Single-cell Proteomics: Progress and Prospects

Kelly, Ryan

doi:10.1074/mcp.r120.002234

Cited by 278 publications

(243 citation statements)

References 74 publications

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“…In the area of lowinput proteomics, the field enjoys considerable excitement with early examples demonstrating proofof-principle of single-cell proteome analysis 16,33,37 . This is the combined result of miniaturized sample preparation, narrow-bore chromatography, and increased sensitivity in mass spectrometry, in conjunction with novel workflows such as TMT multiplexing with booster channels [38][39][40] . The fact that improved bioinformatics solutions have a major role to play in innovative single-cell strategies has remained underexposed, yet our data showed that re-analysis of an existing single-cell data set by IceR boosted the number of consistently quantified proteins from a few dozen to several hundreds.…”

Section: Discussionmentioning

confidence: 99%

IceR improves proteome coverage and data completeness in global and single-cell proteomics

Kalxdorf

Müller

Stegle

et al. 2020

Preprint

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Label-free proteomics by data-dependent acquisition (DDA) enables the unbiased quantification of thousands of proteins, however it notoriously suffers from high rates of missing values, thus prohibiting consistent protein quantification across large sample cohorts. To solve this, we here present IceR, an efficient and user-friendly quantification workflow that combines high identification rates of DDA with low missing value rates similar to DIA. Specifically, IceR uses ion current information in DDA data for a hybrid peptide identification propagation (PIP) approach with superior quantification precision, accuracy, reliability and data completeness compared to other quantitative workflows. We demonstrate greatly improved quantification sensitivity on published plasma and single-cell proteomics data, enhancing the number of reliably quantified proteins, improving discriminability between single-cell populations, and allowing reconstruction of a developmental trajectory. IceR will be useful to improve performance of large scale global as well as low-input proteomics applications, facilitated by its availability as an easy-to-use R-package.

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Section: Discussionmentioning

confidence: 99%

IceR improves proteome coverage and data completeness in global and single-cell proteomics

Kalxdorf

Müller

Stegle

et al. 2020

Preprint

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“… 27 nanoPOTS demonstrate that reduction in sample volume and minimizing exposed surface areas is pivotal for sample recovery and achieves appropriate ratios between chemicals to the sample. Lysis and digestion conditions (i.e., enzyme to substrate ratio) optimized for bulk samples must be adapted to the extremely reduced protein concentration of single cells to ensure effective chemical lysis, improved digestion efficiency, and reduced autolysis 28,29 …”

Section: Sample Preparationmentioning

confidence: 99%

The rise of single‐cell proteomics

Ctortecka

Mechtler

2021

Analytical Science Advances

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Mass spectrometry‐based proteomics comprehensively defines proteome expression patterns in thousands of cells majorly contributing to our current understanding of many biological processes. More recently, single‐cell transcriptome and genome studies, however, have demonstrated overwhelming heterogeneity of tissues and cellular subpopulations. These studies have indicated different cellular functionality and identity, which are mainly driven by proteins and their posttranscriptional modifications. The rapidly emerging field of single‐cell proteomics aims at complementing transcriptome and genome data by generating comparative protein expression profiles from individual cells. Recent developments demonstrated tremendous improvements in sample preparation workflows and MS instrumentation, quantifying over 1000 proteins from a single cell. Efficient and reproducible sample processing in conjunction with sensitive MS acquisition strategies will allow to further increase the proteome coverage of tissues with single‐cell resolution. The required throughput and data reliability of such studies are still subject to further developments. Therefore, we herein discuss recent progress on specialized workflows and instrumentation next to advancements outside the field, which we expect to contribute to the development of comprehensive single‐cell proteomics.

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“…Unbiased measurement of transcripts, proteins, and metabolites in the live cell is the holy grail of molecular systems cell biology. Even today, after the invention of single-cell transcriptomics [1][2][3][4] , there exists no single technology capable of the unbiased characterization of both proteins and metabolites in the same single cell in vivo to enable the study of live organisms. While tools of molecular biology and high/super-resolution optical microscopy empowered systems biology for live organisms, they only work for a limited number of gene products at a time that also have to be known a priori, thus limiting research scope to targeted studies, typically building on prior knowledge.…”

Section: Textmentioning

confidence: 99%

“…Singlecell high-resolution mass spectrometry (HRMS) emerged as a powerful alternative for targeted as well as untargeted (discovery) studies (reviewed in refs. [1][2][4][5][6][7], yielding data to derive new hypotheses for biological investigations. Specialized technologies in cell handling, sample processing [8][9][10][11][12][13] , high-efficiency separations [14][15][16] , and ion generation equipped time-of-flight and orbitrap HRMS instruments with exquisite sensitivity.…”

Section: Textmentioning

confidence: 99%

In VivoSubcellular Mass Spectrometry Enables Proteo-Metabolomic Single-cell Systems Biology in a Chordate Embryo Developing to a Normally Behaving Tadpole (X. laevis)

Lombard‐Banek

Portero

et al. 2021

Preprint

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We present the first example of in vivo high-resolution mass spectrometry (HRMS) for subcellular molecular systems biology of proteins and metabolites. With light microscopy, we identified the left-dorsal and left-ventral animal cells in cleavage-stage non-sentient Xenopus laevis embryos. Using precision-translated fabricated microcapillaries, the subcellular content of each cell was double-probed, each time collecting <5% of cell volume (~10 nL) swiftly (<5 s/event). The proteins and metabolites were analyzed by custom-built ultrasensitive capillary electrophoresis electrospray ionization employing Orbitrap and time-of-flight HRMS. Label-free detection of ~150 metabolites (57 identified) and 738 proteins found proteo-metabolomic networks with differential quantitative activities between the cell types. Spatially and temporally scalable sampling the technology preserved the integrity of the analyzed cells, the neighboring cells, and the embryo. 95% of the analyzed embryos developed into sentient tadpoles that were indistinguishable from their wild-type siblings based on anatomy and visual function in a background color preference assay.

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Single-cell Proteomics: Progress and Prospects

Cited by 278 publications

References 74 publications

IceR improves proteome coverage and data completeness in global and single-cell proteomics

IceR improves proteome coverage and data completeness in global and single-cell proteomics

The rise of single‐cell proteomics

In VivoSubcellular Mass Spectrometry Enables Proteo-Metabolomic Single-cell Systems Biology in a Chordate Embryo Developing to a Normally Behaving Tadpole (X. laevis)

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