Protein carbonyl measurement by a sensitive ELISA method.

We describe a new immunoassay for measuring protein carbonyls as an index of oxidative injury. Protein samples were reacted with dinitrophenylhydrazine then adsorbed to wells of an ELISA plate before probing with a commercial antibody raised against protein-conjugated dinitrophenylhydrazine. The biotin-conjugated primary antibody was then reacted with streptavidin-biotinylated horseradish peroxidase for quantification. The method was calibrated using oxidized albumin and results correlated well with the colorimetric carbonyl assay. The method required only 60 microg protein and was used to analyze the amount of protein carbonyls in plasma and lung aspirate samples. It was sensitive in the 0-2.5 nmol/mg protein range within which clinical samples fell and was linear up to 10 nmol/mg protein. The ELISA method for protein carbonyls is more sensitive and discriminatory than the colorimetric assay and should have wide application for analysing experimental and clinical samples, especially where concentrations are low and where only small amounts of sample are available.

Modification of red cell membrane lipids by hypochlorous acid and haemolysis by preformed lipid chlorohydrins.

Hypochlorous acid (HOCl), a strong oxidant generated by the myeloperoxidase system of neutrophils and monocytes, has been implicated in inflammatory tissue damage by these cells. Reaction of HOCl with the double bonds of unsaturated lipids produces alpha, beta-chlorohydrin isomers. We have exposed red cell membranes to HOCl and used thin layer chromatography (TLC) of the extracted lipids and enzyme-linked immunosorbent assay (ELISA), using an antichlorohydrin monoclonal antibody, to show that fatty acyl chlorohydrins are formed. The ELISA was approximately 25 fold more sensitive than TLC, and chlorohydrins were detected when membranes from 10(6) cells were treated with > or = 0.16 nmoles HOCl. Lipid chlorohydrins are more polar and bulky than their parent lipids and as such could affect membrane stability and function. To determine the effect of incorporation of lipid chlorohydrins into cell membranes, preformed fatty acid and cholesterol chlorohydrins were incubated with red cells. Lysis was measured as release of haemoglobin and incorporation of lipids was determined by 14C scintillation counting. Addition of HOCl-treated oleic acid to red cells resulted in rapid lysis of a fraction of the cells in a concentration dependent manner. HOCl-treated cholesterol also caused a small amount of cell lysis that was predominantly due to chlorohydrin 3, one of the three major cholesterol chlorohydrin products. Chlorohydrin 3, which has a decreased planarity and polarity, was also primarily responsible for altering the critical micelle concentration of HOCl-treated cholesterol-containing liposomes.

A monoclonal antibody recognizing the chlorohydrin derivatives of oleic acid for probing hypochlorous acid involvement in tissue injury.

A monoclonal antibody against hypochlorous acid-modified oleic acid has been raised to investigate involvement of HOCI in tissue injury. Mice were immunized with an isomeric mixture of chlorohydrin derivatives of oleic acid (18:0-chlorohydrin) conjugated to keyhole limpet haemocyanin (CH-KLH). The chlorohydrin was formed by the treatment of oleic acid with hypochlorous acid. Monoclonal antibodies were raised and the fusion was screened with 18:0-chlorohydrin-bovine serum albumin (CH-BSA) conjugate. A number of antibody-secreting clones were identified and the supernatants were characterized by binding studies and dose-response curves. In ELISA, mAb CH-1 had an equivalent titre when either the chlorohydrin or bromohydrin derivative of oleic acid, complexed to bovine serum albumin, was used as screening antigen. The mAb CH-1 recognition of CH-BSA was competed with chlorohydrin and bromohydrin conjugates of BSA and KLH. Similarly, free 18:0-chlorohydrin and the 18:0-chlorohydrin-phosphatidyl choline treated with hypochlorous acid competed with mAb CH-1 binding. The mAb CH-1 also recognised the chlorohydrin derivative of linoleic acid and chlorohydrin formed from palmitoyl, oleyl phosphatidyl choline but with a decreased avidity. Weak cross-reactivity was observed with hydroxy-linoleic acid and linoleic acid hdroperoxide, either as free fatty acid or in phosphatidyl choline. There was minimal competitive binding of mAb CH-1 to free oleic acid, 16:0/18:1 phosphatidylcholine, cholesterol, or cholesterol chlorohydrin. The mAb CH-1 described here may be a useful probe for assessing the involvement of hypochlorous acid in tissue injury.

Decreased thermal stability of red blood cell glu100-->gly superoxide dismutase from a family with amyotrophic lateral sclerosis.

Familial amyotrophic lateral sclerosis is a degenerative motor neuron disease associated in some cases with the presence of a mutant form of Cu/Zn superoxide dismutase. We have studied the stability of the gly100-->glu mutant in extracts of red cells obtained from members of a family with a history of the disease. Extracts containing the mutant had an average 68% of normal superoxide dismutase activity. On heating at 65 degrees C, these extracts lost activity at twice the rate of extracts containing only the normal enzyme. Decreased heat stability was also evident on native polyacrylamide gel electrophoresis with activity staining. This showed selective loss of first the mutant homodimer and then the heterodimer of the enzyme. Decreased stability intracellularly could be a factor in motor neuron degeneration.

Chlorination of tyrosyl residues in peptides by myeloperoxidase and human neutrophils.

Hypochlorous acid is the major strong oxidant generated by human neutrophils, and it has the potential to cause much of the tissue damage that these inflammatory cells promote. It is produced from hydrogen peroxide and chloride by the heme enzyme myeloperoxidase. To unequivocally establish that hypochlorous acid contributes to inflammation, a stable and unique marker for its reaction with biomolecules needs to be identified. In this investigation we have found that reagent hypochlorous acid reacts with tyrosyl residues in small peptides and converts them to chlorotyrosine. Purified myeloperoxidase in combination with hydrogen peroxide and chloride, as well as stimulated human neutrophils, chlorinated tyrosine in the peptide Gly-Gly-Tyr-Arg. Rather than reacting directly with the aromatic ring of tyrosine, hypochlorous acid initially reacted with an amine group of the peptide to form a chloramine. The chloramine then underwent an intramolecular reaction with the tyrosyl residue to convert it to chlorotyrosine. This indicates that tyrosyl residues in proteins that are close to amine groups will be susceptible to chlorination. Peroxidases are the only enzymes capable of chlorinating an aromatic ring. Furthermore, myeloperoxidase is the only human enzyme that produces hypochlorous acid under physiological conditions. Therefore, chlorotyrosine will be a specific marker for the production of hypochlorous acid in vivo and for the involvement of myeloperoxidase in inflammatory tissue damage.

Superoxide dismutase (glu100-->gly) in a family with inherited motor neuron disease: detection of mutant superoxide dismutase activity and the presence of heterodimers.

Superoxide dismutase glu100-->gly, a mutation known to be associated with familial motor neuron disease (familial amyotrophic lateral sclerosis) has been detected in one symptomatic and five of seven asymptomatic members of a family with a history of this disease. On average, the individuals with the mutation had 75% of normal red blood cell superoxide dismutase activity. Native polyacrylamide gels stained for superoxide dismutase activity showed two abnormal bands in the family members identified as carrying the mutation. This indicates that active mutant enzyme is present in red cells and forms stable homodimers and heterodimers with the normal chain. A silent mutation in exon 4, not associated with motor neuron disease, was also detected in one family member.

Characterization of the peribacteroid membrane ATPase of lupin root nodules.

Peribacteroid membranes can be isolated in essentially pure form from 20-day lupin root nodules by osmotic shock of the purified membrane enclosed bacteroids. The ATPase (EC 3.6.1.3) associated with this membrane has an acid pH optimum (5.25) and is specific for ATP (Mg-ATP Km = 0.16 mM). The enzyme activity requires magnesium or manganese ions, is slightly stimulated by the cations potassium and rubidium, and is inhibited by vanadate, diethylstilbestrol, N,N'-dicyclohexylcarbodiimide, fluoride, molybdate, and calcium. Molybdate and fluoride sensitivity do not in this case indicate the presence of significant nonspecific phosphatase activity. The ATPase is not inhibited by oligomycin, azide, or the soluble carbodiimide 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide. In some respects the lupin peribacteroid membrane ATPase appears to differ from the plasma membrane ATPase of other plants.