Single Cell Proteomics Using Frog (<i>Xenopus laevis</i>) Blastomeres Isolated from Early Stage Embryos, Which Form a Geometric Progression in Protein Content

Sun, Liangliang; Dubiak, Kyle M.; Peuchen, Elizabeth H.; Zhang, Zhenbin; Zhu, Guijie; Huber, Paul W.; Dovic̀hi, Norman J.

doi:10.1021/acs.analchem.6b01921

Cited by 86 publications

(77 citation statements)

References 41 publications

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“…21–23 More recently, ESI−MS has been used in conjunction with other significant innovations to detect many more proteins in single human oocytes 24 or small samples from single embryonic frog cells (blastomeres). 25,26 Even with mammalian cells having diameter ∼15 μ m, ESI−MS has made progress in quantifying increasing number of proteins in relatively small number of cells, reaching thousands of proteins in cell lysates corresponding to hundreds of cells 27 or even fewer cells. 28 Recently, we reported a method that allows quantifying over a thousand proteins across many single mouse stem cells.…”

Section: Transformative Opportunities For Realizing Single-cell Protementioning

confidence: 99%

Transformative Opportunities for Single-Cell Proteomics

2018

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Many pressing medical challenges, such as diagnosing disease, enhancing directed stem-cell differentiation, and classifying cancers, have long been hindered by limitations in our ability to quantify proteins in single cells. Mass spectrometry (MS) is poised to transcend these limitations by developing powerful methods to routinely quantify thousands of proteins and proteoforms across many thousands of single cells. We outline specific technological developments and ideas that can increase the sensitivity and throughput of single-cell MS by orders of magnitude and usher in this new age. These advances will transform medicine and ultimately contribute to understanding biological systems on an entirely new level.

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Section: Transformative Opportunities For Realizing Single-cell Protementioning

confidence: 99%

Transformative Opportunities for Single-Cell Proteomics

2018

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“…Combined with continuous developments in HRMS technology for Xenopus , such as multiplexing quantification 23 and ultrasensitive detection, 26,53,54 the methodologies tested here afford possibilities to study developmental processes with progressively deeper molecular coverage, even at the level of single cells. 26,27,55 …”

Section: Resultsmentioning

confidence: 99%

Proteomic Characterization of the Neural Ectoderm Fated Cell Clones in the Xenopus laevis Embryo by High-Resolution Mass Spectrometry

Baxi

Lombard‐Banek

Moody

et al. 2018

ACS Chem. Neurosci.

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The molecular program by which embryonic ectoderm is induced to form neural tissue is essential to understanding normal and impaired development of the central nervous system. Xenopus has been a powerful vertebrate model in which to elucidate this process. However, abundant vitellogenin (yolk) proteins in cells of the early Xenopus embryo interfere with protein detection by high-resolution mass spectrometry (HRMS), the technology of choice for identifying these gene products. Here, we systematically evaluated strategies of bottom-up proteomics to enhance proteomic detection from the neural ectoderm (NE) of X. laevis using nanoflow high-performance liquid chromatography (nanoLC) HRMS. From whole embryos, high-pH fractionation prior to nanoLC-HRMS yielded 1319 protein groups vs 762 proteins without fractionation (control). Compared to 702 proteins from dorsal halves of embryos (control), 1881 proteins were identified after yolk platelets were depleted via sucrose-gradient centrifugation. We combined these approaches to characterize protein expression in the NE of the early embryo. To guide microdissection of the NE tissues from the gastrula (stage 10), their precursor (midline dorsal-animal, or D111) cells were fate-mapped from the 32-cell embryo using a fluorescent lineage tracer. HRMS of the cell clones identified 2363 proteins, including 147 phosphoproteins (without phosphoprotein enrichment), transcription factors, and members from pathways of cellular signaling. In reference to transcriptomic maps of the developing X. laevis, 76 proteins involved in signaling pathways were gene matched to transcripts with known enrichment in the neural plate. Besides a protocol, this work provides qualitative proteomic data on the early developing NE.

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“…30,42 Improvements in sheathless CE-MS interfaces have allowed investigation of complex bioanalytical problems, as in the characterization of protein isoforms and combinatorial PTMs reported by Yates and co-workers. 69,70 Recent examples from Dovichi 71 and Nemes 72,73 of the developing Xenopus laevis embryo demonstrate the great promise for CE-MS-based single-cell proteomics.…”

Section: Specific Cell-type Targeting: Meeting the Needs For Separatimentioning

confidence: 99%

Categorizing Cells on the Basis of their Chemical Profiles: Progress in Single-Cell Mass Spectrometry

et al. 2017

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The chemical differences between individual cells within large cellular populations provide unique information on organisms’ homeostasis and the development of diseased states. Even genetically identical cell lineages diverge due to local microenvironments and stochastic processes. The minute sample volumes and low abundance of some constituents in cells hinder our understanding of cellular heterogeneity. Although amplification methods facilitate single-cell genomics and transcriptomics, the characterization of metabolites and proteins remains challenging both because of the lack of effective amplification approaches and the wide diversity in cellular constituents. Mass spectrometry has become an enabling technology for the investigation of individual cellular metabolite profiles with its exquisite sensitivity, large dynamic range, and ability to characterize hundreds to thousands of compounds. While advances in instrumentation have improved figures of merit, acquiring measurements at high throughput and sampling from large populations of cells are still not routine. In this Perspective, we highlight the current trends and progress in mass-spectrometry-based analysis of single cells, with a focus on the technologies that will enable the next generation of single-cell measurements.

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Single Cell Proteomics Using Frog (Xenopus laevis) Blastomeres Isolated from Early Stage Embryos, Which Form a Geometric Progression in Protein Content

Cited by 86 publications

References 41 publications

Transformative Opportunities for Single-Cell Proteomics

Transformative Opportunities for Single-Cell Proteomics

Proteomic Characterization of the Neural Ectoderm Fated Cell Clones in the Xenopus laevis Embryo by High-Resolution Mass Spectrometry

Categorizing Cells on the Basis of their Chemical Profiles: Progress in Single-Cell Mass Spectrometry

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