Exogenous melatonin improves peanut field productivity and quality at reduced nitrogen application

IF 5.6 1区 农林科学 Q1 AGRONOMY
Lijie Li , Xiangguo Cheng , Yi Zhang , Dana Kohtz , Xiaohui Wang , Xiaotian Zhang , Xiangjun Kong , Huiyun Xue , Peipei Jia , Na Bai , Zengqiang Li , Peng Xiao , Xiaoping Pan , Zhiyong Zhang , Baohong Zhang
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引用次数: 0

Abstract

Context

Nitrogen (N) plays integral roles in plant growth and yield. Finding ways to increase plant yield with reduced N usage will promote both agricultural and environmental sustainability. Melatonin acts as a multifunctional regulatory molecule in numerous metabolic processes crucial for plant growth and development as well as response to environmental stresses. The effects of melatonin on the material accumulation and transport, source-sink dynamics, as well as its association with yield and quality formation of peanut (Arachis hypogaea L.) remain unclear, especially at different N levels.

Objectives

We aim to investigate the response mechanism of melatonin in peanut plants subjected to reduced N application, in order to confirm the hypothesis that melatonin regulates carbon and N accumulation and transport, and coordinates source-sink relationships to increase production and improve quality.

Methods

This study examined the effects of two seed dressing treatments (with or without 0.5 μM MT) and three N fertilizer levels (90, 135, and 180 kg/ha) using a randomized complete block design with split plots and three biological replications over 2021 and 2022. The evaluation focused on photosynthetic physiology, enzyme activities related to carbon and N metabolism, accumulation and transport of dry matter and N, yield, and quality, while exploring the relationships among these variables.

Results

Melatonin-treated plants had more stable carbon and N metabolism than the untreated ones. This stability was linked to improved photosynthesis, sucrose production, and N assimilation, especially at the reduced N levels (90 and 135 kg/ha). Across three N levels and two years of field tests, MT increased peanut dry matter by 23.49 % from 455.63 g/m2 to 562.66 g/m2, enhanced the accumulation and mobilization of dry matter and N to grains by increasing peanut grain mass by 22.41–29.07 % at different N levels. This process appears to subsequently elevate the effective pod rate, leading to an average increase in pod yield, fat and protein content by 12.63 %, 7.95 %, and 10.33 %, respectively, over a two-year period and across three N application levels.

Conclusions

Plants subjected to melatonin treatment exhibited a coordinated source-sink relationship, which is manifested in high photosynthetic capacity and a high proportion of assimilates transported to pods, thus promoting effective proportions and pod fullness to improve peanut yield and quality under reduced N application.

Significance

Our research provided insights into the response mechanism of melatonin on peanut carbon and N metabolism across various N treatments, contributing to a deeper understanding of how melatonin enhances crop yield and quality.
外源褪黑激素在减少氮肥施用量的情况下提高花生田的产量和质量
背景氮(N)对植物的生长和产量起着不可或缺的作用。找到在减少氮用量的同时提高植物产量的方法将促进农业和环境的可持续发展。褪黑激素是一种多功能调控分子,在植物生长和发育以及应对环境胁迫的众多代谢过程中起着至关重要的作用。褪黑激素对花生(Arachis hypogaea L.)的物质积累和运输、源-汇动态的影响及其与产量和品质形成的关系仍不清楚,特别是在不同的氮水平下。目的我们旨在研究褪黑激素在氮施用量减少的花生植株中的响应机制,以证实褪黑激素调节碳和氮的积累和运输以及协调源-汇关系以提高产量和改善品质的假设。方法本研究采用随机完全区组设计,在 2021 年和 2022 年采用分小区和三次生物重复,考察了两种拌种处理(含或不含 0.5 μM MT)和三种氮肥水平(90、135 和 180 千克/公顷)的影响。评价的重点是光合生理、与碳和氮代谢有关的酶活性、干物质和氮的积累和运输、产量和质量,同时探讨这些变量之间的关系。这种稳定性与光合作用、蔗糖产量和氮同化的改善有关,尤其是在氮含量较低的情况下(90 和 135 千克/公顷)。在三个氮水平和两年的田间试验中,MT 使花生干物质增加了 23.49%,从 455.63 克/平方米增加到 562.66 克/平方米,增强了干物质和氮对籽粒的积累和动员,在不同氮水平下,花生籽粒质量增加了 22.41-29.07 %。这一过程似乎随之提高了有效结荚率,在两年时间里,三种氮施用水平下的荚果产量、脂肪和蛋白质含量分别平均提高了 12.63 %、7.95 % 和 10.33 %。意义我们的研究深入探讨了褪黑激素在不同氮处理下对花生碳和氮代谢的响应机制,有助于加深对褪黑激素如何提高作物产量和品质的理解。
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来源期刊
Field Crops Research
Field Crops Research 农林科学-农艺学
CiteScore
9.60
自引率
12.10%
发文量
307
审稿时长
46 days
期刊介绍: Field Crops Research is an international journal publishing scientific articles on: √ experimental and modelling research at field, farm and landscape levels on temperate and tropical crops and cropping systems, with a focus on crop ecology and physiology, agronomy, and plant genetics and breeding.
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