不同玉米杂交种及其亲本自交系耐热性的差异比较

doi:10.3864/j.issn.0578-1752.2024.02.014

摘要/Abstract

摘要：

【目的】近年来，我国黄淮海夏玉米区高温热害不利天气频发重发，已成为威胁玉米生产的重要不利因素。研究并明确高温胁迫对不同基因型玉米品种雌雄穗及产量的影响，为耐高温玉米品种培育和选择提供参考。【方法】以郑单958（郑58×昌7-2）、先玉335（PH6WC×PH4CV）、京农科728（京MC01×京2416）和MC812（京B547×京2416）及其亲本自交系为供试材料，花期前后（大喇叭口期-吐丝后7 d）进行高温胁迫处理，研究高温胁迫对不同基因型玉米杂交种及其亲本自交系雌雄穗生长发育、散粉吐丝间隔（ASI）、花粉活性、产量及其构成要素的影响。【结果】（1）花期前后高温胁迫导致参试玉米品种及其亲本自交系的穗粒数减少，进而产量降低，且不同品种和自交系对高温胁迫的响应存在显著差异。与对照相比，高温胁迫下，郑单958、先玉335、京农科728和MC812的穗粒数降幅分别为22.28%、46.79%、6.13%和8.11%，产量降幅分别为9.50%、50.61%、3.18%和5.00%，其中，京农科728和MC812减产不显著，而郑单958和先玉335显著减产；亲本自交系中，京2416的穗行数、行粒数和产量降幅最小且不显著，而PH6WC均显著降低且降幅最大。（2）高温胁迫下，参试品种及其亲本自交系的雄穗分支总数、雄穗长度、总散粉量和花粉活性降低，散粉持续期缩短，ASI延长。与对照相比，高温胁迫下，ASI延长1.6 d。雄穗长度降幅表现为郑单958>先玉335>MC812>京农科728。郑单958雄穗长度降幅最大，但雄穗分支数多，花粉量最大；先玉335雄穗分支少，雄穗长度降幅大，花粉量最少且活性最低；京2416总散粉量大且花粉活力强，降幅最小（仅为4.50%和3.98%）。【结论】花期前后高温胁迫对参试玉米品种的籽粒产量和花粉活性等影响较大，京农科728和MC812的产量和花粉活性降幅显著低于先玉335和郑单958，耐热性较好。通过比较参试玉米杂交种亲本自交系的耐热性，父本自交系的耐热性要好于母本自交系。其中，京2416的雄穗分支和长度降幅小，花粉量大，花粉活性高，且花丝茸毛多，捕获花粉能力强，单穗产量高，ASI小，耐热性最好。因此，在耐高温玉米品种选育过程中，要重视和加大对耐热种质（如京2416等）的利用与改良创新，组配选育耐高温玉米新品种。

关键词: 高温, 玉米, 亲本自交系, 耐热性

Abstract:

【Objective】 In recent years, the adverse weather of high temperature and heat damage in the Huang-Huai-Hai maize region of China occurred frequently, which has become an important adverse factor threatening maize production. Study and clarify the effects of high temperature stress on male and female ear characteristics and yield of maize can provide useful guidance for the cultivation and selection of high temperature tolerant maize varieties. 【Method】 The variety of Zhengdan958 (Zheng58×Chang7-2), Xianyu335 (PH6WC×PH4CV), Jingnongke728 (JingMC01×Jing2416), MC812 (JingB547×Jing2416), and their parents were used as the test materials. High temperature stress before and after flowering (from V12 stage to 7 d after silking) were conducted. The effects of high temperature stress on the growth and development of male and female panicles, ASI, pollen activity, yield and yield components of different genotypes of maize hybrids and their parents were studied. 【Result】 High temperature stress before and after anthesis significantly reduced the ear length, rows per ear and grains per row of the tested maize varieties and their parents, and then resulted significant decrease in yield. Compared with the control, the grain number per spike of Zhengdan958, Xianyu335, Jingnongke728 and MC812 decreased by 22.28%, 47.69%, 6.13% and 8.11% respectively under high temperature stress, resulting yield decrease of 9.50%, 50.61%, 3.17% and 5.00% respectively. Among the parental materials, the decrease of rows per panicle, grains per row and yield of Jing2416 under high temperature treatment was the smallest and not significant, while the decrease of PH6WC was the largest. Under high temperature stress, the total number of tassel branches, the length of tassel, the total amount of loose pollen and pollen activity decreased significantly, the silking period of loose pollen was prolonged, and the duration of loose pollen was shortened. Among them, Jingnongke728 had the smallest decline, followed by MC812, showing good heat resistance, while Zhengdan958 had the largest decline in the length of tassel, but the amount of pollen was the largest due to the large number of tassel branches. Xianyu335 has fewer male panicle branches, a large decrease in male panicle length, the least amount of pollen and low activity. Among the parental materials, Jing2416 had a large amount of total loose pollen and strong pollen vitality under high temperature treatment, with the smallest decline, only 4.50 and 3.98 percentage points. Compared with the control, the interval of loose pollen silking (ASI) was prolonged by 1.6d under high temperature stress. The decrease in male spike length is manifested as Zhengdan958>Xianyu335>MC812>Jingnongke728. Zhengdan958 had the largest decrease in male spike length, but had more branches and the largest pollen yield; Xianyu335 has fewer branches of male spikes, a significant decrease in male spike length, the least pollen quantity, and the lowest activity; Jing 2416 has a large amount of loose pollen and strong pollen vitality, with the smallest decrease (only 4.50% and 3.98%). 【Conclusion】 High temperature stress before and after anthesis has a significant impact on the grain yield, male and female ear development process, pollen activity and filament microstructure of the tested maize varieties. Under high temperature stress at this stage, the decline of yield and pollen activity of Jingnongke728 and MC812 is significantly less than Xianyu335, showing higher single ear yield and heat tolerance. By comparing the heat resistance of the parental inbred lines of the tested maize hybrids, it was found that the heat resistance of the paternal inbred lines was better than that of the maternal inbred lines. The male panicle branch and length of the parent material Jing2416 decreased slightly, the amount of pollen was large, the pollen activity was high, the filaments were hairy, the ability to capture pollen was strong, the single panicle yield was high, and the heat resistance was the best. Therefore, in the planting area with frequent high temperature and heat damage, selecting maize varieties such as Jingnongke728 can achieve stable and high yield; and during the maize breeding process, we should pay more attention to the utilizing of the higher temperature resistant inbred such an Jing2416 and then combination higher temperature maize varieties.

Key words: high temperature, maize, parental inbred lines, heat resistance

徐田军, 吕天放, 李自豪, 张勇, 刘宏伟, 刘月娥, 蔡万涛, 张如养, 宋伟, 邢锦丰, 赵久然, 王荣焕. 不同玉米杂交种及其亲本自交系耐热性的差异比较[J]. 中国农业科学, 2024, 57(2): 403-415.

XU TianJun, LÜ TianFang, LI ZiHao, ZHANG Yong, LIU HongWei, LIU YueE, CAI WanTao, ZHANG RuYang, SONG Wei, XING JinFeng, ZHAO JiuRan, WANG RongHuan. Comparison of Heat Tolerance of Maize Hybrids and Their Parental Inbreds with Different Genotypes[J]. Scientia Agricultura Sinica, 2024, 57(2): 403-415.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2024.02.014

https://www.chinaagrisci.com/CN/Y2024/V57/I2/403

图/表 11

表1

图1

表2

图2

表3

图3

图4

图5

图6

表4

花期前后高温胁迫对参试玉米品种及其亲本自交系产量及产量构成要素的影响"

年份 Year	品种/自交系 Variety/Inbred line	籽粒产量 Grain yield (g/plant)		百粒重 100-grain weight (g)		穗行数 Rows of ear		行粒数 Grains per row
年份 Year	品种/自交系 Variety/Inbred line	CK	TR	CK	TR	CK	TR	CK	TR
2020	京2416 Jing2416	115.93±3.96efg	111.22±2.49fgh	33.73±1.53fg	32.86±2.77gh	14.10±0.17ghi	13.83±0.21i	29.03±0.02j	28.13±0.20j
	京MC01 JingMC01	101.16±2.84i	88.14±3.24j	27.33±1.52i	25.52±1.76i	13.73±0.70i	12.63±0.50j	31.80±0.35g	28.50±0.23j
	京B547 JingB547	108.94±4.08gh	97.63±3.12i	27.15±0.81i	26.47±1.56i	13.93±0.23hi	12.53±0.32j	28.50±0.12j	25.77±0.26k
	PH4CV	120.08±1.00e	71.50±2.35k	26.19±0.80i	24.69±1.34ij	15.77±0.45bcd	13.87±0.23hi	29.10±0.15ij	20.90±0.06m
	PH6WC	104.60±1.21hi	50.73±4.11l	24.73±1.12ij	30.63±3.60h	13.93±0.70hi	12.30±0.26j	30.40±0.06h	13.50±0.30n
	郑58 Zheng58	117.27±2.63ef	84.33±4.74j	36.45±1.11ef	34.50±2.07fg	12.10±0.17j	10.67±0.29k	28.10±0.20j	21.70±0.15m
	昌7-2 Chang7-2	99.37±0.71i	69.96±1.04k	22.42±0.48j	19.61±1.42k	14.70±0.36efg	12.67±0.61j	30.17±0.15hi	28.23±0.13j
	京农科728 Jingnongke728	226.31±8.41d	218.30±9.45d	39.26±0.95cd	38.30±1.05de	16.00±0.44abc	15.43±0.45cde	37.47±0.28de	36.47±0.90e
	MC812	246.04±10.77b	236.57±11.87bc	43.07±1.00a	42.04±1.53ab	15.20±0.20def	14.60±0.53fgh	39.23±0.40bc	37.50±0.21bcd
	先玉335 Xianyu335	231.62±2.33c	118.97±4.91e	35.71±0.23ef	32.74±2.89gh	16.53±0.21a	14.27±0.46ghi	39.77±0.20ab	24.53±0.41l
	郑单958 Zhengdan958	257.33±2.84a	232.03±2.12c	41.84±0.96abc	39.35±1.66bcd	16.20±0.20ab	14.03±0.06ghi	40.73±1.01a	33.87±1.11f
2021	京2416 Jing2416	104.42±4.91fg	100.78±5.67fg	30.08±0.91h	29.67±1.06h	14.00±0.22ef	13.77±0.49ef	29.47±0.31fghi	28.80±0.56ghij
	京MC01 JingMC01	97.49±1.68gh	79.50±2.11ij	25.44±0.63jkl	24.61±0.66kl	13.80±0.41ef	12.40±0.60h	28.70±0.22hijk	25.20±1.34l
	京B547 JingB547	107.68±4.07ef	84.16±3.79i	26.26±0.17j	25.78±0.30jk	13.40±0.42fg	12.20±0.86g	30.60±0.25f	28.70±0.89hijk
	PH4CV	112.15±2.22e	64.92±3.33k	25.14±1.03jkl	24.71±1.34kl	15.60±0.31abc	13.40±0.45fg	28.60±0.27ijk	20.30±1.12n
	PH6WC	100.56±1.20fg	43.89±1.82l	24.29±0.51l	27.92±0.75i	13.80±0.69ef	12.00±0.99h	30.00±0.63fgh	13.10±0.87o
	郑58 Zheng58	107.15±4.37ef	73.36±2.07j	33.43±1.07fg	32.47±1.20g	12.00±0.94h	10.40±0.53i	27.50±0.19jk	21.10±0.74n
	昌7-2 Chang7-2	92.20±2.21h	59.24±1.21k	21.12±1.02m	16.89±2.12n	14.60±1.56de	12.80±0.67gh	30.11±2.22fg	27.40±0.88k
	京农科728 Jingnongke728	214.26±6.45c	208.28±9.34cd	37.11±0.66bc	36.55±0.87bcd	15.80±0.42abc	15.20±0.48bcd	37.10±0.54cd	36.20±0.69de
	MC812	242.57±2.11a	227.62±3.09ab	38.76±0.99a	37.89±0.36ab	15.00±0.41cd	14.47±0.25de	38.96±1.02ab	37.14±0.45cd
	先玉335 Xianyu335	222.49±3,79b	105.32±3.57ef	34.79±2.33ef	32.33±1.01g	16.40±0.43a	14.41±0.59de	39.00±0.49ab	23.60±0.95m
	郑单958 Zhengdan958	227.09±4.20ab	206.39±8.09d	36.05±0.81cde	35.66±0.07bcd	16.00±0.31ab	15.00±0.17cd	39.80±0.43a	35.50±1.23e

表4

图7

参考文献 32

[1]	赵久然, 王荣焕. 中国玉米生产发展历程、存在问题及对策. 中国农业科技导报, 2013, 15(3): 1-6.
	ZHAO J R, WANG R H. Development process, problem and countermeasure of maize production in China. Journal of Agricultural Science and Technology, 2013, 15(3): 1-6. (in Chinese) doi: 10.3969/j.issn.1008-0864.2013.03.01
[2]	陈翔, 鲍杨俊, 李庆, 丁井魁, 杨明珠, 王冬阳, 曹祖航, 贺亮, 宋有洪. 黄淮海夏玉米花期高温发生特点、危害机理与防控措施综述. 安徽农业大学学报, 2020, 47(2): 304-308.
	CHEN X, BAO Y J, LI Q, DING J K, YANG M Z, WANG D Y, CAO Z H, HE L, SONG Y H. Review on characteristics of high temperature and its damage, and prevention measures of summer maize in Huang-Huai-Hai area. Journal of Anhui Agricultural University, 2020, 47(2): 304-308. (in Chinese)
[3]	BORRÁS L, VITANTONIO-MAZZINI L N. Maize reproductive development and kernel set under limited plant growth environments. Journal of Experimental Botany, 2018, 69(13): 3235-3243. doi: 10.1093/jxb/erx452 pmid: 29304259
[4]	PRASAD P V V, JAGADISH S V K. Field crops and the fear of heat stress-opportunities, challenges and future directions. Procedia Environmental Sciences, 2015, 29: 36-37. doi: 10.1016/j.proenv.2015.07.144
[5]	KRISHNA JAGADISH S V. Heat stress during flowering in cereals- effects and adaptation strategies. The New Phytologist, 2020, 226(6): 1567-1572. doi: 10.1111/nph.v226.6
[6]	LIZASO J I, RUIZ-RAMOSA M, RODRÍGUEZA L, GABALDON- LEALB C, OLIVEIRAC J A, LORITEB I J, SÁNCHEZA D, GARCÍAD E, RODRÍGUEZA A. Impact of high temperatures in maize: Phenology and yield components. Field Crops Research, 2018, 216: 129-140. doi: 10.1016/j.fcr.2017.11.013
[7]	于康珂, 刘源, 李亚明, 孙宁宁, 詹静, 尤东玲, 牛丽, 李潮海, 刘天学. 玉米花期耐高温品种的筛选与综合评价. 玉米科学, 2016, 24(2): 62-71.
	YU K K, LIU Y, LI Y M, SUN N N, ZHAN J, YOU D L, NIU L LI C H, LIU T X. Screening and comprehensive evaluation of heat-tolerance of maize hybrids in flowering stage. Journal of Maize Sciences, 2016, 24(2): 62-71. (in Chinese)
[8]	RATTALINO EDREIRA J I, OTEGUI M E. Heat stress in temperate and tropical maize hybrids: A novel approach for assessing sources of kernel loss in field conditions. Field Crops Research, 2013, 142: 58-67. doi: 10.1016/j.fcr.2012.11.009
[9]	HATFIELD J L, PRUEGER J H. Temperature extremes: Effect on plant growth and development. Weather and Climate Extremes, 2015, 10: 4-10. doi: 10.1016/j.wace.2015.08.001
[10]	WANG Y Y, TAO H B, TIAN B J, SHENG D C, XU C C, ZHOU H M, HUANG S B, WANG P. Flowering dynamics, pollen, and pistil contribution to grain yield in response to high temperature during maize flowering. Environmental and Experimental Botany, 2019, 158: 80-88. doi: 10.1016/j.envexpbot.2018.11.007
[11]	刘伟华, 罗红兵, 邱博. 玉米雄穗发育及其分枝数的QTL定位研究进展. 作物研究, 2015, 29(6): 667-671.
	LIU W H, LUO H B, QIU B. Advances in maize tassel for development and QTL mapping of primary branch number. Crop Research, 2015, 29(6): 667-671. (in Chinese)
[12]	冯晔, 张建华, 包额尔敦嘎, 王东, 李淑兰, 张桂华, 高玉华, 高丽辉, 杨凤玲, 王春雷. 高温、干旱对玉米的影响及相应的预防措施. 内蒙古农业科技, 2008, 36(6): 38-39, 44.
	FENG Y, ZHANG J H, BAOEER D G, WANG D, LI S L, ZHANG G H, GAO Y H, GAO L H, YANG F L, WANG C L. Effect of high temperature and drought on maize and its prevention measures. Inner Mongolia Agricultural Science and Technology, 2008, 36(6): 38-39, 44. (in Chinese)
[13]	GIORNO F, WOLTERS-ARTS M, MARIANI C, RIEU I. Ensuring reproduction at high temperatures: The heat stress response during anther and pollen development. Plants, 2013, 2(3): 489-506. doi: 10.3390/plants2030489
[14]	KAKANI V G, REDDY K R, KOTI S, WALLACE T P, PRASAD P V V, REDDY V R, ZHAO D. Differences in vitro pollen germination and pollen tube growth of cotton cultivars in response to high temperature. Annals of Botany, 2005, 96(1): 59-67. doi: 10.1093/aob/mci149
[15]	VARA PRASAD P V, CRAUFURD P Q, KAKANI V G, WHEELER T R, BOOTE K J. Influence of high temperature during pre- and post-anthesis stages of floral development on fruit-set and pollen germination in peanut. Functional Plant Biology, 2001, 28(3): 233. doi: 10.1071/PP00127
[16]	DUPUIS I, DUMAS C. Influence of temperature stress on in vitro fertilization and heat shock protein synthesis in maize (Zea mays L.) reproductive tissues. Plant Physiology, 1990, 94(2): 665-670. doi: 10.1104/pp.94.2.665
[17]	于康珂. 玉米穗发育对高温胁迫的响应[D]. 郑州: 河南农业大学, 2016.
	YU K K. Responses of reproductive organs development in maize (Zea mays L.) to high temperature stress[D]. Zhengzhou: Henan Agricultural University, 2016. (in Chinese)
[18]	YOUNG L W, WILEN R W, BONHAM-SMITH P C. High temperature stress of Brassica napus during flowering reduces micro- and megagametophyte fertility, induces fruit abortion, and disrupts seed production. Journal of Experimental Botany, 2004, 55(396): 485-495. doi: 10.1093/jxb/erh038
[19]	张桂莲, 张顺堂, 肖浪涛, 唐文帮, 肖应辉, 陈立云. 抽穗开花期高温胁迫对水稻花药、花粉粒及柱头生理特性的影响. 中国水稻科学, 2014, 28(2): 155-166.
	ZHANG G L, ZHANG S T, XIAO L T, TANG W B, XIAO Y H, CHEN L Y. Effect of high temperature stress on physiological characteristics of anther, pollen and stigma of rice during heading- flowering stage. Chinese Journal of Rice Science, 2014, 28(2): 155-166. (in Chinese)
[20]	李川, 乔江方, 朱卫红, 代书桃, 黄璐, 张美微, 刘京宝. 玉米自交系响应花粒期高温胁迫差异表达基因的分析. 华北农学报, 2019, 34(1): 1-11. doi: 10.7668/hbnxb.201750986
	LI C, QIAO J F, ZHU W H, DAI S T, HUANG L, ZHANG M W, LIU J B. Differential expression of high temperature stress in anthesis stage related genes of maize inbred lines. Acta Agriculturae Boreali-Sinica, 2019, 34(1): 1-11. (in Chinese) doi: 10.7668/hbnxb.201750986
[21]	VOGLER A, BERTOSSA M, AULINGER-LEIPNER I, STAMP P. Weather effects on cross-pollination in maize. Crop Science, 2010, 50(2): 713-717. doi: 10.2135/cropsci2009.04.0213
[22]	李余良, 刘建华, 郑锦荣, 胡建广. 高温胁迫下甜玉米雌穗发育基因差异表达谱分析. 作物学报, 2013, 39(2): 269-279.
	LI Y L, LIU J H, ZHENG J R, HU J G. Gene expression profile of sweet corn ears under heat stress. Acta Agronomica Sinica, 2013, 39(2): 269-279. (in Chinese) doi: 10.3724/SP.J.1006.2013.00269
[23]	陶志强, 陈源泉, 隋鹏, 袁淑芬, 高旺盛. 华北春玉米高温胁迫影响机理及其技术应对探讨. 中国农业大学学报, 2013, 18(4): 20-27.
	TAO Z Q, CHEN Y Q, SUI P, YUAN S F, GAO W S. Effects of high temperature stress on spring maize and its technologic solutions in North China Plain. Journal of China Agricultural University, 2013, 18(4): 20-27. (in Chinese)
[24]	高英波, 张慧, 单晶, 薛艳芳, 钱欣, 代红翠, 刘开昌, 李宗新. 吐丝前高温胁迫对不同耐热型夏玉米产量及穗发育特征的影响. 中国农业科学, 2020, 53(19): 3954-3963. doi: 10.3864/j.issn.0578-1752.2020.19.009.
	GAO Y B, ZHANG H, SHAN J, XUE Y F, QIAN X, DAI H C, LIU K C, LI Z X. Effects of pre-silking high temperature stress on yield and ear development characteristics of different heat-resistant summer maize cultivars. Scientia Agricultura Sinica, 2020, 53(19): 3954-3963. doi: 10.3864/j.issn.0578-1752.2020.19.009. (in Chinese)
[25]	周祥利, 陶洪斌, 李梁, 王璞. 花后水分亏缺对玉米叶绿素荧光动力学参数及产量的影响. 华北农学报, 2010, 25(6): 187-190. doi: 10.7668/hbnxb.2010.06.036
	ZHOU X L, TAO H B, LI L, WANG P. Effects of post-anthesis water deficit on the kinetic parameters of chlorophylⅡfluorescence and grain yield of maize (Zea mays L.). Acta Agriculturae Boreali-Sinica, 2010, 25(6): 187-190. (in Chinese)
[26]	王海梅. 高温胁迫对河套灌区玉米生理指标及产量构成要素的影响. 干旱气象, 2015, 33(1): 59-62. doi: 10．11755/j．issn．1006－7639(2015)－01－0059
	WANG H M. Influence of high temperature stress on physiological indexes and yield components of maize in Hetao irrigation district. Journal of Arid Meteorology, 2015, 33(1): 59-62. (in Chinese)
[27]	HALL A J, VILELLA F, TRAPANI N, CHIMENTI C. The effects of water stress and genotype on the dynamics of pollen-shedding and silking in maize. Field Crops Research, 1982, 5: 349-363. doi: 10.1016/0378-4290(82)90036-3
[28]	张凤路, 陈景堂, G.O. Edmeades. 玉米雌雄穗开花间隔影响穗粒数的潜在原因研究. 玉米科学, 2002(2): 53-55.
	ZHANG F L, CHEN J T, EDMEADES G O. Studies on the underlying causes of the relationship between anthesis-silking interval and grain number. Journal of Maize Sciences, 2002, 10(2): 53-55. (in Chinese)
[29]	宋方威, 吴鹏, 邢吉敏, 周小英, 崔筱然, 于秀萍, 王进. 高温胁迫对玉米自交系父本花粉生活力的影响. 玉米科学, 2014, 22(3): 153-158.
	SONG F W, WU P, XING J M, ZHOU X Y, CUI X R, YU X P, WANG J. Influences of high temperature stress on viability of pollen grain inbred lines of male parent. Journal of Maize Sciences, 2014, 22(3): 153-158. (in Chinese)
[30]	降志兵, 陶洪斌, 吴拓, 王璞, 宋庆芳. 高温对玉米花粉活力的影响. 中国农业大学学报, 2016, 21(3): 25-29.
	JIANG Z B, TAO H B, WU T, WANG P, SONG Q F. Effects of high temperature on maize pollen viability. Journal of China Agricultural University, 2016, 21(3): 25-29. (in Chinese)
[31]	RATTALINO EDREIRA J I, BUDAKLI CARPICI E, SAMMARRO D, OTEGUI M E. Heat stress effects around flowering on kernel set of temperate and tropical maize hybrids. Field Crops Research, 2011, 123(2): 62-73. doi: 10.1016/j.fcr.2011.04.015
[32]	ALAM M A, SEETHARAM K, ZAIDI P H, DINESH A, VINAYAN M T, NATH U K. Dissecting heat stress tolerance in tropical maize (Zea mays L.). Field Crops Research, 2017, 204: 110-119. doi: 10.1016/j.fcr.2017.01.006

年份 Year	品种/自交系 Variety/Inbred line	雄穗分支总数 Total number of male panicle branch		雄穗长度 Tassel length (cm)
年份 Year	品种/自交系 Variety/Inbred line	CK	TR	CK	TR
2020	京2416 Jing2416	7.89±0.12hi	7.46±0.47i	108.26±2.58ij	100.85±1.75jk
	京MC01 JingMC01	3.24±0.11l	3.00±0.03l	75.15±4.40no	70.29±1.31o
	京B547 JingB547	6.18±0.14j	4.09±0.05k	93.41±2.75kl	84.99±4.55lm
	PH4CV	6.39±0.13j	4.60±0.11k	115.66±1.54hi	94.09±3.95k
	PH6WC	3.18±0.12l	2.29±0.11m	59.08±1.04p	48.72±1.15q
	郑58 Zheng58	10.21±0.04f	8.92±0.10g	184.20±3.55f	122.49±2.20h
	昌7-2 Chang7-2	32.01±1.63a	24.01±0.19b	320.86±1.41a	246.42±3.36c
	京农科728 Jingnongke728	8.85±0.10g	8.31±0.30gh	175.79±2.89fg	172.04±1.62g
	MC812	11.79±0.13e	11.19±1.02e	219.44±3.25d	213.28±4.56de
	先玉335 Xianyu335	5.88±0.06j	4.36±0.15k	119.62±3.85h	81.33±1.20mn
	郑单958 Zhengdan958	21.05±0.06c	13.86±0.07d	307.22±4.24b	208.15±5.78e
2021	京2416 Jing2416	7.69±0.28hi	7.23±0.22i	98.02±1.95h	92.39±2.67hi
	京MC01 JingMC01	3.20±0.17l	2.92±0.08l	66.78±3.23k	66.17±3.52k
	京B547 JingB547	6.00±0.43j	4.00±0.12k	88.20±0.76i	60.90±5.31kl
	PH4CV	6.33±0.21j	4.43±0.40k	110.00±3.95g	88.09±1.93i
	PH6WC	3.00±0.12l	2.11±0.07m	55.30±1.35l	44.64±2.46m
	郑58 Zheng58	10.14±1.23f	8.88±0.25g	176.10±2.20e	118.11±13.12g
	昌7-2 Chang7-2	29.29±0.97a	23.88±0.87b	310.93±10.07a	236.09±8.62c
	京农科728 Jingnongke728	8.63±0.15g	8.20±0.15gh	168.25±8.09ef	161.07±5.50f
	MC812	11.50±1.23e	10.99±1.23e	204.16±6.81d	196.14±11.19d
	先玉335 Xianyu335	5.75±0.20j	4.13±0.11k	110.72±7.26g	76.70±2.35j
	郑单958 Zhengdan958	20.92±0.82c	13.64±0.53d	293.89±4.09b	198.56±11.89d