Regulation of transcription dynamics in single cells
Details
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State: Public
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State: Public
Version: After imprimatur
Serval ID
serval:BIB_722D3D16077B
Type
PhD thesis: a PhD thesis.
Collection
Publications
Institution
Title
Regulation of transcription dynamics in single cells
Director(s)
Pelet Serge
Codirector(s)
Martin Sophie
Institution details
Université de Lausanne, Faculté de biologie et médecine
Address
Ecole Doctorale
bâtiment Amphipôle - bureau 306
Quartier UNIL-Sorge
1015 Lausanne
bâtiment Amphipôle - bureau 306
Quartier UNIL-Sorge
1015 Lausanne
Publication state
Accepted
Issued date
18/01/2018
Language
english
Number of pages
236
Abstract
In mammalian cells, the MAPK pathways regulate vital processes such as
differentiation, growth or death in response to a wide array of stimuli, like hormones or stresses.
To achieve this, they interpret extracellular cues and reprogram the cell transiently or on longterm,
through the transcriptional regulation of target genes. Understand the regulation of the
MAPK signaling and resulting transcription is of high importance because of the involvement
of mis-regulation of these pathways in many diseases (cancer, diabetes, cardiovascular
diseases). As these signaling cascades are conserved among various organisms, we study them
in the budding yeast Saccharomyces cerevisiae. This widely used model organism possesses its
own MAPK network, and is easy to genetically modify.
The transcription is a crucial process in cellular life, as it drives the production of
proteins involved in all possible aspects of life. As such, it is highly regulated through complex
combination of factors. Moreover, the transcription is a dynamic process that can occur either
continuously or in a bursty manner. These bursts can be variable in their frequencies and
duration, leading to various mRNA productions within cells from a clonal population. Hence,
the transcription regulation needs to be studied at the single cell level and in real-time.
To this purpose, we developed a new kind of gene expression reporters able to quantify
in real-time and at the single cell level the expression arising from a promoter, that we named
dPSTR. Using this system, we measured the extremely fast and transient gene expression
resulting from hyper osmotic stress, and observed a difference on the sub-minute timescale in
gene induction. Then, we used the dPSTR to quantify gene expression triggered by the mating
signaling. We found that despite a signaling activity occurring minutes after addition of
exogenous pheromone, resulting gene expression occurs on different timescales. Finally, by
means of genetic analysis and modification of endogenous promoters, we defined some rules
governing the expression kinetics of mating-induced genes.
differentiation, growth or death in response to a wide array of stimuli, like hormones or stresses.
To achieve this, they interpret extracellular cues and reprogram the cell transiently or on longterm,
through the transcriptional regulation of target genes. Understand the regulation of the
MAPK signaling and resulting transcription is of high importance because of the involvement
of mis-regulation of these pathways in many diseases (cancer, diabetes, cardiovascular
diseases). As these signaling cascades are conserved among various organisms, we study them
in the budding yeast Saccharomyces cerevisiae. This widely used model organism possesses its
own MAPK network, and is easy to genetically modify.
The transcription is a crucial process in cellular life, as it drives the production of
proteins involved in all possible aspects of life. As such, it is highly regulated through complex
combination of factors. Moreover, the transcription is a dynamic process that can occur either
continuously or in a bursty manner. These bursts can be variable in their frequencies and
duration, leading to various mRNA productions within cells from a clonal population. Hence,
the transcription regulation needs to be studied at the single cell level and in real-time.
To this purpose, we developed a new kind of gene expression reporters able to quantify
in real-time and at the single cell level the expression arising from a promoter, that we named
dPSTR. Using this system, we measured the extremely fast and transient gene expression
resulting from hyper osmotic stress, and observed a difference on the sub-minute timescale in
gene induction. Then, we used the dPSTR to quantify gene expression triggered by the mating
signaling. We found that despite a signaling activity occurring minutes after addition of
exogenous pheromone, resulting gene expression occurs on different timescales. Finally, by
means of genetic analysis and modification of endogenous promoters, we defined some rules
governing the expression kinetics of mating-induced genes.
Create date
18/01/2018 10:51
Last modification date
20/08/2019 15:30