Combating aflatoxin contamination by combining biocontrol application and adapted maize germplasm in northeastern and southeastern Mexico

IF 3.7 2区农林科学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biological Control Pub Date : 2025-02-27 DOI:10.1016/j.biocontrol.2025.105727

Carlos Muñoz-Zavala, Aide Molina-Macedo, Fernando H. Toledo, Eugenio Telles-Mejía, Luisa Cabrera-Soto, Natalia Palacios-Rojas

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引用次数: 0

Abstract

Maize is highly vulnerable to aflatoxin (AF) contamination caused by fungi from the Aspergillus section Flavi, with deficiencies in post-harvest management practices further exacerbating AF levels. Due to their carcinogenic properties, AFs pose significant health risks. Biological control using non-aflatoxigenic A. flavus isolates has been effective for over 25 years in the USA, with two formulations being commercially available. However, no such products have been developed yet for use in Mexico. This study evaluated the effectiveness of AF36-Prevail®, a non-aflatoxigenic strain from Arizona, for reducing aflatoxin contamination in Mexico. Over four years (2019–2022), we assessed its impact alongside regionally adapted maize germplasm in northeastern and southeastern Mexico. We analyzed a total of 1,479 grain samples, with 887 from biocontrol-treated fields, and 592 from untreated fields across 69 sites in Tamaulipas and Campeche. Treated fields showed 59.0 % to 89.9 % reductions in AF content compared to untreated fields, and higher ear rot was observed in untreated fields. Correlation coefficients between ear rot and AF content were r = 0.08 for Campeche and r = 0.36 for Tamaulipas. Significant differences (p ≤ 0.001) were noted between years and hybrids for both yields and AF levels. Three hybrids in Tamaulipas and four in Campeche demonstrated better adaptation, higher yields, and lower AF levels (< 20 ppb). This research underscores the potential for safer maize production in Mexico, particularly when combining biocontrol strain application with adapted germplasm.

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墨西哥东北部和东南部防治黄曲霉毒素污染的生物防治应用与玉米适应性种质相结合

玉米极易受到黄曲霉部分真菌引起的黄曲霉毒素（AF）污染，收获后管理措施的缺陷进一步加剧了AF水平。由于其致癌性，AFs构成了重大的健康风险。在美国，使用不产生黄曲霉毒素的黄曲霉分离物进行生物防治已经有效了25年，有两种配方可供商业使用。然而，目前还没有开发出在墨西哥使用的此类产品。本研究评估了来自亚利桑那州的非黄曲霉毒素菌株AF36-Prevail®在墨西哥减少黄曲霉毒素污染的有效性。在四年（2019-2022年）的时间里，我们评估了它与墨西哥东北部和东南部的区域适应性玉米种质的影响。我们总共分析了1479个谷物样本，其中887个来自塔毛利帕斯州和坎佩切州69个地点的生物防治农田，592个来自未经处理的农田。与未处理地相比，处理地AF含量降低59.0% ~ 89.9%，且未处理地的穗腐病发生率较高。坎佩切州穗腐病与AF含量的相关系数为r = 0.08，塔毛利帕斯州为r = 0.36。产量和AF水平在年份和杂交种之间存在显著差异（p≤0.001）。塔毛利帕斯州的3个杂交种和坎佩切州的4个杂交种表现出更好的适应性、更高的产量和更低的AF水平(<；20磅)。这项研究强调了墨西哥更安全的玉米生产的潜力，特别是将生物防治菌株的施用与适应的种质结合起来。

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来源期刊

Biological Control 生物-昆虫学

CiteScore

7.40

自引率

7.10%

发文量

220

审稿时长

63 days

期刊介绍： Biological control is an environmentally sound and effective means of reducing or mitigating pests and pest effects through the use of natural enemies. The aim of Biological Control is to promote this science and technology through publication of original research articles and reviews of research and theory. The journal devotes a section to reports on biotechnologies dealing with the elucidation and use of genes or gene products for the enhancement of biological control agents. The journal encompasses biological control of viral, microbial, nematode, insect, mite, weed, and vertebrate pests in agriculture, aquatic, forest, natural resource, stored product, and urban environments. Biological control of arthropod pests of human and domestic animals is also included. Ecological, molecular, and biotechnological approaches to the understanding of biological control are welcome.