Developing novel optogenetic tools in Caenorhabditis elegans
dc.contributor.advisor
Wallace, Stephen
dc.contributor.advisor
Greiss, Sebastian
dc.contributor.author
Baxter, Kieran Garry
dc.date.accessioned
2023-02-14T17:11:49Z
dc.date.available
2023-02-14T17:11:49Z
dc.date.issued
2023-02-14
dc.description.abstract
Proteins are biopolymers constructed from 20 canonical amino acids which,
while limited in number, work together to carry out an extensive variety of
functions essential to life. Genetic code expansion allows for the site-specific
incorporation of non-canonical amino acids with novel functions not found in
nature, creating proteins with unique properties that can be applied to tasks
that are otherwise unachievable.
Photocaged amino acids contain a bulky ’caging’ group conjugated to the
side chain of a canonical amino acid. This caging group can render the protein
inactive by blocking its active site, but can be rapidly removed by illumination
with 365 nm light, restoring the canonical amino acid and allowing for the photoactivation
of the protein. Photocaged amino acids have been previously used in
Caenorhabditis elegans to develop tools for controlling gene expression, apoptosis,
and protein-protein interactions. In this thesis, I give a general introduction on
genetic code expansion and the use of photocaged amino acids, as well as the use
of C. elegans as a model organism. I then explore the use of photocaged amino
acids in developing optogenetic tools in C. elegans.
The main focus of this thesis is the development of a photocaged FLP
recombinase which can drive gene expression with high spatiotemporal control. I
show that this can be done in two ways, by photocaging either the catalytic lysine
residue, or the catalytic tyrosine residue. In both cases, expression of a target
gene is inhibited by the use of an FRT-flanked transcriptional terminator, which
can be excised by the photoactivated FLP to drive gene expression with single-cell
resolution. This system provides a valuable tool for the study of functions of cells
that could not be targeted by other methods. We demonstrate this by using
photocaged FLP to drive expression of a channelrhodopsin in the PVC neurons,
which do not have their own cell-specific promoter, allowing us to study the
contributions of the PVCs in locomotion and sleep.
I also discuss the use of photocaged amino acids in the generation of genetargeted
random mutagenesis tools, an area of genetic screening that is so far
underutilised in C. elegans. These tools are designed to be targeted to a specific
gene of interest and generate a random set of mutations in the area, which would
facilitate the study of that gene in reverse genetics experiments.
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dc.identifier.uri
https://hdl.handle.net/1842/39847
dc.identifier.uri
http://dx.doi.org/10.7488/era/3095
dc.language.iso
en
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dc.publisher
The University of Edinburgh
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dc.subject
optogenetic tools
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dc.subject
Caenorhabditis elegans
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dc.subject
biopolymers
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dc.subject
Genetic code expansion
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dc.subject
non-canonical amino acids
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dc.subject
Photocaged
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dc.subject
Photocaged amino acids
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dc.subject
caging
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dc.subject
photocaged FLP recombinase
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dc.subject
spatiotemporal control
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dc.subject
catalytic lysine residue
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dc.subject
catalytic tyrosine residue
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dc.subject
photoactivated FLP
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dc.subject
PVC neurons
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dc.subject
FRT-flanked transcriptional terminator
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dc.title
Developing novel optogenetic tools in Caenorhabditis elegans
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dc.type
Thesis or Dissertation
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dc.type.qualificationlevel
Doctoral
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dc.type.qualificationname
PhD Doctor of Philosophy
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