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中国高粱[(L.)Moench]基因型-生态型-种植间距配置的相互作用

Interaction of genotype-ecological type-plant spacing configuration in sorghum [ (L.) Moench] in China.

作者信息

Yan Peng, Song Ying-Hui, Zhang Kuang-Ye, Zhang Feng, Tang Yu-Jie, Zhao Xiang-Na, Wang Nai, Ke Fu-Lai, Gao Feng-Ju, Li Ji-Hong, Li Jun-Xia, Gao Yue, Yang Wei, Gao Fang-Chao, Qi Dan-Dan, Wang Zhi, You Guang-Xia, Han Fen-Xia, Zhou Zi-Yang, Li Gui-Ying

机构信息

Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing, China.

Cereal Crop Institute, Henan Academy of Agricultural Sciences, Zhengzhou, Henan, China.

出版信息

Front Plant Sci. 2023 Jan 12;13:1076854. doi: 10.3389/fpls.2022.1076854. eCollection 2022.

DOI:10.3389/fpls.2022.1076854
PMID:36714717
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9879661/
Abstract

Grain sorghum has been a significant contributor to global food security since the prehistoric period and may contribute even more to the security of both food and energy in the future. Globally, precise management techniques are crucial for increasing grain sorghum productivity. In China, with diverse ecological types, variety introduction occasionally occurs across ecological zones. However, few information is available on the effect of ecological type on genotype performance and how plant spacing configuration influences grain yield in various ecological zones. Hence, a series of two-year field experiments were conducted in 2020 and 2021 in four ecological zones of China, from the northeast to the southwest. The experiments included six widely adapted sorghum varieties under six plant spacing configurations (two row spacing modes: equidistant row spacing (60 cm) mode and wide (80 cm)-narrow (40 cm) row spacing mode; three in-row plant spacings: 10 cm, 15 cm, and 20 cm). Our results indicated that ecological type, variety, and plant spacing configuration had a significant effect on sorghum yield. Ecological type contributed the highest proportion to the yield variance (49.8%), followed by variety (8.3%), while plant spacing configuration contributed 1.8%. Sorghum growth duration was highly influenced by the ecological type, accounting for 87.2% of its total variance, whereas plant height was mainly affected by genotype, which contributed 81.6% of the total variance. All test varieties, developed in the south or north, can reach maturity within 94-108 d, just before fall sowing in central China. Generally, sorghum growth duration becomes longer when a variety is introduced from south to north. A late-maturing variety, developed in the spring sowing and late-maturing regions, possibly could not reach maturity in the early-maturing region. The row spacing modes had no significant affect on sorghum yield, but the equal-row spacing mode consistently caused higher yields with only one exception; this might imply that equal-row spacing mode was more advantageous for boosting sorghum yield potential. In contrast, decreasing in-row plant spacing showed significant positive linear associations with sorghum grain yield in most cases. In addition, these results demonstrated that sorghum is a widely adapted crop and enables success in variety introduction across ecological zones.

摘要

自史前时期以来,粒用高粱一直是全球粮食安全的重要贡献者,未来可能对粮食和能源安全做出更大贡献。在全球范围内,精准管理技术对于提高粒用高粱的生产力至关重要。在中国,生态类型多样,品种引种偶尔会跨越生态区进行。然而,关于生态类型对基因型表现的影响以及种植间距配置如何影响不同生态区的籽粒产量,可用信息很少。因此,2020年和2021年在中国从东北到西南的四个生态区进行了一系列为期两年的田间试验。试验包括六个广泛适应的高粱品种,采用六种种植间距配置(两种行距模式:等行距(60厘米)模式和宽行(80厘米)-窄行(40厘米)行距模式;三种株距:10厘米、15厘米和20厘米)。我们的结果表明,生态类型、品种和种植间距配置对高粱产量有显著影响。生态类型对产量变异的贡献率最高(49.8%),其次是品种(8.3%),而种植间距配置的贡献率为1.8%。高粱生育期受生态类型的影响很大,占其总变异的87.2%,而株高主要受基因型影响,基因型对总变异的贡献率为81.6%。所有测试品种,无论在南方还是北方育成,都能在94-108天内成熟,恰好在中国中部秋季播种之前。一般来说,当一个品种从南向北引种时,高粱生育期会变长。一个在春播晚熟地区育成的晚熟品种,在早熟地区可能无法成熟。行距模式对高粱产量没有显著影响,但等行距模式除了一个例外情况外,始终能带来更高的产量;这可能意味着等行距模式在提高高粱产量潜力方面更具优势。相比之下,在大多数情况下,减小株距与高粱籽粒产量呈显著正线性相关。此外,这些结果表明高粱是一种广泛适应的作物,能够成功地在不同生态区引种。

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