Building a lineage from single cells: genetic techniques for cell lineage tracking

Woodworth, Mollie B.; Girskis, Kelly M.; Walsh, Christopher A.

doi:10.1038/nrg.2016.159

Cited by 219 publications

(181 citation statements)

References 137 publications

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“…The dynamic changes in gene expression patterns at the single cell level in response to environmental or disease conditions may provide important insights into the ongoing cellular responses and mechanisms under relevant physiological and pathological processes. However, one should be cautious in interpreting whether a molecular profile corresponds to a cell type or a cell state [33, 37, 38]. The former refers to a unique, molecular signature that remains stable under different conditions, throughout development and into adulthood, while the latter corresponds to a more dynamic set of genes that shift their expression in response to different signaling stimuli.…”

Section: Transcriptomic Studies Unveil Therapeutically Relevant Targementioning

confidence: 99%

Single-Cell RNA Sequencing: Unraveling the Brain One Cell at a Time

Ofengeim

Γιαγτζόγλου

Huh

et al. 2017

Trends in Molecular Medicine

118

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Single cell RNA sequencing (scRNA-seq) is an exciting new technology allowing the analysis of transcriptomes from individual cells, and is ideally suited to address the inherent complexity and dynamics of the central nervous system. ScRNA-seq has already been applied to the study of molecular taxonomy of the brain. This work has paved the way to expanding our understanding of nervous systems and to providing insights into cellular susceptibilities and molecular mechanisms in neurological and neurodegenerative diseases. Here, we discuss the recent progress and the challenges in applying this technology to advance our understanding of the brain. We favor the application of scRNA-seq in the discovery of targets and biomarkers as a new approach in developing novel therapeutics for the treatment of neurodegenerative diseases.

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Section: Transcriptomic Studies Unveil Therapeutically Relevant Targementioning

confidence: 99%

Single-Cell RNA Sequencing: Unraveling the Brain One Cell at a Time

Ofengeim

Γιαγτζόγλου

Huh

et al. 2017

Trends in Molecular Medicine

118

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“…Most of these methods have been applied to Drosophila (1418) and zebrafish (1921) embryogenesis, or plant morphogenesis (22) studies. Of special relevance to the field of stem cell biology is the ability to integrate the cell behavior analysis with information about lineage (parentprogeny) and contextual (neighborhood) cellular relationships (9,11). In the last decade, several generic processing and tracking packages, such as Icy (23), Cell Profiler (24), tTt (25), qTfy (25), or the Fiji plugin TrackMate (26,27) have been reported.…”

mentioning

confidence: 99%

“…Moreover, a new generation of fluorescent proteins and dyes allows biochemical characterization of signaling pathways in intact living cells (8). Tagging by fluorescent proteins enables positional tracking of any given cell over time, which is easily achieved when the population of tagged cells is distributed among non-expressing cells by virtue of lineage or in experimental mosaics, but it becomes challenging when a fluorescent protein label is widely expressed (9). The ability to track and analyze live cells in time-lapse 4-D microscopy images is a matter of intense research (10,11) since visual inspection and analysis are insufficient to extract meaningful insights, making automated tracking and quantitative analysis of cells an absolute requirement.…”

mentioning

confidence: 99%

ESC-Track: A Computer Workflow for 4-D Segmentation, Tracking, Lineage Tracing and Dynamic Context Analysis of ESCs

Fernandez-de-Manuel¹,

Díaz-Díaz

Jiménez-Carretero³

et al. 2017

BioTechniques

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Embryonic stem cells (ESCs) can be established as permanent cell lines, and their potential to differentiate into adult tissues has led to widespread use for studying the mechanisms and dynamics of stem cell differentiation and exploring strategies for tissue repair. Imaging live ESCs during development is now feasible due to advances in optical imaging and engineering of genetically encoded fluorescent reporters; however, a major limitation is the low spatio-temporal resolution of long-term 3-D imaging required for generational and neighboring reconstructions. Here, we present the ESC-Track (ESC-T) workflow, which includes an automated cell and nuclear segmentation and tracking tool for 4-D (3-D + time) confocal image data sets as well as a manual editing tool for visual inspection and error correction. ESC-T automatically identifies cell divisions and membrane contacts for lineage tree and neighborhood reconstruction and computes quantitative features from individual cell entities, enabling analysis of fluorescence signal dynamics and tracking of cell morphology and motion. We use ESC-T to examine Myc intensity fluctuations in the context of mouse ESC (mESC) lineage and neighborhood relationships. ESC-T is a powerful tool for evaluation of the genealogical and microenvironmental cues that maintain ESC fitness.

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“…Traditionally, gene knock-outs, fluorescent labeling of endogenous genes or sensing of transcription factors or signaling pathways have been used to study essential genes that maintain the pluripotent state or lead to cell state transitions [63]. Another focus, that has recently received new attention due to the introduction of CRISPR/Cas9-based approaches [64,65], lies in developing genetic lineage tracking systems to track lineage choices in single live cells [66]. Other genetic methods have been developed to overcome challenges in producing hPSC-derived cells, most common being the defined control of key-transcription factors to manipulate hPSC transitions to differentiated cells.…”

Section: How Synthetic Decision-making Gene Circuits Can Advance Stemmentioning

confidence: 99%

Synthetic gene circuits and cellular decision-making in human pluripotent stem cells

Prochazka

Benenson

Zandstra

2017

Current Opinion in Systems Biology

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Precise manipulation of human cell fate is a long-standing goal in biological engineering; it underpins efforts to advance new cellular therapeutics, and to develop disease models for fundamental research. Human pluripotent stem cells (hPSC) are emerging as the cells of choice for many of these applications. Currently, most advanced methods for manipulation of hPSC fate involve recapitulating developmental processes by mimicking stem cell niche-associated signals. Alternately, advances in engineering synthetic decision-making gene circuits provide an approach in which cell fate is directly controlled at the gene expression level. Here, we make the case that integrating these two engineering approaches represents an exciting opportunity to advance our fundamental understanding of cell fate control, and to accelerate new engineering strategies to manipulate cellular behavior for therapy.

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Building a lineage from single cells: genetic techniques for cell lineage tracking

Cited by 219 publications

References 137 publications

Single-Cell RNA Sequencing: Unraveling the Brain One Cell at a Time

Single-Cell RNA Sequencing: Unraveling the Brain One Cell at a Time

ESC-Track: A Computer Workflow for 4-D Segmentation, Tracking, Lineage Tracing and Dynamic Context Analysis of ESCs

Synthetic gene circuits and cellular decision-making in human pluripotent stem cells

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