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气候变化背景下的产毒真菌与霉菌毒素:生态、基因组学、分布、风险预测与预防

Toxigenic Fungi and Mycotoxins in a Climate Change Scenario: Ecology, Genomics, Distribution, Prediction and Prevention of the Risk.

作者信息

Perrone Giancarlo, Ferrara Massimo, Medina Angel, Pascale Michelangelo, Magan Naresh

机构信息

Institute of Sciences of Food Production (ISPA), National Research Council (CNR), 70126 Bari, Italy.

Applied Mycology Group, Environment and AgriFood Theme, Cranfield University, Cranfield MK43 0AL, UK.

出版信息

Microorganisms. 2020 Sep 29;8(10):1496. doi: 10.3390/microorganisms8101496.

DOI:10.3390/microorganisms8101496
PMID:33003323
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7601308/
Abstract

Toxigenic fungi and mycotoxins are very common in food crops, with noticeable differences in their host specificity in terms of pathogenicity and toxin contamination. In addition, such crops may be infected with mixtures of mycotoxigenic fungi, resulting in multi-mycotoxin contamination. Climate represents the key factor in driving the fungal community structure and mycotoxin contamination levels pre- and post-harvest. Thus, there is significant interest in understanding the impact of interacting climate change-related abiotic factors (especially increased temperature, elevated CO and extremes in water availability) on the relative risks of mycotoxin contamination and impacts on food safety and security. We have thus examined the available information from the last decade on relative risks of mycotoxin contamination under future climate change scenarios and identified the gaps in knowledge. This has included the available scientific information on the ecology, genomics, distribution of toxigenic fungi and intervention strategies for mycotoxin control worldwide. In addition, some suggestions for prediction and prevention of mycotoxin risks are summarized together with future perspectives and research needs for a better understanding of the impacts of climate change scenarios.

摘要

产毒真菌和霉菌毒素在粮食作物中非常常见,它们在致病性和毒素污染方面的宿主特异性存在显著差异。此外,此类作物可能会被产毒真菌混合物感染,导致多种霉菌毒素污染。气候是驱动收获前和收获后真菌群落结构及霉菌毒素污染水平的关键因素。因此,人们对了解与气候变化相关的非生物因素(特别是温度升高、二氧化碳浓度升高和水资源可利用性极端情况)相互作用对霉菌毒素污染相对风险以及对食品安全和保障的影响非常感兴趣。因此,我们研究了过去十年中关于未来气候变化情景下霉菌毒素污染相对风险的现有信息,并确定了知识空白。这包括有关全球产毒真菌的生态学、基因组学、分布以及霉菌毒素控制干预策略的现有科学信息。此外,总结了一些霉菌毒素风险预测和预防建议以及未来展望和研究需求,以便更好地了解气候变化情景的影响。

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