Shen B , Pade LR , Choi SB , Muñoz-LLancao P , Manzini MC , Nemes P .

R35 GM124755 NIGMS NIH HHS

	FIGURE 1. CE-HRMS for scalable single-cell proteomics. The protein content was collected from identified cells in Xenopus laevis embryos and neurons cultured from the mouse hippocampus. The example labels the normally neural-tissue fated dorsal-animal midline cell (D11) and the normally epidermally fated ventral-animal equatorial cell (V12). The proteins were detected on a custom-built microanalytical capillary electrophoresis (CE) electrospray ionization (ESI) platform using orbitrap (OT) high-resolution tandem mass spectrometry (HRMS-MS/MS).
	FIGURE 2. Scalable collection of trace amounts of proteins from single cells for HRMS detection. (A) Example showing microaspiration of cell contents into a microfabricated glass pipette from a D, D1, and D11 blastomere in a 4, 8-, and 16-cell X. laevis embryo. Scale, 250 µm. (B) Collection of a single cultured mouse neuron into a fabricated microcapillary. Scale, 20 µm. (C) Representative base-peak ion signal traces recorded between m/z 350–1,500 from 400 ng of digest using nanoLC and 10 ng of protein digest using CE, revealing enhancement in sensitivity and speed by electrophoresis.
	FIGURE 3. Benchmarking the analytical figures of merit. (A) Protein identifications in the V12 X. laevis cell from ∼400 ng of protein digest by nanoLC and ∼18 ng of protein digest by CE HRMS. (B) Single-shot analyses identifying (ID) complementary types of proteins. The CE experiment quantified more proteins than nanoLC. (C) Pearson correlation analysis of proteins that were quantifiable by both technologies. (D) Statistical comparison of protein quantification (Wilcoxon signed tests) revealing indistinguishable abundance distribution for commonly quantified proteins. Proteins that were only quantifiable by CE were detected in statistically higher abundance.
	FIGURE 4. Single-to-subcellular neuroproteomics by CE-HRMS. (A) Comparison of the linear dynamic range and depth of the quantified neuroproteome from diluted proteome digests estimating to a single neuron (∼500 pg protein digest), a half neuron (∼250 pg), and quarter of a neuron (∼125 pg). (B) Comparison of proteins identified from the diluted digests.
	FIGURE 5. Reactome analysis of protein-protein interactions from a single-neuron equivalent protein digest (500 pg proteome). More than 700 pathways were represented (Supplementary Table S7). Detected nodes are highlighted in yellow. Pathway key: (A), muscle contraction; (B), digestion and absorption; (C), developmental biology; (D), neuronal system; (E), immune system; (F), signal transduction; (G), hemostasis; (H), gene expression; (I), metabolism of RNA; (J), metabolism; (K), chromatin organization; (L), DNA repair; (M), DNA replication; (N), transport of small molecules; (O), sensory perception; (P), cell cycle; (Q), reproduction; (R), organelle biogenesis and maintenance; (S), metabolism of proteins; (T), programmed cell death; (U), cellular responses to stimuli; (V), autophagy; (W), protein localization; (X), vesicle-mediated transport; (Y), extracellular matrix organization; (Z), cell-cell communication.

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