Land & Water, CSIRO, Ecosciences Precinct, Dutton Park, QLD, 4102, Australia.
Technical Development, Seqirus, 63 Poplar Road, Parkville, VIC, 3052, Australia.
Metabolomics. 2018 Dec 11;14(12):160. doi: 10.1007/s11306-018-1459-0.
Fusarium oxysporum has a high affinity for lignin and cellulose-based substrates and is known to grow in a wide range of environments. It is these properties and its ability to produce mycotoxins that have contributed to its pathogenicity in cereal crops that can affect human and animal health when ingested.
Identify the mechanisms of mycotoxin production and map the functional output of F. oxysporum under varying growth conditions.
Liquid and gas-based chromatography coupled with mass spectrometry was used to identify and map the untargeted metabolic pathway of F. oxysporum grown using nitrogen limited and organic/inorganic nitrogen supplemented media.
Over 1300 metabolites were identified, relating to 42 metabolic pathways. Of these, 520 metabolites merged at pyruvate (glycolysis), succinate (Krebs cycle) and aspartate-glutamate metabolic pathways. CoA depletion at the growth stage triggered the initiation of fatty acid and branched amino acid degradation. This in turn activated propionyl CoA carnitine acetyltransferase enzymes, resulting in nitrogen preservation (urea, putrescine and organic acids end-products). CoA then transferred into the TCA cycle via previously unreported β-alanine and propionyl CoA metabolic pathways, the latter likely being a novel methylmalonyl-CoA mutase activity for F. oxysporum.
The lower supplementation of inorganic nitrogen compounds (≤ 50 mM) and the elimination of nitrates/organic nitrogen sources resulted in TCA autophagy events that boosted mycotoxin-based metabolism and decreased overall F. oxysporum growth. Such knowledge of functional mycotoxin production can be used to supplement agricultural crops and reduce the risk of mycotoxin contamination in human and animal food supplies.
尖孢镰刀菌对木质素和纤维素类基质具有很强的亲和力,已知能在广泛的环境中生长。正是这些特性及其产生霉菌毒素的能力导致了它在谷物作物中的致病性,当这些谷物被摄入时会影响人类和动物的健康。
确定霉菌毒素产生的机制,并绘制尖孢镰刀菌在不同生长条件下的功能输出图谱。
使用液质联用和气质联用技术,鉴定并绘制了在氮限制和有机/无机氮补充培养基中生长的尖孢镰刀菌的非靶向代谢途径。
鉴定出超过 1300 种代谢物,涉及 42 种代谢途径。其中,520 种代谢物在丙酮酸(糖酵解)、琥珀酸(三羧酸循环)和天冬氨酸-谷氨酸代谢途径中融合。生长阶段的 CoA 耗竭触发了脂肪酸和支链氨基酸降解的启动。这反过来又激活了丙酰 CoA 肉碱乙酰转移酶酶,导致氮的保存(尿素、腐胺和有机酸终产物)。然后,CoA 通过以前未报道的β-丙氨酸和丙酰 CoA 代谢途径转移到 TCA 循环中,后者可能是尖孢镰刀菌的一种新的甲基丙二酰 CoA 变位酶活性。
无机氮化合物(≤50mM)的较低补充和硝酸盐/有机氮源的消除导致了 TCA 自噬事件,从而促进了基于霉菌毒素的代谢,并降低了尖孢镰刀菌的整体生长。这种对功能性霉菌毒素产生的了解可以用于补充农业作物,降低人类和动物食品供应中霉菌毒素污染的风险。
