Functional Properties and Molecular Architecture of Leukotriene A4 Hydrolase, a Pivotal Catalyst of Chemotactic Leukotriene Formation

The leukotrienes are a family of lipid mediators involved in inflammation and allergy. Leukotriene B4 is a classical chemoattractant, which triggers adherence and aggregation of leukocytes to the endothelium at only nM concentrations. In addition, leukotriene B4 modulates immune responses, participates in the host defense against infections, and is a key mediator of PAF-induced lethal shock. Because of these powerful biological effects, leukotriene B4 is implicated in a variety of acute and chronic inflammatory diseases, e.g., nephritis, arthritis, dermatitis, and chronic obstructive pulmonary disease. The final step in the biosynthesis of leukotriene B4 is catalyzed by leukotriene A4 hydrolase, a unique bifunctional zinc metalloenzyme with an anion-dependent aminopeptidase activity. Here we describe the most recent developments regarding our understanding of the function and molecular architecture of leukotriene A4 hydrolase

Structure of an Engineered Porcine Phospholipase A2 with Enhanced Activity at 2.1 Å Resolution. Comparison with the Wild-type Porcine and Crotalus atrox Phospholipase A2

The crystal structure of an engineered phospholipase A2 with enhanced activity has been refined to an R-factor of 18.6% at 2.1 Å resolution using a combination of molecular dynamics refinement by the GROMOS package and least-squares refinement by TNT. This mutant phospholipase was obtained previously by deleting residues 62 to 66 in porcine pancreatic phospholipase A2, and changing Asp59 to Ser, Ser60 to Gly and Asn67 to Tyr. The refined structure allowed a detailed comparison with wild-type porcine and Crotalus atrox phospholipase A2. The conformation of the deletion region appears to be intermediate between that in those two enzymes. The residues in the active center are virtually the same. An internal hydrophobic area occupied by Phe63 in the wild-type porcine phospholipase A2 is kept as conserved as possible by local rearrangement of neighboring atoms. In the mutant structure, this hydrophobic pocket is now occupied by the disulfide bond between residues 61 and 91. A detailed description of the second binding site for a calcium ion in this enzyme is given

Enhanced Activity and Altered Specificity of Phospholipase A2 by Deletion of a Surface Loop

Protein engineering and x-ray crystallography have been used to study the role of a surface loop that is present in pancreatic phospholipases but is absent in snake venom phospholipases. Removal of residues 62 to 66 from porcine pancreatic phospholipase A2 does not change the binding constant for micelles significantly, but it improves catalytic activity up to 16 times on micellar (zwitterionic) lecithin substrates. In contrast, the decrease in activity on negatively charged substrates is greater than fourfold. A crystallographic study of the mutant enzyme shows that the region of the deletion has a well-defined structure that differs from the structure of the wild-type enzyme. No structural changes in the active site of the enzyme were detected

Structure and pathogenicity of antibodies specific for citrullinated collagen type II in experimental arthritis

Antibodies to citrulline-modifi ed proteins have a high diagnostic value in rheumatoid arthritis (RA). However, their biological role in disease development is still unclear. To obtain insight into this question, a panel of mouse monoclonal antibodies was generated against a major triple helical collagen type II (CII) epitope (position 359 – 369; ARGLTGRPGDA) with or without arginines modifi ed by citrullination. These antibodies bind cartilage and synovial tissue, and mediate arthritis in mice. Detection of citrullinated CII from RA patients ’ synovial fl uid demonstrates that cartilage-derived CII is indeed citrullinated in vivo. The structure determination of a Fab fragment of one of these antibodies in complex with a citrullinated peptide showed a surprising beta -turn conformation of the peptide and provided information on citrulline recognition. Based on these findings, we propose that autoimmunity to CII, leading to the production of antibodies specific for both native and citrullinated CII, is an important pathogenic factor in the development of RA

Kinetic behaviour of WT 1's zinc finger domain in binding to the alpha-actinin-1 mRNA

The zinc finger transcription factor Wilms tumour protein (WT 1) is known for its essential involvement in the development of the genitourinary system as well as of other organs and tissues. WT 1 is capable of selectively binding either DNA or mRNA targets. A KTS insertion due to alternative splicing between the zinc fingers 3 and 4 and an unconventional zinc finger 1 are the unique features that distinguish WT 1 from classical DNA-binding C2H2-type zinc finger proteins. The DNA binding characteristics of WT 1 are well studied. Due to lack of information about its native RNA targets, no extensive research has been directed at how WT 1 binds RNA. Using surface plasmon resonance, this study attempts to understand the binding behaviour of WT 1 zinc fingers with its recently reported and first putative mRNA target, ACT 34, whose stem-loop structure is believed to be critical for the interactions with WT 1. We have analysed the interactions of five WT 1 zinc finger truncations with wild-type ACT 34 and four variants. Our results indicate that WT 1 zinc fingers bind ACT 34 in a specific manner, and that this occurs as interplay of all four zinc fingers. We also report that a sensitive kinetic balance, which is equilibrated by both zinc finger 1 and KTS, regulates the interaction with ACT 34. The stem-loop and the flanking nucleotides are important elements for specific recognition by WT 1 zinc fingers. © 2010 Elsevier Inc

Purification, Crystallisation and Preliminary X-ray Analysis of Penicillin Binding Protein 4 from Escherichia coli, a Protein Related to Class A β-Lactamases

Crystals of the penicillin binding protein 4 (PBP4) from Escherichia coli have been obtained at 37°C from liquid to liquid diffusion experiments in capillaries. PBP4 was dissolved in a 1.0 M ammonium sulphate solution, buffered at pH 7.2, to a concentration of 5 mg/ml, and was layered on top of a 1.6 to 2.2 M ammonium sulphate solution. Crystals appeared within four to six weeks. They belong to space group C222 with cell dimensions a = 68.5 Å, b = 100.5 Å and c = 137.0 Å, and diffract to at least 2.8 Å resolution. There is one molecule with a molecule mass of 49,568 Da in the asymmetric unit.

Leukotriene A4 hydrolase: Identification of a common carboxylate recognition site for the epoxide hydrolase and aminopeptidase substrates

Leukotriene ( LT) A(4) hydrolase is a bifunctional zinc metalloenzyme, which converts LTA(4) into the neutrophil chemoattractant LTB4 and also exhibits an anion-dependent aminopeptidase activity. In the x-ray crystal structure of LTA(4) hydrolase, Arg(563) and Lys(565) are found at the entrance of the active center. Here we report that replacement of Arg(563), but not Lys(565), leads to complete abrogation of the epoxide hydrolase activity. However, mutations of Arg(563) do not seem to affect substrate binding strength, because values of K-i for LTA(4) are almost identical for wild type and ( R563K) LTA(4) hydrolase. These results are supported by the 2.3-Angstrom crystal structure of (R563A) LTA(4) hydrolase, which does not reveal structural changes that can explain the complete loss of enzyme function. For the aminopeptidase reaction, mutations of Arg(563) reduce the catalytic activity (V-max = 0.3 - 20%), whereas mutations of Lys(565) have limited effect on catalysis (V-max = 58 - 108%). However, in (K565A)- and (K565M) LTA(4) hydrolase, i.e. mutants lacking a positive charge, values of the Michaelis constant for alanine-p-nitroanilide increase significantly (K-m = 480 - 640%). Together, our data indicate that Arg(563) plays an unexpected, critical role in the epoxide hydrolase reaction, presumably in the positioning of the carboxylate tail to ensure perfect substrate alignment along the catalytic elements of the active site. In the aminopeptidase reaction, Arg(563) and Lys(565) seem to cooperate to provide sufficient binding strength and productive alignment of the substrate. In conclusion, Arg(563) and Lys(565) possess distinct roles as carboxylate recognition sites for two chemically different substrates, each of which is turned over in separate enzymatic reactions catalyzed by LTA(4) hydrolase

Site-directed mutagenesis and X-ray crystallography of two phospholipase A2 mutants: Y52F and Y73F

Tyr52 and Tyr73 are conserved amino acid residues throughout all vertebrate phospholipases A2. They are part of an extended hydrogen bonding system that links the N-terminal α-NH3+-group to the catalytic residues His48 and Asp99. These tyrosines were replaced by phenylalanines in a porcine pancreatic phospholipase A2 mutant, in which residues 62-66 had been deleted (Δ62-66PLA2). The mutations did not affect the catalytic properties of the enzyme, nor the folding kinetics. The stability against denaturation by guanidine hydrochloride was decreased, however. To analyse how the enzyme compensates for the loss of the tyrosine hydroxyl group, the X-ray structures of the ΔY52F and ΔY73F mutants were determined. After crystallographic refinement the final crystallographic R-factors were 18.1% for the ΔY52F mutant (data between 7 and 2.3 Å resolution) and 19.1% for the ΔY73F mutant (data between 7 and 2.4 Å resolution). No conformational changes occurred in the mutants compared with the Δ62-66PLA2, but an empty cavity formed at the site of the hydroxyl group of the former tyrosine. In both mutants the Asp99 side chain loses one of its hydrogen bonds and this might explain the observed destabilization.

Crystal Structure of a Porcine Pancreatic Phospholipase A2 Mutant. A Large Conformational Change Caused by the F63V Point Mutation

The highly homologous bovine and porcine pancreatic phospholipases A2 (85% amino acid residue identity) show a large conformational difference in the loop from residue 59 to 71. In bovine phospholipase A2 residues 59 to 66 adopt an α-helix conformation, while residues 67 to 71 are in a surface loop. Residues 59 to 66 in the porcine enzyme have a random coil conformation, and residues 67 to 71 form a short 310-helix. It has been suggested that most probably this conformational difference is caused by the substitution Val63 (bovine) to Phe63 (porcine) in the otherwise invariant loop 59 to 70. To test this hypothesis, a mutant porcine phospholipase A2 was constructed in which residue Phe63 was replaced by a Val. The activity of this F63V mutant towards aggregated substrates was about half the activity of wild-type porcine phospholipase A2, but significantly different from that of the bovine enzyme. The affinity for zwitterionic interfaces was found to be intermediate between porcine and bovine phospholipase. The mutation did not have any effect on the stability of the enzyme towards denaturation by guanidine•HCl. The F63V mutant was crystallized in space group P212121 with cell dimensions a = 79.88 Å, b = 65.23 Å, c = 52.62 Å, with two molecules per asymmetric unit. Its three-dimensional structure was solved by molecular replacement methods, and refined to a crystallographic R-factor of 17.6% for all data between 10 and 2.2 Å resolution. In one molecule the 58 to 71 loop is in very weak density, suggesting a high degree of disorder or flexibility. The conformation of the same loop in the other molecule could be determined unambiguously. It shows a conformation which resembles more that of bovine phospholipase A2 than that of porcine phospholipase. It is concluded that indeed the single F63V substitution causes a dramatic conformational change.