去苞叶对夏玉米籽粒灌浆特性和产量的影响

doi:10.3864/j.issn.0578-1752.2015.11.004

Abstract

Abstract: 【Objective】 A field experiment was conducted to study the effects of dislodging subtending leaf on grain yield, grain volume, dry weight, dehydrating rate and grain filling rate of summer maize.【Method】Three maize cultivars XY335, ZD958 and DH661 were used to analyze the effects of subtending leaf on grain yield and yield components, grain filling (grain volume, dry matter and dehydrating rate), and the time of milk lines disappearance and black layer appearance of summer maize by setting different dislodging subtending leaf treatments such as dislodging 1/4 subtending leaf (S1), dislodging 1/2 subtending leaf (S2), dislodging all subtending leaves (S3), and CK. 【Result】 The results showed that grain yield of summer maize decreased significantly after dislodging subtending leaf. Grain yields of S1, S2 and S3 of XY335 decreased by 9.45%, 13.78% and 27.89% respectively, compared to CK. Yields of ZD958 decreased by 10.72%, 15.07% and 24.75%, respectively, compared to CK. Yields of DH661 decreased by 9.31%, 16.01% and 22.35%, respectively. The damage increased with increasing number of dislodging subtending leaf. Grain weight and grain number per panicle of summer maize decreased significantly after subtending leaves were dislodged. The greatest effect was observed under the S3 treatment. Grain weight and grain number per panicle of S3 decreased by 15.30% and 14.87% in XY335 compared to CK, that of ZD958 decreased by 11.22% and 15.24% compared to CK, and that of DH661 decreased by 15.10% and 8.55% compared to CK. In addition, dislodging subtending leaf significantly affected grain filling characteristics. The damage increased with increasing number of dislodging subtending leaf. Days of reaching maximum grain filling rate (D_max) decreased significantly, and was the most susceptible to damage from dislodging all subtending leaves (S3). That of XY335, ZD958 and DH661 decreased by 3 d, 4 d, and 3.5 d compared to CK. Weight of reaching maximum grain filling rate (W_max) and active grain filling period (P) decreased significantly after the subtending leaves were dislodged, of which the most susceptible to damage was from the S3 treatment. W_max of XY335, DH661, and ZD958 is S3 decreased by 12.75%, 17.78%, and 17.12%, respectively, compared to CK. P of S1, S2, and S3 in DH661 decreased by 6.22%, 9.82%, and 11.78%, respectively, compared to CK. XY335 decreased by 5.39%, 8.39%, and 13.09%. ZD958 decreased by 0.17%, 2.39%, and 5.97%, respectively, compared to CK. Furthermore, dislodging subtending leaf decreased grain volume, grain fresh weight and days of reaching milk lines disappearance and black layer appearance, and increased dehydrating rate. Days of reaching milk lines disappearance of S3 decreased by 10 d, 6 d, and 4 d, respectively, compared to CK in XY335, ZD958, and DH661. Days of black layer appearance decreased by 10 d, 5 d, and 4 d, respectively, compared to CK in XY335, ZD958, and DH661.【Conclusion】Dislodging subtending leaf decreased days of maximum grain filling (D_max), weight of maximum grain filling rate (W_max), maximum grain filling (G_max), resulted in the decline of grain dry matter, affected grain filling characteristics, decreased the time of milk lines disappearance and black layer appearance, leading to the decrease of grain yield of summer maize. The effects decreased with the increase of the number of removed subtending leaves.

Key words: summer maize, subtending leaf, grain yield, grain filling

QIN Ying-ying, DONG Shu-ting, WEI Shan-shan, ZHANG Ji-wang, LIU Peng, ZHAO Bin. Effects of Dislodging Subtending Leaf on Grain Filling and Yield of Summer Maize[J].Scientia Agricultura Sinica, 2015, 48(11): 2118-2126.

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References

[1] 高荣岐, 董树亭, 胡昌浩, 王群瑛. 高产夏玉米籽粒形态建成和营养物质积累与粒重的关系. 玉米科学, 1992: 52-58, 68.

Gao R Q, Dong S T, Hu C H, Wang Q Y. The relationship between grain formation, nutrients accumulation and grain weight of summer maize. Journal of Maize Sciences, 1992: 52-58, 68. (in Chinese)

[2] 孟庆平, 张玉权, 常淑娟, 李桂杰, 李静, 李柏春, 刘凤才. 玉米最佳收获期的主要相关性状研究初探. 玉米科学, 2007, 15(增1): 117-122.

Meng Q P, Zhang Y Q, Chang S J, Li G J, Li J, Li B C, Liu F C. Research on main related properties of maize at best harvest time. Journal of Maize Sciences, 2007, 15(S1): 117-122. (in Chinese)

[3] 孙月轩, 蒋先梅, 张柞木, 单玉清, 鲍继友, 孙顶太. 夏玉米灌浆与温度、籽粒含水率关系的初步探讨. 玉米科学, 1994, 2(1): 54-58.

Sun Y X, Jiang X M, Zhang Z M, Shan Y Q, Bao J Y, Sun D T. Relation between grain filling and temperature, grain moisture content of summer maize. Journal of Maize Sciences, 1994, 2(1): 54-58. (in Chinese)

[4] Stessman D, Miller A, Spalding M. Regulation of photosynthesis during arabidopsis leaf development in continuous light. Photosynthesis Research, 2002, 72: 27-37.

[5] 霍仕平. 玉米灌浆期籽粒脱水速率的研究进展(综述). 玉米科学, 1993, 1(4): 39-44.

Huo S P. The research on kernel dehydration rate of maize during grain filling. Journal of Maize Sciences, 1993, 1(4): 39-44. (in Chinese)

[6] 霍仕平, 许明陆, 晏庆九, 代兴见, 霍仕安. 玉米果穗苞叶特性的配合力研究. 杂粮作物, 1996(2): 1-4.

Huo S P, Xu M L, Yan Q J, Dai X J, Huo S A. Combining ability research on characteristic of maize ear bract. Rain Fed Crops, 1996(2): 1-4. (in Chinese)

[7] 霍仕平, 晏庆九, 许明陆, 张健. 玉米果穗苞叶性状的遗传分析. 杂粮作物, 2000(20): 8-12.

Huo S P, Yan Q J, Xu M L, Zhang J. Genetic analysis of ear bract characters in maize. Rain Fed Crops, 2000(20), 20: 8-12. (in Chinese)

[8] 徐洪文, 宋凤斌, 童淑媛, 朱先灿. 两种基因型玉米苞叶的衰老生理特性. 植物资源与环境学报, 2008, 17: 28-32.

Xu H W, Song F B, Dong S Y, Zhu X C. Senescence phsiological characteristics of husk of two maize genotypes. Journal of Plant Resources and Environment, 2008, 17: 28-32. (in Chinese)

[9] Jain T C. Contribution of stem, laminae and ear to the dry matter production of maize (Zea mays L.) after ear emergence. Indian Journal of Agriculture Science, 1971, 41: 579 -583.

[10] Salvador R J, Pearce R B. Husk removal and its effects on maize grain yield. Crop Science, 1988, 28(6): 961-964.

[11] 霍仕平, 晏庆九. 玉米生理成熟后籽粒快速脱水的意义及其研究进展. 四川农业大学学报, 1993, 11(4): 626-629.

Huo S P, Yan Q J. Significance and research advance of grain moisture quick-loss after physiological maturity in maize. Journal of Sichuan Agricultural University, 1993, 11(4): 626-629. (in Chinese)

[12] 李绍长, 盛茜, 陆嘉惠, 孟宝民. 玉米籽粒灌浆生长分析. 石河子大学学报: 自然科学版, 1999(3): 1-5.

Li S C, Sheng Q, Lu J H, Meng B M. Growth analysis on the process of grain filling in maize. Journal of Shihezi University: Natural Science, 1999(3): 1-5. (in Chinese)

[13] Borrás L, Zinselmeier C, Westgate L M, Muszynski M E, Michael G. Characterization of grain-filling patterns in diverse maize germplasm. Crop Science, 2009, 49(3): 999-1009.

[14] Sadras V O, Egli D B. Seed size variation in grain crops: allometric relationships between rate and duration of seed growth. Crop Science, 2008, 48 (2): 408-416.

[15] 张战辉. 玉米籽粒灌浆速率及其相关性状的QTL分析[D]. 郑州: 河南农业大学, 2011.

Zhang Z H. QTL analysis of grain filling rate and associated traits in maize [D]. Zhengzhou: Henan Agricultural University, 2011. (in Chinese)

[16] 张冬梅, 刘洋, 赵永锋, 祝丽英, 黄亚群, 郭晋杰, 陈景堂. 不同杂种优势群体玉米籽粒灌浆速率的分析. 中国农业科学, 2014, 47(17): 3323-3335.

Zhang D M, Liu Y, Zhao Y F, Zhu L Y, Huang Y Q, Guo J J, Chen J T. Analysis of maize grain filling rate in different heterotic groups. Scientia Agricultura Sinica, 2014, 47(17): 3323-3335. (in Chinese)

[17] 胡昌浩. 玉米栽培生理. 北京: 中国农业出版社, 1995: 33-36.

Hu C H. Corn Cultivation Physiology. Beijing: China Agriculture Press, 1995: 33-36. (in Chinese)

[18] Afuakwa J J, Crookston R K. Using the kernel milk line to visually monitor grain maturity in maize. Crop Science, 1984, 24(4): 687- 691.

[19] Daynard T B. Relationships among black layer formation, grain moisture percentage, and heat unit accumulation in corn. Agronomy Journal, 1972, 64: 716-719.

[20] Rench W E, Shaw R H. Black layer development in corn. Agronomy Journal, 1971, 63: 303-309.

[21] Carter M W, Poneleit C G. Black layer maturity and filling period variation among inbred lines of corn. Crop Science, 1973, 13: 436-439.

[22] Hunter J L, Tekrony D M, Miles D F, Egli D B. Corn seed maturity indicators and their relationship to uptake of Carbon-14 assimilate. Crop Science, 1991, 31: 1309-1313.

[23] Tollenaar M, Daynard T B. Kernel growth and development at two positions on the ear of maize (Zea mays L.). Canadian Journal of Plant Science, 1978, 58: 189-197.

[24] 何丹, 王秀全, 刘昌明, 余先驹, 陈光明, 张超英, 何勇. 玉米苞叶几个农艺性状的相关关系及其遗传研究. 玉米科学, 2001, 9(1): 43-45.

He D, Wang X Q, Liu C M, Yu X J, Chen G M, Zhang C Y, He Y. Studies on relationships among husk agronomical traits and their inheritances in maize. Journal of Maize Sciences, 2001, 9(1): 43-45. (in Chinese)

[25] Cantrell R G. Contribution of husk leaves to maize grain yield. Crop Science, 1981, 21: 544-546.

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