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Synthetic Biology underpins advances in the bioeconomy

Biological systems - including the simplest cells - exhibit a broad range of functions to thrive in their environment. Research in the Imperial College Centre for Synthetic Biology is focused on the possibility of engineering the underlying biochemical processes to solve many of the challenges facing society, from healthcare to sustainable energy. In particular, we model, analyse, design and build biological and biochemical systems in living cells and/or in cell extracts, both exploring and enhancing the engineering potential of biology. 

As part of our research we develop novel methods to accelerate the celebrated Design-Build-Test-Learn synthetic biology cycle. As such research in the Centre for Synthetic Biology highly multi- and interdisciplinary covering computational modelling and machine learning approaches; automated platform development and genetic circuit engineering ; multi-cellular and multi-organismal interactions, including gene drive and genome engineering; metabolic engineering; in vitro/cell-free synthetic biology; engineered phages and directed evolution; and biomimetics, biomaterials and biological engineering.

Publications

Citation

BibTex format

@article{Grob:2018:10.1007/978-1-4939-7768-0_16,
author = {Grob, A and Marbiah, MM and Isalan, M},
doi = {10.1007/978-1-4939-7768-0_16},
journal = {Methods in Molecular Biology},
pages = {285--301},
title = {Functional insulator scanning of CpG islands to identify regulatory regions of promoters using CRISPR},
url = {http://dx.doi.org/10.1007/978-1-4939-7768-0_16},
volume = {1766},
year = {2018}
}

RIS format (EndNote, RefMan)

TY  - JOUR
AB - The ability to mutate a promoter in situ is potentially a very useful approach for gaining insights into endogenous gene regulation mechanisms. The advent of CRISPR/Cas systems has provided simple, efficient, and targeted genetic manipulation in eukaryotes, which can be applied to studying genome structure and function.The basic CRISPR toolkit comprises an endonuclease, Cas9, and a short DNA-targeting sequence, made up of a single guide RNA (sgRNA). The catalytic domains of Cas9 are rendered active upon dimerization of Cas9 with sgRNA, resulting in targeted double stranded DNA breaks. Among other applications, this method of DNA cleavage can be coupled to endogenous homology-directed repair (HDR) mechanisms for the generation of site-specific editing or knockin mutations, at both promoter regulatory and gene coding sequences.A well-characterized regulatory feature of promoter regions is the high abundance of CpGs. These CpG islands tend to be unmethylated, ensuring a euchromatic environment that promotes gene transcription. Here, we demonstrate CRISPR-mediated editing of two CpG islands located within the promoter region of the MDR1 gene (Multi Drug Resistance 1). Cas9 is used to generate double stranded breaks across multiple target sites, which are then repaired while inserting the beta globin (β-globin) insulator, 5′HS5. Thus, we are screening through promoter regulatory sequences with a chromatin barrier element to identify functional regions via “insulator scanning.” Transcriptional and functional assessment of MDR1 expression provides evidence of genome engineering. Overall, this method allows the scanning of CpG islands to identify their promoter functions.
AU - Grob,A
AU - Marbiah,MM
AU - Isalan,M
DO - 10.1007/978-1-4939-7768-0_16
EP - 301
PY - 2018///
SN - 1940-6029
SP - 285
TI - Functional insulator scanning of CpG islands to identify regulatory regions of promoters using CRISPR
T2 - Methods in Molecular Biology
UR - http://dx.doi.org/10.1007/978-1-4939-7768-0_16
UR - http://hdl.handle.net/10044/1/56918
VL - 1766
ER -

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Work in the IC-CSynB is supported by a wide range of Research Councils, Learned Societies, Charities and more.