Summary

A gran escala que no son objeto de perfiles metabolómicos de Serum Ultra Performance Liquid Chromatography-espectrometría de masas (UPLC-MS)

Published: March 14, 2013
doi:

Summary

Non-targeted metabolite profiling by ultra performance liquid chromatography coupled with mass spectrometry (UPLC-MS) is a powerful technique to investigate metabolism. This article outlines a typical workflow utilized for non-targeted metabolite profiling of serum including sample organization and preparation, data acquisition, data analysis, quality control, and metabolite identification.

Abstract

Non-targeted metabolite profiling by ultra performance liquid chromatography coupled with mass spectrometry (UPLC-MS) is a powerful technique to investigate metabolism. The approach offers an unbiased and in-depth analysis that can enable the development of diagnostic tests, novel therapies, and further our understanding of disease processes. The inherent chemical diversity of the metabolome creates significant analytical challenges and there is no single experimental approach that can detect all metabolites. Additionally, the biological variation in individual metabolism and the dependence of metabolism on environmental factors necessitates large sample numbers to achieve the appropriate statistical power required for meaningful biological interpretation. To address these challenges, this tutorial outlines an analytical workflow for large scale non-targeted metabolite profiling of serum by UPLC-MS. The procedure includes guidelines for sample organization and preparation, data acquisition, quality control, and metabolite identification and will enable reliable acquisition of data for large experiments and provide a starting point for laboratories new to non-targeted metabolite profiling by UPLC-MS.

Introduction

The term “metabolomics” can encompass many things. For example, a metabolomics experiment can be performed using a variety of analytical platforms such as NMR and both gas and/or liquid chromatography coupled with mass spectrometry. Furthermore, metabolomics experiments can be performed in a targeted or non-targeted manner, or a combination of both. A targeted metabolomics experiment will involve directed analysis of a panel of molecules important to the biological question at hand (e.g. small molecules involved in the TCA cycle will allow for accurate quantitation of that pathway). In this situation, the biological hypothesis is dictating the choice of metabolites to be targeted in the analysis and the analytical steps are optimized for the detection of these molecules. Alternatively, a non-targeted metabolomics experiment is hypothesis generating. In this case, the experiment is performed in a broad and unbiased manner to enable detection of as many metabolites as possible. The results from a non-targeted experiment will drive the next step of the research (which in many cases may involve a targeted metabolomics workflow). It is also possible to combine the two approaches, in which case an experiment is performed in a non-targeted manner while concurrently a panel of known molecules are monitored within the data.

The tutorial presented here is focused specifically on non-targeted metabolite profiling of serum. As described above, the non-targeted approach provides an unbiased view of the detectable metabolites, can generate large amounts of information, and ultimately allow for novel discoveries. The use of this approach, specifically employing ultra performance liquid chromatography coupled with mass spectrometry (UPLC-MS), is becoming widespread 1, 2, 3 and involves the following steps: (1) experimental design (2) sample collection (3) sample preparation (4) data acquisition by UPLC-MS (5) data pre-processing (peak detection, integration, alignment, and normalization) (6) statistical data analysis (both uni- and multivariate) (7) metabolite identification and (8) biological interpretation.

Currently, there are no established standard methods for UPLC-MS based non-targeted metabolite profiling and subsequent data pre-processing steps. This lack of standardization is due in part to one of the primary analytical challenges of metabolite profiling; the chemical diversity of the metabolome. Because of this diversity, it is impossible for a single extraction method or mass spectrometry acquisition method to provide comprehensive coverage of all metabolites in a single analysis. In concept, metabolite coverage can be maximized by using multiple extractions (e.g. aqueous, methanol, chloroform:methanol, etc.) coupled with various chromatographic conditions (e.g. reverse phase, HILIC, etc.) and various ionization modes (e.g. positive ion, negative ion, chemical ionization, etc.). Often, however, researchers do not have a pre-determined bias for a specific chemical class and thus the expense of performing multiple extractions and instrument acquisitions is not warranted, especially for large-scale experiments. Thus, the video tutorial presented here was designed to provide a general procedure for large scale non-targeted metabolite profiling of serum by UPLC-MS. It will enable new and established laboratories to perform these types of experiments and the building blocks upon which they can expand the approach for various sample types, specific chemical classes, or targeted analysis. Specifically, this protocol will include the steps of: serum sample preparation, sample organization for large scale studies, UPLC-MS data acquisition, quality control (QC) procedures, and metabolite identification. Strategies for data pre-processing and statistical analysis are also presented.

The protocol will not focus on the steps of experimental design, sample collection, or biological data interpretation as it is outside the scope of this tutorial. However, many resources exist in the literature for these topics and the authors encourage researchers new to metabolomics to explore these thoroughly 4, 5, 6, 7, 8, 9. In particular, experimental design is extremely important and is critical to the success of a non-targeted metabolomics experiment. Factors such as appropriate biological replication and consistency in sample collection procedure (e.g. time on bench, storage temperature, storage time, freeze-thaws, etc.) must be considered to ensure a viable study and to facilitate appropriate biological interpretation of the data.

Protocol

1. Sample Organization To create a plate map for sample preparation on a spreadsheet, in the first column enter a sample list in order of loading. In a second column enter the 96 well plate locations using correct nomenclature for your autosampler software. Save one well in each plate for QC samples. If your LC autosampler can handle two plates at a time, separate the sample list into batches of 190 and save this information in a second worksheet. Within each of these batches, us…

Representative Results

The basic analytical steps of a non-targeted metabolite profiling experiment by UPLC-MS are outlined in Figure 1. The raw data for each sample can be visualized as a base peak chromatogram. Figure 2 shows an example base peak chromatogram of a serum sample analyzed by gradient option (a) in the tutorial. Following statistical analysis as described above, metabolite identification is attempted for all statistically significant molecular features. Confident identification (level 1) req…

Discussion

This tutorial is meant to serve as a starting point for conducting large scale non-targeted metabolite profiling by UPLC-MS. The workflow is focused on metabolites that can be extracted with an aqueous methanol solvent, retained on a C8 or C18 UPLC column, and detected as positive ions. In the situation where there is not a pre-determined bias towards a specific metabolite class and a hypothesis generating global profile is desired, this protocol is valuable as it will result in the detection of a large percentage of ser…

Disclosures

The authors have nothing to disclose.

Acknowledgements

The presented tutorial was performed and developed within the Proteomics and Metabolomics Facility at Colorado State University which is partially funded by the CSU Research Administration Resources for Scholarly Projects.

Materials

Name of Reagent/Material Company Catalog Number Comments
96 well plates – 500 μl wells VWR 40002-020 These are used for sample preparation
96 well plate mats VWR 89026-514 These are used for sample preparation
96 well plates – 350 μl wells Waters Corporation WAT058943 These are used for sample injection
96 well plate mats Waters Corporation 186000857 These are used for sample injection
96 well plate heat seals Waters Corporation 186002789 These can be used for sample injection or long term storage
96 well plate heat sealer Waters Corporation 186002786
LC-MS grade methanol Fluka 34966
LC-MS grade acetonitrile Fluka 34967
LC-MS grade aater Fluka 39253
LC-MS grade formic acid Fluka 56302
Multichannel electronic pipettor VWR 89000-674
Pipett tips Eclipse (purchased through Light Labs) B-5061/B-4061
Chilled centrifuge – Allegra X-12R Beckman Coulter N/A – contact Beckman Coulter
Acquity Ultra performance Liquid Chromatography (UPLC) System Waters Corporation N/A – contact Waters Corporation
UPLC C8 column (gradient option a) Waters Corporation 186002876
UplC T3 column (gradient option b) Waters Corporation 186003536
Xevo G2 Q-TOF Mass spectrometer Waters Corporation N/A – contact Waters Corporation

References

  1. Theodoridis, G., Gika, H. G., Wilson, I. D. Mass Spectrometry-Based Holistic Analytical Approaches for Metabolite Profiling in Systems Biology Studies. Mass Spectrom. Rev. 30, 884-906 (2011).
  2. Zelena, E., et al. Development of a robust and repeatable UPLC-MS method for the long-term metabolomic study of human serum. Analytical Chemistry. 81, 1357-1364 (2009).
  3. Michopoulos, F., Lai, L., Gika, H., Theodoridis, G., Wilson, I. UPLC-MS-based analysis of human plasma for metabonomics using solvent precipitation or solid phase extraction. Journal of Proteome Research. 8, 2114-2121 (2009).
  4. Kamburov, A., Cavill, R., Ebbels, T. M., Herwig, R., Keun, H. C. Integrated pathway-level analysis of transcriptomics and metabolomics data with IMPaLA. Bioinformatics. 27, 2917-2918 (2011).
  5. Xia, J., Wishart, D. S. MetPA: a web-based metabolomics tool for pathway analysis and visualization. Bioinformatics. 26, 2342-2344 (2010).
  6. Johnson, C. H., Gonzalez, F. J. Challenges and opportunities of metabolomics. J. Cell. Physiol. 227, 2975-2981 (2012).
  7. Issaq, H. J., Waybright, T. J., Veenstra, T. D. Cancer biomarker discovery: Opportunities and pitfalls in analytical methods. Electrophoresis. 32, 967-975 (2011).
  8. Zhou, B., Xiao, J. F., Tuli, L., Ressom, H. W. LC-MS-based metabolomics. Mol. Biosyst. 8, 470-481 (2012).
  9. Weckwerth, W., Morgenthal, K. Metabolomics: from pattern recognition to biological interpretation. Drug Discov. Today. 10, 1551-1558 (2005).
  10. Smith, C. A., et al. METLIN – A metabolite mass spectral database. Ther. Drug Monit. 27, 747-751 (2005).
  11. Culpepper, S. A., Aguinis, H. R is for Revolution: A Cutting-Edge, Free, Open Source Statistical Package. Organ Res. Methods. 14, 735-740 (2011).
  12. Sumner, L. W., et al. Proposed minimum reporting standards for chemical analysis. Metabolomics. 3, 211-221 (2007).
  13. Vuckovic, D. Current trends and challenges in sample preparation for global metabolomics using liquid chromatography-mass spectrometry. Anal. Bioanal. Chem. 403, 1523-1548 (2012).
  14. Garcia-Canaveras, J. C., Donato, M. T., Castell, J. V., Lahoz, A. A comprehensive untargeted metabonomic analysis of human steatotic liver tissue by RP and HILIC chromatography coupled to mass spectrometry reveals important metabolic alterations. Journal of Proteome Research. 10, 4825-4834 (2011).
  15. Nordstrom, A., Want, E., Northen, T., Lehtio, J., Siuzdak, G. Multiple ionization mass spectrometry strategy used to reveal the complexity of metabolomics. Analytical Chemistry. 80, 421-429 (2008).
  16. Horai, H., et al. MassBank: a public repository for sharing mass spectral data for life sciences. J. Mass Spectrom. 45, 703-714 (2010).
  17. Wishart, D. S. Advances in metabolite identification. Bioanalysis. 3, 1769-1782 (2011).
  18. Broeckling, C., Heuberger, A., Prince, J., Ingelsson, E., Prenni, J. Assigning precursor-product ion relationships in indiscriminant MS/MS data from non-targeted metabolite profiling studies. Metabolomics. , 1-11 (2012).
  19. Kangas, L. J., et al. In silico identification software (ISIS): a machine learning approach to tandem mass spectral identification of lipids. Bioinformatics. 28, 1705-1713 (2012).

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Cite This Article
Broeckling, C. D., Heuberger, A. L., Prenni, J. E. Large Scale Non-targeted Metabolomic Profiling of Serum by Ultra Performance Liquid Chromatography-Mass Spectrometry (UPLC-MS). J. Vis. Exp. (73), e50242, doi:10.3791/50242 (2013).

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