Scientia Agricultura Sinica ›› 2020, Vol. 53 ›› Issue (20): 4152-4163.doi: 10.3864/j.issn.0578-1752.2020.20.005

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY·AGRICULTURE INFORMATION TECHNOLOGY • Previous Articles     Next Articles

The Regulation and Evaluation Indexes Screening of Chemical Topping on Cotton’s Plant Architecture

ZHU LingXiao1(),LIU LianTao1(),ZHANG YongJiang1,SUN HongChun1,ZHANG Ke1,BAI ZhiYing1,DONG HeZhong2,LI CunDong1()   

  1. 1College of Agronomy, Hebei Agricultural University/State Key Laboratory of North China Crop Improvement and Regulation/Key Laboratory of Crop Growth Regulation of Hebei Province, Baoding 071000, Hebei
    2Cotton Research Center, Shandong Academy of Agricultural Sciences, Jinan 250100
  • Received:2020-01-08 Accepted:2020-07-06 Online:2020-10-16 Published:2020-10-26
  • Contact: LianTao LIU,CunDong LI E-mail:zlxhbnydx@163.com;liultday@126.com;nxylcd@hebau.edu.cn

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Abstract:

【Objective】Plant architecture is of major agronomic importance because it strongly influences the suit-ability of a plant for cultivation, its overall yield and its economic coefficient. This study was aimed to explore the effects of chemical topping on the traits of cotton’s plant architecture and to make a comprehensive analysis, thus providing a theoretical basis for the application and popularization of chemical topping. 【Method】Three topping treatments, including manual topping, chemical topping and non-decapitation treatment, were established by using Jimian863 and Nongda601, which were widely grown in Yellow River Valley, in Hebei Agriculture University experimental base during 2015-2016, yield components, plant height, stem diameter, number of fruit branches and other plant architecture related indicators were measured, carry out research on the effect of chemical topping on plant architecture. 【Result】There was no significant difference in seed cotton yield between manual topping treatment and chemical topping treatment, and both treatments were significantly higher than that of non-decapitation treatment. Compared with non-decapitation treatment, chemical topping increased the seed cotton yield of Jiman863 and Nongda601 by 7.19% and 6.78%, respectively. Compared with non-decapitation treatment, chemical topping significantly decreased the cotton plant, internode number, fruiting branches number and fruiting node number, and significantly increased the diameter ratio of near and far branches. Chemical topping significantly decreased the internode length of stem and upper fruiting branches length. The effect of chemical topping on cotton’s plant architecture could be evaluated by the plant height and the diameter ratio of near and far branches according to Pearson correlation analysis, principal component analysis and grey correlation analysis. 【Conclusion】Chemical topping treatment had the same purpose on the regulation of cotton’s vegetative and regenerative growth as manual topping treatment, and had no significant effect on seed cotton yield. The plant height and the diameter ratio of near and far branches were taken as the main evaluation indexes for the regulation of chemical topping on cotton’s plant architecture.

Key words: cotton, plant architecture, manual topping, chemical topping, yield, principal component analysis, grey correlation analysis

Fig. 1

The maximum temperature, minimum temperature and precipitation during the cotton growing season in 2015 and 2016 at the experimental station"

Table 1

Effect of different topping treatments on cotton yield and yield components in 2015 and 2016"

年份
Year		 品种
Cultivar		 处理
Treatment		 单株铃数
Boll number per plant		 单铃重
Boll weight
(g)		 籽棉产量
Seed cotton yield (kg·hm-2)		 衣分
Lint percent
(%)		 皮棉产量
Lint cotton yield (kg·hm-2)
2015 JM863 MT 17.70±0.48a 6.23±0.33a 4266.81±165.79a 38.68±0.48c 1788.13±78.66a
CT 17.98±1.31a 5.38±10.42ab 4157.54±328.77a 41.41±0.41b 1721.70±144.06a
NT 14.75±0.95b 5.85±0.09b 3791.16±378.22b 43.06±0.27a 1632.47±217.67b
ND601 MT 11.21±0.410a 6.41±0.58a 3480.00±196.82a 40.44±0.55c 1407.35±89.80a
CT 11.13±1.46a 6.24±0.48a 3222.13±233.56ab 43.83±0.24a 1412.25±120.29a
NT 10.62±1.46a 6.26±0.24a 3003.50±262.27b 42.29±0.33b 1270.02±94.68b
2016 JM863 MT 17.67±0.59a 6.27±0.06a 4397.76±95.52a 39.33±0.85b 1730.60±75.22a
CT 17.33±0.31a 5.89±0.10b 4281.28±90.74a 41.37±0.49a 1770.79±31.87a
NT 15.70±0.67b 5.81±0.11b 4041.05±156.19b 42.70±0.45a 1725.24±61.45a
ND601 MT 14.10±0.54a 6.72±0.36a 3390.22±110.57a 39.94±1.21b 1355.33±84.33ab
CT 13.05±0.35a 7.06±0.38a 3363.72±16.79a 42.89±0.79a 1442.877±28.10a
NT 11.62±0.41b 7.15±0.12a 3135.93±56.40ab 41.26±0.58ab 1293.88±24.26b
方差分析
Source of variance		 Year (Y) NS NS NS NS NS
Cultivar (C) ** ** ** NS **
Treatment (T) ** NS * ** *
Y×C NS NS NS NS NS
Y×T NS NS NS NS NS
C×T NS NS NS ** NS
Y×C×T NS NS NS NS NS

Fig. 2

Effect of different topping treatments on plant height in 2015-2016"

Fig. 3

Effect of different topping treatments on stem diameter in 2015-2016"

Table 2

Effect of different topping treatments on internode number and internode length of cotton in 2015-2016"

品种
Cultivar		 处理
Treatment		 2015 2016
节间数 Internode number 节间长度 Internode length (cm) 节间数 Internode number 节间长度 Internode length (cm)
JM863 MT 11.67±0.47c 9.39±0.22a 11.67±0.94b 10.08±0.66a
CT 15.33±0.82b 7.84±0.35b 15.33±0.47a 7.94±0.19b
NT 17.33±0.82a 7.58±0.29b 16.33±0.47a 7.94±0.18b
ND601 MT 12.33±0.82b 9.51±0.55a 11.33±0.94c 10.20±0.71a
CT 14.33±0.47a 8.59±0.16ab 13.67±0.47b 8.91±0.12b
NT 16.33±0.82a 8.24±0.29b 15.33±0.47a 8.37±0.07b

Table 3

Effect of different topping treatments on fruiting branches character in 2015-2016"

品种
Cultivar		 处理
Treatment		 2015 2016
果枝数 Fruiting branches number 果节数
Fruiting node number		 上部果枝长度
Fruiting branches length (cm)		 近远端直径比
Diameter ratio of near and far branches		 果枝数
Fruiting branches number		 果节数
Fruiting node number		 上部果枝长度
Fruiting branches length (cm)		 近远端直径比
Diameter ratio of near and far branches
JM863 MT 14.58±0.64c 84.71±6.12b 20.47±1.22a 1.40±0.01b 14.50±0.65c 81.80±7.89c 15.90±1.47a 1.30±0.04b
CT 16.83±1.28b 95.64±10.12a 14.48±2.33b 1.47±0.06b 16.17±1.62b 84.20±6.55bc 10.06±0.82c 1.38±0.05ab
NT 18.50±1.12a 98.64±7.98a 19.69±1.15a 1.66±0.06a 17.58±1.26a 99.90±7.23a 11.56±0.70b 1.47±0.03a
ND601 MT 14.20±0.45c 79.74±3.56c 23.01±2.74a 1.35±0.03c 14.58±0.64c 87.15±4.55b 19.65±1.31a 1.24±0.02c
CT 17.60±0.89b 84.66±7.87b 13.82±1.84c 1.47±0.03b 16.83±1.28b 88.80±7.89b 9.76±0.58c 1.40±0.06b
NT 21.60±0.55a 91.64±9.99a 17.70±0.89b 1.65±0.02a 18.50±1.12a 91.46±9.11a 12.79±0.83b 1.51±0.05c

Fig. 4

Effect of different topping treatments on the length of the upper fruiting branches in 2015-2016"

Table 4

Pearson correlation matrix of cotton shoot architecture parameters and yield"

指标
Index		 产量
SCY		 株高
PH		 茎粗
SD		 节间数
IN		 节间长度
IL		 果枝数
FBN		 果节数
FNN		 上部果枝长度
FBL		 近远端直径比
DRNB
产量SCY 1
株高PH -0.413 1
茎粗SD 0.618* -0.648* 1
节间数IN -0.483 0.853** -0.332 1
节间长度IL -0.143 0.875** -0.290 -0.850** 1
果枝数FBN 0.001 -0.695* 0.062 -0.739** -0.951** 1
果节数FNN 0.265 -0.883** 0.561 -0.715** -0.754** 0.592* 1
上部果枝长度 FBL 0.022 -0.639* 0.035 0.685* 0.779** -0.738** -0.697* 1
近远端直径比DRNB -0.072 -0.456 0.288 -0.272 -0.431 0.430 0.691* -0.273 1

Table 5

Gray correlation analysis of cotton shoot architecture parameters"

指标 Index 关联度 Correlation degree 排序 Order
节间数 Internode number 0.912 1
茎粗 Stem diameter 0.901 2
近远端直径比 Diameter ratio of near and far branches 0.890 3
株高 Plant height 0.847 4
果节数 Fruiting node number 0.835 5
果枝数 Fruiting branches number 0.825 6
节间长度 Internode length 0.750 7
上部果枝长度 Upper fruiting branches length 0.717 8

Table 6

The characteristic value, variance and accumulative contribution of each component"

成分
Component		 初始特征值 Initial eigenvalue 提取的主成分 The extracted principal component
合计
Total		 方差的贡献率
The contribution rate of variance (%)		 累积贡献率
Cumulative contribution rate (%)		 合计
Total		 方差的贡献率
The contribution rate of variance (%)		 累积贡献率
Cumulative contribution rate (%)
1 5.252 65.662 65.662 5.253 65.662 65.662
2 1.328 16.595 82.257 1.328 16.595 82.257
3 0.809 10.117 92.374
4 0.373 4.663 97.037
5 0.191 2.388 99.425
6 0.032 0.401 99.827
7 0.013 0.164 99.990
8 0.001 0.009 100

Table 7

Score coefficient of principal component factors"

指标 Index 第1主成分 Component 1 第2主成分 Component 2
株高 Plant height 0.180 -0.162
果枝数 Fruiting branches number 0.167 0.093
茎粗 Stem diameter -0.084 0.625
节间数 Internode number 0.181 0.153
节间长度 Internode length -0.161 -0.293
近远端直径比 Diameter ratio of near and far branches -0.173 0.198
果节数 Fruiting node number 0.150 0.346
上部果枝长度 Upper fruiting branches length -0.108 0.242
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