Quantifying a Biocatalytic Product from a Few Living Microbial Cells Using Microfluidic Cultivation Coupled to FT-ICR-MS.
Christian DusnyMartin LohseThorsten ReemtsmaAndreas SchmidOliver Jens LechtenfeldPublished in: Analytical chemistry (2019)
The in vivo quantification of metabolic products from microbial single cells is one of the last grand challenges in (bio)analytical chemistry. To date, no label-free analytical concept exists that is powerful enough to detect or even quantify the minute amounts of secreted low molecular weight compounds produced by living and isolated single bacteria or yeast cells. Coupling microfluidic cultivation systems with ultrahigh resolution electrospray-ionization mass spectrometry with its exquisite sensitivity and specificity offers the prospect of single-cell product analysis and quantification, but has not been successfully implemented yet. We report an analytical framework that interfaces noninvasive microfluidic trapping and cultivation of a few bacterial single cells with the analysis of their catalytic products by Fourier-transform ion cyclotron resonance mass spectrometry (FT-ICR-MS). Cell trapping was performed with the microfluidic Envirostat platform for cultivating bacterial cells under continuous perfusion via negative dielectrophoresis (nDEP). A total of 1.5 μL of product-containing cell supernatant was sampled into microcapillaries using a dead volume-reduced world-to-chip interface. The samples were analyzed with a nanoESI ion source coupled to a FT-ICR-MS (limit of detection for lysine: 0.5 pg). As a biocatalytic model system, we analyzed few Corynebacterium glutamicum DM 1919 pSenLys cells that synthesized l-lysine from d-glucose. Secreted lysine was quantified from a few cells (down to 19). Single-cell specific lysine productivities were 2 and 10 fmol/cell/h. This demonstrates that coupling microfluidics and mass spectrometry (SIC-MS) now enables the quantification of catalytic products and extracellular metabolites from only a few living microbial cells.
Keyphrases
- induced apoptosis
- single cell
- mass spectrometry
- cell cycle arrest
- high throughput
- endoplasmic reticulum stress
- ms ms
- microbial community
- cell death
- liquid chromatography
- signaling pathway
- type diabetes
- metabolic syndrome
- computed tomography
- stem cells
- circulating tumor cells
- mesenchymal stem cells
- amino acid
- gas chromatography
- room temperature
- single molecule
- blood glucose
- saccharomyces cerevisiae