Paul B. McCay

Effect of glutathione peroxidase activity on lipid peroxidation in biological membranes

Results are presented indicating that, although glutathione peroxidase activity inhibits lipid peroxidation in membranes, it does not appear to do so by reducing membrane lipid peroxides to lipid alcohols, as has been shown by others to be the case for free fatty acid peroxides in solution. Lipid peroxidation was studied in an enzymic system (microsomal NADPH oxidase) and in a non-enzymic system (mitochondria plus ascorbate). A study of the fatty acids in the phospholipids of microsomes and mitochondria demonstrated that detectable amounts of hydroxy fatty acids were not formed in the membranes when the latter were incubated in the presence of the glutathione peroxidase system even under conditions known to have generated significant levels of lipid peroxides in the membrane. Fatty acid analyses of the microsomal and mitochondrial particles indicated that glutathione peroxidase activity inhibited loss of polyunsaturated fatty acids when these organelles were exposed to peroxidizing conditions. If glutathione peroxidase activity were inhibiting the formation of malondialdehyde (a product of lipid peroxidation) by converting peroxide groups to alcohols, the loss of the constitutive polyunsaturated fatty acids in the membrane should not have been appreciably affected by addition of the peroxidase system. The protective effect cannot be due to quenching of an autocatalytic type of lipid peroxidation (at least in the microsomal system) since it has been established that the microsomal enzyme system (NADPH oxidase) catalyzes a continuous attack on microsomal polyunsaturated fatty acyl groups during the reaction and that the peroxidative process is not autocatalytic in nature. It appears, therefore, that glutathione peroxidase activity must exert its effect on this system by preventing free radical attack on the polyunsaturated membrane lipids in the first place. A possible mechanism for the interruption of a free radical attack on the lipids is proposed.

Lipid peroxidation and the degradation of cytochrome P-450 heme.

Abstract In an in vitro system consisting of rat liver microsomes and NADPH, significant lipid peroxidation was observed along with a concomitant loss of cytochrome P-450. This spectral loss of cytochrome P-450 was shown to be the result of a breakdown of cytochrome P-450 heme. Inhibitors of lipid peroxidation also prevented the loss of cytochrome P-450, demonstrating a direct relationship between lipid peroxidation and breakdown of cytochrome P-450 heme. This breakdown of cytochrome P-450 heme during lipid peroxidation is unrelated to the degradation of cytochrome P-450 heme by an active metabolite of certain allyl-containing barbiturates and barbiturate related compounds. In addition, it appears that different breakdown products of heme are produced by these two mechanisms.

Evidence for superoxide-dependent reduction of Fe3+ and its role in enzyme-generated hydroxyl radical formation☆

This report describes studies yielding additional evidence that superoxide anion (O2) production by some biological oxidoreductase systems is a potential source of hydroxyl radical production. The phenomenon appears to be an intrinsic property of certain enzyme systems which produce superoxide and H2O2, and can result in extensive oxidative degradation of membrane lipids. Earlier studies had suggested that iron (chelated to maintain solubility) augmented production of the hydroxyl radical in such systems according to the following reaction sequence: O2 + Fe3+ leads to O2 + Fe2+ Fe2+ + H2O2 leads to Fe3+ + HO-+OH-. The data reported below provide additional support for the occurrence of these reactions, especially the reduction of Fe3+ by superoxide. Because the conditions for such reactions appear to exist in animal tissues, the results indicate a mechanism for the initiation and promotion of peroxidative attacks on membrane lipids and also suggest that the role of antioxidants in intracellular metabolism may be to inhibit initiation of degradative reactions by the highly reactive radicals formed extraneously during metabolic activity. This report presents the following new information: (1) Fe3+ is reduced to Fe2+ during xanthine oxidase activity and a significant part of the reduction was oxygen dependent. (2) Mn2+ appears to function as an efficient superoxide anion scavenger, and this function can be inhibited by EDTA. (3) The O2-dependent reduction of Fe3+ to Fe2+ by xanthine oxidase activity is inhibited by Mn2+, which, in view of statement 2 above, is a further indication that the reduction of the iron involves superoxide anion. (4) Free radical scavengers prevent or reverse the Fe3+ inhibiton of cytochrome c3+ reduction by xanthine oxidase. (5) The inhibition of xanthine oxidase-catalyzed reduction of cyt c3+ by Fe3+ does not affect uric acid production by the xanthine oxidase system. (6) The reoxidation of reduced cyt c in the xanthine oxidase system is markedly enhanced by Fe3+ and is apparently due to enhanced HO-RADICAL formation since the Fe3+-stimulated reoxidation is inhibited by free radical scavengers, including those with specificity for the hydroxyl radical.

Specificity of a phenobarbital-induced cytochrome P-450 for metabolism of carbon tetrachloride to the trichloromethyl radical

Evidence is presented which demonstrates that the first polypeptide to disappear in liver microsomes of phenobarbital-induced rats treated with CC14 was the 52,000 dalton p-450 cytochrome. Data are also presented which show that this form of cytochrome P-450 was capable of generating the trichloromethyl radical from CCl4 in a reconstituted system containing the purified cytochrome, NADPH-cytochrome P-450 reductase, NADPH, CCl4, and the spin-trapping agent, phenyl-t-butyl nitrone. Other cytochrome P-450 fractions not containing the 52,000 dalton form did not produce this radical. The formation of this highly reactive radical may have resulted in localized damage to the cytochrome, causing the cytochrome either to be released from the microsomal membrane or to form large aggregates which did not migrate in the gel electrophoretic procedures employed.

Confirmation of assignment of the trichloromethyl radical spin adduct detected by spin trapping during 13C-carbon tetrachloride metabolism in, vitro, and, in, vivo

Abstract Rat liver microsomal incubation systems containing the free radical spin trap, phenyl-t-butyl nitrone, as well as an NADPH generating system and [13C]CCl4 (90 atom % 13C) produce electron spin resonance spectra consistent with that expected for a trichloromethyl-phenyl-t-butyl nitrone adduct. This same spectrum is observed in a lipid extract of the liver from a rat orally administered [13C]CCl4 as well as in a solution of phenyl-t-butyl nitrone and [13C]CCl4 irradiated with ultraviolet light.

Spin-trapping of the trichloromethyl radical produced during enzymic NADPH oxidation in the presence of carbon tetrachloride or bromotrichloromethane

Utilizing the spin-trapping agent phenyl-t-butyl nitrone, a free radical has been detected which is produced from carbon tetrachloride or bromotrichloromethane during the enzymic oxidation of NADPH by rat liver microsomes. The presence of NADPH is obligatory for generation of the radical. The formation of the trichloromethyl radical-phenyl-t-butyl nitrone adduct is an enzymic process, as evidenced by the inhibition of its formation in systems containing heated microsomes and in systems containing p-hydroxymercuribenzoate. A computer-simulated ESR spectrum for the trichloromethyl adduct of phenyl-t-butyl nitrone can reproduce the essential features of the spectrum of the spin-trapped radical produced enzymically from CCl4. A mechanism is proposed for the formation of the trichloromethyl radical from CCl4 or BrCCl3.

Recurrent ischemia in the canine heart causes recurrent bursts of free radical production that have a cumulative effect on contractile function. A pathophysiological basis for chronic myocardial "stunning".

Open-chest dogs (total number used, 117) underwent 10 5-min coronary occlusions (O) interspersed with 10 min of reperfusion (R). When systolic thickening fraction was measured 9 min after each R, the first O-R cycle was found to cause the largest decrement, with only a slight additional loss during the next four cycles and no further loss during the last five cycles (group IV), suggesting that the first few episodes of ischemia preconditioned the myocardium against the stunning induced by the last five episodes. However, different results were obtained when the total deficit of wall thickening during the final 4-h R interval was measured. The total deficit was similar after one and three 5-min O (groups V and VI, respectively), indicating that the first ischemic episode did precondition against the next two episodes; however, it was approximately 2.5-fold greater after 10 O (group IV) than after 3, indicating that the first 3 episodes failed to precondition against the next 7. Thus, at some point between the 4th and 10th O, the preconditioning effect was lost and recurrent ischemic episodes started to have a cumulative effect. Measurements of free radicals with alpha-phenyl N-tert-butyl nitrone (PBN) demonstrated a burst of free radical generation immediately after the 1st, 5th, and 10th R (group VIII). The total cumulative release of PBN adducts during the initial 5 min of reflow was 58% less after the 5th R than after the 1st (P < 0.05) but did not differ significantly between the 1st and 10th R. When administered throughout the 10 O-R cycles, the .OH scavenger mercaptopropionyl glycine significantly enhanced the recovery of function (group I) and markedly suppressed the formation of free radicals (group VII). However, the beneficial effects of mercaptopropionyl glycine were completely, or largely, lost if the drug was discontinued after the first five (group II) or eight (group III) O-R cycles, respectively, implying that (a) the oxidative stress associated with the last five, or even two, cycles was sufficient to cause severe postischemic dysfunction, and (b) the cumulative injury caused by repetitive ischemic episodes is mediated by recurrent oxidative stress. This study provides direct in vivo evidence that oxygen radicals play an important role in the pathogenesis of myocardial stunning after repetitive ischemia, and implicates .OH as a primary culprit. Taken together, the data indicate that recurrent brief ischemic episodes result in recurrent bouts of oxyradical-mediated injury that have a cumulative effect on contractility, a situation that could lead to protracted or even chronic myocardial stunning.

In vivo spin trapping of free radicals generated in brain, spleen, and liver during γ radiation of mice

Spin trapping techniques combined with electron spin resonance spectroscopy were used to capture and detect free radicals generated in vivo during exposure to ionizing radiation. Tissue extracts of mice given an intraperitoneal or intragastric dose of the spin trap, alpha-phenyl-t-butyl nitrone prior to exposure to gamma radiation (2 to 5 Gy), contained a radical adduct with hyperfine splitting constants characteristic of spin adducts of carbon-centered lipid radicals. Considerably more radicals were trapped in tissues when the trap was given 3 h before radiation as compared to 30 min before exposure. The radicals observed may either be secondary species resulting from an attack on cellular components by products of water radiolysis, or primary radicals resulting from direct interaction of the radiation with biological molecules. The results indicate that the spin trapping agent is able to penetrate well into animal tissues, and to capture radical species under conditions where the latter would be expected to occur.

Excretion, Metabolism and Tissue Distribution of A Spin Trapping Agent, α-Phenyl-N-Tert-Butyl-Nitrone (Pbn) in Rats

The objective of this study is using radiolabelled PBN to determine the tissue distribution, excretion, and metabolism of PBN in rats in order to evaluate the effective time to trap free radical in appropriate tissue(s). Our results demonstrated that PBN is rapidly absorbed when it is injected intraperitoneally in the animal. PBN can be used as an effective spin trapping agent for a variety of tissues since it is evenly distributed among a wide range of tissues measured. Since there is no difference in the tissue concentrations and distribution pattern of PBN at 15, 30 and 60 min after injection of PBN, it is appropriate to choose any of these time intervals to terminate the experiment and extract the spin adduct. The excretion of PBN, however, is slow. The majority of the radioactivity (70%) was excreted by the first 3 days. Only 5.7% of radioactivity was collected from 3 to 14 days. The remaining 25% of the radioactivity may be in the form of expired 14CO2. Trace amounts of radioactivity were recovered in the feces. PBN has probably only one major form of metabolite excreted in the urine. A small amount of the parent compound, however, was also excreted in the urine. The chemical structure of the metabolite(s) is still unknown.

A function for α-tocopherol: Stabilization of the microsomal membrane from radical attack during TPNH-dependent oxidations

Events accompanying electron transport in the membrane fraction of liver and other tissues have led us to propose a specific function for α-tocopherol based on a sequence of biochemical changes we observed to occur in these membranes and on pertinent information from other laboratories. The activity of a membrane-bound enzyme system (TPNH oxidase) which involves transport of electrons from substrate to oxygen, has been shown to promote simultaneous formation of peroxide functions on the β position polyunsaturated fatty acids (PUFA) of phospholipids in the membrane. The phospholipid peroxides then undergo a chain cleavage reaction producing phospholipids containing a variety of carbonyl moieties in the β position. The process results in marked alteration of the membrane structure. During the overall reaction α-tocopherol present in the membrane is converted to a compound more polar than tocopheryl quinone and the conversion is dependent on the same enzymic factors promoting the phospholipid alterations. The membrane alteration process is enhanced in microsomes from animals fed diets containing relatively high levels of PUFA or diets low in α-tocopherol, and is diminished by low levels of dietary PUFA or relatively high levels of α-tocopherol. The experimental data indicate that enzymic electron transport associated with TPNH oxidation by the microsomal membrane involves free radical functions. The latter apparently can promote extensive peroxidative alterations of phospholipids that result in structural changes in the membrane unless adequate α-tocopherol is present in this organelle. This system appears to be part of the microsomal drug metabolizing system.