Design of a switchable eliminase

The active sites of enzymes are lined with side chains whose dynamic, geometric, and chemical properties have been finely tuned relative to the corresponding residues in water. For example, the carboxylates of glutamate and aspartate are weakly basic in water but become strongly basic when dehydrated in enzymatic sites. The dehydration of the carboxylate, although intrinsically thermodynamically unfavorable, is achieved by harnessing the free energy of folding and substrate binding to reach the required basicity. Allosterically regulated enzymes additionally rely on the free energy of ligand binding to stabilize the protein in a catalytically competent state. We demonstrate the interplay of protein folding energetics and functional group tuning to convert calmodulin (CaM), a regulatory binding protein, into AlleyCat, an allosterically controlled eliminase. Upon binding Ca(II), native CaM opens a hydrophobic pocket on each of its domains. We computationally identified a mutant that (i) accommodates carboxylate as a general base within these pockets, (ii) interacts productively in the Michaelis complex with the substrate, and (iii) stabilizes the transition state for the reaction. Remarkably, a single mutation of an apolar residue at the bottom of an otherwise hydrophobic cavity confers catalytic activity on calmodulin. AlleyCat showed the expected pH-rate profile, and it was inactivated by mutation of its active site Glu to Gln. A variety of control mutants demonstrated the specificity of the design. The activity of this minimal 75-residue allosterically regulated catalyst is similar to that obtained using more elaborate computational approaches to redesign complex enzymes to catalyze the Kemp elimination reaction.

[1]  W. DeGrado,et al.  Protein design, a minimalist approach. , 1989, Science.

[2]  Eva Thulin,et al.  Calcium-induced structural changes and domain autonomy in calmodulin , 1995, Nature Structural Biology.

[3]  A J Wand,et al.  Structural analysis of a novel interaction by calmodulin: high-affinity binding of a peptide in the absence of calcium. , 1995, Biochemistry.

[4]  Eric A. Althoff,et al.  Kemp elimination catalysts by computational enzyme design , 2008, Nature.

[5]  D. Hilvert,et al.  Large rate accelerations in antibody catalysis by strategic use of haptenic charge , 1995, Nature.

[6]  L. Baltzer,et al.  Catalysis of Hydrolysis and Transesterification Reactions of p-Nitrophenyl Esters by a Designed Helix−Loop−Helix Dimer , 1997 .

[7]  R. Hodges,et al.  Calcium-induced peptide association to form an intact protein domain: 1H NMR structural evidence. , 1990, Science.

[8]  B. García-Moreno E.,et al.  Charges in the hydrophobic interior of proteins , 2010, Proceedings of the National Academy of Sciences.

[9]  Benjamin D Allen,et al.  Combinatorial methods for small-molecule placement in computational enzyme design , 2006, Proceedings of the National Academy of Sciences.

[10]  V. Hilser,et al.  Ligand effects on the protein ensemble: unifying the descriptions of ligand binding, local conformational fluctuations, and protein stability. , 2008, Methods in cell biology.

[11]  D. Kemp,et al.  Physical organic chemistry of benzisoxazoles. IV. Origins and catalytic nature of the solvent rate acceleration for the decarboxylation of 3-carboxybenzisoxazoles , 1975 .

[12]  Jose M. Sanchez-Ruiz,et al.  Modulation of buried ionizable groups in proteins with engineered surface charge. , 2010, Journal of the American Chemical Society.

[13]  L Regan,et al.  A tetrahedral zinc(II)-binding site introduced into a designed protein. , 1990, Biochemistry.

[14]  Michael H Hecht,et al.  Cofactor binding and enzymatic activity in an unevolved superfamily of de novo designed 4‐helix bundle proteins , 2009, Protein science : a publication of the Protein Society.

[15]  S. Benner,et al.  Synthesis, structure and activity of artificial, rationally designed catalytic polypeptides , 1993, Nature.

[16]  Donald Hilvert,et al.  Structural origins of efficient proton abstraction from carbon by a catalytic antibody. , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[17]  Alessandro Senes,et al.  De novo design and molecular assembly of a transmembrane diporphyrin-binding protein complex. , 2010, Journal of the American Chemical Society.

[18]  David Baker,et al.  Evolutionary optimization of computationally designed enzymes: Kemp eliminases of the KE07 series. , 2010, Journal of molecular biology.

[19]  Garrett M Morris,et al.  Using AutoDock for Ligand‐Receptor Docking , 2008, Current protocols in bioinformatics.

[20]  B. García-Moreno E.,et al.  High tolerance for ionizable residues in the hydrophobic interior of proteins , 2008, Proceedings of the National Academy of Sciences.

[21]  F. Hollfelder,et al.  Catalysis of the Kemp elimination by antibodies elicited against a cationic hapten , 1997 .

[22]  Dale E Tronrud,et al.  Lessons from the lysozyme of phage T4 , 2010, Protein science : a publication of the Protein Society.

[23]  W. DeGrado,et al.  An artificial di-iron oxo-protein with phenol oxidase activity. , 2009, Nature chemical biology.

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

[25]  B K Shoichet,et al.  A relationship between protein stability and protein function. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[26]  Christopher I. Bayly,et al.  Fast, efficient generation of high‐quality atomic charges. AM1‐BCC model: II. Parameterization and validation , 2002, J. Comput. Chem..

[27]  W. DeGrado,et al.  De novo design of catalytic proteins. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[28]  J. Falke,et al.  Molecular Tuning of Ion Binding to Calcium Signaling Proteins , 1994, Quarterly Reviews of Biophysics.

[29]  S. Martin,et al.  Ligand binding and thermodynamic stability of a multidomain protein, calmodulin , 2000, Protein science : a publication of the Protein Society.

[30]  S. L. Mayo,et al.  Enzyme-like proteins by computational design , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[31]  N. D. Clarke,et al.  Metal search: A computer program that helps design tetrahedral metal‐binding sites , 1995, Proteins.

[32]  D. Hilvert,et al.  Nonspecific medium effects versus specific group positioning in the antibody and albumin catalysis of the base-promoted ring-opening reactions of benzisoxazoles. , 2004, Journal of the American Chemical Society.

[33]  Dan S. Tawfik,et al.  Efficient Catalysis of Proton Transfer by Synzymes , 1997 .

[34]  D. Kemp,et al.  Physical organic chemistry of benzisoxazoles. I. Mechanism of the base-catalyzed decomposition of benzisoxazoles , 1973 .