Response of nitrogen redistribution to irrigation at jointing in winter wheat

Wu, Baojian; Shang, Yunqiu; Wang, Sen; Hu, Xinhui; Zhang, Rui; Zhang, Baojun; Wang, Dong

doi:10.1002/agj2.20458

Cited by 5 publications

(8 citation statements)

References 50 publications

(60 reference statements)

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“…Moreover, there is a negative association between GPC and total irrigation amount ( Moradi et al., 2022 ). Wu et al. (2020) also found that the concentration of grain protein was significantly increased by a water deficit during the grain-filling stage.…”

Section: Discussionmentioning

confidence: 75%

“…In this regard, the findings of some studies (Beral et al, 2020;Sanchez-Bragado et al, 2020) have indicated that the TGW is negatively correlated with grain number. Wu et al (2020) also found that irrigation at the jointing stage increased spike number, kernels per spike, and grain yield, but reduced grain weight. Consistently, we detected a significant negative relationship between TGW and the NGB (r = -0.58, p< 0.05) in the present study.…”

Section: Effects Of Drought Stress On the Yield And The Mechanisms Wh...mentioning

confidence: 80%

“…Moreover, there is a negative association between GPC and total irrigation amount (Moradi et al, 2022). Wu et al (2020) also found that the concentration of grain protein was significantly increased by a water deficit during the grain-filling stage. However, the effects of drought at the grain-filling stage were found to differ according to stress intensity, with a slight water deficit significantly reducing GPC, whereas severe water deficit has been found to increase the concentration of grain proteins during the grain-filling stage (Meng et al, 2016).…”

Section: Effects Of Drought Stress On the Enduse Functional Propertie...mentioning

confidence: 82%

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The end-use quality of wheat can be enhanced by optimal water management without incurring yield loss

Sheng

Wang

et al. 2022

Front. Plant Sci.

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In China, water-saving irrigation is playing important roles in ensuring food security, and improving wheat quality. A barrel experiment was conducted with three winter wheat (Triticum aestivum L.) genotypes and two irrigation pattens to examine the effects of regulated deficit irrigation (RDI) on wheat grain yield, water-use efficiency (WUE), and grain quality. In order to accurately control the soil water content, wheat was planted in the iron barrels set under a rainproof shelter, and the soil water content in the iron barrel was controlled by gravity method. The mechanisms whereby water management influences the end-use functional properties of wheat grain were also investigated. The results revealed that RDI improved the end-use functional properties of wheat and WUE, without significant yield loss (less than 3%). Moderate water deficit (60% to 65% field capacity) before jointing and during the late grain-filling stage combined with a slight water deficit (65% to 70% field capacity) from jointing to booting increased grain quality and WUE. The observed non-significant reduction in wheat yield associated with RDI may be attributed to higher rate of photosynthesis during the early stage of grain development and higher rate of transfer of carbohydrates from vegetative organs to grains during the later stage. By triggering an earlier rapid transfer of nitrogen deposited in vegetative organs, RDI enhances grain nitrogen content, which in turn could enhance dough elasticity, given the positive correlation between grain nitrogen content and dough midline peak value. Our results also indicate that the effects of RDI on grain quality are genotype dependent. Therefore, the grain end-use quality of some specific wheat genotypes may be enhanced without incurring yield loss by an optimal water management.

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Section: Discussionmentioning

confidence: 75%

Section: Effects Of Drought Stress On the Yield And The Mechanisms Wh...mentioning

confidence: 80%

Section: Effects Of Drought Stress On the Enduse Functional Propertie...mentioning

confidence: 82%

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The end-use quality of wheat can be enhanced by optimal water management without incurring yield loss

Sheng

Wang

et al. 2022

Front. Plant Sci.

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“…We found that, compared with irrigation of other border lengths, L40 treatment promoted significantly higher grain nitrogen accumulation by increasing the grain nitrogen accumulation rates (Vmax and Vmean; Figure 7, Table 3). The low rate of nitrogen accumulation in grains under L20 and L30 treatments may be due to low nitrogen transport in vegetative organs, and to water stress, resulting in premature leaf senescence and reduced nitrogen accumulation in plants after anthesis [12]. Compared with that under L40 treatment, the decrease in the grain nitrogen accumulation under L50 treatment was mainly due to excessive irrigation, which caused the plants to retain nitrogen in stems and leaves and mature late; high temperatures in the later growth stage led to their rapid maturity, and the nitrogen accumulation in the stems and leaves was not transferred to the grains [39].…”

Section: Discussionmentioning

confidence: 99%

“…However, water stress significantly reduces the absorption of nitrogen by plants, and insufficient nitrogen reduces the chlorophyll content in leaves and the accumulation of photosynthetic products [11]. In another study, the plant nitrogen accumulation at anthesis, net photosynthetic rate in flag leaves after anthesis, and grain yield under supplemental irrigation at jointing and anthesis were 45.8%, 24%, and 8.86% higher, respectively, than those under supplemental irrigation at anthesis only [12]. Many studies of the effect of soil moisture and irrigation period on plant nitrogen accumulation have been conducted; however, information on the characteristics of grain nitrogen accumulation and the activity of nitrogen metabolic enzymes in flag leaves, especially under irrigation with different border lengths, is limited.…”

Section: Introductionmentioning

confidence: 96%

Optimized Border Irrigation Improved Nitrogen Accumulation, Translocation of Winter Wheat and Reduce Soil Nitrate Nitrogen Residue

Yan

Zhang

2022

Agronomy

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We aimed to optimize field border length in the Huang-Huai-Hai Plain of China (HPC) to reduce soil inorganic nitrogen residues and increase nitrogen absorption and utilization by wheat plants using a traditional border irrigation system. In a two-year experiment (2017–2019) conducted in the HPC, four border lengths were tested: 20 m (L20), 30 m (L30), 40 m (L40), and 50 m (L50). Supplementary irrigation was implemented during jointing and anthesis stages, and control fields received treatment without irrigation. The results showed that, compared with irrigation of other border lengths, L40 irrigation significantly increased nitrogen transport in stems and leaves. In addition, L40 irrigation had the highest rate of grain nitrogen accumulation after anthesis. The risk of nitrate leaching to deep layers increased with increasing border length; however, L40 irrigation improved the plants’ capacity to absorb soil nitrogen, and the soil inorganic nitrogen residue was significantly lower than that with irrigation of other border lengths. Therefore, the grain yield and nitrogen fertilizer utilization under L40 irrigation were significantly higher than those under irrigation of other border lengths, and L40 was considered as the best border irrigation length.

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Changes in Nitrogen-Related Performance Attributes of Winter Wheat Varieties Released Between 1950 and 2020 in Dryland Region of China

Lijuan,

Ali,

Xiaohu

et al. 2023

J Soil Sci Plant Nutr

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Response of nitrogen redistribution to irrigation at jointing in winter wheat

Cited by 5 publications

References 50 publications

The end-use quality of wheat can be enhanced by optimal water management without incurring yield loss

The end-use quality of wheat can be enhanced by optimal water management without incurring yield loss

Optimized Border Irrigation Improved Nitrogen Accumulation, Translocation of Winter Wheat and Reduce Soil Nitrate Nitrogen Residue

Changes in Nitrogen-Related Performance Attributes of Winter Wheat Varieties Released Between 1950 and 2020 in Dryland Region of China

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