中国不同年代玉米单交种及其亲本主要性状演变                    对密度的响应

doi:10.3864/j.issn.0578-1752.2013.12.003

Abstract

Abstract: 【Objective】The purpose of this study was to investigate the evolution characteristics of main agronomic traits and the responses to density of maize hybrids and their parents released in different eras, thus providing the critically important information for further developing the promising maize cultivars.【Method】Sixteen elite parents and their maize hybrids widely popularized and utilized in China released in 1960s, 1980s and 2000s were used to analyze the changes in main agronomic and physiology traits associated with yields in genetic improvement made during the past four decades in 2007-2008.【Result】The results showed that compared with 1980s and 1960s hybrids and their parents, the modern varieties had higher grain yield with the eras evolution, the grain yield increased by 25.7%, 35.8% and 16.3%, 29.7%, respectively. The 100-kenerl-weight increased significantly, but no significant difference was observed in heterosis index of maize hybrid under high density. However, plant height, ear position height and ear position height/plant height of hybrids released in different eras did not change significantly with eras evolution, while plant stem diameter increased, and leaf orientation value was higher significantly, the plant density-resistance and lodging-resistance enhanced significantly. Compared with 1980s and 1960s hybrids, the contemporary hybrids and their parents had obviously higher dry matter accumulation, post-anthesis dry matter accumulation/total dry matter accumulation and harvest index, especially the distribution ratio in post-anthesis was significantly increased of dry matter of contemporary hybrids. Also, the contemporary hybrids photosynthesis capacity (mean leaf index, chlorophyll contents, and mean net assimilation rate) had obviously advantages under high density, and 2000s hybrids had higher grain-leaf ratio, and leaf area per unit showed more contribution to their yields. The correlation analysis indicated that yield was positively correlated with 100-kernel weight, plant stem diameter and leaf orientation value, but not significantly correlated with plant height, ear height and plant height/ear height, positively significantly correlated with biomass, ratio of post-anthesis dry matter accumulation and mean net photosynthetic rate. The grain-leaf ratio and obtained grain yield of leaf area per unit of the contemporary hybrids positively significantly correlated with its grain yield, but not positively with their parents. So physical density-resistance of high-yielding maize population was significantly ameliorated.【Conclusion】These results demonstrated that maize grain yield enhancing mainly attributed by synergistically increased plant morphology and physiological density tolerance improvement in the progress of genetic improvement for maize in China.

Key words: single hybrid maize , parents , eras , traits evolution , plant density

LI Cong-Feng, ZHAO Ming, LIU Peng, ZHANG Ji-Wang, YANG Jin-Sheng, LIU Jing-Guo, WANG Kong-Jun, DONG Shu-Ting. Responses of Main Traits of Maize Hybrids and Their Parents to Density in Different Eras of China[J].Scientia Agricultura Sinica, 2013, 46(12): 2421-2429.

0
/ / Recommend

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

URL: https://www.chinaagrisci.com/EN/10.3864/j.issn.0578-1752.2013.12.003

https://www.chinaagrisci.com/EN/Y2013/V46/I12/2421

References

[1]Huang J K, Carl P, Scott R. Enhance the crops to feed the poor. Nature, 2002, 418: 678-684.

[2]佟屏亚. 中国玉米科技史. 北京: 中国农业科技出版社, 2004.

Dong P Y. The History of Science and Technology of Maize in China. Beijing: China Agriculture Science and Technology Publishing Company, 2004. (in Chinese)

[3]Duvick D N, Cassman K G. Post-green revolution trends in yield potential of temperate maize in the North-Central United States. Crop Science, 1999, 39: 1662-1630.

[4]戴景瑞. 我国玉米遗传育种的回顾和展望//玉米遗传育种国际学术讨论会文集. 长春, 2000: 1-7.

Dai J R. The review and prospect of genetic breeding in maize of China//The Collected Works of International Academic Symposium in Genetic Breeding of China. Changchun, 2000: 1-7. (in Chinese)

[5]Ding L, Wang K J, Jiang G M, Biswas D K, Xu H, Li L F, Li Y H. Effect of nitrogen deficiency on photosynthetic traits of maize hybrids released in different years. Annals of Botany, 2005, 96(5): 925-930.

[6]胡昌浩, 董树亭, 王空军. 我国不同年代玉米品种生育特性演进规律的研究. I 籽粒产量特性的演进. 玉米科学, 1998, 6(2): 44-48.

Hu C H, Dong S T, Wang K J. Revolution trends of reproductive characteristics of maize cultivars released in different years in China. Maize Science, 1998, 6(2): 44-48. (in Chinese)

[7]张泽民, 刘丰明, 牛连杰, 田兰荣. 不同年代自交系性状改良趋势的研究. 遗传, 1998, 20(增刊): 75-77.

Zhang Z M, Liu F M, Niu L J, Tian L R. Studied on the improvement trend of inbred lines in different years. Genetic, 1998, 20(Suppl.): 75-77. (in Chinese)

[8]张永科, 姚伯岐, 马永平. 玉米自交系产量优势性状及其研究利用. 国外农学-杂粮作物, 1998, 18(3): 1-4.

Zhang Y K, Yao B Q, Ma Y P. The dominant trait of yield in maize inbred lines and utilization. Foreign Agronomy-Rain Fed Crop, 1998, 18(3): 1-4. (in Chinese)

[9]Tollenaar M. Physiological basis of genetic improvement of maize hybrids in Ontario from 1959 to 1988. Crop Science, 1991, 31: 119-124.

[10]胡昌浩, 董树亭, 王空军. 我国不同年代玉米品种生育特性演进规律的研究. II 物质生产特性的演进. 玉米科学, 1998, 6(3): 49-53.

Hu C H, Dong S T, Wang K J. The evolution of growth and development traits in maize released in different years. II The evolution of dry matter accumulation. Maize Science, 1998, 6(3): 49-53. (in Chinese)

[11]Dwyer L M, Tollenaar M. Genetic improvement in photosynthetic response of hybrid maize cultivars, 1959 to 1988. Canada Journal of Plant Science, 1989, 69: 81-91.

[12]Ding L, Wang K J, Jiang G M, Liu M Z, Niu S L, Gao L M. Post-anthesis changes in photosynthetic traits of maize hybrids released in different years. Field Crops Research, 2005, 93: 108-115.

[13]李少昆, 赵明, 郭小强, 尚有军, 王树安, 王美云. 玉米自交系株型及其光合特性研究. 中国农业大学学报, 1999, 4(5): 77-81.

Li S K, Zhao M, Guo X Q, Shang Y J, Wang S A, Wang M Y. Relationships of plant-type and photosynthetic characteristics in different inbred lines of maize. Journal of China Agricultural University, 1999, 4(5): 77-81. (in Chinese)

[14]王建革. 我国玉米自交系性状的改进. 玉米科学, 1997, 5(4): 26-29.

Wang J G. The improvement of traits in maize lines of China. Maize Science, 1997, 5(4): 26-29. (in Chinese)

[15]徐庆章, 王忠孝, 黄舜阶, 牛玉贞, 王庆成, 张军. 玉米群体库源关系的研究 II不同玉米杂交种的群体库源潜力. 玉米科学, 1993, 1(4): 45-46.

Xu Q Z, Wang Z X, Huang S J, Niu Y Z, Wang Q C, Zhang J. Studied on the source-sink relationship of maize population ⅡPopulation source-sink potential of different maize hybrids. Maize Science, 1993, 1(4): 45-46. (in Chinese)

[16]Ci X K, Li M S, Liang X L, Xie Z J, Zhang D G, Li X H, Lu Z Y, Ru G L, Bai L, Xie C X, Hao Z F, Zhang S H. Genetic contribution to advanced yield for maize hybrids released from 1970 to 2000 in China. Crop Science, 2011, 51: 13-20.

[17]Pepper G Z. Leaf orientation and yield of maize. Crop Science, 1977, 17: 883-886.

[18]卢庆善, 孙毅, 华泽田. 农作物杂种优势. 北京: 中国农业科技出版社, 2001: 7-8.

Lu Q S, Sun Y, Hua Z T. Crops Heterosis. Beijing: China Agriculture Science and Technology Press, 2001: 7-8. (in Chinese)

[19]Arnon D I. Copper enzymes in isolated chloroplasts: polyphenoloxidase in Beta vulgaris. Plant Physiology, 1949, 24: 1-15.

[20]Evance L T, Ficher R A. Yield potential: its defination, measurement, and signicance. Crop Science, 1999, 39: 1544-1551.

[21]王振华, 王义波, 王永普, 张新. 玉米自交系株型和产量性状的遗传改良效果. 玉米科学, 2000, 8(1): 15-16.

Wang Z H, Wang Y B, Wang Y P, Zhang X. The effect of genetic improvement of plant type and yield traits in maize inbred lines. Maize Science, 2000, 8(1): 15-16. (in Chinese)

[22]Ioannis S T. Variation within maize lines and hybrids in the absence of competition and relation between hybrid potential yield per plant with line traits. The Journal of Agricultural Science, 2000, 134: 391-398.

[23]谢振江, 李明顺, 徐家舜, 张世煌. 遗传改良对中国华北不同年代玉米单交种产量的贡献. 中国农业科学, 2009, 42(3): 781-789.

Xie Z J, Li M S, Xu J S, Zhang S H. Contributions of genetic improvement to yields of maize hybrids during different eras in North China. Scientia Agricultura Sinica, 2009, 42(3): 781-789. (in Chinese)

[24]丰光, 刘志芳, 李妍妍, 景希强, 邢锦丰, 黄长玲. 中国不同时期玉米单交种产量变化的研究. 中国农业科学, 2010, 43(2): 277-285.

Feng G, Liu Z F, Li Y Y, Jing X Q, Xing J F, Huang C L. Study on the trends in yield change of maize single cross hybrids in different periods in China. Scientia Agricultura Sinica, 2010, 43(2): 277-285. (in Chinese)

[25]Ci X K, Li M S, Xu J S, Lu Z Y, Bai P F, Ru G L, Liang X L, Zhang D G, Li X H, Bai L, Xie C X, Hao Z F, Zhang S H, Dong S T. Trends of grain yield and plant traits in Chinese maize cultivars from the 1950s to the 2000s. Euphytica, 2012, 185: 395-406.

[26]李飒, 彭云峰, 于鹏, 张瑜, 方正, 李春俭. 不同年代玉米品种干物质积累与钾素吸收及其分配. 植物营养与肥料学报, 2011, 17(2): 325-332.

Li S, Peng Y F, Yu P, Zhang Y, Fang Z, Li C J. Accumulation and distribution of dry matter and potassium in maize varieties released in different years. Plant Nutrition and Fertilizer Science, 2011, 17(2): 325-332. (in Chinese)

[27]Rajcan I, Tollenaar M. Source–sink ratio and leaf senescence in maize. I. Dry matter accumulation and partitioning during the grain-filling period. Field Crops Research, 1999, 60: 245-253.

[28]Serageldin I. Biotechnology and food security in the 21st century. Science, 1999, 285: 387-389.

[29]Sangoi L. Understanding plant density effects on maize growth and development: an important issue to maximize grain yield. Ciência Rural, 2001, 31: 159-168.

Related Articles 15

[1]	LIU ZhenShan, TU HongXia, ZHOU JingTing, MA Yan, CHAI JiuFeng, WANG ZhiYi, YANG PengFei, YANG XiaoQin, Kumail Abbas, WANG Hao, WANG Yan, WANG XiaoRong. Genetic Analysis of Fruits Characters in Reciprocal Cross Progenies of Chinese Cherry [J]. Scientia Agricultura Sinica, 2023, 56(2): 345-356.
[2]	SHU JingTing,SHAN YanJu,JI GaiGe,ZHANG Ming,TU YunJie,LIU YiFan,JU XiaoJun,SHENG ZhongWei,TANG YanFei,LI Hua,ZOU JianMin. Relationship Between Expression Levels of Guangxi Partridge Chicken m6A Methyltransferase Genes, Myofiber Types and Myogenic Differentiation [J]. Scientia Agricultura Sinica, 2022, 55(3): 589-601.
[3]	JI XiaoHao,LIU FengZhi,WANG BaoLiang,LIU PeiPei,WANG HaiBo. Genetic Variation of Alcohol Acyltransferase Encoding Gene in Grape [J]. Scientia Agricultura Sinica, 2022, 55(14): 2797-2811.
[4]	ZHANG JingYuan,MIAO FaMing,CHEN Teng,LI Min,HU RongLiang. Development and Application of a Real-Time Fluorescent RPA Diagnostic Assay for African Swine Fever [J]. Scientia Agricultura Sinica, 2022, 55(1): 197-207.
[5]	WANG JinFeng,WANG ZhuangZhuang,GU FengXu,MOU HaiMeng,WANG Yu,DUAN JianZhao,FENG Wei,WANG YongHua,GUO TianCai. Effects of Nitrogen Fertilizer and Plant Density on Carbon Metabolism, Nitrogen Metabolism and Grain Yield of Two Winter Wheat Varieties [J]. Scientia Agricultura Sinica, 2021, 54(19): 4070-4083.
[6]	ZHOU JingLong,FENG ZiLi,WEI Feng,ZHAO LiHong,ZHANG YaLin,ZHOU Yi,FENG HongJie,ZHU HeQin. Biocontrol Effect and Mechanism of Cotton Endophytic Bacterium YUPP-10 and Its Secretory Protein CGTase Against Fusarium Wilt in Cotton [J]. Scientia Agricultura Sinica, 2021, 54(17): 3691-3701.
[7]	Zhen LI,ShiXiong YANG,Sheng NIU,Ning ZHANG,Xin LI,YangYang ZHANG,YunFei JIA,ZhiXiong TIAN,GuanBao NING,Ding ZHANG,WenXia TIAN. Effect of Recombinant GSTA3 Protein on Expression of the Anti-Apoptotic Gene BAG-3 in Thiram-Induced Tibial Chondrodysplasia [J]. Scientia Agricultura Sinica, 2020, 53(9): 1921-1930.
[8]	DONG ZhiDan,SONG ShangWei,SONG ChunHui,ZHENG XianBo,JIAO Jian,WANG MiaoMiao,YAN ZhenLi,ZHANG RuiPing,BAI TuanHui. Pedigree Analysis and Breeding Inspiration of Apple Cultivars in China [J]. Scientia Agricultura Sinica, 2020, 53(21): 4485-4496.
[9]	LI HuiXia,TIAN Gang,WANG YuWen,LIU Xin,LIU Hong. Genetic Correlation Coefficients of Foxtail Millet Traits Between Parents and Hybrids [J]. Scientia Agricultura Sinica, 2020, 53(2): 239-246.
[10]	TIAN Yuan,WANG Li,LONG Feng,ZAN LinSen,CHENG Gong. Codon Optimization of Human Lysozyme and High-Efficiency Expression in Bovine Mammary Cells [J]. Scientia Agricultura Sinica, 2020, 53(18): 3805-3817.
[11]	PIAO Lin,LI Bo,CHEN XiChang,DING ZaiSong,ZHANG Yu,ZHAO Ming,LI CongFeng. Regulation Effects of Improved Cultivation Measures on Canopy Structure and Yield Formation of Dense Spring Maize Population [J]. Scientia Agricultura Sinica, 2020, 53(15): 3048-3058.
[12]	BAI YanWen,ZHANG HongJun,ZHU YaLi,ZHENG XueHui,YANG Mei,LI CongFeng,ZHANG RenHe. Responses of Canopy Radiation and Nitrogen Distribution, Leaf Senescence and Radiation Use Efficiency on Increased Planting Density of Different Variety Types of Maize [J]. Scientia Agricultura Sinica, 2020, 53(15): 3059-3070.
[13]	MA Wen,LIU Jiao,ZHANG XueYao,SHEN GuoHua,QIN XueMei,ZHANG JianQin. Enzymatic Characteristics and Metabolic Analysis to Malathion and p,p’-DDT of LmGSTS2 from Locusta migratoria [J]. Scientia Agricultura Sinica, 2019, 52(8): 1389-1399.
[14]	BIAN ShuXun,HAN XiaoLei,YUAN GaoPeng,ZHANG LiYi,TIAN Yi,ZHANG CaiXia,CONG PeiHua. Cloning and Functional Analysis of U6 Promoter in Apple [J]. Scientia Agricultura Sinica, 2019, 52(23): 4364-4373.
[15]	ShaoKang DI,QingGang YIN,YaYing XIA,YongZhen PANG. Functional Characterization of a UDP: Flavonoid Glycosyltransferase Gene UGT73C19 in Glycine max [J]. Scientia Agricultura Sinica, 2019, 52(20): 3507-3519.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

Responses of Main Traits of Maize Hybrids and Their Parents to Density in Different Eras of China

PDF

Cited

Abstract

Cite this article

share this article

References

Related Articles 15

Metrics

Comments

Recommended 0