Effect of nitrogen application rates on root growth and organic acid secretion in two rice varieties with different eating quality

doi:10.11686/cyxb2024142

Abstract

Abstract:

The application of nitrogen fertilizer affects the growth， yield， and quality of rice （Oryza sativa）. The aim of this study was to determine the effects of different nitrogen application rates on root growth and organic acid secretion in two rice varieties with different eating quality. A pot experiment was conducted with the rice varieties ‘Zhengdao C42’ （high flavor quality） and ‘Xudao 3’ （medium flavor quality）. The experiment was established with a control and three nitrogen fertilization treatments： 0 （N₀）， 120 （N₁₂₀）， 240 （N₂₄₀）， and 360 （N₂₄₀） kg N·ha^-1. The rice plants were analyzed to determine root length， root surface area， root oxidation activity， root exudation， the contents of zeatin and zeatin riboside （Z+ZR）， and abscisic acid （ABA）， and total organic acids in root exudates. The results showed that the root surface area， root oxidation activity， Z+ZR contents， and total organic acids in root exudates showed trends of initially increasing and then decreasing as the rate of nitrogen fertilizer application was increased. In both rice varieties， the maximum values of all measured indexes were in the N₂₄₀ treatment. The root surface area， root oxidation activity， Z+ZR content， and total organic acids in root exudates were increased by 148.0%， 48.5%， 16.0%， and 86.5%， respectively， in Xudao 3 in the N₂₄₀treatment at the heading stage； and by 103.7%， 72.5%， 17.8%， and 98.0%， respectively， in Zhengdao C42 in the N₂₄₀ treatment at the heading stage， compared with their respective controls at the same stage. The ABA content first decreased and then increased as the nitrogen application rate increased， and was lowest in the N₂₄₀ treatment. Comparisons of the two varieties showed that the root oxidation activity， root exudation， Z+ZR content， and total organic acids in root exudates were 40.7%， 74.7%， 9.7%， and 34.1% higher， respectively， in Zhengdao C42 than in Xudao 3. The root length and root surface area were lower in Zhengdao C42 than in Xudao 3. The root surface area， root oxidation activity， root exudation， Z+ZR content， and total organic acid content in exudates showed significant or extremely significant negative correlations with amylose content， and significant or extremely significant positive correlations with gel consistency. The ABA content in root exudates showed an extremely significant positive correlation with amylose content， but a negative correlation with gel consistency. For both rice cultivars， root growth and organic acid secretion showed the best results in N₂₄₀ treatment. These results provide guidance for nitrogen management during the cultivation of high-quality eating rice.

Key words: rice, eating quality, nitrogen application amount, root growth, root secretion

Hao-jing LI, Dan-ke ZHANG, Hai-run LI, Jing CAO, Guo-wei XU. Effect of nitrogen application rates on root growth and organic acid secretion in two rice varieties with different eating quality[J]. Acta Prataculturae Sinica, 2025, 34(2): 163-173.

Figures/Tables 8

References 38

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品种Cultivar	处理Treatment	分蘖盛期Mid-tillering	幼穗分化始期Panicle initiation	抽穗期Heading	成熟期Maturity
徐稻3号 Xudao 3	N₀	105.77e	142.55c	205.13d	230.36d
	N₁₂₀	201.81bc	282.83b	352.53b	244.71cd
	N₂₄₀	253.49a	340.70a	465.08a	276.83b
	N₃₆₀	211.09bc	335.27a	357.15b	235.32d
	平均值Mean	193.04	275.34	344.98	246.81
郑稻C42 Zhengdao C42	N₀	136.47d	192.77c	213.57d	207.02e
	N₁₂₀	159.49d	311.42ab	238.29c	264.58bc
	N₂₄₀	223.46b	333.26a	347.41b	305.37a
	N₃₆₀	195.79c	330.70a	353.24b	322.97a
	平均值Mean	178.81	292.04	288.13	274.99
方差分析Variance analysis （ANOVA）
品种Cultivar （C）		6.16**	2.36*	179.04**	35.79**
施氮量Nitrogen （N）		73.88**	103.31**	396.65**	27.81**
品种×施氮量C×N		7.75**	1.86*	64.90**	18.27**

品种Cultivar	处理Treatment	分蘖盛期Mid-tillering	幼穗分化始期Panicle initiation	抽穗期Heading	成熟期Maturity
徐稻3号 Xudao 3	N₀	105.77e	142.55c	205.13d	230.36d
	N₁₂₀	201.81bc	282.83b	352.53b	244.71cd
	N₂₄₀	253.49a	340.70a	465.08a	276.83b
	N₃₆₀	211.09bc	335.27a	357.15b	235.32d
	平均值Mean	193.04	275.34	344.98	246.81
郑稻C42 Zhengdao C42	N₀	136.47d	192.77c	213.57d	207.02e
	N₁₂₀	159.49d	311.42ab	238.29c	264.58bc
	N₂₄₀	223.46b	333.26a	347.41b	305.37a
	N₃₆₀	195.79c	330.70a	353.24b	322.97a
	平均值Mean	178.81	292.04	288.13	274.99
方差分析Variance analysis （ANOVA）
品种Cultivar （C）		6.16**	2.36*	179.04**	35.79**
施氮量Nitrogen （N）		73.88**	103.31**	396.65**	27.81**
品种×施氮量C×N		7.75**	1.86*	64.90**	18.27**

品种Cultivar	处理Treatment	分蘖盛期Mid-tillering	幼穗分化始期Panicle initiation	抽穗期Heading	成熟期Maturity
徐稻3号 Xudao 3	N₀	0.15f	0.27d	0.25e	0.24d
	N₁₂₀	0.20d	0.46c	0.42c	0.31c
	N₂₄₀	0.30a	0.58ab	0.62a	0.45a
	N₃₆₀	0.26b	0.55b	0.55b	0.38b
	平均值Mean	0.23	0.47	0.46	0.35
郑稻C42 Zhengdao C42	N₀	0.17ef	0.22e	0.27e	0.22d
	N₁₂₀	0.19de	0.42c	0.34d	0.36b
	N₂₄₀	0.27b	0.63a	0.55b	0.38b
	N₃₆₀	0.23c	0.54b	0.47c	0.37b
	平均值Mean	0.22	0.45	0.41	0.33
方差分析Variance analysis （ANOVA）
品种Cultivar （C）		6.57**	1.40	15.13**	11.77**
施氮量Nitrogen （N）		100.81**	174.18**	116.61**	253.65**
品种×施氮量C×N		4.57*	3.20*	3.03	26.35**

品种Cultivar	处理Treatment	分蘖盛期Mid-tillering	幼穗分化始期Panicle initiation	抽穗期Heading	成熟期Maturity
徐稻3号 Xudao 3	N₀	0.15f	0.27d	0.25e	0.24d
	N₁₂₀	0.20d	0.46c	0.42c	0.31c
	N₂₄₀	0.30a	0.58ab	0.62a	0.45a
	N₃₆₀	0.26b	0.55b	0.55b	0.38b
	平均值Mean	0.23	0.47	0.46	0.35
郑稻C42 Zhengdao C42	N₀	0.17ef	0.22e	0.27e	0.22d
	N₁₂₀	0.19de	0.42c	0.34d	0.36b
	N₂₄₀	0.27b	0.63a	0.55b	0.38b
	N₃₆₀	0.23c	0.54b	0.47c	0.37b
	平均值Mean	0.22	0.45	0.41	0.33
方差分析Variance analysis （ANOVA）
品种Cultivar （C）		6.57**	1.40	15.13**	11.77**
施氮量Nitrogen （N）		100.81**	174.18**	116.61**	253.65**
品种×施氮量C×N		4.57*	3.20*	3.03	26.35**

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