Human serum Paraoxonase/Arylesterase's retained hydrophobic N-terminal leader sequence associates with HDLs by binding phospholipids : apolipoprotein A-I stabilizes activity.

In serum, human paraoxonase/arylesterase (PON1) is found exclusively associated with high density lipoprotein (HDL) and contributes to its antiatherogenic properties by inhibiting low density lipoprotein (LDL) oxidation. Difficulties in purifying PON1 from apolipoprotein A-I (apoA-I) suggested that PON1's association with HDL may occur through a direct binding between these 2 proteins. An unusual property of PON1 is that the mature protein retains its hydrophobic N-terminal signal sequence. By expressing in vitro a mutant PON1 with a cleavable N-terminus, we demonstrate that PON1 associates with lipoproteins through its N-terminus by binding phospholipids directly rather than binding apoA-I. Nonetheless, apoA-I stabilized arylesterase activity more than did phospholipid alone, apoA-II, or apoE. Consequently, we studied the role of apoA-I in PON1 expression and HDL association in mice genetically deficient in apoA-I. Though present in HDL fractions at decreased levels, PON1 arylesterase activity was less stable than in control mice. Furthermore, PON1 could be competitively removed from HDL by phospholipids, suggesting that PON1's retained N-terminal peptide allows transfer of the enzyme between phospholipid surfaces. Thus, our data suggest that PON1 is stabilized by apoA-I, and its binding to HDL and physiological distribution are dependent on the direct binding of the retained hydrophobic N-terminus to phospholipids optimally presented in association with apoA-I.

Evidence that several conserved histidine residues are required for hydrolytic activity of human paraoxonase/arylesterase.

Recent evidence has been acquired that implicates an important role for several histidine residues in the hydrolytic mechanisms of human paraoxonase/arylesterase (PON1). Following titration with diethylpyrocarbonate (DEPC), both human serum and recombinant human type Q PON1 were inhibited in respect to their hydrolytic activity in a dose-responsive manner. Human PON1 treated with varying concentrations lost hydrolytic activity, and with each histidine modified, there was an exponential drop in hydrolytic activity. The reaction was followed spectrophotometrically at 244 nm. Recombinant wild-type and C283A PON1 enzymes inhibited with DEPC and subsequently treated with hydroxylamine had partial restoration of activity. The C283A mutant lacks a free sulfhydryl group, indicating that its inactivation is due to histidine specific modification. The dose response and time course of inactivation as well as the extent of reactivation by hydroxylamine were similar for both the wild-type and mutant recombinant enzymes. Mutants of PON1 containing an asparagine substituted for each of several conserved histidine residues lost hydrolytic activity for each single substitution. The mutants of PON1 constructed and assayed for arylesterase activity were H114N, H133N, and H284N. Each single aminoacid substitution rendered the enzyme catalytically inactive. These two pieces of evidence implicate an important role for several histidine residues in the hydrolytic mechanism of PON1. Although it is unusual for a calcium dependent enzyme to require histidines for its catalytic activity, acquired data suggest such a circumstance.

Properties of the retained N-terminal hydrophobic leader sequence in human serum paraoxonase/arylesterase.

Human serum paraoxonase/arylesterase (PON1) is HDL-associated and appears to protect low density lipoproteins (LDL) from oxidation. Mature PON1 retains its N-terminal hydrophobic signal sequence, which may be needed for binding to HDL. By site-directed mutagenesis, we created a mutant PON1 (A19A20) with a cleavable N-terminus to determine if this peptide mediated binding to lipoproteins. As a model system, we studied binding of mutant and wild type PON1s to lipoproteins in fetal bovine serum-containing expression medium and found that the wild type recombinant enzyme associated with lipoproteins whereas the A19A20 mutant did not. These results show that the N-terminus is required for binding to either apolipoproteins or phospholipids. Furthermore, we showed that wild type enzyme can bind to phospholipids directly without apolipoproteins. To determine if lipid binding is a requirement for PON1's protection against LDL oxidation, we used a copper ion-induced oxidation system and found that the wild type enzyme and A19A20 mutant showed similar reductions in both peroxide and aldehyde formation. We conclude that PON1 depends upon its N-terminal hydrophobic peptide for its association with serum lipoproteins.

On the physiological role(s) of the paraoxonases.

In recent years several lines of evidence have indicated that serum paraoxonase (PON1), and perhaps other mammalian paraoxonases, act as important guardians against cellular damage from toxic agents, such as organophosphates, oxidized lipids in the plasma low density lipoproteins (LDL), and against bacterial endotoxins. For some of these protective activities but not all, PON1 requires calcium ion. The catalyzed chemical reactions generally seem to be hydrolytic, but for some types of protection this may not be so. Several other metals have very high affinity for PON1 and may displace calcium. Replacement or substitution of calcium by other metals could extend the range of catalytic properties and the substrate specificity of the paraoxonases, as it does for the mammalian DFPases. Although this Third International Meeting on Esterases Reacting with Organophosphorus Compounds focuses on the organophosphatase activities of paraoxonase and related enzymes, it is important to also briefly review some of the current directions in several laboratories searching for additional functions of the paraoxonases to extend our understanding of the properties of this family of enzymes which now seem to have both physiological and toxicological importance.

The human serum paraoxonase/arylesterase gene (PON1) is one member of a multigene family.

A physiological role for paraoxonase (PON1) is still uncertain, but it catalyzes the hydrolysis of toxic organophosphates. Evidence that the human genome contains two PON1-like genes, designated PON2 and PON3, is presented here. Human PON1 and PON2 each have nine exons, and the exon/intron junctions occur at equivalent positions. PON1 and PON2 genes are both on chromosome 7 in human and on chromosome 6 in the mouse. Turkey and chicken, like most birds, lack paraoxonase activity and are very susceptible to organophosphates. However, they have a PON-like gene with approximately 70% identity with human PON1, PON2, and PON3. Another unexpected finding is that the deduced amino acid sequences of PON2 in human, mouse, dog, turkey, and chicken and of human PON3 are all missing the amino acid residue 105, which is lysine in human PON1. The expanded number of PON genes will have important implications for future experiments designed to discover the individual functions, catalytic properties, and physiological roles of the paraoxonases.

The genetic mapping and gene structure of mouse paraoxonase/arylesterase.

The physiological role of mammalian paraoxonase/arylesterase is unknown. However, paraoxonase is an HDL-associated protein, and recent studies indicate that it may have anti-atherogenic functions. We describe the chromosomal localization and structure of the mouse paraoxonase gene (Pon1) to establish Pon1 as a candidate gene for genetically determined traits or pathological states in the mouse. The coding portion of Pon1 extends over approximately 25-26 kb and consists of nine exons and eight introns. We also present nucleotide sequences from the 5'-flanking region of Pon1 containing numerous consensus sequences for DNA binding proteins. Haplotype analysis of 94 N2 progeny from an interspecific cross indicates that Pon1 is localized on proximal mouse chromosome 6 near D6Mit86. This assignment excludes Pon1 as a candidate for the atherosclerosis susceptibility genes Ath1, Ath2, and Ath3. However, Pon1 is a promising candidate for the remaining unmapped Ath genes.

Reconsideration of the catalytic center and mechanism of mammalian paraoxonase/arylesterase.

For three decades, mammalian paraoxonase (A-esterase, aromatic esterase, arylesterase; PON, EC 3.1.8.1) has been thought to be a cysteine esterase demonstrating structural and mechanistic homologies with the serine esterases (cholinesterases and carboxyesterases). Human, mouse, and rabbit PONs each contain only three cysteine residues, and their positions within PON have been conserved. In purified human PON, residues Cys-41 and Cys-352 form an intramolecular disulfide bond and neither could function as an active-center cysteine. Highly purified, enzymatically active PON contains a single titratable sulfhydryl group. Thus, Cys-283 is the only probable candidate for an active-center cysteine. Through site-directed mutagenesis of the human cDNA, Cys-283 was replaced with either serine (C283S) or alanine (C283A). The expressed C283 (wild-type) enzyme was inactivated by para-hydroxymercuribenzoate, but the C283S and C283A mutant enzymes were not inactivated. C283A and C283S mutant enzymes retained both paraoxonase and arylesterase activities, and the Km values for paraoxon and phenyl acetate were similar to those of the wild type. Clearly, residue Cys-283 is free in active PON, but a free sulfhydryl group is not required for either paraoxonase or arylesterase activities. Consequently, it is necessary to examine other models for the active-site structure and catalytic mechanism of PON.

Mutation His322Asn in human acetylcholinesterase does not alter electrophoretic and catalytic properties of the erythrocyte enzyme.

The YT blood group antigen is located on human red blood cell (RBC) acetylcholinesterase. Wild-type acetylcholinesterase, YT1, has histidine at codon 322, whereas the genetic variant of acetylcholinesterase, YT2, has asparagine. This mutation is located within exon 2 of the ACHE gene, an exon that is present in all alternatively spliced forms of acetylcholinesterase. Therefore, acetylcholinesterase in brain and muscle has the same mutation as RBC acetylcholinesterase. We compared the electrophoretic and kinetic properties of RBC acetylcholinesterases having His 322 or Asn 322. We found no differences in the isoelectric point, mobility on non-denaturing gel electrophoresis, affinity for acetylthiocholine, activity per milligram of RBC ghost protein, substrate inhibition constants, binding to the peripheral site ligand (propidium), and binding to active site ligands (tetrahydroaminoacridine and edrophonium). Thus, although the point mutation elicits antibody production in nonmatching blood transfusion recipients, it has no effect on the enzymatic properties of acetylcholinesterase.

Detection of human DNA mutations with nonradioactive, allele-specific oligonucleotide probes.

We describe a method of detecting human DNA mutations with nonradioactive, biotinylated allele-specific oligonucleotide probes. This method can detect seven different mutations in the butyrylcholinesterase, cystic fibrosis, and N-acetyltransferase genes under identical assay conditions. This indicates that it may be used to detect mutations responsible for a wide variety of genetic diseases and pharmacogenetic conditions. The method involves first amplifying selected DNA fragments by the polymerase chain reaction and dot blotting the amplified DNA in duplicate onto small nitrocellulose squares. Each dot blot is then hybridized in individual wells containing a tetramethylammonium chloride solution with short biotinylated probes specific for either the normal or mutant allele. Successfully hybridized probes are detected by a simple colorimetric reaction using an avidin-alkaline phosphatase conjugate, which yields a very strong, clear signal. DNA from homozygous normal or mutant individuals hybridizes only to the normal- or mutant-specific probes respectively, while DNA from heterozygous individuals hybridizes equally well with both probes. These results can be easily interpreted to assign a genotype to the sample DNA. This method is amenable to automation, and may be useful in clinical laboratories for diagnosis of a wide variety of DNA mutations responsible for unusual reactions to drugs and environmental chemicals.