Optogenetic dissection of transcriptional repression in a multicellular organism

Jiaxi Zhao; Nicholas C. Lammers; Simon Alamos; Yang Joon Kim; Gabriella Martini; Hernan G. Garcia

doi:10.1038/s41467-024-53539-0

Optogenetic dissection of transcriptional repression in a multicellular organism

Jiaxi Zhao
, Nicholas C. Lammers
, Simon Alamos
, Yang Joon Kim
, Gabriella Martini
, Hernan G. Garcia

University of California at Berkeley
Harvard University
Brigham and Women’s Hospital
University of Washington
United States Department of Energy
Lawrence Berkeley National Laboratory
California Institute for Quantitative Biosciences
Chan Zuckerberg Biohub

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

4 Citas (Scopus)

Resumen

Transcriptional control is fundamental to cellular function. However, despite knowing that transcription factors can repress or activate specific genes, how these functions are implemented at the molecular level has remained elusive, particularly in the endogenous context of developing animals. Here, we combine optogenetics, single-cell live-imaging, and mathematical modeling to study how a zinc-finger repressor, Knirps, induces switch-like transitions into long-lived quiescent states. Using optogenetics, we demonstrate that repression is rapidly reversible (~1 min) and memoryless. Furthermore, we show that the repressor acts by decreasing the frequency of transcriptional bursts in a manner consistent with an equilibrium binding model. Our results provide a quantitative framework for dissecting the in vivo biochemistry of eukaryotic transcriptional regulation.

Idioma original	Inglés
Número de artículo	9263
Publicación	Nature Communications
Volumen	15
N.º	1
DOI	https://doi.org/10.1038/s41467-024-53539-0
Estado	Publicada - dic. 2024
Publicado de forma externa	Sí

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title = "Optogenetic dissection of transcriptional repression in a multicellular organism",

abstract = "Transcriptional control is fundamental to cellular function. However, despite knowing that transcription factors can repress or activate specific genes, how these functions are implemented at the molecular level has remained elusive, particularly in the endogenous context of developing animals. Here, we combine optogenetics, single-cell live-imaging, and mathematical modeling to study how a zinc-finger repressor, Knirps, induces switch-like transitions into long-lived quiescent states. Using optogenetics, we demonstrate that repression is rapidly reversible (\textasciitilde{}1 min) and memoryless. Furthermore, we show that the repressor acts by decreasing the frequency of transcriptional bursts in a manner consistent with an equilibrium binding model. Our results provide a quantitative framework for dissecting the in vivo biochemistry of eukaryotic transcriptional regulation.",

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T1 - Optogenetic dissection of transcriptional repression in a multicellular organism

AU - Zhao, Jiaxi

AU - Lammers, Nicholas C.

AU - Alamos, Simon

AU - Kim, Yang Joon

AU - Martini, Gabriella

AU - Garcia, Hernan G.

PY - 2024/12

Y1 - 2024/12

N2 - Transcriptional control is fundamental to cellular function. However, despite knowing that transcription factors can repress or activate specific genes, how these functions are implemented at the molecular level has remained elusive, particularly in the endogenous context of developing animals. Here, we combine optogenetics, single-cell live-imaging, and mathematical modeling to study how a zinc-finger repressor, Knirps, induces switch-like transitions into long-lived quiescent states. Using optogenetics, we demonstrate that repression is rapidly reversible (~1 min) and memoryless. Furthermore, we show that the repressor acts by decreasing the frequency of transcriptional bursts in a manner consistent with an equilibrium binding model. Our results provide a quantitative framework for dissecting the in vivo biochemistry of eukaryotic transcriptional regulation.

AB - Transcriptional control is fundamental to cellular function. However, despite knowing that transcription factors can repress or activate specific genes, how these functions are implemented at the molecular level has remained elusive, particularly in the endogenous context of developing animals. Here, we combine optogenetics, single-cell live-imaging, and mathematical modeling to study how a zinc-finger repressor, Knirps, induces switch-like transitions into long-lived quiescent states. Using optogenetics, we demonstrate that repression is rapidly reversible (~1 min) and memoryless. Furthermore, we show that the repressor acts by decreasing the frequency of transcriptional bursts in a manner consistent with an equilibrium binding model. Our results provide a quantitative framework for dissecting the in vivo biochemistry of eukaryotic transcriptional regulation.

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SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

IS - 1

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ER -

Optogenetic dissection of transcriptional repression in a multicellular organism

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