Catalysis by a de novo zinc-mediated protein interface: implications for natural enzyme evolution and rational enzyme engineering.

Here we show that a recent computationally designed zinc-mediated protein interface is serendipitously capable of catalyzing carboxyester and phosphoester hydrolysis. Although the original motivation was to design a de novo zinc-mediated protein-protein interaction (called MID1-zinc), we observed in the homodimer crystal structure a small cleft and open zinc coordination site. We investigated if the cleft and zinc site at the designed interface were sufficient for formation of a primitive active site that can perform hydrolysis. MID1-zinc hydrolyzes 4-nitrophenyl acetate with a rate acceleration of 10(5) and a k(cat)/K(M) of 630 M(-1) s(-1) and 4-nitrophenyl phosphate with a rate acceleration of 10(4) and a k(cat)/K(M) of 14 M(-1) s(-1). These rate accelerations by an unoptimized active site highlight the catalytic power of zinc and suggest that the clefts formed by protein-protein interactions are well-suited for creating enzyme active sites. This discovery has implications for protein evolution and engineering: from an evolutionary perspective, three-coordinated zinc at a homodimer interface cleft represents a simple evolutionary path to nascent enzymatic activity; from a protein engineering perspective, future efforts in de novo design of enzyme active sites may benefit from exploring clefts at protein interfaces for active site placement.

[1]  David Baker,et al.  Characterization of the folding energy landscapes of computer generated proteins suggests high folding free energy barriers and cooperativity may be consequences of natural selection. , 2004, Journal of molecular biology.

[2]  R. S. Brown,et al.  The hydrolysis of an activated ester by a tris(4,5-di-n-propyl-2-imidazolyl)phosphine-Zn2+ complex in neutral micellar medium as a model for carbonic anhydrase , 2002 .

[3]  Pinak Chakrabarti,et al.  Cavities and Atomic Packing in Protein Structures and Interfaces , 2008, PLoS Comput. Biol..

[4]  David Baker,et al.  Emergence of symmetry in homooligomeric biological assemblies , 2008, Proceedings of the National Academy of Sciences.

[5]  W. Jencks,et al.  Nonlinear structure-reactivity correlations. The reactivity of nucleophilic reagents toward esters , 1968 .

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

[7]  Yi Lu,et al.  Rational Design of a Structural and Functional Nitric Oxide Reductase , 2009, Nature.

[8]  O. Taran,et al.  Solvent effects and alkali metal ion catalysis in phosphodiester hydrolysis. , 2006, Journal of Organic Chemistry.

[9]  R. Wolfenden,et al.  A proficient enzyme. , 1995, Science.

[10]  Eric A. Althoff,et al.  De Novo Computational Design of Retro-Aldol Enzymes , 2008, Science.

[11]  R. Gibbs,et al.  Substituent effects of an antibody-catalyzed hydrolysis of phenyl esters: further evidence for an acyl-antibody intermediate , 1992 .

[12]  Bryan S. Der,et al.  Metal-mediated affinity and orientation specificity in a computationally designed protein homodimer. , 2012, Journal of the American Chemical Society.

[13]  X. Ambroggio,et al.  Evolution of metal selectivity in templated protein interfaces. , 2010, Journal of the American Chemical Society.

[14]  Jeffrey Skolnick,et al.  The distribution of ligand-binding pockets around protein-protein interfaces suggests a general mechanism for pocket formation , 2012, Proceedings of the National Academy of Sciences.

[15]  David E. Hansen,et al.  DIRECT MEASUREMENT OF THE UNCATALYZED RATE OF HYDROLYSIS OF A PEPTIDE BOND , 1996 .

[16]  Roberto A. Chica,et al.  Iterative approach to computational enzyme design , 2012, Proceedings of the National Academy of Sciences.

[17]  T. Koike,et al.  A zinc(II) complex of 1,5,9-triazacyclododecane ([12]aneN3) as a model for carbonic anhydrase , 1990 .

[18]  Vikas Nanda,et al.  Designing artificial enzymes by intuition and computation. , 2010, Nature chemistry.

[19]  H W Hellinga,et al.  Rational design of nascent metalloenzymes. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[20]  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.

[21]  L. Baltzer,et al.  Designed four-helix bundle catalysts--the engineering of reactive sites for hydrolysis and transesterification reactions of p-nitrophenyl esters. , 1999, Bioorganic & medicinal chemistry.

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

[23]  Barbara Imperiali,et al.  Protein oligomerization: how and why. , 2005, Bioorganic & medicinal chemistry.

[24]  Jens Meiler,et al.  New algorithms and an in silico benchmark for computational enzyme design , 2006, Protein science : a publication of the Protein Society.

[25]  R. Wolfenden Degrees of difficulty of water-consuming reactions in the absence of enzymes. , 2006, Chemical reviews.

[26]  F. Tezcan,et al.  Controlling protein-protein interactions through metal coordination: assembly of a 16-helix bundle protein. , 2007, Journal of the American Chemical Society.

[27]  B. König,et al.  1,4,7,10-tetraazacyclododecane metal complexes as potent promoters of carboxyester hydrolysis under physiological conditions. , 2007, Inorganic chemistry.

[28]  Yinan Wei,et al.  Enzyme-like proteins from an unselected library of designed amino acid sequences. , 2004, Protein engineering, design & selection : PEDS.

[29]  Jasmine L. Gallaher,et al.  Computational Design of an Enzyme Catalyst for a Stereoselective Bimolecular Diels-Alder Reaction , 2010, Science.

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

[31]  S. Aoki,et al.  Selective hydrolysis of phosphate monoester by a supramolecular phosphatase formed by the self-assembly of a bis(Zn(2+)-cyclen) complex, cyanuric acid, and copper in an aqueous solution (cyclen = 1,4,7,10-tetraazacyclododecane). , 2011, Inorganic chemistry.

[32]  S. Son,et al.  Kinetics of Hydrolysis of Phenyl Acetates Catalyzed by the Zinc(II) Complex of 1,5,9-Triazacyclododecane. Evidence for Attack of Water or Hydroxide Ion at the Coordinated Ester. , 1998, Inorganic chemistry.

[33]  N. Grishin,et al.  The subunit interfaces of oligomeric enzymes are conserved to a similar extent to the overall protein sequences , 1994, Protein science : a publication of the Protein Society.

[34]  Reactive-site design in folded-polypeptide catalysts--the leaving group pKa of reactive esters sets the stage for cooperativity in nucleophilic and general-acid catalysis. , 2000, Chemistry.

[35]  R. Radford Expanding the Utility of Proteins as Platforms for Coordination Chemistry , 2011 .

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

[37]  R. Allemann,et al.  Nucleophilic and general acid catalysis at physiological pH by a designed miniature esterase. , 2005, Organic & biomolecular chemistry.

[38]  Daniel W. Kulp,et al.  Design of a switchable eliminase , 2011, Proceedings of the National Academy of Sciences.

[39]  R. Wolfenden,et al.  The "neutral" hydrolysis of simple carboxylic esters in water and the rate enhancements produced by acetylcholinesterase and other carboxylic acid esterases. , 2011, Journal of the American Chemical Society.

[40]  Vikas Nanda,et al.  De novo design of a redox-active minimal rubredoxin mimic. , 2005, Journal of the American Chemical Society.

[41]  Ryo Takeuchi,et al.  Computational redesign of a mononuclear zinc metalloenzyme for organophosphate hydrolysis. , 2012, Nature chemical biology.

[42]  Jeanne A. Stuckey,et al.  Hydrolytic catalysis and structural stabilization in a designed metalloprotein , 2011, Nature chemistry.

[43]  Yi Lu,et al.  From Myoglobin to Heme-Copper Oxidase: Design and Engineering of a CuB Center into Sperm Whale Myoglobin , 2000 .

[44]  K. Ichikawa,et al.  Hydrolysis of natural and artificial phosphoesters using zinc model compound with a histidine-containing pseudopeptide. , 2002, Journal of inorganic biochemistry.

[45]  Janet M. Thornton,et al.  Metal ions in biological catalysis: from enzyme databases to general principles , 2008, JBIC Journal of Biological Inorganic Chemistry.

[46]  J. Edsall,et al.  Esterase activities of human carbonic anhydrases B and C. , 1967, The Journal of biological chemistry.

[47]  R. Lerner,et al.  Induction of an antibody that catalyzes the hydrolysis of an amide bond. , 1988, Science.

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

[49]  D. Rao,et al.  Catalytic antibodies: Concept and promise , 2007 .

[50]  Andrew Williams Effective charge and Leffler's index as mechanistic tools for reactions in solution , 1984 .