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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{MacDonald:2013:10.1371/journal.pone.0065770,
author = {MacDonald, JT and Kelley, LA and Freemont, PS},
doi = {10.1371/journal.pone.0065770},
journal = {PLOS One},
title = {Validating a Coarse-Grained Potential Energy Function through Protein Loop Modelling},
url = {http://dx.doi.org/10.1371/journal.pone.0065770},
volume = {8},
year = {2013}
}

RIS format (EndNote, RefMan)

TY  - JOUR
AB - Coarse-grained (CG) methods for sampling protein conformational space have the potential to increase computational efficiency by reducing the degrees of freedom. The gain in computational efficiency of CG methods often comes at the expense of non-protein like local conformational features. This could cause problems when transitioning to full atom models in a hierarchical framework. Here, a CG potential energy function was validated by applying it to the problem of loop prediction. A novel method to sample the conformational space of backbone atoms was benchmarked using a standard test set consisting of 351 distinct loops. This method used a sequence-independent CG potential energy function representing the protein using -carbon positions only and sampling conformations with a Monte Carlo simulated annealing based protocol. Backbone atoms were added using a method previously described and then gradient minimised in the Rosetta force field. Despite the CG potential energy function being sequence-independent, the method performed similarly to methods that explicitly use either fragments of known protein backbones with similar sequences or residue-specific /-maps to restrict the search space. The method was also able to predict with sub-Angstrom accuracy two out of seven loops from recently solved crystal structures of proteins with low sequence and structure similarity to previously deposited structures in the PDB. The ability to sample realistic loop conformations directly from a potential energy function enables the incorporation of additional geometric restraints and the use of more advanced sampling methods in a way that is not possible to do easily with fragment replacement methods and also enable multi-scale simulations for protein design and protein structure prediction. These restraints could be derived from experimental data or could be design restraints in the case of computational protein design. C++ source code is available for download from http://www.sbg.
AU - MacDonald,JT
AU - Kelley,LA
AU - Freemont,PS
DO - 10.1371/journal.pone.0065770
PY - 2013///
SN - 1932-6203
TI - Validating a Coarse-Grained Potential Energy Function through Protein Loop Modelling
T2 - PLOS One
UR - http://dx.doi.org/10.1371/journal.pone.0065770
UR - http://hdl.handle.net/10044/1/33137
VL - 8
ER -

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