FUM 和 BIK 基因表达有助于描述伏马菌素和比克替林在轮枝镰孢中的合成。

FUM and BIK gene expression contribute to describe fumonisin and bikaverin synthesis in Fusarium verticillioides.

机构信息

Institute of Entomology and Plant Pathology, Università Cattolica del Sacro Cuore, Piacenza, Italy.

出版信息

Int J Food Microbiol. 2012 Nov 15;160(2):94-8. doi: 10.1016/j.ijfoodmicro.2012.10.004. Epub 2012 Oct 13.

DOI:10.1016/j.ijfoodmicro.2012.10.004

Abstract

Fusarium verticillioides is a maize pathogen that produces toxic secondary metabolites, including fumonisins and bikaverin. The regulation of biosynthetic gene expression and the production of these metabolites are not fully understood and in this study we investigated the influence of water activity (0.955 and 0.990) on the expression of 5 genes (FUM3-FUM8-FUM13-FUM14 and BIK1) in F. verticillioides strains after 14 and 21days incubation. Fumonisin production and biosynthetic gene expression were greatest at a(w)=0.990, and the same trend was observed for bikaverin production, and BIK1 expression. FUM3 and FUM14 were the most highly expressed genes and were positively correlated with the production of FB(1), FB(2) and FB(3). When FUM14 is more highly expressed than FUM3 the amount of FB(3) quantified is higher with respect to FB(1); this could be explained by the role of FUM3 in the hydroxylation of FB(3) to FB(1).

摘要

串珠镰刀菌是一种玉米病原体，可产生有毒的次生代谢物，包括伏马菌素和比卡菌素。生物合成基因表达的调控和这些代谢物的产生尚未完全了解，在这项研究中，我们研究了水分活度（0.955 和 0.990）对 14 和 21 天培养后 5 个基因（FUM3-FUM8-FUM13-FUM14 和 BIK1）在串珠镰刀菌菌株中的表达的影响。在 a(w)=0.990 时，伏马菌素产量和生物合成基因表达最大，比卡菌素产量和 BIK1 表达也呈现相同趋势。FUM3 和 FUM14 是表达量最高的基因，与 FB(1)、FB(2)和 FB(3)的产生呈正相关。当 FUM14 的表达量高于 FUM3 时，相对于 FB(1)，定量的 FB(3)更多；这可以通过 FUM3 在 FB(3)羟化生成 FB(1)中的作用来解释。

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FUM 和 BIK 基因表达有助于描述伏马菌素和比克替林在轮枝镰孢中的合成。

FUM and BIK gene expression contribute to describe fumonisin and bikaverin synthesis in Fusarium verticillioides.

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