2nd floor	第3层 3rd floor	第4层 4th floor	第5层 5th floor	第6层 6th floor	第7层 7th floor	第8层 8th floor
根拔力 RPF	1	0.071	0.185	0.092	0.367^**	0.345^**	0.249^**	0.299^**	0.658^**
第1层 1st floor		1	0.525^**	0.352^**	0.323^*	0.239	0.139	0.115	0.055
第2层 2nd floor			1	0.378^**	0.437^**	0.265^**	0.128	0.184	0.217^*
第3层 3rd floor				1	0.417^**	0.475^**	0.216^*	0.233^*	0.261^**
第4层 4th floor					1	0.416^**	0.215^*	0.231^*	0.367^**
第5层 5th floor						1	0.413^**	0.558^**	0.379^**
第6层 6th floor							1	0.413^**	0.207^*
第7层 7th floor								1	0.442^**
第8层 8th floor									1

指标 Index	根拔力 RPF	第1层 1st floor	第2层 2nd floor	第3层 3rd floor	第4层 4th floor	第5层 5th floor	第6层 6th floor	第7层 7th floor	第8层 8th floor
根拔力 RPF	1	0.376^**	0.234^*	0.201^**	0.422^**	0.454^**	0.624^**	0.609^**	0.207^*
第1层 1st floor		1	0.438^**	0.147	0.172^**	-0.033	0.023^**	0.113^**	0.158^**
第2层 2nd floor			1	0.252^*	0.045^**	-0.162^**	0.067^**	0.079	0.132^**
第3层 3rd floor				1	0.083^**	-0.085	0.002	-0.05	0.078^**
第4层 4th floor					1	0.256^**	0.243^*	0.262	0.097
第5层 5th floor						1	0.386^**	0.352^**	0.169
第6层 6th floor							1	0.731^**	0.163
第7层 7th floor								1	0.128
第8层 8th floor									1

指标 Index	根拔力 RPF	第1层 1st floor	第2层 2nd floor	第3层 3rd floor	第4层 4th floor	第5层 5th floor	第6层 6th floor	第7层 7th floor	第8层 8th floor
根拔力 RPF	1	0.115	0.240^*	0.383^**	0.365^**	0.454^**	0.495^**	0.568^**	0.666^**
第1层 1st floor		1	0.231	0.457^**	0.634^**	0.623^**	0.765^**	0.780^**	0.795^**
第2层 2nd floor			1	0.272	0.501^**	0.691^**	0.710^**	0.807^**	0.855^**
第3层 3rd floor				1	0.167	0.481^**	0.669^**	0.640^*	0.873^**
第4层 4th floor					1	0.256	0.474^**	0.689^**	0.718^**
第5层 5th floor						1	0.268	0.591^**	0.763^**
第6层 6th floor							1	0.227	0.661^**
第7层 7th floor								1	0.357
第8层 8th floor									1

指标 Index	植株根拔力 RPF	根干重 RDM	节根条数 RN	节根总条数 TRN	节根着生角度 RA	节根长度 RL
植株根拔力RPF	1
根干重RDM	0.671^**	1
节根条数RN	0.609^**	0.379^**	1
节根总条数TRN	0.870^**	0.585^**	0.717^**	1
节根着生角度RA	0.299^**	0.173	0.302^**	0.279^**	1
节根长度RL	0.568^**	0.394^**	0.313^**	0.511^**	0.077	1

成分 Ingredient	初始特征值 Initial eigen value	方差百分比 Percentage of variances (%)	累积 Accumulation (%)
PC1	2.607	31.012	31.012
PC2	1.701	28.156	59.168
PC3	1.283	24.015	83.183
PC4	0.819	9.013	92.196
PC5	0.232	7.804	100.000

Relationship between root architecture and root pulling force of summer maize

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指标 Index	第1主成分 PC1	第2主成分 PC2	第3主成分 PC3
根干重RDM	-0.201	0.535	-0.249
每层节根条数RN	0.878	0.012	-0.198
节根总条数TRN	0.806	0.776	0.187
节根着生角度RA	0.615	0.769	0.601
节根长度RL	-0.014	0.370	0.721

[1]	YIN Fang-Bing, LI Ya-Nan, BAO Jian-Xi, MA Ya-Jie, QIN Wen-Xuan, WANG Rui-Pu, LONG Yan, LI Jin-Ping, DONG Zhen-Ying, WAN Xiang-Yuan. Genome-wide association study and candidate genes predication of yield related ear traits in maize [J]. Acta Agronomica Sinica, 2023, 49(2): 377-391.
[2]	SONG Jie, WANG Shao-Xiang, LI Liang, HUANG Jin-Ling, ZHAO Bin, ZHANG Ji-Wang, REN Bai-Zhao, LIU Peng. Effects of potassium application rate on NPK uptake and utilization and grain yield in summer maize (Zea mays L.) [J]. Acta Agronomica Sinica, 2023, 49(2): 539-551.
[3]	LIU Meng, ZHANG Yao, GE Jun-Zhu, ZHOU Bao-Yuan, WU Xi-Dong, YANG Yong-An, HOU Hai-Peng. Effects of nitrogen application and harvest time on grain yield and nitrogen use efficiency of summer maize under different rainfall years [J]. Acta Agronomica Sinica, 2023, 49(2): 497-510.
[4]	XU Tong, LYU Yan-Jie, SHAO Xi-Wen, GENG Yan-Qiu, WANG Yong-Jun. Effect of different times of spraying chemical regulator on the canopy structure and grain filling characteristics of high planting densities [J]. Acta Agronomica Sinica, 2023, 49(2): 472-484.
[5]	SUN Zhi-Chao, ZHANG Ji-Wang. Physiological mechanism and regulation effect of low light on maize yield formation [J]. Acta Agronomica Sinica, 2023, 49(1): 12-23.
[6]	CHEN Bing-Jie, ZHANG Fu-Liang, YANG Shuo, LI Xiao-Li, HE Tang-Qing, ZHANG Chen-Xi, TIAN Ming-Hui, WU Mei, HAO Xiao-Feng, ZHANG Xue-Lin. Effects of arbuscular mycorrhizae fungi on maize physiological characteristics during grain filling stage, yield, and grain quality under different nitrogen fertilizer forms [J]. Acta Agronomica Sinica, 2023, 49(1): 249-261.
[7]	WANG Rui-Pu, DONG Zhen-Ying, GAO Yue-Xin, BAO Jian-Xi, YIN Fang-Bing, LI Jin-Ping, LONG Yan, WAN Xiang-Yuan. Genome-wide association study and candidate gene prediction of kernel starch content in maize [J]. Acta Agronomica Sinica, 2023, 49(1): 140-152.
[8]	SHANG Meng-Fei, SHI Xiao-Yu, ZHAO Jiong-Chao, LI Shuo, CHU Qing-Quan. Spatiotemporal variation of high temperature stress in different regions of China under climate change [J]. Acta Agronomica Sinica, 2023, 49(1): 167-176.
[9]	DUAN Can-Xing, CUI Li-Na, XIA Yu-Sheng, DONG Huai-Yu, YANG Zhi-Huan, HU Qing-Yu, SUN Su-Li, LI Xiao, ZHU Zhen-Dong, WANG Xiao-Ming. Precise characterization and analysis of maize germplasm resources for resistance to Fusarium ear rot and Gibberella ear rot [J]. Acta Agronomica Sinica, 2022, 48(9): 2155-2167.
[10]	ZHANG Zhen-Bo, QU Xin-Yue, YU Ning-Ning, REN Bai-Zhao, LIU Peng, ZHAO Bin, ZHANG Ji-Wang. Effects of nitrogen application rate on grain filling characteristics and endogenous hormones in summer maize [J]. Acta Agronomica Sinica, 2022, 48(9): 2366-2376.
[11]	GUO Yao, CHAI Qiang, YIN Wen, FAN Hong. Research progress of photosynthetic physiological mechanism and approaches to application in dense planting maize [J]. Acta Agronomica Sinica, 2022, 48(8): 1871-1883.
[12]	WANG Tian-Bo, HE Wen-Xue, ZHANG Jun-Ming, LYU Wei-Zeng, LIANG Yu-Huan, LU Yang, WANG Yu-Lu, GU Feng-Xu, SONG Ci, CHEN Jun-Ying. ROS production and ATP synthase subunit mRNAs integrity in artificially aged maize embryos [J]. Acta Agronomica Sinica, 2022, 48(8): 1996-2006.
[13]	PEI Li-Zhen, CHEN Yuan-Xue, ZHANG Wen-Wen, XIAO Hua, ZHANG Sen, ZHOU Yuan, XU Kai-Wei. Effects of organic material returned on photosynthetic performance and nitrogen metabolism of ear leaf in summer maize [J]. Acta Agronomica Sinica, 2022, 48(8): 2115-2124.
[14]	YANG Ying-Xia, ZHANG Guan, WANG Meng-Meng, LU Guo-Qing, WANG Qian, CHEN Rui. Molecular characterization of transgenic maize GM11061 based on high-throughput sequencing technology [J]. Acta Agronomica Sinica, 2022, 48(7): 1843-1850.
[15]	WANG Dan, ZHOU Bao-Yuan, MA Wei, GE Jun-Zhu, DING Zai-Song, LI Cong-Feng, ZHAO Ming. Characteristics of the annual distribution and utilization of climate resource for double maize cropping system in the middle reaches of Yangtze River [J]. Acta Agronomica Sinica, 2022, 48(6): 1437-1450.