INRA, UMR619 Fruit Biology, Centre INRA de Bordeaux, 71 Ave Edouard Bourlaux, F-33140 Villenave d'Ornon, FR, France.
J Plant Physiol. 2010 Feb 15;167(3):242-5. doi: 10.1016/j.jplph.2009.08.010. Epub 2009 Sep 25.
A metabolomics approach using (1)H NMR and GC-MS profiling of primary metabolites and quantification of adenine nucleotides with luciferin bioluminescence was employed to investigate the spatial changes of metabolism in melon fruit. Direct (1)H NMR profiling of juice collected from different locations in the fruit flesh revealed several gradients of metabolites, e.g. sucrose, alanine, valine, GABA or ethanol, with increase in concentrations from the periphery to the center of the fruit. GC-MS profiling of ground samples revealed gradients for metabolites not detected using (1)H NMR, including pyruvic and fumaric acids. The quantification of adenine nucleotides highlighted a strong decrease in both ATP and ADP ratios and the adenylate energy charge from the periphery to the center of the fruit. These concentration patterns are consistent with an increase in ethanol fermentation due to oxygen limitation and were confirmed by observed changes in alanine and GABA concentrations, as well as other markers of hypoxia in plants. Ethanol content in melon fruit can affect organoleptic properties and consumer acceptance. Understanding how and when fermentation occurred can help to manage the culture and limit ethanol production.
采用(1)H NMR 和 GC-MS 对初级代谢物进行代谢组学分析,并利用荧光素生物发光对腺嘌呤核苷酸进行定量分析,研究了甜瓜果实代谢的空间变化。直接对果肉不同部位采集的果汁进行(1)H NMR 分析,揭示了几种代谢物的梯度,如蔗糖、丙氨酸、缬氨酸、GABA 或乙醇,其浓度从果实边缘向中心逐渐增加。利用 GC-MS 对粉碎后的样品进行分析,揭示了(1)H NMR 无法检测到的代谢物的梯度,包括丙酮酸和富马酸。腺嘌呤核苷酸的定量分析突出显示,从果实边缘到中心,ATP 和 ADP 比值以及腺苷酸能量电荷均显著下降。这些浓度模式与由于缺氧导致的乙醇发酵增加一致,并通过观察到的丙氨酸和 GABA 浓度以及植物缺氧的其他标志物的变化得到证实。甜瓜果实中的乙醇含量会影响感官特性和消费者接受度。了解发酵发生的方式和时间有助于管理栽培和限制乙醇的产生。
