Sample preparation for single-cell proteomics is generally performed in a one-pot workflow with multiple dispensing and incubation steps. These hours-long processes can be labor intensive and lead to ...long sample-to-answer times. Here we report a sample preparation method that achieves cell lysis, protein denaturation, and digestion in 1 h using commercially available high-temperature-stabilized proteases with a single reagent dispensing step. Four different one-step reagent compositions were evaluated, and the mixture providing the highest proteome coverage was compared to the previously employed multistep workflow. The one-step preparation increases proteome coverage relative to the previous multistep workflow while minimizing labor input and the possibility of human error. We also compared sample recovery between previously used microfabricated glass nanowell chips and injection-molded polypropylene chips and found the polypropylene provided improved proteome coverage. Combined, the one-step sample preparation and the polypropylene substrates enabled the identification of an average of nearly 2400 proteins per cell using a standard data-dependent workflow with Orbitrap mass spectrometers. These advances greatly simplify sample preparation for single-cell proteomics and broaden accessibility with no compromise in terms of proteome coverage.
We combined efficient sample preparation and ultra‐low‐flow liquid chromatography with a newly developed data acquisition and analysis scheme termed wide window acquisition (WWA) to quantify >3,000 ...proteins from single cells in rapid label‐free analyses. WWA employs large isolation windows to intentionally co‐isolate and co‐fragment adjacent precursors along with the selected precursor. Optimized WWA increased the number of MS2‐identified proteins by ≈40 % relative to standard data‐dependent acquisition. For a 40‐min LC gradient operated at ≈15 nL/min, we identified an average of 3,524 proteins per single‐cell‐sized aliquot of protein digest. Reducing the active gradient to 20 min resulted in a modest 10 % decrease in proteome coverage. Using this platform, we compared protein expression between single HeLa cells having an essential autophagy gene, atg9a, knocked out, with their isogenic WT parental line. Similar proteome coverage was observed, and 268 proteins were significantly up‐ or downregulated. Protein upregulation primarily related to innate immunity, vesicle trafficking and protein degradation.
A new data acquisition strategy for biological mass spectrometry, termed wide‐window acquisition, combined with efficient sample preparation and ultra‐low‐flow liquid chromatography, enables single‐cell proteome profiling to an unprecedented depth of >3000 proteins per cell. This advance allows additional classes of proteins to be studied within single cells.
We combined efficient sample preparation and ultra‐low‐flow liquid chromatography with a newly developed data acquisition and analysis scheme termed wide window acquisition (WWA) to quantify >3,000 ...proteins from single cells in rapid label‐free analyses. WWA employs large isolation windows to intentionally co‐isolate and co‐fragment adjacent precursors along with the selected precursor. Optimized WWA increased the number of MS2‐identified proteins by ≈40 % relative to standard data‐dependent acquisition. For a 40‐min LC gradient operated at ≈15 nL/min, we identified an average of 3,524 proteins per single‐cell‐sized aliquot of protein digest. Reducing the active gradient to 20 min resulted in a modest 10 % decrease in proteome coverage. Using this platform, we compared protein expression between single HeLa cells having an essential autophagy gene, atg9a, knocked out, with their isogenic WT parental line. Similar proteome coverage was observed, and 268 proteins were significantly up‐ or downregulated. Protein upregulation primarily related to innate immunity, vesicle trafficking and protein degradation.
A new data acquisition strategy for biological mass spectrometry, termed wide‐window acquisition, combined with efficient sample preparation and ultra‐low‐flow liquid chromatography, enables single‐cell proteome profiling to an unprecedented depth of >3000 proteins per cell. This advance allows additional classes of proteins to be studied within single cells.
