Analysis of Yield Advantage and Physiological Mechanis of Changzagu Series Millet Hybrids

GUO Yu-Rong; LIU Hong; YU Zhen-Hua; TIAN Gang; LIU Xin; LI Hui-Xia

doi:10.11983/CBB24187

Chinese Bulletin of Botany >

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DOI: https://doi.org/10.11983/CBB24187

Analysis of Yield Advantage and Physiological Mechanis of Changzagu Series Millet Hybrids

GUO Yu-Rong ,
LIU Hong ,
YU Zhen-Hua ,
TIAN Gang ,
LIU Xin ,
LI Hui-Xia

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1College of Agronomy, Shanxi Agricultural University, Taigu 030801, China; 2Millet Research Institute, Shanxi Agricultural University, Changzhi 046011, China; 3Shanxi Center for Testing of Functional Agro-Products, Shanxi Agricultural University, Taiyuan 030031, China

Received date: 2024-12-02

Revised date: 2025-02-20

Online published: 2025-03-26

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Abstract

INTRODUCTION: In agricultural production, the utilization of heterosis has brought significant benefits to society and economic development by markedly increasing crop yield, stress resistance, and quality. Foxtail millet (Setaria italica var. germanica), as an important coarse grain crop in the arid and semi-arid regions of northern China, holds a significant position in dryland ecological agriculture. However, the slow increase in the yield per unit area of foxtail millet has limited the further realization of its production potential. Utilizing heterosis has thus become one of the effective ways to enhance the yield of foxtail millet. Nevertheless, research on the physiological and molecular mechanisms of its heterosis is still relatively weak, and the formation mechanism remains unclear. Therefore, a deep understanding of the physiological mechanisms of heterosis in foxtail millet is of great importance for improving the yield of hybrid varieties.

RATIONALE: The Changzagu series of foxtail millet hybrids (Changzagu 466, Changzagu 2922, and Changzagu 333) exhibit significant over-parent heterosis in yield. To elucidate the formation mechanism of yield heterosis in foxtail millet, we systematically analyzed the yield advantages of these hybrids and their influencing factors by measuring yield-related traits and key physiological indicators of the hybrids and their parental lines.

RESULTS: Throughout the entire growth period, the chlorophyll content of the three hybrid varieties was higher than that of their parents. Among them, Changzagu 466 exhibited the highest chlorophyll content at the jointing stage, reaching 13.86 mg∙g⁻¹ FW. During the seedling and jointing stages, the root activity of the three hybrids was significantly higher than that of their parents. Specifically, Changzagu 466 showed the highest root activity at the seedling stage, measuring 1.76 mg∙g⁻¹∙h⁻¹, which was 7.8 times and 5.5 times higher than its female and male parents, respectively. Changzagu 2922 had root activity values at the seedling stage that were 0.38 and 0.66 mg∙g⁻¹∙h⁻¹ higher than its female and male parents, respectively. Meanwhile, Changzagu 333 displayed more pronounced advantages at the jointing stage, with root activity values 0.31 and 0.62 mg∙g⁻¹∙h⁻¹ higher than its female and male parents, respectively. In terms of yield-related traits, compared to their parents, the hybrids showed significant improvements in both grain filling rate and spikelet number. Changzagu 466 reached its maximum grain filling rate of 1.58 g∙d⁻¹ per panicle at 19 days after flowering. Both Changzagu 466 and Changzagu 333 had significantly higher spikelet numbers than their parents, while Changzagu 2922 also showed a significant increase in spikelet numbers. In addition, the hybrid varieties also demonstrate certain advantages in root nitrogen accumulation and nitrogen translocation efficiency. Among them, Changzagu 2922 exhibits the strongest root nitrogen accumulation advantage and the highest nitrogen translocation efficiency (nearly 56%), which is significantly higher than that of its male parent line M22.

CONCLUSION: The Changzagu series of foxtail millet hybrids effectively enhances photosynthetic capacity and nutrient absorption and utilization efficiency by significantly increasing chlorophyll content, root activity during the early growth stages, and root nitrogen accumulation. Meanwhile, the significant increase in grain filling rate and spikelet number of the hybrids further enhances both grain weight and grain number per panicle, ultimately achieving high yield.

Key words： hybrid millet; physiological index; grouting rate; agronomic traits; yield

Cite this article

GUO Yu-Rong , LIU Hong , YU Zhen-Hua , TIAN Gang , LIU Xin , LI Hui-Xia . Analysis of Yield Advantage and Physiological Mechanis of Changzagu Series Millet Hybrids[J]. Chinese Bulletin of Botany, 0 : 1 -0 . DOI: 10.11983/CBB24187

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References

参考文献
[1] 皮凯, 黄莺, 段丽丽, 莫泽君, 罗雯, 柯渔洲, 王平松, 曾帅波, 刘仁祥(2022). 烟草根系杂种优势表现及相关基因差异表达分析. 南方农业学报, 53 (11): 3028-3036
PI K, Huang Y, Duan LL, Mo ZJ, Luo W, Ke YZ, Wang PS, Zeng SB, Liu RX (2022). Analysis of heterosis in tobacco roots and differential expression of related genes. Journal of Southern Agricultural Sciences, 53 (11): 3028-3036
[2] 彭翠兰（2020）.不同农艺措施对基质栽培番茄生理、果实产量和品质的影响.硕士论文. 新疆：塔里木大学. pp:1-53
Peng CL (2020). Effects of different agronomic measures on physiology, fruit yield and quality of tomato cultivated in substrate. Master's thesis. Xinjiang: Tarim University. pp:1-53.
[3] 唐兴旺, 石玉, 于振文, 张永丽, 赵俊晔(2020). 开花期土壤水分含量对不同穗型小麦品种光合特性及产量的影响. 麦类作物学报, 40 (05): 609-614
Tang XF, Shi Y, Yu ZW, Zhang YL, Zhao JY (2020). Effects of soil moisture content at flowering stage on photosynthetic characteristics and yield of wheat cultivars with different ear types. Journal of Wheat Crops, 40 (05): 609-614
[4] 刘金兰, 李艳军, 段选林, 石玖芳, 康敏(2017). 春播谷子产量及其相关数量性状关系的分析.农业开发与装备.(11)
Liu JL, Li YJ, Duan XL, Shi JF, Kang M (2017). Analysis of the relationship between spring sowing grain yield and its related quantitative traits. Agricultural development and equipment.(11)
[5] 李素英, 刘丹, 李强, 代小冬, 韩燕丽, 陈超, 李君霞, 刘正理(2018). 谷子杂交种产量及产量性状杂种优势的表现型鉴定. 河南农业科学, 47 (08): 28-34
Li SY, Liu D, Li Q, Dai XD, Han YL, Chen C, Li JX, Liu ZL (2018). Phenotypic identification of yield and yield trait heterosis of millet hybrids. Henan Agricultural Sciences, 47 (08): 28-34
[6] 刘童, 夏文君, 彭小爱, 卢茂昂, 曹磊, 张玲, 何贤芳, 朱玉磊(2024). 氮肥运筹对小麦籽粒灌浆、花后干物质转运及植株糖含量影响.四川农业大学学报, 42(04):771-779
Liu T, Xia WJ, Peng XA, Lu MA, Cao L, Zhang L, He XF, Zhu YL (2024). Effects of nitrogen fertilizer operation on grain filling, dry matter transport after anthesis and sugar content in wheat plants. Journal of Sichuan Agricultural University, 42(04):771-779
[7] 卢海博, 李鸿强, 龚学臣, 乔永明, 赵治海, 赵娜娜(2016). 张杂谷灌浆期杂种优势的研究. 湖北农业科学, 55 (02): 293-295+309
Lu HB, Li HQ, Gong XC, Qiao YM, Zhao ZH, Zhao NN (2016). Study on heterosis of Zhangzagu during grouting stage. Hubei Agricultural Sciences, 55 (02): 293-295+309
[8] 黄玲, 高阳, 李新强, 邱新强, 申孝军, 刘战东, UZOKWE Pauline Adaobi, 段爱旺(2013).水分胁迫下不同年代冬小麦品种干物质积累与转运特性.中国生态农业学报 ,21(08):943-950
Huang L, Gao Y, Li XQ, Qiu XQ, Shen XJ, Liu ZD, UZOKWE Pauline Adaobi, and Duan Ai-Wang (2013). Dry matter accumulation and transport characteristics of winter wheat varieties in different years under water stress. Chinese Journal of Eco-Agriculture,21(08):943-950
[9] 肖层林, 张海清, 麻浩（2015）.植物杂种优势原理与利用. 北京：高等教育出版社，pp:1-2
Xiao CL, Zhang HQ, Ma H (2015). Principle and utilization of plant heterosis. Beijing: Higher Education Press, pp:1-2
[10] 徐田军, 张勇, 赵久然, 王荣焕, 吕天放, 刘宏伟, 刘月娥, 蔡万涛, 张如养, 宋伟, 邢锦丰, 王元东(2021). 不同杂种优势群玉米自交系籽粒灌浆和脱水速率评价.植物遗传资源学报, 22(06):1595-1605
Xu TJ, Zhang Y, Zhao JR, Wang RH, Lu TF, Liu HW, Liu YE, Cai WT, Zhang RY, Song W, Xing JF, Wang YD (2021). Evaluation of grain filling and dehydration rate of maize inbred lines in different heterosis groups. Journal of Plant Genetic Resources, 22(06):1595-1605
[11] 周花, 戴丽君, 李永平, 黄小兰, 马亚平(2020). 11个谷子新品种的主要农艺性状灰色关联度分析与综合评价.甘肃农业科技, (12):25-30
Zhou H, Dai LJ, Li YP, Huang XL, Ma YP (2020). Grey correlation analysis and comprehensive evaluation of main agronomic traits of 11 new millet varieties. Gansu Agricultural Science and Technology, (12):25-30
[12] 张霞, 冯永忠(2017)。神木县不同谷子品种主要农艺性状及产量分析.西北农业学报,, 26(01):32-37
Zhang X, Feng YZ (2017). Analysis of main agronomic characters and yield of different millet varieties in Shenmu County. Journal of Northwest Agricultural Sciences, 26(01):32-37
[13] 史根生, 史关燕, 杨成元, 麻慧芳, 陈瑛(2016).谷子杂交种主要农艺性状的灰色关联度分析及综合评价.农学学报, 6(05):1-5
Shi GS, Shi GY, Yang CY, Ma HF, Chen Y (2016). Grey correlation degree analysis and comprehensive evaluation of main agronomic traits of millet hybrids. Journal of Agricultural Sciences, 6(05):1-5
[14] 史关燕, 王啸旗, 韩渊怀, 杨成元, 麻慧芳, 赵雄伟, 乔治军(2021). 谷子产量和品质相关性状的杂种优势及遗传特性分析.热带亚热带植物学报, 29(04):349-359
Shi GY, Wang XQ, Han YH, Yang CY, Ma HF, Zhao XW, Qiao ZJ(2021). Heterosis and genetic characteristics analysis of yield and quality related traits of millet. Journal of Tropical and Subtropical Botany, 29(04):349-359
[15] 任青, 马娟娟, 孙西欢, 郭向红, 段勇, 李若帆(2021). 灌溉与施肥方式对糯玉米叶绿素与产量的影响. 人民黄河, 43 (11): 150-15
Ren Q, Ma JJ, Sun XH, Guo XH, Duan Y, Li RF (2021). Effects of irrigation and fertilization on chlorophyll and yield of waxy maize. Huanghe River, 43 (11): 150-15
[16] 宋中强, 陈亚光, 刘金荣(2023). 华北地区谷子农艺性状和产量的综合分析. 农业科技通讯, (07): 35-38
Song ZQ, Chen YG, Liu JR (2023). Comprehensive analysis of agronomic traits and yield of millet in North China. Journal of Agricultural Science and Technology, (07): 35-38
[17] 宋慧, 王涛, 闫宏山, 邢璐, 解慧芳, 李龙, 王淑君, 宋中强, 何庆, 刘金荣, 冯佰利(2022).不同类型谷子品种（系）光合性能、干物质积累转运和籽粒灌浆特性对产量的影响.中国农业大学学报, 27(07):58-72
Song H, Wang T, Yan HS, Xing L, Xie HF, Li L, Wang SJ, Song ZQ, He Q, Liu JR, Feng BL(2022). Effects of photosynthetic performance, dry matter accumulation and transport and grain filling characteristics on yield of different types of millet varieties (lines). Journal of China Agricultural University, 27(07):58-72
[18] 闫锋, 董扬, 赵富阳, 侯晓敏, 李清泉, 韩业辉(2023). 黑龙江地区谷子高光效栽培模式研究. 天津农林科技, (04): 31-34
Yan F, Dong Y, Zhao FY, Hou XM, Li QQ, Han YH (2023). Study on cultivation model of millet with high light efficiency in Heilongjiang region. Tianjin Agriculture and Forestry Science and Technology, (04): 31-34
[19] 杨艳君, 郭平毅, 曹玉凤, 王宏富, 王玉国, 原向阳, 邢国芳, 邵东红, 祁祥, 解丽丽, 聂萌恩, 郭俊, 宁娜(2012). 施肥水平和种植密度对张杂谷5号产量及其构成要素的影响. 作物学报, 38 (12): 2278-2285
Yang YJ, Guo PY, Cao YF, Wang HF, Wang YG, Yuan XY, Xing GF, Shao DH, Qi X, Xie LL, Nie ME, Guo J, Ning N (2012). Effects of fertilization level and planting density on yield and components of Zhangzagu No. 5. Acta Agronomica Sinica, 38 (12): 2278-2285
[20] 魏玮, 赵芳, 张晓磊, 李双东, 宋国亮, 朱学海, 赵治海(2019). 张杂谷谷子主要农艺性状与产量的灰色关联度分析.农业科技通讯, (09):182-188
Wei W, Zhao F, Zhang XL, Li SD, Song GL, Zhu XH, Zhao ZH (2019). Grey correlation degree analysis of main agronomic traits and yield of Zhangzagu millet. Journal of Agricultural Science and Technology, (09):182-188
[21] 王蕾, 张想平, 严宗山, 徐也, 张燕, 赵海鹏, 唐辉春, 马树琳, 蔺泽荣, 张自强, 蔡小斌(2024).不同类型大麦光合特性、灌浆特征差异及源库关系比较.华北农学报, 39(03):114-123
Wang L, Zhang XP, Yan ZS, Xu Y, Zhang Y, Zhao HP, Tang HC, Ma SL, Lin ZR, Zhang ZQ, Cai XB (2024). Comparison of photosynthetic characteristics, filling characteristics and source-sink relationship among different types of barley. Journal of North China Agricultural Sciences, 39(03):114-123
[22] Du RQ , Li ZJ , Xiang YZ, Sun T, Liu XC, Shi HZ, Li WY, Huang XY, Tang ZJ, Lu JS, Chen JY, Zhang FC(2024). Drip Fertigation Increases Maize Grain Yield by Affecting Phenology, Grain Filling Process, Biomass Accumulation and Translocation: A 4-Year Field Trial. Plants, 13 (14): 1903-1903
[23] Li DY, Huang ZY, Song SH, Xin YY, Mao DH, Lv QM, Zhou M, Tian DM, Tang MF, Wu Q, Liu X, Chen TT, Song XW, Fu XQ, Zhao BR, Liang CZ, Li AH, Liu GZ, Li SH, Hu SN, Cao XF, Yu J, Yuan LP, Chen CY, Zhu LH(2016). Integrated analysis of phenome, genome, and transcriptome of hybrid rice uncovered multiple heterosis-related loci for yield increase. Proceedings of the National Academy of Sciences of the United States of America, 113 (41): E6026-E6035
[24] Nesma S ,A. A I M ,Jie X, Hu K, Yang Y, Nishawy E, Yi B, Wen J, Ma C, Shen J, Fu T, Tu J(2021). Overdominance at the Gene Expression Level Plays a Critical Role in the Hybrid Root Growth of Brassica napus[J].International Journal of Molecular Sciences, 22(17):9246-9246
[25] Wu HX , Song XH ,Amjid W M ,Chen C, Zhang DY, Guo WZ(2024). Mining elite loci and candidate genes for root morphology-related traits at the seedling stage by genome-wide association studies in upland cotton (Gossypium hirsutum L.).Journal of Integrative Agriculture, 23 (10): 3406-3418
[26] Zhang XC ,Liu XL ,Wang L , Zhao QC, Yu Y, Du RR, Xu YD, Zhen WC, Wang YD(2024). Wheat yield and grain-filling characteristics due to cultivar replacement in the Haihe Plain in China [J]. Frontiers in Plant Science, 151374453-1374453

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