Synthetic recording and in situ readout of lineage information in single cells

Frieda, Kirsten L.; Linton, Jamie; Hormoz, Sahand; Choi, Jong‐Soo; Chow, Ke-Huan K.; Singer, Zachary S.; Budde, Mark W.; Elowitz, Michael B.; Cai, Long

doi:10.1038/nature20777

Cited by 377 publications

(336 citation statements)

References 42 publications

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“…Powell, one of the pioneers of single-cells measurements, was described as sitting in a 37°C room for many hours watching bacteria divide and recording manually celldivision events [3]. Recent technological advances in microscopy and microfluidics [4,5] have boosted our ability to gather information over tens of thousands of cells and opened the door to quantitative analyses of the process of cell division on lineages [6,7].…”

Section: Introductionmentioning

confidence: 99%

Inheritance of Cell-Cycle Duration in the Presence of Periodic Forcing

et al. 2018

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Periodic forcing of nonlinear oscillators leads to a large number of dynamic behaviors. The coupling of the cell cycle to the circadian clock provides a biological realization of such forcing. A previous model of forcing leads to nontrivial relations between correlations along cell lineages. Here, we present a simplified two-dimensional nonlinear map for the periodic forcing of the cell cycle. Using high-throughput single-cell microscopy, we have studied the correlations between cell-cycle duration in discrete lineages of several different organisms, including those with known coupling to a circadian clock and those without known coupling to a circadian clock. The model reproduces the paradoxical correlations and predicts new features that can be compared with the experimental data. By fitting the model to the data, we extract the important parameters that govern the dynamics. Interestingly, the model reproduces bimodal distributions for * nathalie.balaban@mail.huji.ac.il PHYSICAL REVIEW X 8, 021035 (2018) 2160-3308=18=8(2)=021035 (15) 021035-1 Published by the American Physical Society cell-cycle duration, as well as the gating of cell division by the phase of the clock, without having been explicitly fed into the model. In addition, the model predicts that circadian coupling may increase cell-tocell variability in a clonal population of cells. In agreement with this prediction, deletion of the circadian clock reduces variability. Our results show that simple correlations can identify systems under periodic forcing and that studies of nonlinear coupling of biological oscillators provide insight into basic cellular processes of growth.

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Section: Introductionmentioning

confidence: 99%

Inheritance of Cell-Cycle Duration in the Presence of Periodic Forcing

et al. 2018

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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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“…Michael Elowitz and Long Cai, both at the California Institute of Technology in Pasadena, have developed a lineage tracer that creates fluorescent probes to help them observe the histories of cells as they develop 8 . Their method can track whether certain developmental genes have been turned on in the past for a given lineage.…”

Section: From Blobs To Barcodesmentioning

confidence: 99%

The trickiest family tree in biology

Callaway

2017

Nature

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Synthetic recording and in situ readout of lineage information in single cells

Cited by 377 publications

References 42 publications

Inheritance of Cell-Cycle Duration in the Presence of Periodic Forcing

Inheritance of Cell-Cycle Duration in the Presence of Periodic Forcing

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

The trickiest family tree in biology

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