Plant Science Department, McGill University, Sainte-Anne-de-Bellevue, Quebec, Canada.
Plant Mol Biol. 2011 Nov;77(4-5):355-70. doi: 10.1007/s11103-011-9815-8. Epub 2011 Aug 10.
Fusarium head blight (FHB) is an economically important disease of the family Triticeae, as, apart from yield reduction it also causes quality deterioration by producing mycotoxins. Host resistance is the most promising way to control the disease. Metabolic profiling was applied to identify resistance related (RR) metabolites against Fusarium graminearum in five FHB-resistant genotypes ('Chevron', 'H5277-44', 'H5277-164', 'M92-513' and 'M122') relative to one FHB-susceptible genotype ('Stander'). The disease severity was assessed in greenhouse to group the genotypes based on FHB-resistance. The disease was quantified as the proportion of diseased spikelets (PSD) and the area under the disease progress curve (AUDPC). Spikelets were collected at 72 h post inoculation. Metabolites were extracted into an aqueous solution of methanol and analyzed using a LC-hybrid-MS system. Metabolite abundances were subjected to a resistant versus susceptible pair-wise analysis, using a t test. Resistance related (RR) metabolites, both constitutive (RRC) and induced (RRI), were identified amongst metabolites whose levels were significantly higher in resistant genotype than in susceptible. Among 1,430 RR metabolites, 115 were putatively identified. These RR metabolites belonged to different chemical groups: fatty acids: linolenic acid; phenylpropanoids: p-coumaric, sinapic acid; flavonoids: naringenin, kaempferol glucoside, catechol glucoside. In addition, resistance indicator metabolites, such as deoxynivalenol (DON) and DON-3-O-glucoside (D3G) were also detected. The amount of total DON synthesized converted to D3G (PDC) was the greatest in resistant genotype 'Chevron' (PDC = 0.76). The role of the resistance-related and resistance-indicator metabolites on plant defense, and their use as potential biomarkers to screen barley genotypes for FHB resistance is discussed.
镰刀菌穗腐病(FHB)是禾本科植物的一种重要经济病害,除了减产外,它还通过产生真菌毒素导致品质下降。寄主抗性是控制该病害最有希望的方法。代谢组学被应用于鉴定五个 FHB 抗性基因型('Chevron'、'H5277-44'、'H5277-164'、'M92-513'和'M122')相对于一个 FHB 敏感基因型('Stander')中与抗镰刀菌有关的(RR)代谢物。在温室中评估疾病严重程度,根据 FHB 抗性对基因型进行分组。疾病通过病变小穗比例(PSD)和疾病进展曲线下面积(AUDPC)进行量化。接种后 72 小时采集小穗。将代谢物提取到甲醇的水溶液中,并使用 LC-混合-MS 系统进行分析。使用 t 检验对代谢物丰度进行抗性与敏感的成对分析。鉴定出在抗性基因型中水平显著高于敏感基因型的代谢物,它们是组成型(RRC)和诱导型(RRI)的抗性相关(RR)代谢物。在 1430 个 RR 代谢物中,有 115 个被假定为鉴定出来。这些 RR 代谢物属于不同的化学组:脂肪酸:亚麻酸;苯丙素:对香豆酸、阿魏酸;类黄酮:柚皮苷、山柰酚葡萄糖苷、儿茶素葡萄糖苷。此外,还检测到抗性指示代谢物,如脱氧雪腐镰刀菌烯醇(DON)和 DON-3-O-葡萄糖苷(D3G)。在抗性基因型'Chevron'(PDC=0.76)中,合成的总 DON 转化为 D3G 的量(PDC)最大。讨论了与抗性相关的和抗性指示的代谢物在植物防御中的作用,以及它们作为潜在的生物标志物筛选大麦基因型对 FHB 抗性的用途。
