Alan R. Brash

Lipoxygenases: Occurrence, Functions, Catalysis, and Acquisition of Substrate

Lipoxygenase reactions may initiate the synthesis of a signaling molecule or be involved in inducing structural or metabolic changes in the cell. For signaling, synthesis of a single fatty acid hydroperoxide is required. For inducing structural changes, synthesis of a particular product may not be so important as the ability to induce what amounts to an enzyme-catalyzed lipid peroxidation. Reflecting these different functions are lipoxygenases with different characteristics in catalysis. There are enzymes that tightly control the reaction with molecular oxygen and others that form mixed products and permit the release of free radicals. In this review the diversity of lipoxygenase expression will be highlighted and the several facets of lipoxygenase function considered, concluding with a discussion of issues related to the acquisition of substrate in a cellular environment.

Endogenous biosynthesis of prostacyclin and thromboxane and platelet function during chronic administration of aspirin in man.

To assess the pharmacologic effects of aspirin on endogenous prostacyclin and thromboxane biosynthesis, 2,3-dinor-6-keto PGF1 alpha (PGI-M) and 2,3-dinor-thromboxane B2 (Tx-M) were measured in urine by mass spectrometry during continuing administration of aspirin. To define the relationship of aspirin intake to endogenous prostacyclin biosynthesis, sequential urines were initially collected in individuals prior to, during, and subsequent to administration of aspirin. Despite inter- and intra-individual variations, PGI-M excretion was significantly reduced by aspirin. However, full mass spectral identification confirmed continuing prostacyclin biosynthesis during aspirin therapy. Recovery of prostacyclin biosynthesis was incomplete 5 d after drug administration was discontinued. To relate aspirin intake to indices of thromboxane biosynthesis and platelet function, volunteers received 20 mg aspirin daily followed by 2,600 mg aspirin daily, each dose for 7 d in sequential weeks. Increasing aspirin dosage inhibited Tx-M excretion from 70 to 98% of pretreatment control values; platelet TxB2 formation from 4.9 to 0.5% and further inhibited platelet function. An extended study was performed to relate aspirin intake to both thromboxane and prostacyclin generation over a wide range of doses. Aspirin, in the range of 20 to 325 mg/d, resulted in a dose-dependent decline in both Tx-M and PGI-M excretion. At doses of 325-2,600 mg/d Tx-M excretion ranged from 5 to 3% of control values while PGI-M remained at 37-23% of control. 3 d after the last dose of aspirin (2,600 mg/d) mean Tx-M excretion had returned to 85% of control, whereas mean PGI-M remained at 40% of predosing values. Although the platelet aggregation response (Tmax) to ADP ex vivo was inhibited during administration of the lower doses of aspirin the aggregation response returned to control values during the final two weeks of aspirin administration (1,300 and 2,600 mg aspirin/d) despite continued inhibition of thromboxane biosynthesis. These results suggest that although chronic administration of aspirin results in inhibition of endogenous thromboxane and prostacyclin biosynthesis over a wide dose range, inhibition of thromboxane biosynthesis is more selective at 20 than at 2,600 mg aspirin/d. However, despite this, inhibition of platelet function is not maximal at the lower aspirin dosage. Doses of aspirin in excess of 80 mg/d resulted in substantial inhibition of endogenous prostacyclin biosynthesis. Thus, it is unlikely that any dose of aspirin can maximally inhibit thromboxane generation without also reducing endogenous prostacyclin biosynthesis. These results also indicate that recovery of endogenous prostacyclin biosynthesis is delayed following aspirin administration and that the usual effects of aspirin on platelet function ex vivo may be obscured during chronic aspirin administration in man.

Increased prostacyclin biosynthesis in patients with severe atherosclerosis and platelet activation.

Prostacyclin is a potent vasodilator and platelet inhibitor produced by vascular endothelium. Endogenous production of prostacyclin under physiologic conditions is extremely low, far below the capacity of vascular tissue to generate this substance in response to stimulation in vitro. This may reflect a low frequency or intensity of stimulation of prostacyclin production. We postulated that if prostacyclin does act as an endogenous platelet-inhibitory agent, it should be produced in greater amounts in a clinical setting in which platelet-vascular interactions are likely to be increased. To test this hypothesis, we examined prostacyclin biosynthesis in patients with severe atherosclerosis and evidence of platelet activation in vivo. Excretion of 2,3-dinor-6-keto-prostaglandin F1 alpha, a major urinary prostacyclin metabolite, was significantly higher in 9 patients with severe atherosclerosis and evidence of platelet activation (251 to 1859 pg per milligram of creatinine) than in 54 healthy volunteers (45 to 219 pg per milligram of creatinine; P less than 0.001). This difference represented an alteration in biosynthesis rather than in metabolism, since the fractional conversion of infused prostacyclin to the dinor metabolite was identical in both groups. Prostacyclin production may be low in healthy persons because there is almost no stimulus for its production but enhanced in patients with severe atherosclerosis as a consequence of platelet interactions with endothelium or other vascular insults. These observations are compatible with a role for prostacyclin as a local regulator of platelet-vascular interactions.

Release of prostaglandin D2 into human airways during acute antigen challenge

Among the many possible mediators of the early asthmatic response, prostaglandin D2, a bronchoconstrictor, is the principal cyclooxygenase metabolite of arachidonic acid that is released upon the activation of mast cells and is also synthesized by human alveolar macrophages. We performed bronchoalveolar lavage in five patients with chronic stable asthma, before and up to nine minutes after local provocative challenge with Dermatophagoides pteronyssinus. The lavage fluid was analyzed for products of arachidonic acid metabolism. Prostaglandin D2 levels in all five patients rose an average of 150-fold, from less than 8 to 332 +/- 114 pg per milliliter (mean +/- SEM; P less than 0.050), after local instillation of the antigen. Levels of 15-hydroxyeicosatetraenoic acid, which may also have a role in the pulmonary allergic response, were detectable in lavage fluid before challenge and increased after provocation with the antigen in four of the five patients. The activity of beta-glucuronidase, an enzyme released by macrophages and mast cells upon stimulation, tended to increase in the lavage fluid after provocation in all patients. These studies provide evidence that the release of prostaglandin D2 into the airways is an early event after the instillation of D. pteronyssinus in patients who are sensitive to this antigen.

Arachidonic acid as a bioactive molecule

Arachidonic acid is a slippery molecule that owes its mobility to its four cis double bonds. These are the source of its flexibility, keeping the pure fatty acid liquid, even at subzero temperatures, and helping to give mammalian cell membranes their correct fluidity at physiological temperatures. The double bonds are also the key to the propensity of arachidonic acid to react with molecular oxygen. This can happen nonenzymatically, contributing to oxidative stress, or through the actions of three types of oxygenase: cyclooxygenase (COX), lipoxygenase (LOX), and cytochrome P450. While the products of these enzymes and of the nonenzymatic transformations have well-substantiated bioactivities, unchanged arachidonic acid itself has biological activity. This will be a main focus this review. Before dealing with bioactivity, I will consider the solubility properties of the molecule, which are crucial to understanding the availability within the cell of endogenous and exogenous arachidonic acid. I then discuss two controversial issues, arachidonic acid transport into cells and the accessibility of added arachidonic acid to endogenous cellular compartments, and finally turn to selected biological actions of this lipid. The enzymes of arachidonic acid release have been well covered in specialized reviews and are introduced here only in passing.

Estimated rate of prostacyclin secretion into the circulation of normal man.

The rate of secretion of prostacyclin (PGI2) into the circulation of normal man was estimated by measurement of the 2,3-dinor-6-keto-PGF1 alpha (D) and 15-keto-13,14-dihydro-2,3-dinor-6-keto-PGF1 alpha (KDD) urinary metabolites of PGI2. Subjects received 6-h intravenous infusions of vehicle alone and PGI2 at 0.1, 0.4, and 2.0 ng/kg per min in random order. The fractional elimination of the metabolites was independent of the rate of PGI2 infusion. 6.8 +/- 0.3% of the infused PGI2 appeared as D and 4.1 +/- 0.4% as KDD. The regression of infused PGI2 upon the quantities of the two metabolites excreted in excess of control values permitted estimation of the rate of entry of endogenous PGI2 into the circulation corresponding to a given quantity of metabolite excreted. Using the quantities excreted in the 24 h from commencement of the infusions the estimated rates were 0.08 +/- 0.02 ng/kg per min from D and 0.10 +/- 0.03 from KDD. Studies with exogenous PGI2 suggest that infusion rates 2--4 ng/kg per min are required to achieve the threshold for inhibition of platelet function (ex vivo) in man. Although not precluding a role for PGI2 in local platelet-vessel wall interactions, the much lower estimates obtained in this study suggest that endogenous PGI2 is unlikely to act as a circulating antiplatelet agent in healthy man.

The Structure of Human 5-Lipoxygenase

Substitution of a destabilizing sequence has allowed crystallization of a key enzyme of the inflammatory response. The synthesis of both proinflammatory leukotrienes and anti-inflammatory lipoxins requires the enzyme 5-lipoxygenase (5-LOX). 5-LOX activity is short-lived, apparently in part because of an intrinsic instability of the enzyme. We identified a 5-LOX–specific destabilizing sequence that is involved in orienting the carboxyl terminus, which binds the catalytic iron. Here, we report the crystal structure at 2.4 angstrom resolution of human 5-LOX stabilized by replacement of this sequence.

Prostacyclin production during pregnancy: Comparison of production during normal pregnancy and pregnancy complicated by hypertension

We investigated prostacyclin (PGI2) biosynthesis during pregnancy by measuring urinary excretion of 2,3-dinor-6-keto-prostaglandin F1 alpha (dinor) and 15-keto-13,14-dihydro-2,3-dinor-6-keto-prostaglandin F1 alpha (15 kd dinor) with the use of specific gas chromatography-mass spectrometry assays. Nine normotensive nonpregnant women, five normotensive women in the mid-trimester of pregnancy, eight normotensive women in the third trimester of pregnancy, and six women who developed hypertension during the third trimester provided 24-hour samples of urine. Normal pregnant women had a fivefold increase in urinary excretion of dinor in comparison to nonpregnant women (253 +/- 21 ng dinor/gm creatinine for controls vs. 1,224 +/- 110 and 1,127 +/- 152 for second and third trimesters) (mean +/- SEM). Pregnant subjects with hypertension had a significant (50%) reduction in urinary dinor excretion in comparison to normotensive pregnant subjects (561 +/- 105 ng dinor/gm creatinine). In subjects selected from each group, the ratio of dinor to 15 kd dinor remained constant. We conclude that PGI2 biosynthesis is increased during normal pregnancy, and that this increase is less in pregnancy-induced hypertension. This raises the possibility that PGI2 helps mediate hemodynamic changes during normal pregnancy, and that a relative decrease in production might be related to the pathogenesis of pregnancy-induced hypertension.

Routes to 4-Hydroxynonenal: Fundamental Issues in the Mechanisms of Lipid Peroxidation

Although investigation of the toxicological and physiological actions of α/β-unsaturated 4-hydroxyalkenals has made great progress over the last 2 decades, understanding of the chemical mechanism of formation of 4-hydroxynonenal and related aldehydes has advanced much less. The aim of this review is to discuss mechanistic evidence for these non-enzymatic routes, especially of the underappreciated intermolecular pathways that involve dimerized and oligomerized fatty acid derivatives as key intermediates. These cross-molecular reactions of fatty acid peroxyls have also important implications for understanding of the basic initiation and propagation steps during lipid peroxidation and the nature of the products that arise.

Preparation and assay of monohydroxy-eicosatetraenoic acids

Abstract 5-, 8-, 9-, 11-, 12-, and 15-hydroxy-eicosatetraenoic acids (HETEs) were prepared from arachidonic acid by reaction with H2O2 in the presence of Cu2+ ions. They were separated by high-performance liquid chromatography on silica gel (μPorasil), using a linear solvent gradient from hexane to chloroform: only the 8- and 9-isomers were not resolved. Multi-milligram quantities of highly purified HETEs could be easily generated by this method, which thus provides a useful tool to study the biological activity of these compounds. Octadeuterated analogs of HETEs prepared from octadeuterated arachidonic acid by this procedure were suitable for use as internal standards in stable isotope dilution assays, by combined gas chromatography and mass spectrometry, with selected ion monitoring. The detection limit of the HETEs was less than 1 ng.