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Tracking single-cell gene regulation in dynamically controlled environments using an integrated microfluidic and computational setup

Authors :
Olin K. Silander
Gene Myers
Siddharth Deshpande
Marcel Kaiser
Nimwegen Ev
Florian Jug
Thomas Pfohl
Thomas Julou
Publication Year :
2016
Publisher :
Cold Spring Harbor Laboratory, 2016.

Abstract

Bacteria adapt to changes in their environment by regulating gene expression, often at the level of transcription. However, since the molecular processes underlying gene regulation are subject to thermodynamic and other stochastic fluctuations, gene expression is inherently noisy, and identical cells in a homogeneous environment can display highly heterogeneous expression levels. To study how stochasticity affects gene regulation at the single-cell level, it is crucial to be able to directly follow gene expression dynamics in single cells under changing environmental conditions. Recently developed microfluidic devices, used in combination with quantitative fluorescence time-lapse microscopy, represent a highly promising experimental approach, allowing tracking of lineages of single cells over long time-scales while simultaneously measuring their growth and gene expression. However, current devices do not allow controlled dynamical changes to the environmental conditions which are needed to study gene regulation. In addition, automated analysis of the imaging data from such devices is still highly challenging and no standard software is currently available. To address these challenges, we here present an integrated experimental and computational setup featuring, on the one hand, a new dual-input microfluidic chip which allows mixing and switching between two growth media and, on the other hand, a novel image analysis software which jointly optimizes segmentation and tracking of the cells and allows interactive user-guided fine-tuning of its results. To demonstrate the power of our approach, we study the lac operon regulation in E. coli cells grown in an environment that switches between glucose and lactose, and quantify stochastic lag times and memory at the single cell level.

Details

Database :
OpenAIRE
Accession number :
edsair.doi.dedup.....36f943a29ae22b38f02b1bbfe70008ee
Full Text :
https://doi.org/10.1101/076224