Abstract
Lipids are important biomolecules in all biological systems and serve numerous essential cellular functions. The global analysis of complex lipids is very challenging due to the extreme diversity in lipid structures. Variation in linkages and positions of fatty acyl chain(s) on the lipid backbone, functional group modification, occurrence of the molecular species as isomers or isobars are among some of the greatest challenges to resolve in lipidomics. In this work, we describe a routine analytical approach combining two liquid chromatography platforms: hydrophilic interaction (HILIC) and C30 reversed-phase chromatography (C30RP) coupled to high resolution mass spectrometry (HRMS) as complementary high throughput platforms to analyze complex lipid mixtures. Vascular plants (kale leaves and corn roots), rat brain and soil microbes were used as proxies to evaluate the efficiency of the enhanced approach to resolve traditional, as well as, modified lipids during routine lipidomics analysis. We report for the first time, the observation of a modified class of acylphosphatidylglycerol (acylPG) in corn roots by HILIC, and further resolution of the isomers using C30RP chromatography. We also used this approach to demonstrate the presence of high levels of N-monomethyl phosphatidylethanolamine (MMPE) in soil microbes, as well as to determine the regioisomers of lysophospholipids in kale leaves. Additionally, neutral lipids were demonstrated using C30RP chromatography in positive ion mode to resolve triacylglycerol isomers in rat brain. The work presented here demonstrates how the enhanced approach can more routinely permit novel biomarker discovery, or lipid metabolism in a wide range of biological samples.
Highlights
Www.nature.com/scientificreports glycerophospholipids (GP), sphingolipids (SP), sterol lipids (ST), prenol lipids (PR), saccharolipids (SL) and polyketides (PK)[8,9]
We utilized a solvent system consisting of acetonitrile, water and ammonium acetate buffer for hydrophilic interaction (HILIC) chromatography, which efficiently separated 15 classes of the lipids present in the complex lipid standard mix in negative ion mode (Fig. 1a)
We present the utilization of two enhanced high resolution liquid chromatography platforms coupled to high resolution accurate mass tandem mass spectrometry, for the analysis of modified lipids and regioisomers during routine lipidomics analysis
Summary
Thu Huong Pham 1, Muhammad Zaeem[1], Tiffany A. Regioisomerism has been a target in the development of analytical methods using mass spectrometry, such as collision-induced dissociation (CID) in tandem time-of-flight (i.e.., ToF-ToF) mass spectrometers[29,30], multistage mass spectrometry (i.e., MSn, where n > 3) in a linear ion trap[31,32], or incorporating the ozonolysis in an ion-molecule reaction ion trap (i.e., CID-OzID technique)[33,34], to name a few Taking these into consideration, we sought to apply HILIC complementary with C30 reverse phase chromatography coupled with high resolution tandem mass spectrometry (HILIC/C30RPLC-HRMS/MS) as a high throughput lipidomics platform to routinely analyze complex lipids (isobars, regioisomers, ether-linkage or headgroup modification) in diverse biological systems. Tune parameters were optimized using a mixture of lipid standards (Avanti Polar Lipids, Alabama, USA) in both negative and positive ion modes
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