Digital signaling decouples activation probability and population heterogeneity

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Digital signaling decouples activation probability and population heterogeneity. / Kellogg, Ryan A; Tian, Chengzhe; Lipniacki, Tomasz; Quake, Stephen R; Tay, Savaş.

In: eLife, Vol. 4, e08931, 2015.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Kellogg, RA, Tian, C, Lipniacki, T, Quake, SR & Tay, S 2015, 'Digital signaling decouples activation probability and population heterogeneity', eLife, vol. 4, e08931. https://doi.org/10.7554/eLife.08931

APA

Kellogg, R. A., Tian, C., Lipniacki, T., Quake, S. R., & Tay, S. (2015). Digital signaling decouples activation probability and population heterogeneity. eLife, 4, [e08931]. https://doi.org/10.7554/eLife.08931

Vancouver

Kellogg RA, Tian C, Lipniacki T, Quake SR, Tay S. Digital signaling decouples activation probability and population heterogeneity. eLife. 2015;4. e08931. https://doi.org/10.7554/eLife.08931

Author

Kellogg, Ryan A ; Tian, Chengzhe ; Lipniacki, Tomasz ; Quake, Stephen R ; Tay, Savaş. / Digital signaling decouples activation probability and population heterogeneity. In: eLife. 2015 ; Vol. 4.

Bibtex

@article{9be6622b9cbf4a34b5b2926a44d1f595,
title = "Digital signaling decouples activation probability and population heterogeneity",
abstract = "Digital signaling enhances robustness of cellular decisions in noisy environments, but it is unclear how digital systems transmit temporal information about a stimulus. To understand how temporal input information is encoded and decoded by the NF-κB system, we studied transcription factor dynamics and gene regulation under dose- and duration-modulated inflammatory inputs. Mathematical modeling predicted and microfluidic single-cell experiments confirmed that integral of the stimulus (or area, concentration × duration) controls the fraction of cells that activate NF-κB in the population. However, stimulus temporal profile determined NF-κB dynamics, cell-to-cell variability, and gene expression phenotype. A sustained, weak stimulation lead to heterogeneous activation and delayed timing that is transmitted to gene expression. In contrast, a transient, strong stimulus with the same area caused rapid and uniform dynamics. These results show that digital NF-κB signaling enables multidimensional control of cellular phenotype via input profile, allowing parallel and independent control of single-cell activation probability and population heterogeneity.",
author = "Kellogg, {Ryan A} and Chengzhe Tian and Tomasz Lipniacki and Quake, {Stephen R} and Sava{\c s} Tay",
year = "2015",
doi = "10.7554/eLife.08931",
language = "English",
volume = "4",
journal = "eLife",
issn = "2050-084X",
publisher = "eLife Sciences Publications Ltd.",

}

RIS

TY - JOUR

T1 - Digital signaling decouples activation probability and population heterogeneity

AU - Kellogg, Ryan A

AU - Tian, Chengzhe

AU - Lipniacki, Tomasz

AU - Quake, Stephen R

AU - Tay, Savaş

PY - 2015

Y1 - 2015

N2 - Digital signaling enhances robustness of cellular decisions in noisy environments, but it is unclear how digital systems transmit temporal information about a stimulus. To understand how temporal input information is encoded and decoded by the NF-κB system, we studied transcription factor dynamics and gene regulation under dose- and duration-modulated inflammatory inputs. Mathematical modeling predicted and microfluidic single-cell experiments confirmed that integral of the stimulus (or area, concentration × duration) controls the fraction of cells that activate NF-κB in the population. However, stimulus temporal profile determined NF-κB dynamics, cell-to-cell variability, and gene expression phenotype. A sustained, weak stimulation lead to heterogeneous activation and delayed timing that is transmitted to gene expression. In contrast, a transient, strong stimulus with the same area caused rapid and uniform dynamics. These results show that digital NF-κB signaling enables multidimensional control of cellular phenotype via input profile, allowing parallel and independent control of single-cell activation probability and population heterogeneity.

AB - Digital signaling enhances robustness of cellular decisions in noisy environments, but it is unclear how digital systems transmit temporal information about a stimulus. To understand how temporal input information is encoded and decoded by the NF-κB system, we studied transcription factor dynamics and gene regulation under dose- and duration-modulated inflammatory inputs. Mathematical modeling predicted and microfluidic single-cell experiments confirmed that integral of the stimulus (or area, concentration × duration) controls the fraction of cells that activate NF-κB in the population. However, stimulus temporal profile determined NF-κB dynamics, cell-to-cell variability, and gene expression phenotype. A sustained, weak stimulation lead to heterogeneous activation and delayed timing that is transmitted to gene expression. In contrast, a transient, strong stimulus with the same area caused rapid and uniform dynamics. These results show that digital NF-κB signaling enables multidimensional control of cellular phenotype via input profile, allowing parallel and independent control of single-cell activation probability and population heterogeneity.

U2 - 10.7554/eLife.08931

DO - 10.7554/eLife.08931

M3 - Journal article

C2 - 26488364

VL - 4

JO - eLife

JF - eLife

SN - 2050-084X

M1 - e08931

ER -

ID: 146663488