Single-Cell Mass Spectrometry of Metabolites Extracted from Live Cells by Fluidic Force Microscopy

Guillaume‐Gentil, Orane; Rey, Timo; Kiefer, Patrick; Ibáñez, Alfredo J.; Steinhoff, Robert; Brönnimann, Rolf; Dorwling-Carter, Livie; Zambelli, Tomaso; Zenobi, Renato; Vorholt, Julia A.

doi:10.1021/acs.analchem.7b00367

Cited by 91 publications

(94 citation statements)

References 36 publications

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“…The discovered critical roles of metabolism and the growing awareness of a hidden world beneath population averages created an urgent need to investigate intracellular metabolism at the single-cell level (Rubakhin et al, 2013; Zenobi, 2013). In the recent years, the sensitivity of mass spectrometry-based metabolite detection has improved substantially opening novel avenues to metabolomics of either single cells or small groups of cells (Do et al, 2017; Guillaume-Gentil et al, 2017; Ibáñez et al, 2013; Merrill et al, 2017) and even at a subcellular level (Passarelli et al, 2017). However, despite these methods successfully demonstrated detection of metabolites in individual cells, analytical and computational challenges precluded studies of spatio-molecular organization and cellular heterogeneity, and prevented discovering the links between intracellular metabolomes, cellular phenotypes and spatial organisation of cells.…”

Section: Introductionmentioning

confidence: 99%

Spatial single-cell profiling of intracellular metabolomesin situ

Rappez

Stadler

Triana

et al. 2019

Preprint

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The recently unveiled extent of cellular heterogeneity demands for single-cell investigations of 15 intracellular metabolomes to reveal their roles in intracellular processes, molecular 16 microenvironment and cell-cell interactions. To address this, we developed SpaceM, a method 17 for in situ spatial single-cell metabolomics of cell monolayers which detects >100 metabolites in 18 >10000 individual cells together with fluorescence and morpho-spatial cellular features. We 19 discovered that the intracellular metabolomes of co-cultured human HeLa cells and mouse 20 NIH3T3 fibroblasts predict the cell type with 90.4% accuracy and revealed a short-distance 21 metabolic intermixing between HeLa and NIH3T3. We characterized lipid classes composing 22 lipid droplets in steatotic differentiated human hepatocytes, and discovered a preferential 23 accumulation of long-chain phospholipids, a co-regulation of oleic and linoleic acids, and an 24 association of phosphatidylinositol monophosphate with high cell-cell contact. SpaceM provides 25 single-cell metabolic, phenotypic, and spatial information and enables spatio-molecular 26 investigations of intracellular metabolomes in a variety of cellular models. 27 28 Keywords 29 Spatial single-cell metabolomics, imaging mass spectrometry, microscopy, heterogeneity, 30 metabolic intermixing, macrovesicular steatosis, lipid droplets, cell-cell contact, SpaceM 31 32 77 6 interrogate changes of single-cell metabolomes upon perturbations, and discover spatio-78 molecular associations. 79 80 Results 81The SpaceM method 82 SpaceM relies on using Matrix Assisted Laser Desorption Ionization (MALDI)-imaging mass 83 spectrometry, a spatially-resolved mass spectrometry technology for detection of a wide range of 84 molecules (Baker et al., 2017). MALDI-imaging is increasingly used for spatial metabolomics 85 (Palmer et al., 2016) and was demonstrated to achieve the femtomolar-levels sensitivity 86 (Soltwisch et al., 2015). This, together with soft ionisation preventing excessive in-source 87 molecular fragmentation makes it a perfect choice for single-cell metabolomics as demonstrated 88 by others (Do et al., 2017; Ibáñez et al., 2013). The experimental part of SpaceM combines 89 MALDI-imaging with microscopy as well as with collecting supporting information to integrate 90 these two sources of data ( Figure 1; for a detailed workflow see Figure S1). The cells for 91 SpaceM are cultured on a labtek chamber glass slide in a monolayer, with the cell confluence 92 sufficient to allow cells to interact between each other but at the same time preventing the growth 93 of cells on top of each other. After washing, cells are fixed to halt enzymatic activity, stained 94 with a fluorescent dye with the staining protocol compatible with metabolomics, and dried in a 95 desiccator following regular cell preparation protocols. SpaceM requires the Hoechst (or any 96 similar) staining for nuclei detection. For investigation of the steatotic hepatocytes, we also used 97 the lipophilic LD540 staining to d...

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Section: Introductionmentioning

confidence: 99%

Spatial single-cell profiling of intracellular metabolomesin situ

Rappez

Stadler

Triana

et al. 2019

Preprint

View full text Add to dashboard Cite

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“…[73] As uspension of S. cerevisiae cells was deposited on the platform, and single or af ew cells were trapped in each micro-well for MALDI-MS analysis.Metabolic variations between individual cells due to drug treatment or genetic modifications were explored, and phenotypic changes in metabolite levels were revealed. [80] Ac antilever probe,d riven by an atomic force microscope,w as used to gently extract 1t o3 pL of the cytoplasm from HeLa cells and dispense it onto the MAMS substrate for MALDI-MS analysis.A nother cell-trapping method, based on am icro-well patterned microfluidic chip, was introduced for the high-throughput analysis of phospholipids in single A549 cells by MALDI-MS imaging. [74,79] More recently,t his technique was combined with fluidic force microscopy (FluidFM) for the nondestructive and quantitative sampling of cell contents followed by MALDI-MS analysis (Figure 1).…”

Section: Linwenmentioning

confidence: 99%

“…[74,79] More recently,t his technique was combined with fluidic force microscopy (FluidFM) for the nondestructive and quantitative sampling of cell contents followed by MALDI-MS analysis (Figure 1). [80] Ac antilever probe,d riven by an atomic force microscope,w as used to gently extract 1t o3 pL of the cytoplasm from HeLa cells and dispense it onto the MAMS substrate for MALDI-MS analysis.A nother cell-trapping method, based on am icro-well patterned microfluidic chip, was introduced for the high-throughput analysis of phospholipids in single A549 cells by MALDI-MS imaging. [81] Another high-throughput MALDI-MS approach utilized microscope imaging to identify the coordinates of individual cells dispersed on amicroscope slide,and was used to analyze the peptide and protein species in targeted cells.…”

Section: Angewandte Chemiementioning

confidence: 99%

Single‐Cell Mass Spectrometry Approaches to Explore Cellular Heterogeneity

2018

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Compositional diversity is a fundamental property in cell populations. Single-cell analysis promises new insight into this cellular heterogeneity on the genomic, transcriptomic, proteomic, and metabolomic levels. Mass spectrometry (MS) is a label-free technique that enables the multiplexed analysis of proteins, peptides, lipids, and metabolites in individual cells. The abundances of these molecular classes are correlated with the physiological states and environmental responses of the cells. In this Minireview, we discuss recent advances in single-cell MS techniques with an emphasis on sampling and ionization methods developed for volume-limited samples. Strategies for sample treatment, separation methods, and data analysis require special considerations for single cells. Ongoing analytical challenges include subcellular heterogeneity, non-normal statistical distributions of cellular properties, and the need for high-throughput, high molecular coverage and minimal perturbation.

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“…However, most microfluidic approaches do not provide the spatiotemporal information on the intracellular contents because the collection methods are based on complete cell lysis. To study the dynamics of intracellular transportation or localization of cytoplasmic content , techniques for extracting subcellular cytoplasm are needed. In this section, we focused on recent electrical techniques of collecting subcellular cytoplasm (Figure ).…”

Section: Electrical Extraction Of Subcellular Cytosol From Cellsmentioning

confidence: 99%

Intracellular Electrochemical Sensing

et al. 2018

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Observing biochemical processes within living cell is imperative for biological and medical research. Fluoresce imaging is widely used for intracellular sensing of cell membranes, nuclei, lysosomes, and pH. Electrochemical assays have been proposed as an alternative to fluorescence‐based assays because of excellent analytical features of electrochemical devices. Notably, thanks to the rapid progress of micro/nanotechnologies and electrochemical techniques, intracellular electrochemical sensing is making rapid progress, leading to a successful detection of intracellular components. Such insight can provide a deep understanding of cellular biological processes and, ultimately, define the human healthy and diseased states. In this review, we present an overview of recent research progress in intracellular electrochemical sensing. We focus on two main topics, electrochemical extraction of cytosolic contents from cells and intracellular electrochemical sensing in situ.

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Single-Cell Mass Spectrometry of Metabolites Extracted from Live Cells by Fluidic Force Microscopy

Cited by 91 publications

References 36 publications

Spatial single-cell profiling of intracellular metabolomesin situ

Spatial single-cell profiling of intracellular metabolomesin situ

Single‐Cell Mass Spectrometry Approaches to Explore Cellular Heterogeneity

Intracellular Electrochemical Sensing

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