Ensemble Generation and the Influence of Protein Flexibility on Geometric Tunnel Prediction in Cytochrome P450 Enzymes

Computational prediction of ligand entry and egress paths in proteins has become an emerging topic in computational biology and has proven useful in fields such as protein engineering and drug design. Geometric tunnel prediction programs, such as Caver3.0 and MolAxis, are computationally efficient methods to identify potential ligand entry and egress routes in proteins. Although many geometric tunnel programs are designed to accommodate a single input structure, the increasingly recognized importance of protein flexibility in tunnel formation and behavior has led to the more widespread use of protein ensembles in tunnel prediction. However, there has not yet been an attempt to directly investigate the influence of ensemble size and composition on geometric tunnel prediction. In this study, we compared tunnels found in a single crystal structure to ensembles of various sizes generated using different methods on both the apo and holo forms of cytochrome P450 enzymes CYP119, CYP2C9, and CYP3A4. Several protein structure clustering methods were tested in an attempt to generate smaller ensembles that were capable of reproducing the data from larger ensembles. Ultimately, we found that by including members from both the apo and holo data sets, we could produce ensembles containing less than 15 members that were comparable to apo or holo ensembles containing over 100 members. Furthermore, we found that, in the absence of either apo or holo crystal structure data, pseudo-apo or –holo ensembles (e.g. adding ligand to apo protein throughout MD simulations) could be used to resemble the structural ensembles of the corresponding apo and holo ensembles, respectively. Our findings not only further highlight the importance of including protein flexibility in geometric tunnel prediction, but also suggest that smaller ensembles can be as capable as larger ensembles at capturing many of the protein motions important for tunnel prediction at a lower computational cost.

[1]  Jan Brezovsky,et al.  Software tools for identification, visualization and analysis of protein tunnels and channels. , 2013, Biotechnology advances.

[2]  Rafael Najmanovich,et al.  Side‐chain flexibility in proteins upon ligand binding , 2000, Proteins.

[3]  Rebecca C Wade,et al.  Do mammalian cytochrome P450s show multiple ligand access pathways and ligand channelling? , 2005, EMBO reports.

[4]  Michal Otyepka,et al.  What common structural features and variations of mammalian P450s are known to date? , 2007, Biochimica et biophysica acta.

[5]  P. Kollman,et al.  Automatic atom type and bond type perception in molecular mechanical calculations. , 2006, Journal of molecular graphics & modelling.

[6]  Rebecca C Wade,et al.  Conformational diversity and ligand tunnels of mammalian cytochrome P450s , 2013, Biotechnology and applied biochemistry.

[7]  Rebecca C Wade,et al.  The ins and outs of cytochrome P450s. , 2007, Biochimica et biophysica acta.

[8]  R. Wade,et al.  Comparison of the dynamics of substrate access channels in three cytochrome P450s reveals different opening mechanisms and a novel functional role for a buried arginine , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[9]  Karel Berka,et al.  Dynamics and hydration of the active sites of mammalian cytochromes P450 probed by molecular dynamics simulations. , 2012, Current drug metabolism.

[10]  N. Guex,et al.  SWISS‐MODEL and the Swiss‐Pdb Viewer: An environment for comparative protein modeling , 1997, Electrophoresis.

[11]  H. Wolfson,et al.  MolAxis: Efficient and accurate identification of channels in macromolecules , 2008, Proteins.

[12]  Jan Kern,et al.  Cyanobacterial photosystem II at 2.9-Å resolution and the role of quinones, lipids, channels and chloride , 2009, Nature Structural &Molecular Biology.

[13]  K. Berka,et al.  Behavior of human cytochromes P450 on lipid membranes. , 2013, The journal of physical chemistry. B.

[14]  Rommie E. Amaro,et al.  Ensemble-Based Virtual Screening Reveals Potential Novel Antiviral Compounds for Avian Influenza Neuraminidase , 2008, Journal of medicinal chemistry.

[15]  Markus Ulmschneider,et al.  Molecular dynamics of ion transport through the open conformation of a bacterial voltage-gated sodium channel , 2013, Proceedings of the National Academy of Sciences.

[16]  Antonín Pavelka,et al.  CAVER 3.0: A Tool for the Analysis of Transport Pathways in Dynamic Protein Structures , 2012, PLoS Comput. Biol..

[17]  Yan Wang,et al.  Molecular Dynamic Investigations of the Mutational Effects on Structural Characteristics and Tunnel Geometry in CYP17A1 , 2013, J. Chem. Inf. Model..

[18]  Zohar Ben-Barak Zelas,et al.  The influence of key residues in the tunnel entrance and the active site on activity and selectivity of toluene-4-monooxygenase , 2010 .

[19]  Jan Sykora,et al.  Expansion of Access Tunnels and Active‐Site Cavities Influence Activity of Haloalkane Dehalogenases in Organic Cosolvents , 2013, Chembiochem : a European journal of chemical biology.

[20]  J. Richardson,et al.  Asparagine and glutamine: using hydrogen atom contacts in the choice of side-chain amide orientation. , 1999, Journal of molecular biology.

[21]  Michal Otyepka,et al.  Flexibility of human cytochromes P450: molecular dynamics reveals differences between CYPs 3A4, 2C9, and 2A6, which correlate with their substrate preferences. , 2008, The journal of physical chemistry. B.

[22]  M. Machius,et al.  Pivotal role of water in the mechanism of P450BM-3. , 2001, Biochemistry.

[23]  Mark S. P. Sansom,et al.  Structure and Dynamics of the Membrane-Bound Cytochrome P450 2C9 , 2011, PLoS Comput. Biol..

[24]  Yuji Nagata,et al.  Redesigning dehalogenase access tunnels as a strategy for degrading an anthropogenic substrate. , 2009, Nature chemical biology.

[25]  Karel Berka,et al.  MOLEonline 2.0: interactive web-based analysis of biomacromolecular channels , 2012, Nucleic Acids Res..

[26]  Oliver Korb,et al.  Potential and Limitations of Ensemble Docking , 2012, J. Chem. Inf. Model..

[27]  Attilio V Vargiu,et al.  Multidrug binding properties of the AcrB efflux pump characterized by molecular dynamics simulations , 2012, Proceedings of the National Academy of Sciences.

[28]  AKIFUMI ODA,et al.  New AMBER force field parameters of heme iron for cytochrome P450s determined by quantum chemical calculations of simplified models , 2005, J. Comput. Chem..

[29]  Artur Gora,et al.  A Single Mutation in a Tunnel to the Active Site Changes the Mechanism and Kinetics of Product Release in Haloalkane Dehalogenase LinB* , 2012, The Journal of Biological Chemistry.

[30]  S. Pochet,et al.  Crystal structure of poxvirus thymidylate kinase: An unexpected dimerization has implications for antiviral therapy , 2008, Proceedings of the National Academy of Sciences.

[31]  D. van der Spoel,et al.  GROMACS: A message-passing parallel molecular dynamics implementation , 1995 .

[32]  J. Mccammon,et al.  Solvent fluctuations in hydrophobic cavity–ligand binding kinetics , 2013, Proceedings of the National Academy of Sciences.

[33]  R. Abagyan,et al.  Flexible ligand docking to multiple receptor conformations: a practical alternative. , 2008, Current opinion in structural biology.

[34]  Jürgen Pleiss,et al.  Multiple molecular dynamics simulations of human p450 monooxygenase CYP2C9: The molecular basis of substrate binding and regioselectivity toward warfarin , 2006, Proteins.

[35]  Berk Hess,et al.  LINCS: A linear constraint solver for molecular simulations , 1997, J. Comput. Chem..

[36]  G. de Fabritiis,et al.  Complete reconstruction of an enzyme-inhibitor binding process by molecular dynamics simulations , 2011, Proceedings of the National Academy of Sciences.