Armitage Emily G, Barnes Alan, Deda Olga, Virgiliou Christina, Loftus Neil J, Gika Helen, Wilson Ian D
Shimadzu Corporation, Manchester, M17 1GP, UK.
Department of Medicine, Aristotle University of Thessaloniki, Thessaloniki, 54124, Greece.
Metabolomics. 2025 Jul 1;21(4):95. doi: 10.1007/s11306-025-02282-8.
In metabolic profiling studies the structural characterisation of lipids requires the identification of the head group, carbon number and the position(s) of carbon-carbon double bonds (C = C). Locating the position of double bonds is vital since minor structural differences between positional isomers can alter a lipid's biochemical function.
Oxygen Attachment Dissociation (OAD) is a novel fragmentation technology that enables the localisation of C = C double bonds in lipids. To evaluate its use in the structural characterisation of lipids, OAD has been applied in a discovery-based untargeted analysis of the metabolic impact of acute ethanol exposure in a mouse model.
UHPLC-OAD-MS/MS was used to enhance the identification of lipids found to be significantly altered by acute ethanol exposure in the gut, liver and pancreas tissues of male C57BL/6 mice receiving a Lieber-DeCarli liquid diet either containing 5% ethanol or an isocaloric control diet. Tissue extracts were analysed using untargeted UHPLC-DIA-MS/MS; UHPLC-OAD-MS/MS analysis was performed to further annotate lipids that were significantly increased or diminished in the animals exposed to ethanol.
UHPLC-DIA-MS/MS analysis of gut, liver and pancreas tissue revealed 101 lipids that were significantly increased or diminished in ethanol treated mice. Of the included 83 unsaturated lipids detected, UHPLC-OAD-MS/MS enabled the localisation of C = C double bonds in 61, including isomers indistinguishable by MS/MS with collision induced dissociation.
The results demonstrate the value of OAD-MS/MS in enhancing lipid identification. The resulting improvement may enable better understanding of the underlying biochemistry in the response of mice to exposure to ethanol.
在代谢谱研究中,脂质的结构表征需要确定头部基团、碳原子数以及碳-碳双键(C = C)的位置。确定双键位置至关重要,因为位置异构体之间的微小结构差异会改变脂质的生化功能。
氧附着解离(OAD)是一种新型碎裂技术,可实现脂质中C = C双键的定位。为评估其在脂质结构表征中的应用,OAD已应用于基于发现的非靶向分析,以研究急性乙醇暴露对小鼠模型的代谢影响。
使用超高效液相色谱-氧附着解离串联质谱(UHPLC-OAD-MS/MS)来增强对在接受含5%乙醇的Lieber-DeCarli液体饮食或等热量对照饮食的雄性C57BL/6小鼠的肠道、肝脏和胰腺组织中因急性乙醇暴露而显著改变的脂质的鉴定。使用非靶向超高效液相色谱-数据独立采集串联质谱(UHPLC-DIA-MS/MS)分析组织提取物;进行UHPLC-OAD-MS/MS分析以进一步注释在暴露于乙醇的动物中显著增加或减少的脂质。
对肠道、肝脏和胰腺组织的UHPLC-DIA-MS/MS分析显示,在乙醇处理的小鼠中有101种脂质显著增加或减少。在所检测的83种不饱和脂质中,UHPLC-OAD-MS/MS能够确定61种脂质中C = C双键的位置,包括通过碰撞诱导解离的串联质谱无法区分的异构体。
结果证明了OAD-MS/MS在增强脂质鉴定方面的价值。由此带来的改进可能有助于更好地理解小鼠对乙醇暴露反应的潜在生物化学机制。
