Method Article

A Method for Measuring Metabolism in Sorted Subpopulations of Complex Cell Communities Using Stable Isotope Tracing

DOI:

10.3791/55011

February 4th, 2017

In This Article

Summary

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This article describes a method for studying cellular metabolism in complex communities of multiple cell types, using a combination of stable isotope tracing, cell sorting to isolate specific cell types, and mass spectrometry.

Abstract

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Mammalian cell types exhibit specialized metabolism, and there is ample evidence that various co-existing cell types engage in metabolic cooperation. Moreover, even cultures of a single cell type may contain cells in distinct metabolic states, such as resting or cycling cells. Methods for measuring metabolic activities of such subpopulations are valuable tools for understanding cellular metabolism. Complex cell populations are most commonly separated using a cell sorter, and subpopulations isolated by this method can be analyzed by metabolomics methods. However, a problem with this approach is that the cell sorting procedure subjects cells to stresses that may distort their metabolism.

To overcome these issues, we reasoned that the mass isotopomer distributions (MIDs) of metabolites from cells cultured with stable isotope-labeled nutrients are likely to be more stable than absolute metabolite concentrations, because MIDs are formed over longer time scales and should be less affected by short-term exposure to cell sorting conditions. Here, we describe a method based on this principle, combining cell sorting with liquid chromatography-high resolution mass spectrometry (LC-HRMS). The procedure involves analyzing three types of samples: (1) metabolite extracts obtained directly from the complex population; (2) extracts of "mock sorted" cells passed through the cell sorter instrument without gating any specific population; and (3) extracts of the actual sorted populations. The mock sorted cells are compared against direct extraction to verify that MIDs are indeed not altered by the cell sorting procedure itself, prior to analyzing the actual sorted populations. We show example results from HeLa cells sorted according to cell cycle phase, revealing changes in nucleotide metabolism.

Introduction

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Higher organisms contain complex communities of distinct cell types that collaborate to bring about more complex functions. For example, tumors contain not only cancerous cells, but also fibroblasts, cells that constitute blood vessels, and often immune cell infiltrates1; blood contains a complex mixture of dozens of immune cell subtypes2; and even cultured cell lines may consist of multiple subpopulations, such as the luminal and basal subtypes of breast cancer cells3. Moreover, distinct cell types that coexist can exhibit metabolic "collaboration". For example, in the brain, astrocytes a....

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Protocol

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1. Metabolite Extraction

  1. Extraction from dish
    1. Culture cells in a 6-well plate in triplicates in stable isotope labeled culture media + dialyzed supplements (serum or other growth supplements) until cells become 75% confluent.
      NOTE: Here culture HeLa cells for 48 h in RPMI containing 40% U-13C-Glucose and 70% U-13C, 15N2-Glutamine and 5% dialyzed FBS (Fetal Bovine Serum). Dialyzed FBS is used to get rid of the small molecular weight metabolites which might contaminate the labeled media. Culturing cells in dialyzed supplement prior to the real experiment is recommended to ensure cells are gr....

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Results

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As an example, here we describe an experiment investigating the metabolism of HeLa cells sorted according to cell cycle phase. To label a wide range of central metabolites on both carbons and nitrogens, we cultured cells for 48 h using U-13C-glucose and U-13C, 15N-glutamine as tracers. To obtain rich MIDs for the validation experiment, we here chose a mixture of 40% U-13C-Glucose and 70% U-13C,15N2-Glutamine, as intermediat.......

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Discussion

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Our method is based on the principle that MIDs in cellular metabolites reflect the "history" of metabolic activities of a cell. This makes it possible to investigate metabolic activities in subpopulation of cells, as they occurred in the complex community of cells, prior to the cell sorting procedure. In contrast, peak areas of metabolites differ markedly between extracts of sorted cells and direct extraction from the culture dish11. In part this is because the different chemical compositi.......

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Disclosures

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The authors have nothing to disclose.

Acknowledgements

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The authors would like to thank Dr. Anas Kamleh for valuable help with optimizing mass spectrometry methods, and Annika von Vollenhoven for assistance with cell sorting. This research was supported by the Swedish Foundation for Strategic Research (grant no. FFL12-0220) and the Strategic Programme in Cancer Research (IR, RN); the Swedish Heart-Lung Foundation (CEW, HG); and Mary Kay Foundation (JW, MJ).

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Materials

List of materials used in this article
NameCompanyCatalog NumberComments
HBSSSigmaH6648
INFLUX (inFlux v7 Sorter)BD Biosciences
U-13C-GlucoseCambridge isotopes40762-22-9 / GLC-018
U-13C,15N2-GlutamineCambridge isotopesCNLM-1275-H-0.1
Methanol (JT Baker), HPLC gradeVWRBAKR8402.2500
Ultrafree - MC - VV centrifugal Filters. Durapore PVDF 0.1 µmMilliporeUFC30VV00
Ultimate 3,000 UHPLCThermo Fisher scientific
Q-Exactive Orbitrap Mass spectrometerThermo Fisher scientific
Merk-Sequant ZIC HILIC column (150 mm x 4.6 mm, 5 µm)Merck KGaA1.50444.0001
Merk-Sequant ZIC HILIC guard column (20 mm x 2.1 mm)Merck KGaA
Acetonitrile Optima LC-MS, amber glassFisher ScientificA955-212
Milli-Q waterMilliporeProduced with a Milli-Q Gradient system
Myrsyra 99.5% Optima (Formic acid)Fisher Scientific11423423
X100 Screw Vial 1.5 ml, 8-425 32x11.6 mm, amber, 100 unitsThermo Fisher scientific10560053
X100 Lock Skruv Vitt PTFE Packing 8-425 (Screw caps)Thermo Fisher scientific12458636
ProteoMass LTQ/FT-Hybrid ESI Pos. Mode Cal MixSigma-AldrichMSCAL5Calibration kit
SNAKESKIN 10K MWCO Thermo Fisher scientific88245
Mathematica v.10 Wolfram Research

References

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  1. Gregersen, P. K. Cell type-specific eQTLs in the human immune system. Nat. Genet. 44 (5), 478-480 (2012).
  2. Heppner, G. H. Tumor heterogeneity. Cancer Res. 44 (6), 2259-2265 (1984).
  3. Prat, A., et al.

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Tags

Stable Isotope TracingCell SortingMetabolite ExtractionLC HRMS AnalysisMass Isotopomer DistributionsCell Cycle SortingMock Sorted CellsMetabolic CollaborationNucleotide MetabolismFlow Cytometry

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