Interfacial catalysis: the mechanism of phospholipase A2

A chemical description of the action of phospholipase A2 (PLA2) can now be inferred with confidence from three high-resolution x-ray crystal structures. The first is the structure of the PLA2 from the venom of the Chinese cobra (Naja naja atra) in a complex with a phosphonate transition-state analogue. This enzyme is typical of a large, well-studied homologous family of PLA2S. The second is a similar complex with the evolutionarily distant bee-venom PLA2. The third structure is the uninhibited PLA2 from Chinese cobra venom. Despite the different molecular architectures of the cobra and bee-venom PLA2s, the transition-state analogue interacts in a nearly identical way with the catalytic machinery of both enzymes. The disposition of the fatty-acid side chains suggests a common access route of the substrate from its position in the lipid aggregate to its productive interaction with the active site. Comparison of the cobra-venom complex with the uninhibited enzyme indicates that optimal binding and catalysis at the lipid-water interface is due to facilitated substrate diffusion from the interfacial binding surface to the catalytic site rather than an allosteric change in the enzyme's structure. However, a second bound calcium ion changes its position upon the binding of the transition-state analogue, suggesting a mechanism for augmenting the critical electrophile.

[1]  J. Kraut,et al.  Structure of Subtilisin BPN′ at 2.5 Å Resolution , 1969, Nature.

[2]  D. Blow,et al.  Role of a Buried Acid Group in the Mechanism of Action of Chymotrypsin , 1969, Nature.

[3]  M. Lazdunski,et al.  Zymogen-enzyme transformations. On the mechanism of activation of prophospholipase A. , 1972, European journal of biochemistry.

[4]  M. Wells The mechanism of interfacial activation of phospholipase A2. , 1974, Biochemistry.

[5]  J. Vidal,et al.  Zymogen-catalyzed hydrolysis of monomeric substrates and the presence of a recognition site for lipid-water interfaces in phospholipase A2. , 1974, Biochemistry.

[6]  J. Seelig Deuterium magnetic resonance: theory and application to lipid membranes , 1977, Quarterly Reviews of Biophysics.

[7]  R. Verger,et al.  Further studies of mode of action of lipolytic enzymes. , 1977, The Journal of biological chemistry.

[8]  P. Hitchcock,et al.  A refinement analysis of the crystallography of the phospholipid, 1,2-dilauroyl-DL-phosphatidylethanolamine, and some remarks on lipid—lipid and lipid-protein interactions , 1977, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[9]  R. Pearson,et al.  The molecular structure of lecithin dihydrate , 1979, Nature.

[10]  H. Hauser,et al.  Interactions of the Polar Groups of Phospholipid Bilayer Membranes , 1979 .

[11]  J. Drenth,et al.  Methylation of histidine-48 in pancreatic phospholipase A2. Role of histidine and calcium ion in the catalytic mechanism. , 1980, Biochemistry.

[12]  K. H. Kalk,et al.  Active site and catalytic mechanism of phospholipase A2 , 1981, Nature.

[13]  H. Verheij,et al.  Modification of carboxylate groups in bovine pancreatic phospholipase A2. Identification of aspartate-49 as Ca2+-binding ligand. , 1981, European journal of biochemistry.

[14]  W. Hol,et al.  Structure of bovine pancreatic phospholipase A2 at 1.7A resolution. , 1981, Journal of molecular biology.

[15]  H. Hauser,et al.  Preferred conformation and molecular packing of phosphatidylethanolamine and phosphatidylcholine. , 1981, Biochimica et biophysica acta.

[16]  A. Kossiakoff,et al.  Direct determination of the protonation states of aspartic acid-102 and histidine-57 in the tetrahedral intermediate of the serine proteases: neutron structure of trypsin. , 1981, Biochemistry.

[17]  R. Gandour On the importance of orientation in general base catalysis by carboxylate , 1981 .

[18]  E. Dennis,et al.  Immobilized phospholipase A2 from cobra venom. Prevention of substrate interfacial and activator effects. , 1985, The Journal of biological chemistry.

[19]  M. Tsai,et al.  Phospholipids chiral at phosphorus. Use of chiral thiophosphatidylcholine to study the metal-binding properties of bee venom phospholipase A2. , 1985, Biochemistry.

[20]  P. Sigler,et al.  Facing up to membranes: structure/function relationships in phospholipases. , 1987, Cold Spring Harbor symposia on quantitative biology.

[21]  Mahendra K. Jain,et al.  Dehydration of the lipid-protein microinterface on binding of phospholipase A2 to lipid bilayers. , 1987, Biochimica et biophysica acta.

[22]  R. Biltonen,et al.  The activation of porcine pancreatic phospholipase A2 by dipalmitoylphosphatidylcholine large unilamellar vesicles. Analysis of the state of aggregation of the activated enzyme. , 1987, The Journal of biological chemistry.

[23]  O. Kuipers,et al.  Expression of porcine pancreatic phospholipase A2. Generation of active enzyme by sequence-specific cleavage of a hybrid protein from Escherichia coli. , 1987, Nucleic acids research.

[24]  A. Joachimiak,et al.  Crystal structure of trp represser/operator complex at atomic resolution , 1988, Nature.

[25]  A. Tomasselli,et al.  The chemical basis for interfacial activation of monomeric phospholipases A2. Autocatalytic derivatization of the enzyme by acyl transfer from substrate. , 1988, The Journal of biological chemistry.

[26]  I. Johnson,et al.  Rotational dynamics of the single tryptophan of porcine pancreatic phospholipase A2, its zymogen, and an enzyme/micelle complex. A steady-state and time-resolved anisotropy study. , 1988, Biochemistry.

[27]  M. Gelb,et al.  Phosphonate-containing phospholipid analogues as tight-binding inhibitors of phospholipase-A2 , 1988 .

[28]  P. Fitzgerald MERLOT, an integrated package of computer programs for the determination of crystal structures by molecular replacement , 1988 .

[29]  E. Dennis,et al.  Probing the role of substrate conformation in phospholipase A2 action on aggregated phospholipids using constrained phosphatidylcholine analogues. , 1988, The Journal of biological chemistry.

[30]  N. Oda,et al.  Tryptophan residue essential for activity of Naja naja atra phospholipase A2. , 1988, Journal of biochemistry.

[31]  J. Noel,et al.  Phospholipase A2 engineering: Design, synthesis, and expression of a gene for bovine (pro)phospholipase A2 , 1989, Journal of cellular biochemistry.

[32]  H. Verheij,et al.  The role of Asp‐49 and other conserved amino acids in phospholipases A2 and their importance for enzymatic activity , 1989, Journal of cellular biochemistry.

[33]  M. James,et al.  Crystal structures of the helix-loop-helix calcium-binding proteins. , 1989, Annual review of biochemistry.

[34]  O. Kuipers,et al.  Evidence for the involvement of tyrosine-69 in the control of stereospecificity of porcine pancreatic phospholipase A2. , 1989, Protein engineering.

[35]  O. Berg,et al.  The kinetics of interfacial catalysis by phospholipase A2 and regulation of interfacial activation: hopping versus scooting. , 1989, Biochimica et biophysica acta.

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

[37]  D. Blow More of the catalytic triad , 1990, Nature.

[38]  J. Noel,et al.  Phospholipase A2 engineering. 4. Can the active-site aspartate-99 function alone? , 1990 .

[39]  M. Gelb,et al.  Kinetic and inhibition studies of phospholipase A2 with short-chain substrates and inhibitors. , 1990, Biochemistry.

[40]  M. Gelb,et al.  Crystal structure of bee-venom phospholipase A2 in a complex with a transition-state analogue , 1990, Science.

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