Analysis of zinc binding sites in protein crystal structures

The geometrical properties of zinc binding sites in a dataset of high quality protein crystal structures deposited in the Protein Data Bank have been examined to identify important differences between zinc sites that are directly involved in catalysis and those that play a structural role. Coordination angles in the zinc primary coordination sphere are compared with ideal values for each coordination geometry, and zinc coordination distances are compared with those in small zinc complexes from the Cambridge Structural Database as a guide of expected trends. We find that distances and angles in the primary coordination sphere are in general close to the expected (or ideal) values. Deviations occur primarily for oxygen coordinating atoms and are found to be mainly due to H‐bonding of the oxygen coordinating ligand to protein residues, bidentate binding arrangements, and multi‐zinc sites. We find that H‐bonding of oxygen containing residues (or water) to zinc bound histidines is almost universal in our dataset and defines the elec‐His‐Zn motif. Analysis of the stereochemistry shows that carboxyl elec‐His‐Zn motifs are geometrically rigid, while water elec‐His‐Zn motifs show the most geometrical variation. As catalytic motifs have a higher proportion of carboxyl elec atoms than structural motifs, they provide a more rigid framework for zinc binding. This is understood biologically, as a small distortion in the zinc position in an enzyme can have serious consequences on the enzymatic reaction. We also analyze the sequence pattern of the zinc ligands and residues that provide elecs, and identify conserved hydrophobic residues in the endopeptidases that also appear to contribute to stabilizing the catalytic zinc site. A zinc binding template in protein crystal structures is derived from these observations.

[1]  B. Henrissat,et al.  The crystal structures of Sinapis alba myrosinase and a covalent glycosyl-enzyme intermediate provide insights into the substrate recognition and active-site machinery of an S-glycosidase. , 1997, Structure.

[2]  Y. Kai,et al.  Structure of the zinc endoprotease from Streptomyces caespitosus. , 1997, Journal of biochemistry.

[3]  S. Ramaswamy,et al.  Flexibility of liver alcohol dehydrogenase in stereoselective binding of 3-butylthiolane 1-oxides. , 1997, Biochemistry.

[4]  William N. Lipscomb,et al.  Recent Advances in Zinc Enzymology. , 1996, Chemical reviews.

[5]  G. Schulz,et al.  Refined high-resolution structure of the metal-ion dependent L-fuculose-1-phosphate aldolase (class II) from Escherichia coli. , 1996, Acta crystallographica. Section D, Biological crystallography.

[6]  C. Pabo,et al.  Zif268 protein-DNA complex refined at 1.6 A: a model system for understanding zinc finger-DNA interactions. , 1996, Structure.

[7]  Z. Dauter,et al.  Zinc- and iron-rubredoxins from Clostridium pasteurianum at atomic resolution: a high-precision model of a ZnS4 coordination unit in a protein. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[8]  L. Wyns,et al.  Sequential Structural Changes upon Zinc and Calcium Binding to Metal-free Concanavalin A* , 1996, The Journal of Biological Chemistry.

[9]  O. Herzberg,et al.  Crystal structure of the wide-spectrum binuclear zinc beta-lactamase from Bacteroides fragilis. , 1996, Structure.

[10]  Charles W. Bock,et al.  Calcium Ion Coordination: A Comparison with That of Beryllium, Magnesium, and Zinc , 1996 .

[11]  D. Suck,et al.  Crystal structure of tRNA‐guanine transglycosylase: RNA modification by base exchange. , 1996, The EMBO journal.

[12]  M. Browner,et al.  Matrilysin-inhibitor complexes: common themes among metalloproteases. , 1996, Biochemistry.

[13]  L. Liotta,et al.  Batimastat, a potent matrix mealloproteinase inhibitor, exhibits an unexpected mode of binding. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[14]  S. Ramaswamy,et al.  Crystal structure of cod liver class I alcohol dehydrogenase: Substrate pocket and structurally variable segments , 1996, Protein science : a publication of the Protein Society.

[15]  Steven L. Cohen,et al.  Structural similarity between TAFs and the heterotetrameric core of the histone octamer , 1996, Nature.

[16]  J. Berg,et al.  The Galvanization of Biology: A Growing Appreciation for the Roles of Zinc , 1996, Science.

[17]  W. Lipscomb,et al.  Two-metal ion mechanism of bovine lens leucine aminopeptidase: active site solvent structure and binding mode of L-leucinal, a gem-diolate transition state analogue, by X-ray crystallography. , 1995, Biochemistry.

[18]  P. Beachy,et al.  A potential catalytic site revealed by the 1.7-Å crystal structure of the amino-terminal signalling domain of Sonic hedgehog , 1995, Nature.

[19]  J. Fox,et al.  Structural interaction of natural and synthetic inhibitors with the venom metalloproteinase, atrolysin C (form d). , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[20]  K. Acharya,et al.  Crystal structure of the superantigen enterotoxin C2 from Staphylococcus aureus reveals a zinc-binding site. , 1995, Structure.

[21]  W. Lipscomb,et al.  Transition state analogue L-leucinephosphonic acid bound to bovine lens leucine aminopeptidase: X-ray structure at 1.65 A resolution in a new crystal form. , 1995, Biochemistry.

[22]  M. Bolognesi,et al.  Three-dimensional structure of Xenopus laevis Cu,Zn superoxide dismutase b determined by X-ray crystallography at 1.5 A resolution. , 1995, Acta crystallographica. Section D, Biological crystallography.

[23]  D. Christianson,et al.  X-Ray Crystallographic Studies of Engineered Hydrogen Bond Networks in a Protein-Zinc Binding Site , 1995 .

[24]  C. Fierke,et al.  Hydrogen bond network in the metal binding site of carbonic anhydrase enhances zinc affinity and catalytic efficiency , 1995 .

[25]  L Regan,et al.  Protein design: novel metal-binding sites. , 1995, Trends in biochemical sciences.

[26]  J. Hurley,et al.  Crystal structure of the Cys2 activator-binding domain of protein kinase Cδ in complex with phorbol ester , 1995, Cell.

[27]  M. Browner,et al.  Crystal structures of matrilysin-inhibitor complexes , 1995 .

[28]  P. Reinemer,et al.  The metzincins — Topological and sequential relations between the astacins, adamalysins, serralysins, and matrixins (collagenases) define a super family of zinc‐peptidases , 1995, Protein science : a publication of the Protein Society.

[29]  A G Murzin,et al.  SCOP: a structural classification of proteins database for the investigation of sequences and structures. , 1995, Journal of molecular biology.

[30]  A. Hassell,et al.  Crystal structures of recombinant 19-kDa human fibroblast collagenase complexed to itself. , 1995, Biochemistry.

[31]  R. Huber,et al.  X-ray structures of human neutrophil collagenase complexed with peptide hydroxamate and peptide thiol inhibitors. Implications for substrate binding and rational drug design. , 1995, European journal of biochemistry.

[32]  D I Stuart,et al.  Alpha-lactalbumin possesses a distinct zinc binding site. , 1995, The Journal of biological chemistry.

[33]  U. Baumann Crystal structure of the 50 kDa metallo protease from Serratia marcescens. , 1994, Journal of molecular biology.

[34]  L. Amzel,et al.  Structures of three human beta alcohol dehydrogenase variants. Correlations with their functional differences. , 1994, Journal of molecular biology.

[35]  R. Wahl,et al.  1.56 Å structure of mature truncated human fibroblast collagenase , 1994, Proteins.

[36]  S. Ramaswamy,et al.  Structures of Horse Liver Alcohol Dehydrogenase Complexed with NAD+ and Substituted Benzyl Alcohols , 1994 .

[37]  B Chevrier,et al.  Crystal structure of Aeromonas proteolytica aminopeptidase: a prototypical member of the co-catalytic zinc enzyme family. , 1994, Structure.

[38]  J. Ghuysen,et al.  Binding site‐shaped repeated sequences of bacterial wall peptidoglycan hydrolases , 1994, FEBS letters.

[39]  R. Huber,et al.  The X‐ray crystal structure of the catalytic domain of human neutrophil collagenase inhibited by a substrate analogue reveals the essentials for catalysis and specificity. , 1994, The EMBO journal.

[40]  J. Springer,et al.  The NMR structure of the inhibited catalytic domain of human stromelysin–1 , 1994, Nature Structural Biology.

[41]  A. Liljas,et al.  Inhibition and catalysis of carbonic anhydrase. Recent crystallographic analyses. , 1994, European journal of biochemistry.

[42]  K. Flaherty,et al.  Three-dimensional structure of the elastase of Pseudomonas aeruginosa at 1.5-A resolution. , 1993, The Journal of biological chemistry.

[43]  U. Baumann,et al.  Three‐dimensional structure of the alkaline protease of Pseudomonas aeruginosa: a two‐domain protein with a calcium binding parallel beta roll motif. , 1993, The EMBO journal.

[44]  Y. Hata,et al.  Structural analysis of Serratia protease , 1993 .

[45]  R. Chidambaram,et al.  Modelling of hydrogen bonding in X-ray protein structures using neutron data from amino acids and small peptides , 1993 .

[46]  B. Vallee,et al.  New perspective on zinc biochemistry: cocatalytic sites in multi-zinc enzymes. , 1993, Biochemistry.

[47]  A. Wehnert,et al.  Structure of cobalt carbonic anhydrase complexed with bicarbonate. , 1992, Journal of molecular biology.

[48]  D. R. Holland,et al.  Structural comparison suggests that thermolysin and related neutral proteases undergo hinge-bending motion during catalysis. , 1992, Biochemistry.

[49]  R. Huber,et al.  Structure of astacin and implications for activation of astacins and zinc-ligation of collagenases , 1992, Nature.

[50]  K. Wilson,et al.  The structure of neutral protease from Bacillus cereus at 0.2-nm resolution. , 1992, European journal of biochemistry.

[51]  F. Richards,et al.  Construction of new ligand binding sites in proteins of known structure. I. Computer-aided modeling of sites with pre-defined geometry. , 1991, Journal of molecular biology.

[52]  S. Harrison,et al.  A structural taxonomy of DNA-binding domains , 1991, Nature.

[53]  D. Silverman The catalytic mechanism of carbonic anhydrase , 1991 .

[54]  E. E. Kim,et al.  Reaction mechanism of alkaline phosphatase based on crystal structures. Two-metal ion catalysis. , 1991, Journal of molecular biology.

[55]  P. Chakrabarti,et al.  Geometry of interaction of metal ions with histidine residues in protein structures. , 1990, Protein engineering.

[56]  D. Christianson,et al.  Another catalytic triad? , 1990, Nature.

[57]  B. Vallee,et al.  Zinc coordination, function, and structure of zinc enzymes and other proteins. , 1990, Biochemistry.

[58]  Angelo Vedani,et al.  A new force field for modeling metalloproteins , 1990 .

[59]  L. Lebioda,et al.  Crystal Structure of Holoenzyme Refined at 1.9 Angstroms Resolution: Trigonal-Bipyramidal Geometry of the Cation Binding Site , 1989 .

[60]  D. Christianson,et al.  Carboxylate-histidine-zinc interactions in protein structure and function , 1989 .

[61]  E. Dodson,et al.  Phenol stabilizes more helix in a new symmetrical zinc insulin hexamer , 1989, Nature.

[62]  H M Holden,et al.  Slow- and fast-binding inhibitors of thermolysin display different modes of binding: crystallographic analysis of extended phosphonamidate transition-state analogues. , 1989, Biochemistry.

[63]  T L Blundell,et al.  The structure of 2Zn pig insulin crystals at 1.5 A resolution. , 1988, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[64]  M. Sternberg,et al.  Analysis of the relationship between side-chain conformation and secondary structure in globular proteins. , 1987, Journal of molecular biology.

[65]  A. Gronenborn,et al.  The pKa values of two histidine residues in human haemoglobin, the Bohr effect, and the dipole moments of alpha-helices. , 1985, Journal of molecular biology.

[66]  E. Dodson,et al.  Structural stability in the 4-zinc human insulin hexamer. , 1984, Proceedings of the National Academy of Sciences of the United States of America.

[67]  Carver Ja,et al.  Assignment of 1H NMR resonances of histidine and other aromatic residues in met-, cyano-, oxy-, and (carbon monoxy)myoglobins. , 1984 .

[68]  D C Rees,et al.  Refined crystal structure of carboxypeptidase A at 1.54 A resolution. , 1983, Journal of molecular biology.

[69]  B. Matthews,et al.  Structure of thermolysin refined at 1.6 A resolution. , 1982, Journal of molecular biology.

[70]  T. Blundell,et al.  X-ray analysis (1. 4-A resolution) of avian pancreatic polypeptide: Small globular protein hormone. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[71]  J. Richardson,et al.  Determination and analysis of the 2 A-structure of copper, zinc superoxide dismutase. , 1980, Journal of molecular biology.

[72]  F. Allen,et al.  The Cambridge Crystallographic Data Centre: computer-based search, retrieval, analysis and display of information , 1979 .

[73]  P. Argos,et al.  Similarities in active center geometries of zinc-containing enzymes, proteases and dehydrogenases. , 1978, Journal of molecular biology.

[74]  G J Williams,et al.  The Protein Data Bank: a computer-based archival file for macromolecular structures. , 1977, Journal of molecular biology.

[75]  K. Uğurbil,et al.  Nuclear magnetic resonance and chemical modification studies of bovine erythrocyte superoxide dismutase: evidence for zinc-promoted organization of the active site structure. , 1977, Biochemistry.

[76]  Peter J. Sadler,et al.  Zinc in enzymes , 1976, Nature.

[77]  B. Jonsson,et al.  The catalytic mechanism of carbonic anhydrase. , 1973, Proceedings of the National Academy of Sciences of the United States of America.

[78]  F. Albert Cotton,et al.  Advanced Inorganic Chemistry , 1999 .

[79]  J. Berg,et al.  Lessons from zinc-binding peptides. , 1997, Annual review of biophysics and biomolecular structure.

[80]  A. Bairoch,et al.  The PROSITE database, its status in 1997 , 1997, Nucleic Acids Res..

[81]  R. Hubbard,et al.  The x-ray crystal structure of phosphomannose isomerase from Candida albicans at 1.7 angstrom resolution. , 1996, Nature structural biology.

[82]  Charles W. Bock,et al.  Hydration of Zinc Ions: A Comparison with Magnesium and Beryllium Ions , 1995 .

[83]  Anders Liljas,et al.  Inhibition and catalysis of carbonic anhydrase , 1994 .

[84]  S. Ramaswamy,et al.  Structures of horse liver alcohol dehydrogenase complexed with NAD+ and substituted benzyl alcohols. , 1994, Biochemistry.

[85]  A R Rees,et al.  The prediction and characterization of metal binding sites in proteins. , 1993, Protein engineering.

[86]  A. Liljas,et al.  Carbonic anhydrase and the role of orientation in catalysis , 1993 .

[87]  J P Glusker,et al.  The stereochemistry of the recognition of nitrogen-containing heterocycles by hydrogen bonding and by metal ions. , 1993, Receptor.

[88]  J. Coleman,et al.  Zinc proteins: enzymes, storage proteins, transcription factors, and replication proteins. , 1992, Annual review of biochemistry.

[89]  J. Glusker Structural aspects of metal liganding to functional groups in proteins. , 1991, Advances in protein chemistry.

[90]  D. Christianson,et al.  Structural biology of zinc. , 1991, Advances in protein chemistry.

[91]  D. Silverman,et al.  The catalytic mechanism of carbonic anhydrase: implications of a rate-limiting protolysis of water , 1988 .

[92]  W. H. Armstrong Metalloprotein Crystallography Survey of Recent Results and Relationships to Model Studies , 1988 .

[93]  T A Jones,et al.  Refined structure of human carbonic anhydrase II at 2.0 Å resolution , 1988, Proteins.