Enhancing zinc and iron bioavailability through crop rotation and organic farming: Insights from a long-term study

IF 5.6 1区 农林科学 Q1 AGRONOMY
Jing Hou, Xiaopeng Gao, Martin H. Entz
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Abstract

Agronomic biofortification of Zinc (Zn) and iron (Fe) in cereal grains is a critical strategy to address human deficiencies in these micronutrients. Our study examined the effects of crop rotation and farming system on Zn and Fe bioavailability in wheat grains, using data from 2011 to 2020 from the Glenlea Long-term Crop Rotation Study, Canada’s longest running study on organic farming. Two crop rotations, continuous annual (spring wheat, flax, oat, soybean) and annual-perennial (spring wheat, flax, alfalfa, alfalfa), managed both organically and conventionally, were fully phased. Compared to conventional farming, organic farming significantly increased grain Zn concentration in six out of ten years, with no significant effect on grain Fe. Additionally, grain Zn was also significantly higher in the annual-perennial rotation compared to the annual rotation in seven of the ten years. A significant interactive effect was observed for grain phytate, which was approximately 35 % lower in the annual-perennial rotation under organic farming than in other treatments. Consequently, the diversified rotation under organic farming significantly reduced the phytate/Zn and phytate/Fe molar ratios, indicating enhanced micronutrient bioavailability for human consumption. However, these effects were strongly associated with reduced phosphorus (P) availability in organic systems, particularly following alfalfa, which limited grain yields. Livestock manure-based compost application improved grain yield and nutrient uptake, but reduced Zn/Fe bioavailability due to increased phytate accumulation. This study demonstrates that diversified crop rotation and organic farming could improve micronutrient bioavailability, but at a cost of lower grain production tied to reduced P availability.
对谷物中的锌(Zn)和铁(Fe)进行农艺生物强化是解决人类缺乏这些微量营养素的关键策略。我们的研究利用格伦利亚长期轮作研究(Glenlea Long-term Crop Rotation Study)2011 年至 2020 年的数据,考察了轮作和耕作制度对小麦籽粒中锌和铁生物利用率的影响。对有机和常规管理的两种作物轮作,即连续一年生作物(春小麦、亚麻、燕麦、大豆)和一年-多年生作物(春小麦、亚麻、紫花苜蓿、苜蓿)进行了全面分期。与常规耕作相比,有机耕作在十年中有六年显著提高了谷物的锌浓度,而对谷物的铁含量没有显著影响。此外,与一年生轮作相比,在十年中的七年里,一年生-多年生轮作的谷物锌含量也明显高于一年生轮作。谷物植酸具有明显的交互效应,有机耕作下的一年生-多年生轮作比其他处理低约 35%。因此,有机耕作下的多样化轮作大大降低了植酸/锌和植酸/铁的摩尔比,表明人类食用的微量元素生物利用率提高了。然而,这些影响与有机系统中磷(P)的可用性降低密切相关,尤其是在苜蓿之后,这限制了谷物产量。施用以牲畜粪便为基础的堆肥提高了谷物产量和养分吸收率,但由于植酸积累增加,降低了锌/铁的生物利用率。这项研究表明,多种作物轮作和有机耕作可以提高微量营养元素的生物利用率,但其代价是谷物产量降低,因为钾的利用率降低了。
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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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