Maize breeding strategies for increased grain yield and nitrogen use efficiency

IF 6.4 1区农林科学 Q1 AGRONOMY

Field Crops Research Pub Date : 2025-07-24 DOI:10.1016/j.fcr.2025.110076

Ezequiel Saenz , Slobodan Trifunovic , Jim Narvel , Tony Vyn , Sotirios V. Archontoulis

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引用次数: 0

Abstract

Context

Breeding and higher plant densities over the last 40 years have increased maize yield and biomass production in the US Corn Belt. However, the effects of planting density versus genetic changes over time on plant and organ nitrogen (N) concentrations and uptake remain poorly understood.

Objectives

This study aimed to (i) quantify changes (genetic gains) in N concentration and uptake across different plant organs at the R2 and R6 stages, (ii) determine whether maize breeding and increasing plant density have altered N dilution patterns, and (iii) examine changes in the yield to crop N uptake relationship to guide future breeding strategies to increase yield and nitrogen utilization efficiency (NUE).

Methods

We conducted seven field experiments over two years across the US Corn Belt, evaluating 18 maize hybrids released between 1983 and 2017. The hybrids were grown under varying plant densities to reflect historical and current management practices. Organ dry matter and N concentrations were measured at R2 and R6 growth stages. The N utilization efficiency (NUE) was calculated as yield divided with crop N uptake at R6 stage.

Results

Breeding and plant density have increased crop N uptake by 45 kg N ha⁻¹ over the past four decades. Breeding accounted for 54 % of this increase and plant density for the remaining 46 %. Breeding primarily increased ear N uptake while plant density improved leaf N uptake. The increase in reproductive organ N uptake was higher than that of vegetative organs, resulting in a higher nitrogen harvest index (NHI) in newer hybrids. Whole-plant and organ level N concentrations declined over time, which was driven by dry matter increases rather than changes in the rate of N dilution. Modern hybrids exhibit greater efficiency in converting N into yield, resulting in a 25 % increase in NUE over the last 40 years. This resulted from increasing crop N uptake by 17 %, NHI by 5 %, and decreasing grain N concentration by 15 % over the last decades. Present grain N concentration and NUE estimates are below crop physiological limits, suggesting that there remains genetic potential to further increase both yield and NUE through targeted breeding.

Implications

These findings offer valuable insights for understanding historical changes in maize N uptake and N allocation to organs, which could help design future breeding targets to further increase yield and NUE.

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提高籽粒产量和氮利用效率的玉米育种策略

在过去的40年里，育种和更高的植物密度增加了美国玉米带的玉米产量和生物量生产。然而，随着时间的推移，种植密度与遗传变化对植物和器官氮(N)浓度和吸收的影响仍然知之甚少。本研究旨在(i)量化R2和R6期不同植物器官氮浓度和吸收的变化（遗传增益），（ii）确定玉米育种和增加植株密度是否改变了氮稀释模式，以及（iii）研究产量与作物氮吸收关系的变化，以指导未来的育种策略，以提高产量和氮利用效率（NUE）。方法在两年多的时间里，我们在美国玉米带进行了7次田间试验，评估了1983年至2017年发布的18种玉米杂交种。杂交种在不同的植物密度下生长，以反映历史和当前的管理实践。R2和R6生育期测定器官干物质和氮浓度。氮素利用效率（NUE）计算为产量与作物氮素吸收量之比。结果在过去的40年里，育种和种植密度使作物氮吸收量增加了45 kg N ha¹ 。育种占这一增长的54. %，植物密度占剩余的46% %。育种主要提高穗部吸氮量，密度提高叶片吸氮量。生殖器官氮吸收量的增加高于营养器官氮吸收量的增加，导致新杂交种氮素收获指数（NHI）较高。随着时间的推移，全株和器官水平的氮浓度下降，这是由干物质的增加而不是氮稀释率的变化驱动的。现代杂交种在将氮转化为产量方面表现出更高的效率，在过去的40年里，氮肥利用效率提高了25% %。这是由于在过去几十年中，作物氮素吸收量增加了17. %，NHI增加了5. %，而籽粒氮素浓度减少了15. %。目前的籽粒氮浓度和氮肥利用效率估计值低于作物生理极限，这表明通过有针对性的育种仍有进一步提高产量和氮肥利用效率的遗传潜力。这些发现为了解玉米氮素吸收和氮素分配的历史变化提供了有价值的见解，可以帮助设计未来的育种目标，进一步提高产量和氮肥利用效率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

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.