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2. KIF—Key Interactions Finder: A program to identify the key molecular interactions that regulate protein conformational changes.

Author

Crean, Rory M., Slusky, Joanna S. G., Kasson, Peter M., and Kamerlin, Shina Caroline Lynn

Subjects
*MOLECULAR interactions, *MOLECULAR dynamics, *PROTEIN-tyrosine phosphatase, *PHOSPHOPROTEIN phosphatases, *PROTEIN conformation, *PYTHON programming language
Abstract

Simulation datasets of proteins (e.g., those generated by molecular dynamics simulations) are filled with information about how a non-covalent interaction network within a protein regulates the conformation and, thus, function of the said protein. Most proteins contain thousands of non-covalent interactions, with most of these being largely irrelevant to any single conformational change. The ability to automatically process any protein simulation dataset to identify non-covalent interactions that are strongly associated with a single, defined conformational change would be a highly valuable tool for the community. Furthermore, the insights generated from this tool could be applied to basic research, in order to improve understanding of a mechanism of action, or for protein engineering, to identify candidate mutations to improve/alter the functionality of any given protein. The open-source Python package Key Interactions Finder (KIF) enables users to identify those non-covalent interactions that are strongly associated with any conformational change of interest for any protein simulated. KIF gives the user full control to define the conformational change of interest as either a continuous variable or categorical variable, and methods from statistics or machine learning can be applied to identify and rank the interactions and residues distributed throughout the protein, which are relevant to the conformational change. Finally, KIF has been applied to three diverse model systems (protein tyrosine phosphatase 1B, the PDZ3 domain, and the KE07 series of Kemp eliminases) in order to illustrate its power to identify key features that regulate functionally important conformational dynamics. [ABSTRACT FROM AUTHOR]

Published
2023
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6. Specificity of bispecific T cell receptors and antibodies targeting peptide-HLA

Author

Holland, Christopher J., Crean, Rory M., Pentier, Johanne M., de WeAngharad Lloyd, Ben, Srikannathasan, Velupillai, Lissin, Nikolai, Lloyd, Katy A., Blicher, Thomas H., Conroy, Paul J., Hock, Miriam, Pengelly, Robert J., Spinner, Thomas E., Cameron, Brian, Potter, Elizabeth A., Jeyanthan, Anitha, Molloy, Peter E., Sami, Malkit, Aleksic, Milos, Liddy, Nathaniel, Robinson, Ross A., Harper, Stephen, Lepore, Marco, Pudney, Chris R., van der Kamp, Marc W., Rizkallah, Pierre J., Jakobsen, Bent K., and Cole, Annelise Vuidepoand David K.

Subjects
Peptides -- Health aspects, Antibodies -- Health aspects, Antigenic determinants -- Health aspects, HLA antigens -- Health aspects, T cells -- Health aspects, Antigens, Cancer treatment, Cancer, Reagents, Tumors, Health care industry
Abstract

Tumor-associated peptide-human leukocyte antigen complexes (pHLAs) represent the largest pool of cell surface-expressed cancer-specific epitopes, making them attractive targets for cancer therapies. Soluble bispecific molecules that incorporate an anti-CD3 effector function are being developed to redirect T cells against these targets using 2 different approaches. The first achieves pHLA recognition via affinity-enhanced versions of natural TCRs (e.g., immune-mobilizing monoclonal T cell receptors against cancer [ImmTAC] molecules), whereas the second harnesses an antibody-based format (TCR-mimic antibodies). For both classes of reagent, target specificity is vital, considering the vast universe of potential pHLA molecules that can be presented on healthy cells. Here, we made use of structural, biochemical, and computational approaches to investigate the molecular rules underpinning the reactivity patterns of pHLA-targeting bispecifics. We demonstrate that affinity-enhanced TCRs engage pHLA using a comparatively broad and balanced energetic footprint, with interactions distributed over several HLA and peptide side chains. As ImmTAC molecules, these TCRs also retained a greater degree of pHLA selectivity, with less off-target activity in cellular assays. Conversely, TCR-mimic antibodies tended to exhibit binding modes focused more toward hot spots on the HLA surface and exhibited a greater degree of crossreactivity. Our findings extend our understanding of the basic principles that underpin pHLA selectivity and exemplify a number of molecular approaches that can be used to probe the specificity of pHLA-targeting molecules, aiding the development of future reagents., Introduction The ability to selectively target tumor-specific antigens holds great promise for the development of specific cancer treatments, but their identification remains a key challenge. Peptide fragments presented on the [...]

Published
2020
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7. Promiscuous recognition of MR1 drives self-reactive Mucosal-Associated Invariant T cell responses

Author

Chancellor, Andrew, Simmons, Robert Alan, Crean, Rory M, Van der Kamp, Marc W, De Libero , Gennaro, and Lepore, Marco

Abstract

Mucosal-associated invariant T (MAIT) cells use canonical semi-invariant T cell receptors (TCR) to recognize microbial riboflavin precursors displayed by the antigen-presenting molecule MR1. The extent of MAIT TCR crossreactivity toward physiological, microbially unrelated antigens remains underexplored. We describe MAIT TCRs endowed with MR1-dependent reactivity to tumor and healthy cells in the absence of microbial metabolites. MAIT cells bearing TCRs crossreactive toward self are rare but commonly found within healthy donors and display T-helper-like functions in vitro. Experiments with MR1-tetramers loaded with distinct ligands revealed significant crossreactivity among MAIT TCRs both ex vivo and upon in vitro expansion. A canonical MAIT TCR was selected on the basis of extremely promiscuous MR1 recognition. Structural and molecular dynamic analyses associated promiscuity to unique TCRβ-chain features that were enriched within self-reactive MAIT cells of healthy individuals. Thus, self-reactive recognition of MR1 represents a functionally relevant indication of MAIT TCR crossreactivity, suggesting a potentially broader role of MAIT cells in immune homeostasis and diseases, beyond microbial immunosurveillance.

Published
2023

8. Promiscuous recognition of MR1 drives self-reactive mucosal-associated invariant T cell responses

Author

Chancellor, Andrew, primary, Alan Simmons, Robert, additional, Khanolkar, Rahul C., additional, Nosi, Vladimir, additional, Beshirova, Aisha, additional, Berloffa, Giuliano, additional, Colombo, Rodrigo, additional, Karuppiah, Vijaykumar, additional, Pentier, Johanne M., additional, Tubb, Vanessa, additional, Ghadbane, Hemza, additional, Suckling, Richard J., additional, Page, Keith, additional, Crean, Rory M., additional, Vacchini, Alessandro, additional, De Gregorio, Corinne, additional, Schaefer, Verena, additional, Constantin, Daniel, additional, Gligoris, Thomas, additional, Lloyd, Angharad, additional, Hock, Miriam, additional, Srikannathasan, Velupillai, additional, Robinson, Ross A., additional, Besra, Gurdyal S., additional, van der Kamp, Marc W., additional, Mori, Lucia, additional, Calogero, Raffaele, additional, Cole, David K., additional, De Libero, Gennaro, additional, and Lepore, Marco, additional

Published
2023
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11. Insights into the Importance of WPD-Loop Sequence for Activity and Structure in Protein Tyrosine Phosphatases

Author

Shen, Ruidan, primary, Crean, Rory M., additional, Olsen, Keith J., additional, Corbella, Marina, additional, Calixto, Ana Rita, additional, Richan, Teisha, additional, Brandão, Tiago A. S., additional, Berry, Ryan D., additional, Tolman, Alex, additional, Loria, J. Patrick, additional, Johnson, Sean J., additional, Kamerlin, Shina Caroline Lynn, additional, and Hengge, Alvan C., additional

Published
2022
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12. Essential Functional Interplay of the Catalytic Groups in Acid Phosphatase

Author

Pfeiffer, Martin, Crean, Rory M., Moreira, Catia, Parracino, Antonietta, Oberdorfer, Gustav, Brecker, Lothar, Hammerschmidt, Friedrich, Kamerlin, Shina C. Lynn, Nidetzky, Bernd, Pfeiffer, Martin, Crean, Rory M., Moreira, Catia, Parracino, Antonietta, Oberdorfer, Gustav, Brecker, Lothar, Hammerschmidt, Friedrich, Kamerlin, Shina C. Lynn, and Nidetzky, Bernd

Abstract

The cooperative interplay between the functional devices of a preorganized active site is fundamental to enzyme catalysis. An in-depth understanding of this phenomenon is central to elucidating the remarkable efficiency of natural enzymes and provides an essential benchmark for enzyme design and engineering. Here, we study the functional interconnectedness of the catalytic nucleophile (His18) in an acid phosphatase by analyzing the consequences of its replacement with aspartate. We present crystallographic, biochemical, and computational evidence for a conserved mechanistic pathway via a phospho-enzyme intermediate on Asp18. Linear free-energy relationships for phosphoryl transfer from phosphomonoester substrates to His18/Asp18 provide evidence for the cooperative interplay between the nucleophilic and general-acid catalytic groups in the wild-type enzyme, and its substantial loss in the H18D variant. As an isolated factor of phosphatase efficiency, the advantage of a histidine compared to an aspartate nucleophile is similar to 10(4)-fold. Cooperativity with the catalytic acid adds >= 10(2)-fold to that advantage. Empirical valence bond simulations of phosphoryl transfer from glucose 1-phosphate to His and Asp in the enzyme explain the loss of activity of the Asp18 enzyme through a combination of impaired substrate positioning in the Michaelis complex, as well as a shift from early to late protonation of the leaving group in the H18D variant. The evidence presented furthermore suggests that the cooperative nature of catalysis distinguishes the enzymatic reaction from the corresponding reaction in solution and is enabled by the electrostatic preorganization of the active site. Our results reveal sophisticated discrimination in multifunctional catalysis of a highly proficient phosphatase active site.

Published
2022
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13. Reliable In Silico Ranking of Engineered Therapeutic TCR Binding Affinities with MMPB/GBSA

Author

Crean, Rory M., Pudney, Christopher R., Cole, David K., van der Kamp, Marc W., Crean, Rory M., Pudney, Christopher R., Cole, David K., and van der Kamp, Marc W.

Abstract

Accurate and efficient in silico ranking of protein–protein binding affinities is useful for protein design with applications in biological therapeutics. One popular approach to rank binding affinities is to apply the molecular mechanics Poisson–Boltzmann/generalized Born surface area (MMPB/GBSA) method to molecular dynamics (MD) trajectories. Here, we identify protocols that enable the reliable evaluation of T-cell receptor (TCR) variants binding to their target, peptide-human leukocyte antigens (pHLAs). We suggest different protocols for variant sets with a few (≤4) or many mutations, with entropy corrections important for the latter. We demonstrate how potential outliers could be identified in advance and that just 5–10 replicas of short (4 ns) MD simulations may be sufficient for the reproducible and accurate ranking of TCR variants. The protocols developed here can be applied toward in silico screening during the optimization of therapeutic TCRs, potentially reducing both the cost and time taken for biologic development.

Published
2022
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14. Insights into the importance of WPD-loop sequence for activity and structure in protein tyrosine phosphatases

Author

Shen, Ruidan, Crean, Rory M., Olsen, Keith J., Corbella Morató, Marina, Calixto, Ana R., Richan, Teisha, Brandao, Tiago A. S., Berry, Ryan D., Tolman, Alex, Loria, J. Patrick, Johnson, Sean J., Kamerlin, Shina C. L., Hengge, Alvan C., Shen, Ruidan, Crean, Rory M., Olsen, Keith J., Corbella Morató, Marina, Calixto, Ana R., Richan, Teisha, Brandao, Tiago A. S., Berry, Ryan D., Tolman, Alex, Loria, J. Patrick, Johnson, Sean J., Kamerlin, Shina C. L., and Hengge, Alvan C.

Abstract

Protein tyrosine phosphatases (PTPs) possess a conserved mobile catalytic loop, the WPD-loop, which brings an aspartic acid into the active site where it acts as an acid/base catalyst. Prior experimental and computational studies, focused on the human enzyme PTP1B and the PTP from Yersinia pestis, YopH, suggested that loop conformational dynamics are important in regulating both catalysis and evolvability. We have generated a chimeric protein in which the WPD-loop of YopH is transposed into PTP1B, and eight chimeras that systematically restored the loop sequence back to native PTP1B. Of these, four chimeras were soluble and were subjected to detailed biochemical and structural characterization, and a computational analysis of their WPD-loop dynamics. The chimeras maintain backbone structural integrity, with somewhat slower rates than either wild-type parent, and show differences in the pH dependency of catalysis, and changes in the effect of Mg2+. The chimeric proteins' WPD-loops differ significantly in their relative stability and rigidity. The time required for interconversion, coupled with electrostatic effects revealed by simulations, likely accounts for the activity differences between chimeras, and relative to the native enzymes. Our results further the understanding of connections between enzyme activity and the dynamics of catalytically important groups, particularly the effects of non-catalytic residues on key conformational equilibria.

Published
2022
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16. EVB Parameters For The Manuscript: The Essential Functional Interplay of the Catalytic Groups in Acid Phosphatase

Author

Crean, Rory M., Moreira, Cátia, and Kamerlin, L.S.C.

Subjects
empirical valence bond (EVB) Simulations, Enzyme catalysis, molecular dynamics
Abstract

Starting structures, input + parameter files and exemplaranalysis scriptsfor the empirical valencebond (EVB) simulations performed to generate the data for the article:The Essential Functional Interplay of the Catalytic Groups in Acid Phosphatase (in submission). Documentation (Same as in the README.txt file): In this folder, you will find all the items you need to re-run our EVB simulations. You should first be familiar with the EVB method, a good starting point for this can be found here: https://onlinelibrary.wiley.com/doi/book/10.1002/9781119245544 Each subfolder contains the files needed to run the EVB equil and production simulations for a given system. Further, example helper scripts are provided to show the steps used. ### 1. Equilibration part. For each system the input run files for the equilibration are attached alongside the topology and coordinate files. Note that for each replica you need to choose a new random seed (defined in: "dyn_min_wat_noshake.inp") The order of operations for the equil files is as follows: "dyn_min_wat_noshake", "dyn_min_wat", "dyn_min_wat_eq", "dyn_cool", "dyn_min", "dyn_warm30k", "dyn_warm150k", "dyn_warm300k", "dyn_eq300k_{1..20}". Also included is a helper script "1_Example_Create_Equil_Runs.sh" to generate the directories and job scripts (for Slurm architecture) for the 30 replicas per system. ### 2. Production part. The production runs were performed inside each equilibration run folder inside a folder called "EVB_Prod". The file "2_Example_Setup_Prod_Runs.sh" provides an example of how to setup for production simulations after the equilibration run has complete. Take care to add the final restart file to the production folders working directory (see the script attached) ### 3. Mapping part. The mapping protocol used for the enzyme reactions to determine both the reaction and activation free energies are described in the Supplementary Methods. The file "3_Example_Map_Enzyme_Reaction.sh" provides an example of how to do this using all 30 replicas. ### 4. Identifying the Lambda Values for the RS, TS and PS. For many of the analyses performed, we described the differences between the key stationary/saddle points along the reaction coordinate. The file "4_Example_Get_Lambda_Values.sh" provides an example of how to obtain the Lambda values corresponding to this for all 30 replicas, alongside providing an example of how to generate trajectories of each of these states for easy analysis later on. Note also the python script "q_get_extrema.py" needs to be used for this analysis (this is provided in the main folder). ### 5. Generating trajectories of the equilibration runs. An example helper script "5_Example_Equil_Trajectory_Store.sh" is provided to combine the equilibration MD simulation trajectories (those at 300 K) for each run for easier analysis (e.g. to measure things like Calpha RMSD, see section below). Note that you will need the program catdcd installed for this: https://www.ks.uiuc.edu/Development/MDTools/catdcd/ ### 6. Some example analysis scripts with CPPTRAJ. CPPTRAJ was used for the majority of the analysis performed in this paper based on the authors personal preference. Example CPPTRAJ analysis scripts to measure various properties are attached for your convenience. (the scripts themselves are commented to explain what they are doing.) These are provided in the folder "Example_CPPTRAJ_Scripts.sh" #### 7. Electrostatic Contributions calculations. To calculate the per residue group contributions (between the RS and TS) we used qtools. An example of how to do this is provided in the file: "7_Example_Get_Group_Contributions.sh"

Published
2021
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19. Supplementary Simulation Data for Insights into the Importance of WPD-Loop Sequence for Activity and Structure in Protein Tyrosine Phosphatases

Author

Shen, Ruidan, Crean, Rory M., Olsen, Keith J., Richan, Teisha, Brandão, Tiago A. S., Berry, Ryan D., Tolman, A., Loria, J. Patrick, Johnson, Sean J., Kamerlin, Shina Caroline Lynn, and Hengge, Alvan C.

Subjects
Molecular Simulation Data, Loop Dynamics, PTP1B, Protein Tyrosine Phosphatases, YopH, Molecular Dynamics, Conformational Plasticitiy
Abstract

Additional simulation data for "Insights into the Importance of WPD-Loop Sequence for Activity and Structure in Protein Tyrosine Phosphatases", which has been submitted as a preprint to ChemRxiv.

Published
2021
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20. Updated Supplementary Simulation Data for Insights into the Importance of WPD-Loop Sequence for Activity and Structure in Protein Tyrosine Phosphatases

Author

Shen, Ruidan, Crean, Rory M., Olsen, Keith J., Richan, Teisha, Brandão, Tiago A. S., Berry, Ryan D., Tolman, A., Loria, J. Patrick, Johnson, Sean J., Kamerlin, Shina Caroline Lynn, and Hengge, Alvan C.

Subjects
Molecular Simulation Data, Loop Dynamics, PTP1B, Protein Tyrosine Phosphatases, YopH, Molecular Dynamics, Conformational Plasticitiy
Abstract

Additional simulation data for "Insights into the Importance of WPD-Loop Sequence for Activity and Structure in Protein Tyrosine Phosphatases", with additional data compared to our original submission, DOI:10.5281/zenodo.5500670

Published
2021
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21. Chemical Mapping Exposes the Importance of Active Site Interactions in Governing the Temperature Dependence of Enzyme Turnover

Author

Winter, Samuel D., primary, Jones, Hannah B. L., additional, Răsădean, Dora M., additional, Crean, Rory M., additional, Danson, Michael J., additional, Pantoş, G. Dan, additional, Katona, Gergely, additional, Prentice, Erica, additional, Arcus, Vickery L., additional, van der Kamp, Marc W., additional, and Pudney, Christopher R., additional

Published
2021
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24. Chemical Mapping Exposes the Importance of Active Site Interactions in Governing the Temperature Dependence of Enzyme Turnover

Author

Winter, Samuel D., Jones, Hannah B. L., Rasadean, Dora M., Crean, Rory M., Danson, Michael J., Panto, G. Dan, Katona, Gergely, Prentice, Erica, Arcus, Vickery L., van der Kamp, Marc W., Pudney, Christopher R., Winter, Samuel D., Jones, Hannah B. L., Rasadean, Dora M., Crean, Rory M., Danson, Michael J., Panto, G. Dan, Katona, Gergely, Prentice, Erica, Arcus, Vickery L., van der Kamp, Marc W., and Pudney, Christopher R.

Abstract

Uncovering the role of global protein dynamics in enzyme turnover is needed to fully understand enzyme catalysis. Recently, we have demonstrated that the heat capacity of catalysis, Delta C-P(double dagger), can reveal links between the protein free energy landscape, global protein dynamics, and enzyme turnover, suggesting that subtle changes in molecular interactions at the active site can affect long-range protein dynamics and link to enzyme temperature activity. Here, we use a model promiscuous enzyme (glucose dehydrogenase from Sulfolobus solfataricus) to chemically map how individual substrate interactions affect the temperature dependence of enzyme activity and the network of motions throughout the protein. Utilizing a combination of kinetics, red edge excitation shift (REES) spectroscopy, and computational simulation, we explore the complex relationship between enzyme-substrate interactions and the global dynamics of the protein. We find that changes in Delta C-P(double dagger) and protein dynamics can be mapped to specific substrate-enzyme interactions. Our study reveals how subtle changes in substrate binding affect global changes in motion and flexibility extending throughout the protein.

Published
2021
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25. Single Residue on the WPD-Loop Affects the pH Dependency of Catalysis in Protein Tyrosine Phosphatases

Author

Shen, Ruidan, Crean, Rory M., Johnson, Sean J., Kamerlin, Shina C. L., Hengge, Alvan C., Shen, Ruidan, Crean, Rory M., Johnson, Sean J., Kamerlin, Shina C. L., and Hengge, Alvan C.

Abstract

Catalysis by protein tyrosine phosphatases (PTPs) relies on the motion of a flexible protein loop (the WPD-loop) that carries a residue acting as a general acid/base catalyst during the PTP-catalyzed reaction. The orthogonal substitutions of a noncatalytic residue in the WPD-loops of YopH and PTP1B result in shifted pH-rate profiles from an altered kinetic pKa of the nucleophilic cysteine. Compared to wild type, the G352T YopH variant has a broadened pH-rate profile, similar activity at optimal pH, but significantly higher activity at low pH. Changes in the corresponding PTP1B T177G variant are more modest and in the opposite direction, with a narrowed pH profile and less activity in the most acidic range. Crystal structures of the variants show no structural perturbations but suggest an increased preference for the WPD-loop-closed conformation. Computational analysis confirms a shift in loop conformational equilibrium in favor of the closed conformation, arising from a combination of increased stability of the closed state and destabilization of the loop-open state. Simulations identify the origins of this population shift, revealing differences in the flexibility of the WPD-loop and neighboring regions. Our results demonstrate that changes to the pH dependency of catalysis by PTPs can result from small changes in amino acid composition in their WPD-loops affecting only loop dynamics and conformational equilibrium. The perturbation of kinetic pKa values of catalytic residues by nonchemical processes affords a means for nature to alter an enzyme’s pH dependency by a less disruptive path than altering electrostatic networks around catalytic residues themselves.

Published
2021
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26. Loop Dynamics and Enzyme Catalysis in Protein Tyrosine Phosphatases

Author

Crean, Rory M., Biler, Michal, van der Kamp, Marc W., Hengge, Alvan C., Kamerlin, Shina C. Lynn, Crean, Rory M., Biler, Michal, van der Kamp, Marc W., Hengge, Alvan C., and Kamerlin, Shina C. Lynn

Abstract

Protein tyrosine phosphatases (PTPs) play an important role in cellular signaling and have been implicated in human cancers, diabetes, and obesity. Despite shared catalytic mechanisms and transition states for the chemical steps of catalysis, catalytic rates within the PTP family vary over several orders of magnitude. These rate differences have been implied to arise from differing conformational dynamics of the closure of a protein loop, the WPD-Ioop, which carries a catalytically critical residue. The present work reports computational studies of the human protein tyrosine phosphatase 1B (PTP1B) and YopH from Yersinia pestis, for which NMR has demonstrated a link between their respective rates of WPD-Ioop motion and catalysis rates, which differ by an order of magnitude. We have performed detailed structural analysis, both conventional and enhanced sampling simulations of their loop dynamics, as well as empirical valence bond simulations of the chemical step of catalysis. These analyses revealed the key residues and structural features responsible for these differences, as well as the residues and pathways that facilitate allosteric communication in these enzymes. Curiously, our wild-type YopH simulations also identify a catalytically incompetent hyper-open conformation of its WPD-loop, sampled as a rare event, previously only experimentally observed in YopH-based chimeras. The effect of differences within the WPD-loop and its neighboring loops on the modulation of loop dynamics, as revealed in this work, may provide a facile means for the family of PTP enzymes to respond to environmental changes and regulate their catalytic activities., Correction in: JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, Volume 144, Issue 22, Page 10091-10093, DOI 10.1021/jacs.2c04624

Published
2021
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29. Molecular rules underpinning enhanced affinity binding of human T cell receptors engineered 2 for immunotherapy

Author

Crean, Rory M, MacLachlan, Bruce J, Madura, Florian, Whalley, Thomas, Rizkallah, Pierre J, Holland, Christopher J, McMurran, Catriona, Harper, Stephen, Godkin, Andrew, Sewell, Andrew K, Pudney, Christopher R, Van Der Kamp, Marc W, and Cole, David K

Subjects
cancer immunotherapy, peptide-human leukocyte antigen (pHLA), T cells, hemic and immune systems, chemical and pharmacologic phenomena, T cell receptor (TCR), molecular dynamics (MD) simulations, X-ray crystallography
Abstract

Immuno-oncology approaches that utilize T cell receptors (TCRs) are becoming highly attractive because of their potential to target virtually all cellular proteins, including cancer-specific epitopes, via the recognition of peptide-human leukocyte antigen (pHLA) complexes presented at the cell surface. However, because natural TCRs generally recognize cancer-derived pHLAs with very weak affinities, efforts have been made to enhance their binding strength, in some cases by several million-fold. In this study, we investigated the mechanisms underpinning human TCR affinity enhancement by comparing the crystal structures of engineered enhanced affinity TCRs with those of their wild-type progenitors. Additionally, we performed molecular dynamics simulations to better understand the energetic mechanisms driving the affinity enhancements. These data demonstrate that supra-physiological binding affinities can be achieved without altering native TCR-pHLA binding modes via relatively subtle modifications to the interface contacts, often driven through the addition of buried hydrophobic residues. Individual energetic components of the TCR-pHLA interaction governing affinity enhancements were distinct and highly variable for each TCR, often resulting from additive, or knock-on, effects beyond the mutated residues. This comprehensive analysis of affinity-enhanced TCRs has important implications for the future rational design of engineered TCRs as efficacious and safe drugs for cancer treatment.

Published
2020

30. Harnessing Conformational Plasticity to Generate Designer Enzymes

Author

Crean, Rory M., Gardner, Jasmine M., Kamerlin, Shina C. Lynn, Crean, Rory M., Gardner, Jasmine M., and Kamerlin, Shina C. Lynn

Abstract

Recent years have witnessed an explosion of interest in understanding the role of conformational dynamics both in the evolution of new enzymatic activities from existing enzymes and in facilitating the emergence of enzymatic activity de novo on scaffolds that were previously non-catalytic. There are also an increasing number of examples in the literature of targeted engineering of conformational dynamics being successfully used to alter enzyme selectivity and activity. Despite the obvious importance of conformational dynamics to both enzyme function and evolvability, many (although not all) computational design approaches still focus either on pure sequence-based approaches or on using structures with limited flexibility to guide the design. However, there exist a wide variety of computational approaches that can be (re)purposed to introduce conformational dynamics as a key consideration in the design process. Coupled with laboratory evolution and more conventional existing sequence- and structure-based approaches, these techniques provide powerful tools for greatly expanding the protein engineering toolkit. This Perspective provides an overview of evolutionary studies that have dissected the role of conformational dynamics in facilitating the emergence of novel enzymes, as well as advances in computational approaches that allow one to target conformational dynamics as part of enzyme design. Harnessing conformational dynamics in engineering studies is a powerful paradigm with which to engineer the next generation of designer biocatalysts.

Published
2020
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31. Ground-State Destabilization by Active-Site Hydrophobicity Controls the Selectivity of a Cofactor-Free Decarboxylase

Author

Biler, Michal, Crean, Rory M., Schweiger, Anna K., Kourist, Robert, Kamerlin, Shina C. Lynn, Biler, Michal, Crean, Rory M., Schweiger, Anna K., Kourist, Robert, and Kamerlin, Shina C. Lynn

Abstract

Bacterial arylmalonate decarboxylase (AMDase) and evolved variants have become a valuable tool with which to access both enantiomers of a broad range of chiral arylaliphatic acids with high optical purity. Yet, the molecular principles responsible for the substrate scope, activity, and selectivity of this enzyme are only poorly understood to date, greatly hampering the predictability and design of improved enzyme variants for specific applications. In this work, empirical valence bond and metadynamics simulations were performed on wild-type AMDase and variants thereof to obtain a better understanding of the underlying molecular processes determining reaction outcome. Our results clearly reproduce the experimentally observed substrate scope and support a mechanism driven by ground-state destabilization of the carboxylate group being cleaved by the enzyme. In addition, our results indicate that, in the case of the nonconverted or poorly converted substrates studied in this work, increased solvent exposure of the active site upon binding of these substrates can disturb the vulnerable network of interactions responsible for facilitating the AMDase-catalyzed cleavage of CO2. Finally, our results indicate a switch from preferential cleavage of the pro-(R) to the pro-(S) carboxylate group in the CLG-IPL variant of AMDase for all substrates studied. This appears to be due to the emergence of a new hydrophobic pocket generated by the insertion of the six amino acid substitutions, into which the pro-(S) carboxylate binds. Our results allow insight into the tight interaction network determining AMDase selectivity, which in turn provides guidance for the identification of target residues for future enzyme engineering.

Published
2020
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33. Molecular Rules Underpinning Enhanced Affinity Binding of Human T Cell Receptors Engineered for Immunotherapy

Author

Crean, Rory M., primary, MacLachlan, Bruce J., additional, Madura, Florian, additional, Whalley, Thomas, additional, Rizkallah, Pierre J., additional, Holland, Christopher J., additional, McMurran, Catriona, additional, Harper, Stephen, additional, Godkin, Andrew, additional, Sewell, Andrew K., additional, Pudney, Christopher R., additional, van der Kamp, Marc W., additional, and Cole, David K., additional

Published
2020
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38. Reliable In SilicoRanking of Engineered Therapeutic TCR Binding Affinities with MMPB/GBSA

Author

Crean, Rory M., Pudney, Christopher R., Cole, David K., and van der Kamp, Marc W.

Abstract

Accurate and efficient in silicoranking of protein–protein binding affinities is useful for protein design with applications in biological therapeutics. One popular approach to rank binding affinities is to apply the molecular mechanics Poisson–Boltzmann/generalized Born surface area (MMPB/GBSA) method to molecular dynamics (MD) trajectories. Here, we identify protocols that enable the reliable evaluation of T-cell receptor (TCR) variants binding to their target, peptide-human leukocyte antigens (pHLAs). We suggest different protocols for variant sets with a few (≤4) or many mutations, with entropy corrections important for the latter. We demonstrate how potential outliers could be identified in advance and that just 5–10 replicas of short (4 ns) MD simulations may be sufficient for the reproducible and accurate ranking of TCR variants. The protocols developed here can be applied toward in silicoscreening during the optimization of therapeutic TCRs, potentially reducing both the cost and time taken for biologic development.

Published
2022
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39. Insights into the importance of WPD-loop sequence for activity and structure in protein tyrosine phosphatases.

Author

Shen R, Crean RM, Olsen KJ, Corbella M, Calixto AR, Richan T, Brandão TAS, Berry RD, Tolman A, Loria JP, Johnson SJ, Kamerlin SCL, and Hengge AC

Abstract

Protein tyrosine phosphatases (PTPs) possess a conserved mobile catalytic loop, the WPD-loop, which brings an aspartic acid into the active site where it acts as an acid/base catalyst. Prior experimental and computational studies, focused on the human enzyme PTP1B and the PTP from Yersinia pestis , YopH, suggested that loop conformational dynamics are important in regulating both catalysis and evolvability. We have generated a chimeric protein in which the WPD-loop of YopH is transposed into PTP1B, and eight chimeras that systematically restored the loop sequence back to native PTP1B. Of these, four chimeras were soluble and were subjected to detailed biochemical and structural characterization, and a computational analysis of their WPD-loop dynamics. The chimeras maintain backbone structural integrity, with somewhat slower rates than either wild-type parent, and show differences in the pH dependency of catalysis, and changes in the effect of Mg 2+ . The chimeric proteins' WPD-loops differ significantly in their relative stability and rigidity. The time required for interconversion, coupled with electrostatic effects revealed by simulations, likely accounts for the activity differences between chimeras, and relative to the native enzymes. Our results further the understanding of connections between enzyme activity and the dynamics of catalytically important groups, particularly the effects of non-catalytic residues on key conformational equilibria., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published
2022
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40. Molecular Rules Underpinning Enhanced Affinity Binding of Human T Cell Receptors Engineered for Immunotherapy.

Author

Crean RM, MacLachlan BJ, Madura F, Whalley T, Rizkallah PJ, Holland CJ, McMurran C, Harper S, Godkin A, Sewell AK, Pudney CR, van der Kamp MW, and Cole DK

Abstract

Immuno-oncology approaches that utilize T cell receptors (TCRs) are becoming highly attractive because of their potential to target virtually all cellular proteins, including cancer-specific epitopes, via the recognition of peptide-human leukocyte antigen (pHLA) complexes presented at the cell surface. However, because natural TCRs generally recognize cancer-derived pHLAs with very weak affinities, efforts have been made to enhance their binding strength, in some cases by several million-fold. In this study, we investigated the mechanisms underpinning human TCR affinity enhancement by comparing the crystal structures of engineered enhanced affinity TCRs with those of their wild-type progenitors. Additionally, we performed molecular dynamics simulations to better understand the energetic mechanisms driving the affinity enhancements. These data demonstrate that supra-physiological binding affinities can be achieved without altering native TCR-pHLA binding modes via relatively subtle modifications to the interface contacts, often driven through the addition of buried hydrophobic residues. Individual energetic components of the TCR-pHLA interaction governing affinity enhancements were distinct and highly variable for each TCR, often resulting from additive, or knock-on, effects beyond the mutated residues. This comprehensive analysis of affinity-enhanced TCRs has important implications for the future rational design of engineered TCRs as efficacious and safe drugs for cancer treatment., (Crown Copyright © 2020.)

Published
2020
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