| De novo protein design: how do we expand into the universe of possible protein structures? DN Woolfson, GJ Bartlett, AJ Burton, JW Heal, A Niitsu, AR Thomson, ... Current opinion in structural biology 33, 16-26, 2015 | 232 | 2015 |
| ISAMBARD: an open-source computational environment for biomolecular analysis, modelling and design CW Wood, JW Heal, AR Thomson, GJ Bartlett, AÁ Ibarra, RL Brady, ... Bioinformatics 33 (19), 3043-3050, 2017 | 77 | 2017 |
| Engineering protein stability with atomic precision in a monomeric miniprotein EG Baker, C Williams, KL Hudson, GJ Bartlett, JW Heal, KL Porter Goff, ... Nature chemical biology 13 (7), 764-770, 2017 | 62 | 2017 |
| ‘Something in the way she moves’: The functional significance of flexibility in the multiple roles of protein disulfide isomerase (PDI) RB Freedman, JL Desmond, LJ Byrne, JW Heal, MJ Howard, N Sanghera, ... Biochimica et Biophysica Acta (BBA)-Proteins and Proteomics 1865 (11), 1383-1394, 2017 | 46 | 2017 |
| Does deamidation cause protein unfolding? A top‐down tandem mass spectrometry study AJ Soulby, JW Heal, MP Barrow, RA Roemer, PB O'Connor Protein Science 24 (5), 850-860, 2015 | 40 | 2015 |
| Membrane-spanning α-helical barrels as tractable protein-design targets A Niitsu, JW Heal, K Fauland, AR Thomson, DN Woolfson Philosophical Transactions of the Royal Society B: Biological Sciences 372 …, 2017 | 38 | 2017 |
| Inhibition of HIV-1 protease: the rigidity perspective JW Heal, JE Jimenez-Roldan, SA Wells, RB Freedman, RA Römer Bioinformatics 28 (3), 350-357, 2012 | 37 | 2012 |
| Applying graph theory to protein structures: an Atlas of coiled coils JW Heal, GJ Bartlett, CW Wood, AR Thomson, DN Woolfson Bioinformatics 34 (19), 3316-3323, 2018 | 24 | 2018 |
| Characterization of folding cores in the cyclophilin A-cyclosporin A complex JW Heal, SA Wells, CA Blindauer, RB Freedman, RA Römer Biophysical Journal 108 (7), 1739-1746, 2015 | 8 | 2015 |
| Rigidity analysis of HIV-1 protease JW Heal, SA Wells, E Jimenez-Roldan, RF Freedman, RA Römer Journal of Physics: Conference Series 286 (1), 012006, 2011 | 7 | 2011 |
| Effects of ligand binding on the rigidity and mobility of proteins: a computational and experimental approach JW Heal University of Warwick, 2013 | 2 | 2013 |
| ORIGINAL PAPERS Genome analysis Application of the cghRA framework to the genomic characterization of Diffuse Large B-Cell Lymphoma S. Mareschal, P. Ruminy, M. Alcantara, C … CW Wood, JW Heal, AR Thomson, GJ Bartlett, AA Ibarra, RL Brady, ... BIOINFORMATICS 33 (19), 2017 | | 2017 |
| Effects of Ligand Binding on the Rigidity and Mobility of Proteins: An Experimental and Computational Approach J Heal, C Blindauer, RB Freedman, R Roemer Biophysical Journal 106 (2), 658a, 2014 | | 2014 |
| Experimental and Computational Studies on the Dynamics and Flexibility of Protein Disulfide-Isomerase (PDI) RB Freedman, J Blood, D Clarke, J Heal, E Jimenez-Roldan, R Roemer, ... Biophysical Journal 106 (2), 246a, 2014 | | 2014 |
| Characterizing the folding core of the cyclophilin A—cyclosporin A complex II: improving folding core predictions by including mobility JW Heal, SA Wells, RB Freedman, RA Römer Biophysical Journal, 2014 | | 2014 |
| Effects of Ligand Binding on the Rigidity and Mobility of Proteins: an Experimental and Computational Approach: 437 JW Heal, SA Wells, CA Blindauer, RA Römer, RB Freedman Protein Science 22, 155-156, 2013 | | 2013 |
| The effects of ligand binding on protein structure and rigidity: studies with HIV-1 protease and cyclophilin A: P20-214 JW Heal, E Jimenez-Roldan, S Wells, R Freedman, R Roemer FEBS Journal, The 279, 472, 2012 | | 2012 |
| (2017). Membrane-spanning-helical barrels as tractable protein-design targets. Philosophical Transactions B: Biological Sciences, 372 (1726),[20160213]. https://doi. org/10 … A Niitsu, JW Heal, K Fauland, AR Thomson, DN Woolfson | | |
| 246a Monday, February 17, 2014 RB Freedman, J Blood, D Clarke, J Heal, E Jimenez-Roldan, R Roemer, ... | | |
Rudolf A RömerProfessor of Physics, University of WarwickVerified email at warwick.ac.uk
