Genome editing using site-specific nucleases: targeting highly expressed genomic regions for robust transgene expression and genetic analysis
dc.contributor.advisor
Boyd, Chris
en
dc.contributor.advisor
Gilbert, Nicholas
en
dc.contributor.advisor
Wood, Andrew
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dc.contributor.author
Tennant, Peter Andrew
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dc.contributor.sponsor
Medical Research Council (MRC)
en
dc.date.accessioned
2017-07-17T14:34:46Z
dc.date.available
2017-07-17T14:34:46Z
dc.date.issued
2016-07-02
dc.description.abstract
Integration and expression of exogenous genetic material – in particular, transgenes –
into the genomes of model organisms, cell lines or patients is widely used for the
creation of genetically modified experimental systems and gene therapy. However,
loss of transgene expression due to silencing is still a major hurdle which remains to
be overcome. Judicious selection of integration loci can help alleviate the risk of
silencing; in recent years the ability to efficiently and specifically target transgene
integration has been improved by the advent of site-specific nucleases (SSNs). SSNs
can be used to generate double strand breaks (DSBs) in a targeted manner, which
increases the efficiency of homologous recombination (HR) mediated transgene
integration into predetermined loci. In this work I investigate four human genomic
loci for their potential to act as transgene integration sites which will support robust
long term expression: the adeno-associated virus (AAV) integration site 1 (AAVS1);
the human homologue of the mouse Rosa26 locus (hROSA26); the inosine
monophosphate dehydrogenase 2 (IMPDH2) gene and the eukaryotic translation
elongation factor 1 alpha 1 (EEF1A1) gene. I also investigate the potential of
creating a novel drug-selectable transgene integration system at the IMPDH2 locus to
allow for rapid and specific selection of correctly inserted transgenes.
In addition to their ability to drive targeted transgene integration, SSNs can be
harnessed to specifically disrupt gene function through indel formation following
erroneous repair of the induced DSB. Using this strategy, I aimed to answer some
important biological questions about eukaryotic translation elongation factor 1 alpha
(eEF1A); eEF1A is responsible for providing aminoacylated tRNAs to the ribosome
during the elongation phase of protein synthesis. Humans and other vertebrates
express two isoforms, eEF1A1 and eEF1A2 (encoded by EEF1A1 and EEF1A2
respectively). During development eEF1A1 is replaced by eEF1A2 in some tissues.
The reasons for this remain elusive, but one explanation may lie in the moonlighting
functions of eEF1A1, which may not be shared by eEF1A2. Additionally, eEF1A2
can act as an oncogene, while there is no evidence that eEF1A1 is overexpressed in
tumours. To begin to untangle these issues I targeted EEF1A1 using SSNs with the
aim of making a cell line expressing only the eEF1A2 isoform. This work suggests
that eEF1A1 may be essential even in the presence of eEF1A2, though further
studies will be required to confirm this.
en
dc.identifier.uri
http://hdl.handle.net/1842/22857
dc.language.iso
en
dc.publisher
The University of Edinburgh
en
dc.subject
TALENs
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dc.subject
CRISPR/Cas9
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dc.subject
transgene
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dc.subject
EEF1A1
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dc.subject
IMPDH2
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dc.subject
hROSA26
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dc.title
Genome editing using site-specific nucleases: targeting highly expressed genomic regions for robust transgene expression and genetic analysis
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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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