Distinct structural mechanisms determine substrate affinity and kinase activity of protein kinase Cα

Protein kinase Cα (PKCα) belongs to the family of AGC kinases that phosphorylate multiple peptide substrates. Although the consensus sequence motif has been identified and used to explain substrate specificity for PKCα, it does not inform the structural basis of substrate-binding and kinase activity for diverse substrates phosphorylated by this kinase. The transient, dynamic, and unstructured nature of this protein–protein interaction has limited structural mapping of kinase–substrate interfaces. Here, using multiscale MD simulation-based predictions and FRET sensor-based experiments, we investigated the conformational dynamics of the kinase–substrate interface. We found that the binding strength of the kinase–substrate interaction is primarily determined by long-range columbic interactions between basic (Arg/Lys) residues located N-terminally to the phosphorylated Ser/Thr residues in the substrate and by an acidic patch in the kinase catalytic domain. Kinase activity stemmed from conformational flexibility in the region C-terminal to the phosphorylated Ser/Thr residues. Flexibility of the substrate–kinase interaction enabled an Arg/Lys two to three amino acids C-terminal to the phosphorylated Ser/Thr to prime a catalytically active conformation, facilitating phosphoryl transfer to the substrate. The structural mechanisms determining substrate binding and catalytic activity formed the basis of diverse binding affinities and kinase activities of PKCα for 14 substrates with varying degrees of sequence conservation. Our findings provide insight into the dynamic properties of the kinase–substrate interaction that govern substrate binding and turnover. Moreover, this study establishes a modeling and experimental method to elucidate the structural dynamics underlying substrate selectivity among eukaryotic kinases.

[1]  Roland L. Dunbrack,et al.  The Rosetta all-atom energy function for macromolecular modeling and design , 2017, bioRxiv.

[2]  R. Sommese,et al.  The Role of Regulatory Domains in Maintaining Autoinhibition in the Multidomain Kinase PKCα* , 2017, The Journal of Biological Chemistry.

[3]  R. Sommese,et al.  Substrate Affinity Differentially Influences Protein Kinase C Regulation and Inhibitor Potency* , 2016, The Journal of Biological Chemistry.

[4]  Felipe A. N. Ferraz,et al.  Revisiting protein kinase–substrate interactions: Toward therapeutic development , 2016, Science Signaling.

[5]  P. Langan,et al.  Phosphoryl Transfer Reaction Snapshots in Crystals , 2015, The Journal of Biological Chemistry.

[6]  Jeffrey R. Wagner,et al.  GneimoSim: A modular internal coordinates molecular dynamics simulation package , 2014, J. Comput. Chem..

[7]  J. Tesmer,et al.  Conserved Modular Domains Team up to Latch-open Active Protein Kinase Cα* , 2014, The Journal of Biological Chemistry.

[8]  Abhinandan Jain,et al.  Protein Structure Refinement of CASP Target Proteins Using GNEIMO Torsional Dynamics Method , 2014, J. Chem. Inf. Model..

[9]  Jing Huang,et al.  CHARMM36 all‐atom additive protein force field: Validation based on comparison to NMR data , 2013, J. Comput. Chem..

[10]  Abhinandan Jain,et al.  Mapping conformational dynamics of proteins using torsional dynamics simulations. , 2013, Biophysical journal.

[11]  Susan S. Taylor,et al.  Insights into the Phosphoryl Transfer Catalyzed by cAMP-Dependent Protein Kinase: An X-ray Crystallographic Study of Complexes with Various Metals and Peptide Substrate SP20 , 2013, Biochemistry.

[12]  Abhinandan Jain,et al.  Advanced techniques for constrained internal coordinate molecular dynamics , 2013, J. Comput. Chem..

[13]  R. Neubig,et al.  Detection of G Protein-selective G Protein-coupled Receptor (GPCR) Conformations in Live Cells* , 2013, The Journal of Biological Chemistry.

[14]  Susan S. Taylor,et al.  Phosphoryl transfer by protein kinase A is captured in a crystal lattice. , 2013, Journal of the American Chemical Society.

[15]  L. Johnson,et al.  The structural basis for control of eukaryotic protein kinases. , 2012, Annual review of biochemistry.

[16]  Abhinandan Jain,et al.  Structure refinement of protein low resolution models using the GNEIMO constrained dynamics method. , 2012, The journal of physical chemistry. B.

[17]  J. Spudich,et al.  Systematic control of protein interaction using a modular ER/K α-helix linker , 2011, Proceedings of the National Academy of Sciences.

[18]  Paul R Thompson,et al.  Kinase consensus sequences: a breeding ground for crosstalk. , 2011, ACS chemical biology.

[19]  Abhinandan Jain,et al.  Folding of small proteins using constrained molecular dynamics. , 2011, The journal of physical chemistry. B.

[20]  Susan S. Taylor,et al.  Protein kinases: evolution of dynamic regulatory proteins. , 2011, Trends in biochemical sciences.

[21]  G. Hummer,et al.  Crystal Structure and Allosteric Activation of Protein Kinase C βII , 2011, Cell.

[22]  Jianpeng Ma,et al.  CHARMM: The biomolecular simulation program , 2009, J. Comput. Chem..

[23]  Ben M. Webb,et al.  Comparative Protein Structure Modeling Using MODELLER , 2007, Current protocols in protein science.

[24]  S. Itzkovitz,et al.  Functional atlas of the integrin adhesome , 2007, Nature Cell Biology.

[25]  J. Ferrell,et al.  Mechanisms of specificity in protein phosphorylation , 2007, Nature Reviews Molecular Cell Biology.

[26]  James E. Ferrell,et al.  Mechanisms of specificity in protein phosphorylation , 2007, Nature Reviews Molecular Cell Biology.

[27]  István Simon,et al.  BIOINFORMATICS ORIGINAL PAPER doi:10.1093/bioinformatics/btm035 Structural bioinformatics Local structural disorder imparts plasticity on linear motifs , 2022 .

[28]  Ben M. Webb,et al.  Comparative Protein Structure Modeling Using Modeller , 2006, Current protocols in bioinformatics.

[29]  Gerrit Groenhof,et al.  GROMACS: Fast, flexible, and free , 2005, J. Comput. Chem..

[30]  B. Honig,et al.  A hierarchical approach to all‐atom protein loop prediction , 2004, Proteins.

[31]  L. Iakoucheva,et al.  The importance of intrinsic disorder for protein phosphorylation. , 2004, Nucleic acids research.

[32]  Brian A. Hemmings,et al.  Crystal structure of an activated Akt/Protein Kinase B ternary complex with GSK3-peptide and AMP-PNP , 2002, Nature Structural Biology.

[33]  Y. Sugita,et al.  Replica-exchange molecular dynamics method for protein folding , 1999 .

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

[35]  Zhou Songyang,et al.  Determination of the Specific Substrate Sequence Motifs of Protein Kinase C Isozymes* , 1997, The Journal of Biological Chemistry.

[36]  Abhinandan Jain,et al.  Constant temperature constrained molecular dynamics: The Newton-Euler inverse mass operator method , 1996 .

[37]  T. Darden,et al.  A smooth particle mesh Ewald method , 1995 .

[38]  T. Hunter,et al.  The eukaryotic protein kinase superfamily: kinase (catalytic) domain structure and classification 1 , 1995, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[39]  D. Beglov,et al.  Finite representation of an infinite bulk system: Solvent boundary potential for computer simulations , 1994 .

[40]  T. Darden,et al.  Particle mesh Ewald: An N⋅log(N) method for Ewald sums in large systems , 1993 .

[41]  Abhinandan Jain,et al.  A fast recursive algorithm for molecular dynamics simulation , 1993 .