Single-cell mass spectrometry with multi-solvent extraction identifies metabolic differences between left and right blastomeres in the 8-cell frog (Xenopus) embryo

Onjiko, Rosemary M.; Morris, Sydney E.; Moody, Sally A.; Nemes, Péter

doi:10.1039/c6an00200e

Cited by 79 publications

(97 citation statements)

References 66 publications

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“…These developments enabled femtogram (zeptomole) limit of detection (38) for protein digests from cell populations. For example, we recently developed metabolomic CE microflow electrospray ionization (ESI) HRMS platforms (26) for measuring metabolites (27,39) and proteins (36) in single Xenopus blastomeres. Using microdissection to isolate single blastomeres, tandem mass tags to enable multiplexing quantification, and bottom-up proteomics, CE-ESI-HRMS was able to quantify 130 -150 different protein groups (isoforms) in common between multiple single blastomeres in the 16-cell Xenopus embryo.…”

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confidence: 99%

Label-free Quantification of Proteins in Single Embryonic Cells with Neural Fate in the Cleavage-Stage Frog (Xenopus laevis) Embryo using Capillary Electrophoresis Electrospray Ionization High-Resolution Mass Spectrometry (CE-ESI-HRMS)

Lombard‐Banek¹,

Reddy²,

Moody

et al. 2016

Molecular & Cellular Proteomics

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Quantification of protein expression in single cells promises to advance a systems-level understanding of normal development. Using a bottom-up proteomic workflow and multiplexing quantification by tandem mass tags, we recently demonstrated relative quantification between single embryonic cells (blastomeres) in the frog (Xenopus laevis) embryo. In this study, we minimize derivatization steps to enhance analytical sensitivity and use label-free quantification (LFQ) for single Xenopus cells. The technology builds on a custom-designed capillary electrophoresis microflow-electrospray ionization high-resolution mass spectrometry platform and LFQ by MaxLFQ (MaxQuant). By judiciously tailoring performance to peptide separation, ionization, and data-dependent acquisition, we demonstrate an ϳ75-amol (ϳ11 nM) lower limit of detection and quantification for proteins in complex cell digests. The platform enabled the identification of 438 nonredundant protein groups by measuring 16 ng of protein digest, or <0.2% of the total protein contained in a blastomere in the 16-cell embryo. LFQ intensity was validated as a quantitative proxy for protein abundance. Correlation analysis was performed to compare protein quantities between the embryo and n ‫؍‬ 3 different single D11 blastomeres, which are fated to develop into the nervous system. A total of 335 nonredundant protein groups were quantified in union between the single D11 cells spanning a 4 log-order concentration range. LFQ and correlation analysis detected expected proteomic differences between the whole embryo and blastomeres, and also found translational differences between individual D11 cells. LFQ on single cells raises exciting possibilities to study gene expression in other cells and models to help better understand cell processes on a systems biology level. Molecular & Cellular

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confidence: 99%

Label-free Quantification of Proteins in Single Embryonic Cells with Neural Fate in the Cleavage-Stage Frog (Xenopus laevis) Embryo using Capillary Electrophoresis Electrospray Ionization High-Resolution Mass Spectrometry (CE-ESI-HRMS)

Lombard‐Banek¹,

Reddy²,

Moody

et al. 2016

Molecular & Cellular Proteomics

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“…This process is best understood in frog embryos, but has also been observed and functionally implicated in amphioxus [149], sea urchin [146,150,151], C. elegans [152 -154], zebrafish [96,155,156] and recently humans [157,158]. Indeed, a recent analysis of the differences between blastomeres at the very earliest stages of embryo development identified distinct metabolites in L versus R cells in the eight-cell embryo using mass spectrometry [88]. The majority of these metabolites themselves have roles in functional regulation of ion transport [159 -167], suggesting possible feedback loops in electrophysiology that could be important amplifying mechanisms for initially subtle LR asymmetry.…”

Section: Physics Upstream and Downstream Of Transcriptional Networkmentioning

confidence: 99%

“…From data in a range of model species, it is clear that numerous aspects of development, including maternal protein localization [84,[95][96][97], Wnt signalling [98] and small signalling molecules [88], are already consistently asymmetric long before cilia appear: most animal embryos can tell their left from their right at very early stages. Thus, the search for the origin of asymmetry has been extended far upstream of neurulation [22,99].…”

Section: Physics Upstream and Downstream Of Transcriptional Networkmentioning

confidence: 99%

“…Recent functional data revealed conserved mechanisms in a range of organisms from plants to mammals, which establish asymmetry without a ciliated structure, or long before it forms; indeed, many phyla including some vertebrates determine their LR axis very early after fertilization [80][81][82][83][84][85][86][87][88][89][90]. Even mouse embryos are known to exhibit molecular and functional asymmetries (e.g.…”

Section: Physics Upstream and Downstream Of Transcriptional Networkmentioning

confidence: 99%

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From cytoskeletal dynamics to organ asymmetry: a nonlinear, regulative pathway underlies left–right patterning

McDowell

Rajadurai

Levin

2016

Phil. Trans. R. Soc. B

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One contribution of 17 to a theme issue 'Provocative questions in left -right asymmetry'. Consistent left -right (LR) asymmetry is a fundamental aspect of the bodyplan across phyla, and errors of laterality form an important class of human birth defects. Its molecular underpinning was first discovered as a sequential pathway of left-and right-sided gene expression that controlled positioning of the heart and visceral organs. Recent data have revised this picture in two important ways. First, the physical origin of chirality has been identified; cytoskeletal dynamics underlie the asymmetry of single-cell behaviour and patterning of the LR axis. Second, the pathway is not linear: early disruptions that alter the normal sidedness of upstream asymmetric genes do not necessarily induce defects in the laterality of the downstream genes or in organ situs. Thus, the LR pathway is a unique example of two fascinating aspects of biology: the interplay of physics and genetics in establishing largescale anatomy, and regulative (shape-homeostatic) pathways that correct molecular and anatomical errors over time. Here, we review aspects of asymmetry from its intracellular, cytoplasmic origins to the recently uncovered ability of the LR control circuitry to achieve correct gene expression and morphology despite reversals of key 'determinant' genes. We provide novel functional data, in Xenopus laevis, on conserved elements of the cytoskeleton that drive asymmetry, and comparatively analyse it together with previously published results in the field. Our new observations and meta-analysis demonstrate that despite aberrant expression of upstream regulatory genes, embryos can progressively normalize transcriptional cascades and anatomical outcomes. LR patterning can thus serve as a paradigm of how subcellular physics and gene expression cooperate to achieve developmental robustness of a body axis.This article is part of the themed issue 'Provocative questions in leftright asymmetry'.

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“…mechanosensitive cilia, morphogen gradients or vesicular particles. More recent studies have shown that primary cilia are not in fact calcium-responsive mechanosensors [8], and that asymmetries in cleavage-stage frog embryos have not only consistently asymmetric metabolic profiles [9], but also protein components with functional roles in asymmetry development [10]. Consistent with the existence of L/R asymmetry at such an early stage of development, Dasgupta and Amack [6] used mosaic cell labelling and time-lapse imaging in the zebrafish embryo to demonstrate that ciliated cells within Kupffer's vesicle-a structure that is functionally analogous to the embryonic node and alternatively termed the 'L/R organizer'-are non-stochastically arranged, suggesting that they may be propagating L/R positional information that exists prior to L/R Organizer morphogenesis and hence, generation of directional fluid flow.…”

Section: Synopsis Of Laterality Chaptersmentioning

confidence: 99%

Introduction to provocative questions in left–right asymmetry

Levin

Klar

Ramsdell

2016

Phil. Trans. R. Soc. B

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Left–right asymmetry is a phenomenon that has a broad appeal—to anatomists, developmental biologists and evolutionary biologists—because it is a morphological feature of organisms that spans scales of size and levels of organization, from unicellular protists, to vertebrate organs, to social behaviour. Here, we highlight a number of important aspects of asymmetry that encompass several areas of biology—cell-level, physiological, genetic, anatomical and evolutionary components—and that are based on research conducted in diverse model systems, ranging from single cells to invertebrates to human developmental disorders. Together, the contributions in this issue reveal a heretofore-unsuspected variety in asymmetry mechanisms, including ancient chirality elements that could underlie a much more universal basis to asymmetry development, and provide much fodder for thought with far reaching implications in biomedical, developmental, evolutionary and synthetic biology. The new emerging theme of binary cell-fate choice, promoted by asymmetric cell division of a deterministic cell, has focused on investigating asymmetry mechanisms functioning at the single cell level. These include cytoskeleton and DNA chain asymmetry—mechanisms that are amplified and coordinated with those employed for the determination of the anterior–posterior and dorsal–ventral axes of the embryo. This article is part of the themed issue ‘Provocative questions in left–right asymmetry’.

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Single-cell mass spectrometry with multi-solvent extraction identifies metabolic differences between left and right blastomeres in the 8-cell frog (Xenopus) embryo

Cited by 79 publications

References 66 publications

Label-free Quantification of Proteins in Single Embryonic Cells with Neural Fate in the Cleavage-Stage Frog (Xenopus laevis) Embryo using Capillary Electrophoresis Electrospray Ionization High-Resolution Mass Spectrometry (CE-ESI-HRMS)

Label-free Quantification of Proteins in Single Embryonic Cells with Neural Fate in the Cleavage-Stage Frog (Xenopus laevis) Embryo using Capillary Electrophoresis Electrospray Ionization High-Resolution Mass Spectrometry (CE-ESI-HRMS)

From cytoskeletal dynamics to organ asymmetry: a nonlinear, regulative pathway underlies left–right patterning

Introduction to provocative questions in left–right asymmetry

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