Crystal structure of carboxylesterase from Pseudomonas fluorescens, an α/β hydrolase with broad substrate specificity

Background: A group of esterases, classified as carboxylesterases, hydrolyze carboxylic ester bonds with relatively broad substrate specificity and are useful for stereospecific synthesis and hydrolysis of esters. One such carboxylesterase from Pseudomonas fluorescens is a homodimeric enzyme, consisting of 218-residue subunits. It shows a limited sequence similarity to some members of the α/β hydrolase superfamily. Although crystal structures of a number of serine esterases and lipases have been reported, structural information on carboxylesterases is very limited. This study was undertaken in order to provide such information and to understand a structural basis for the substrate specificity of this carboxylesterase. Results: In this study, the crystal structure of carboxylesterase from P. fluorescens has been determined by the isomorphous replacement method and refined to 1.8 A resolution. Each subunit consists of a central seven-stranded β sheet flanked by six α helices. The structure reveals the catalytic triad as Ser114‐His199‐Asp168. The structure of the enzyme in complex with the inhibitor phenylmethylsulfonyl fluoride has also been determined and refined to 2.5 A. The inhibitor is covalently attached to Ser114 of both subunits, with the aromatic ring occupying a hydrophobic site defined by the aliphatic sidechains of Leu23, Ile58, Ile70, Met73 and Val170. No large structural changes are observed between the free and inhibitorbound structures. Conclusions: Carboxylesterase from P. fluorescens has the α/β hydrolase fold and the Ser‐His‐Asp catalytic triad. The active-site cleft in each subunit is formed by the six loops covering the catalytic serine residue. Three of the active-site loops in each subunit are involved in a head-to-head subunit interaction to form a dimer; it may be these extra structural elements, not seen in other esterases, that account for the inability of carboxylesterase to hydrolyze long chain fatty acids. As a result of dimerization, the active-site clefts from the two subunits merge to form holes in the dimer. The active-site clefts are relatively open and thus the catalytic residues are exposed to the solvent. An oxyanion hole, formed by nitrogen atoms of Leu23 and Gln115, is present in both the free and inhibitor-bound structures. An open active site, as well as a large binding pocket for the acid part of substrates, in P. fluorescens carboxylesterase may contribute to its relatively broad substrate specificity.

[1]  K. H. Kalk,et al.  Refined X-ray structures of haloalkane dehalogenase at pH 6.2 and pH 8.2 and implications for the reaction mechanism. , 1993, Journal of molecular biology.

[2]  C. Cambillau,et al.  Crystal structure of cutinase covalently inhibited by a triglyceride analogue , 1997, Protein science : a publication of the Protein Society.

[3]  U Derewenda,et al.  Structure of a myristoyl-ACP-specific thioesterase from Vibrio harveyi. , 1994, Biochemistry.

[4]  S J Remington,et al.  Refined atomic model of wheat serine carboxypeptidase II at 2.2-A resolution. , 1992, Biochemistry.

[5]  M. Haas,et al.  An unusual buried polar cluster in a family of fungal lipases , 1994, Nature Structural Biology.

[6]  Z. Derewenda,et al.  Structure and function of lipases. , 1994, Advances in protein chemistry.

[7]  J. Robert,et al.  Conversion of irinotecan (CPT-11) to its active metabolite, 7-ethyl-10-hydroxycamptothecin (SN-38), by human liver carboxylesterase. , 1996, Biochemical pharmacology.

[8]  Wolfgang Kabsch,et al.  Evaluation of Single-Crystal X-ray Diffraction Data from a Position-Sensitive Detector , 1988 .

[9]  G. Ashley,et al.  Catalysis by dienelactone hydrolase: A variation on the protease mechanism , 1993, Proteins.

[10]  L. Norskov,et al.  A serine protease triad forms the catalytic centre of a triacylglycerol lipase , 1990, Nature.

[11]  H. Sobek,et al.  Further kinetic and molecular characterization of an extremely heat-stable carboxylesterase from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius. , 1989, The Biochemical journal.

[12]  Y Li,et al.  The open conformation of a Pseudomonas lipase. , 1997, Structure.

[13]  Collaborative Computational,et al.  The CCP4 suite: programs for protein crystallography. , 1994, Acta crystallographica. Section D, Biological crystallography.

[14]  J. Thornton,et al.  PROCHECK: a program to check the stereochemical quality of protein structures , 1993 .

[15]  E. Toone,et al.  Enzymes in organic synthesis. 47. Active-site model for interpreting and predicting the specificity of pig liver esterase , 1990 .

[16]  M. Tanaka,et al.  Purification and characterization of a carboxylesterase from rabbit liver lysosomes. , 1987, Journal of biochemistry.

[17]  D. Ollis,et al.  Refined structure of dienelactone hydrolase at 1.8 A. , 1990, Journal of molecular biology.

[18]  C. Cambillau,et al.  Fusarium solani cutinase is a lipolytic enzyme with a catalytic serine accessible to solvent , 1992, Nature.

[19]  B Rubin,et al.  Insights into interfacial activation from an open structure of Candida rugosa lipase. , 1994, The Journal of biological chemistry.

[20]  J. Sack,et al.  CHAIN — A crystallographic modeling program , 1988 .

[21]  David Eisenberg,et al.  Generalized method of determining heavy-atom positions using the difference Patterson function , 1987 .

[22]  R. Verger Lipases: Structure, mechanism and genetic engineering , 1992 .

[23]  H. Jörnvall,et al.  Monomeric and dimeric forms of cholesterol esterase from Candida cylindracea , 1994, FEBS letters.

[24]  J. Thornton,et al.  PROMOTIF—A program to identify and analyze structural motifs in proteins , 1996, Protein science : a publication of the Protein Society.

[25]  K. Sharp,et al.  Protein folding and association: Insights from the interfacial and thermodynamic properties of hydrocarbons , 1991, Proteins.

[26]  H. Tilbeurgh,et al.  Interfacial activation of the lipase–procolipase complex by mixed micelles revealed by X-ray crystallography , 1993, Nature.

[27]  C. Lowe,et al.  The Use of a Novel Recombinant Heroin Esterase in the Development of an Illicit Drugs Biosensor a , 1996, Annals of the New York Academy of Sciences.

[28]  W. Pangborn,et al.  Structure of uncomplexed and linoleate-bound Candida cylindracea cholesterol esterase. , 1995, Structure.

[29]  L. Johnson,et al.  The crystal structure of triacylglycerol lipase from Pseudomonas glumae reveals a partially redundant catalytic aspartate , 1993, FEBS letters.

[30]  J. Pflugrath,et al.  Crystal orientation and X-ray pattern prediction routines for area-detector diffractometer systems in macromolecular crystallography , 1987 .

[31]  S. Suh,et al.  Crystallization and preliminary X-ray crystallographic analysis of carboxylesterase from pseudomonas fluorescens. , 1993, Archives of biochemistry and biophysics.

[32]  J. Schrag,et al.  1.8 A refined structure of the lipase from Geotrichum candidum. , 1993, Journal of molecular biology.

[33]  A. Goldman,et al.  Atomic structure of acetylcholinesterase from Torpedo californica: a prototypic acetylcholine-binding protein , 1991, Science.

[34]  T A Jones,et al.  The sequence, crystal structure determination and refinement of two crystal forms of lipase B from Candida antarctica. , 1994, Structure.

[35]  C Cambillau,et al.  Cutinase, a lipolytic enzyme with a preformed oxyanion hole. , 1994, Biochemistry.

[36]  F. Winkler,et al.  Structure of human pancreatic lipase , 1990, Nature.

[37]  L. Thim,et al.  A model for interfacial activation in lipases from the structure of a fungal lipase-inhibitor complex , 1991, Nature.

[38]  R. Fletterick,et al.  Structural basis for the broad substrate specificity of fiddler crab collagenolytic serine protease 1. , 1997, Biochemistry.

[39]  T. Higashi The processing of diffraction data taken on a screenless Weissenberg camera for macromolecular crystallography , 1989 .

[40]  M. Karplus,et al.  Crystallographic R Factor Refinement by Molecular Dynamics , 1987, Science.

[41]  N. Sakabe X-ray diffraction data collection system for modern protein crystallography with a Weissenberg camera and an imaging plate using synchrotron radiation , 1991 .

[42]  K. Hong,et al.  Characterization of Pseudomonas fluorescens carboxylesterase: cloning and expression of the esterase gene in Escherichia coli. , 1991, Agricultural and biological chemistry.

[43]  M Czjzek,et al.  Atomic resolution (1.0 A) crystal structure of Fusarium solani cutinase: stereochemical analysis. , 1997, Journal of molecular biology.

[44]  O. Ghisalba,et al.  Application of microbes and microbial esterases to the preparation of optically active N-acetylindoline-2-carboxylic acid. , 1987 .

[45]  S. Suh,et al.  The crystal structure of a triacylglycerol lipase from Pseudomonas cepacia reveals a highly open conformation in the absence of a bound inhibitor. , 1997, Structure.

[46]  J. Sussman,et al.  Quaternary ligand binding to aromatic residues in the active-site gorge of acetylcholinesterase. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[47]  Sydney Brenner,et al.  The molecular evolution of genes and proteins: a tale of two serines , 1988, Nature.

[48]  K. Zhang SQUASH - combining constraints for macromolecular phase refinement and extension. , 1993, Acta crystallographica. Section D, Biological crystallography.

[49]  Jones Ta,et al.  Diffraction methods for biological macromolecules. Interactive computer graphics: FRODO. , 1985, Methods in enzymology.

[50]  F. Fonnum,et al.  Purification and characterization of carboxylesterases from rat lung. , 1991, The Biochemical journal.

[51]  Joel L. Sussman,et al.  The α/β hydrolase fold , 1992 .