JIA-2021-2042   1964至2014年间中国育成玉米单交种的
籽粒灌浆特性演变规律研究

doi:10.1016/j.jia.2022.08.006

Journal of Integrative Agriculture ›› 2023, Vol. 22 ›› Issue (3): 691-700.DOI: 10.1016/j.jia.2022.08.006

JIA-2021-2042 1964至2014年间中国育成玉米单交种的籽粒灌浆特性演变规律研究

收稿日期:2021-11-26 接受日期:2022-02-16 出版日期:2023-03-20 发布日期:2022-03-07

Changes in grain-filling characteristics of single-cross maize hybrids released in China from 1964 to 2014

GAO Xing^*, LI Yong-xiang^*, YANG Ming-tao, LI Chun-hui, SONG Yan-chun, WANG Tian-yu, LI Yu^#, SHI Yun-su^#

Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing 100081, P.R.China

Received:2021-11-26 Accepted:2022-02-16 Online:2023-03-20 Published:2022-03-07
About author:#Correspondence LI Yu, E-mail: liyu03@caas.cn; SHI Yun-su, E-mail: shiyunsu@caas.cn * These authors contributed equally to this study.
Supported by:
This work was partly supported by the National Key R&D Program of China (2016YFD0100303 and 2016YFD0100103), the Fundamental Research Funds for Central Non-Profit of Institute of Crop Sciences, Chinese Academy of Agricultural Sciences (Y2020YJ09 and CAAS-ZDRW202109), and the Agricultural Science and Technology Innovation Program, China (ASTIP).

摘要/Abstract

摘要：

灌浆是籽粒形成的重要生理过程，直接决定最终产量。本研究以1964至2014年间在中国育成的50个代表性玉米单交种为试验材料，在多环境下对玉米籽粒灌浆特性演变规律进行研究。结果表明，籽粒灌浆快增期（Effective grain filling phase）的灌浆速率（43.40%）与灌浆持续时间（54.46%）对百粒重的形成具有重要作用。同时发现，随着不同时期育成单交种百粒重的显著增加，实际灌浆期（Actual grain filling period duration，AFPD）表现为持续上升，每10年有效积温平均增加23.41 ℃day。但对生理成熟期（Days from sowing to physiological maturity，DPM）而言，每10年有效积温仅平均增加19.76°C d，播种至吐丝的天数（Days from sowing to silking, DTS）占整个生理成熟期的比例则明显降低，由上世纪60年代的53.24%降至本世纪初的49.78%（2010s）。另外，还发现不同年代间中国育成单交种的各阶段籽粒灌浆速率均不存在显著差异，但籽粒灌浆相关性状的稳定性明显改善。对本土育种家选育单交种与国外种子企业选育单交种的灌浆特性进行比较，发现外来品种的籽粒快增期灌浆持续时间更长、灌浆相关性状的稳定性更高。根据本研究的结果，认为缩短播种至吐丝的天数，延长籽粒灌浆持续时间，提高籽粒灌浆速率，并继续提升籽粒灌浆相关性状的稳定性将有利于未来玉米品种产量的进一步提高。

Abstract: Grain filling is the physiological process for determining the obtainment of yield in cereal crops. The grain-filling characteristics of 50 maize brand hybrids released from 1964 to 2014 in China were assayed across multiple environments. We found that the grain-filling duration (54.46%) and rate (43.40%) at the effective grain-filling phase greatly contributed to the final performance parameter of 100-kernel weight (HKW). Meanwhile, along with the significant increase in HKW, the accumulated growing degree days (GDDs) for the actual grain-filling period duration (AFPD) among the selected brand hybrids released from the 1960s to the 2010s in China had a decadal increase of 23.41°C d. However, there was a decadal increase of only 19.76°C d for GDDs of the days from sowing to physiological maturity (DPM), which was also demonstrated by a continuous decrease in the ratio between the days from sowing to silking (DS) and DPM (i.e., from 53.24% in the 1960s to 49.78% in the 2010s). In contrast, there were no significant changes in grain-filling rate along with the release years of the selected hybrids. Moreover, the stability of grain-filling characteristics across environments also significantly increased along with the hybrid release years. We also found that the exotic hybrids showed a longer grain-filling duration at the effective grain-filling phase and more stability of the grain-filling characteristics than those of the Chinese local hybrids. According to the results of this study, it is expected that the relatively longer grain-filling duration, shorter DS, higher grain-filling rate, and steady grain-filling characteristics would contribute to the yield improvement of maize hybrids in the future.

Key words: maize (Zea mays L.) , grain filling rate , grain filling duration , stability

. JIA-2021-2042 1964至2014年间中国育成玉米单交种的籽粒灌浆特性演变规律研究[J]. Journal of Integrative Agriculture, 2023, 22(3): 691-700.

GAO Xing, LI Yong-xiang, YANG Ming-tao, LI Chun-hui, SONG Yan-chun, WANG Tian-yu, LI Yu, SHI Yun-su. Changes in grain-filling characteristics of single-cross maize hybrids released in China from 1964 to 2014[J]. Journal of Integrative Agriculture, 2023, 22(3): 691-700.

参考文献

Bai D P. 2007. Discussion on breeding test system of Pioneer company and modern maize breeding. In: China Corn Variety Science and Technology Forum. The National Agro-Tech Extension and Service Center (NATESC), Beijing, China. pp. 312–321. (in Chinese)
Bewley J D, Black M. 1985. Seeds: Physiology of Development and Germination. Plenum, New York.
Bradley J P, Knittle K H, Troyer A F. 1988. Statistical methods in seed corn product selection. Journal of Production Agriculture, 1, 34–38.
Cardwell V B. 1982. Fifty years of Minnesota corn production: sources of yield increase. Agronomy Journal, 74, 984–990.
Cavalieri A J, Smith O S. 1984. Grain filling and field drying of a set of maize hybrids released from 1930 to 1982. Crop Science, 5, 856–860.
Cross H Z. 1975. Diallel analysis of duration and rate of grain filling of seven inbred lines of corn. Crop Science, 15, 532–535.
Dai J R. 2000. Prospects of maize genetics and breeding for the 21st century. In: Paper Collection International Maize Genetics Breeding Symposium, Changchun, Jilin Province, China. September 15–17, 2000. Chinese Association of Agricultural Sciences, Beijing, China. pp. 16–22. (in Chinese)
Ding J Q. 2012. A study of grain filling and dehydration of rate for different period of maize single-cross hybrids and their parents in China. MSc thesis, Chinese Academy of Agricultural Sciences, Beijing. (in Chinese)
Duvick D N. 1992. Genetic contributions to advances in yield of U.S. maize. Maydica, 37, 69–79.
Duvick D N. 1997. What is yield? In: Edmeades G O, Bänziger B, Mickelson H R, Pena-Valdivia C B, eds., Developing Drought and Low N-Tolerant Maize. Proceedings of a Symposium, March 25–29, 1996. The Centro Internacional de Mejoramiento de Maiz y Trigo (CIMMYT), El Batán, Mexico. pp. 332–335.
Duvick D N. 2005. Genetic progress in yield of United States maize (Zea mays L.). Maydica, 50, 193–202.
Duvick D N, Smith J S C, Cooper M. 2004. Long-term selection in a commercial hybrid maize breeding program. Plant Breeding Reviews, 24, 109–151.
Eyherabide G H, Damilano A L. 2001. Comparison of genetic gain for grain yield of maize between the 1980s and 1990s in Argentina. Maydica, 46, 277–281.
Hubert B, Rosegrant M, Van Boekel M, Ortiz R. 2010. The future of food: Scenarios for 2050. Crop Science, 50, 33–50.
Li Y, Ma X, Wang T, Li Y, Liu C, Liu Z, Sun B, Shi Y, Song Y, Carlone M, Bubeck D, Bhardwaj H, Whitaker D, Wilson W, Jones E, Wright K, Sun S, Niebur W, Smith S. 2011. Increasing maize productivity in China by planting hybrids with germplasm that responds favorably to higher planting densities. Crop Science, 51, 2391–2400.
Li Y X, Li Y, Ma X, Liu C, Liu Z, Tan X, Sun B, Shi Y, Song Y, Wang T, Smith S. 2014. Contributions of parental inbreds and heterosis to morphology and yield of single-cross maize hybrids in China. Crop Science, 54, 76–88.
Liu Y, Li M, Li X, Yong H, Yan N, Zhou Z, Zhang X, Xia R, Zhang D, Hao Z, Weng J, Bai L, Shi Z, Zhang S. 2015. Preliminary study on grain filling and dehydration rate of maize hybrids used predominantly in 1970s–2000s. Journal of Maize Science, 23, 85–91. (in Chinese)
Luque S F, Cirilo A G, Otegui M E. 2006. Genetic gains in grain yield and related physiological attributes in Argentine maize hybrids. Field Crops Research, 95, 383–397.
Mitrović B, Stojaković M, Zorić M, Stanisavljević D, Bekavac G, Nastasić A, Mladenov V. 2016. Genetic gains in grain yield, morphological traits and yield stability of middle-late maize hybrids released in Serbia between 1978 and 2011. Euphytica, 211, 321–330.
Qin X, Feng F, Li Y, Xu S, Siddique KHM, Liao Y C. 2016. Maize yield improvements in China: Past trends and future directions. Plant Breeding, 135, 166–176.
Richards F J. 1959. A flexible growth function for empirical use. Journal of Experimental Botany, 10, 290–301.
Russell W A. 1991. Genetic improvement of maize yields. Advances in Agronomy, 46, 245–298.
Sun Z, Tian P, Wang J. 1990. Preliminary study on the growth period structure of soybean varieties in the northeast of China. Soybean Science, 9, 198–205. (in Chinese)
Tao Z, Chen Y, Li C, Zou J, Yan P, Yuan S, Wu X, Sui P. 2016. The causes and impacts for heat stress in spring maize during grain filling in the North China Plain - A review. Journal of Integrative Agriculture, 15, 2677–2687.
Tollenaar M. 1989. Genetic improvement in grain yield of commercial maize hybrids grown in Ontario from 1959 to 1988. Crop Science, 29, 1365–1371.
Wang T, Ma X, Li Y, Bai D, Liu C, Liu Z, Tan X, Shi Y, Song Y, Carlone M, Bubeck D, Bhardwaj H, Jones E, Wright K, Smith S. 2011. Changes in yield and yield components of single-cross maize hybrids released in China between 1964 and 2001. Crop Science, 51, 512–525.
Wang Y, Cheng L, Leng J, Wu C, Shao G, Hou W, Han T. 2015. Genetic analysis and quantitative traits locus identification of reproductive to vegetative growth period ratio in soybean (Glycine max (L.) Merr). Euphytica, 201, 275–284.
Yang J, Zhang J, Wang Z, Zhu Q, Wang W. 2001. Hormonal changes in the grains of rice subjected to water stress during grain filling. Plant Physiology, 127, 315–323.
Zhu Q, Cao X, Luo Y. 1988. Growth analysis on the process of grain filling in rice. Acta Agronomica Sinica, 14, 182–192. (in Chinese)

JIA-2021-2042 1964至2014年间中国育成玉米单交种的籽粒灌浆特性演变规律研究

Changes in grain-filling characteristics of single-cross maize hybrids released in China from 1964 to 2014

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics

JIA-2021-2042 1964至2014年间中国育成玉米单交种的 籽粒灌浆特性演变规律研究

Changes in grain-filling characteristics of single-cross maize hybrids released in China from 1964 to 2014

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics

JIA-2021-2042 1964至2014年间中国育成玉米单交种的籽粒灌浆特性演变规律研究