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The present study has identified the metabolites of arachidonic acid (AA) formed by the isolated frog cornea and has shown that this tissue is capable of the biosynthesis of both lipoxygenase and cyclo-oxygenase pathway metabolites. The cyclo-oxygenase (CO) metabolites found in greatest abundance were the prostaglandins E2 and F2a (PGE2 and PGF2a). The major lipoxygenase (LO) pathway metabolite found by thin-layer chromatography (TLC) was leukotriene B4 (LTB4), whereas leukotriene C4 (LTC4) biosynthesis was detected by radioimmunoassay. These leukotrienes (LTs) are highly potent modulators of active chloride transport, since incubation with LTC4 (10(-7)-10(-9) M) resulted in a dose-dependent stimulation of both the Cl- originated short-circuit current (SCC) and potential difference (PD). In contrast, LTB4 (10(-7)-10(-9) M) inhibited both of these parameters. Both LTC4 and LTB4 exerted these effects only when applied to the endothelial side. Preincubation with the leukotriene receptor antagonist, FPL 55712 completely blocked the response to LTC4, indicating that the action of LTC4 in the cornea is receptor-mediated. In this report the authors show that LTB4 and LTC4 are formed by the cornea and that they are potent modulators of the SCC and PD in chamber experiments. The possibility exists that LTB4 and LTC4 may function as endogenous regulators of net Cl- transport in the cornea, since the addition of these metabolites resulted in a dose-dependent stimulation (with LTC4), and inhibition (with LTB4), of both the short-circuit current (SCC) and potential difference (PD).

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The leukotriene, LTC4, exerts a stimulatory effect on chloride transport in the frog cornea. In the work described here, the mechanism of action of LTC4 to stimulate chloride transport was studied. In corneas pretreated with indomethacin, the effect of LTC4 was abolished, suggesting the involvement of cyclo-oxygenase products in the response. Incubation of corneas with LTC4 resulted in a significant stimulation in PGE2 synthesis, as determined by TLC-autoradiography and radioimmunoassay. In addition, LTC4 was found to stimulate cAMP synthesis in the cornea, and this stimulation was blocked with indomethacin. PGE2 was previously shown by us to be the dominant cyclo-oxygenase product formed in the frog cornea, and is capable of stimulating cAMP and chloride transport. We suggest that LTC4 stimulation of chloride transport is mediated via activation of the cyclo-oxygenase pathway, resulting in enhanced PGE2 synthesis. Elevated PGE2 levels induce cAMP synthesis, and ultimately, the stimulation of chloride transport. Further, the activation of cyclo-oxygenase was found to be dependent on phospholipase A2 activity. This was shown by the inhibition of the LTC4 effect in the presence of quinacrine. Similarly, inhibition of the LTC4 effect in the presence of trifluoperazine suggests that cyclo-oxygenase activation by LTC4 may be mediated via calmodulin. We have previously demonstrated that the frog cornea has the biosynthetic capacity to produce LTC4. Therefore LTC4 may function as an endogenous regulator of chloride transport in this tissue.

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We demonstrate that arachidonic acid (AA) stimulation of chloride transport across frog cornea is mediated via two independent pathways: (1) stimulation of prostaglandins and cAMP synthesis, and (2) a direct physical change in the membrane produced by substitution of different phospholipid acyl chains. AA is well known as a precursor in the synthesis of prostaglandins, which have been shown to stimulate cAMP synthesis and chloride transport in frog cornea. We show that frog cornea can convert exogenous AA to PGE2, but that in the presence of 10(-5) M indomethacin both the conversion to PGE2 and stimulation of cAMP are completely blocked. However, with indomethacin the action of AA to stimulate chloride transport (as measured by SCC) remains, but peak height of the response is reduced to 57% of that found when AA alone is given. Similarly, we show that propranolol completely blocks cAMP stimulation, but stimulation of SCC is reduced to 45% of the original response. Therefore, cAMP appears to be responsible for roughly half of the observed stimulation in SCC. By gas chromatographic analysis we show that significant quantities of AA can rapidly substitute into membrane phospholipids of corneal epithelium and L929 cells following the addition of AA to the medium. Modification of membrane phospholipid structure can affect membrane viscosity, membrane-bound enzyme activity, and the distribution and lateral mobility of integral proteins. It seems likely that such alterations in the properties of the membrane may modulate the rate of chloride transport, and this may constitute the second mechanism. Upon addition of AA, both mechanisms appear to stimulate chloride transport simultaneously, and are apparently additive. We show that prolonged exposure to AA results in a large incorporation of AA into phospholipid and consequently, a perturbation in the ratio of unsaturated to saturated fatty acids. We also find evidence of a compensatory cellular mechanism that alters the ratio of endogenously synthesized fatty acids and tends to reduce the membrane-perturbing effect of AA.U

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The effect of altering cell membrane lipids on ion transport across isolated corneas was studied. Corneas mounted in Ussing-type chambers showed a rapid increase in short-circuit current following treatment with a variety of unsaturated fatty acids of varying chain length and unsaturation. Measurements of membrane fluidity which utilize immunofluorescence labelling of membrane proteins showed corneal epithelial cell membranes to be significantly more fluid following linoleic acid treatment. Uptake studies indicate rapid incorporation of [14C]linoleic acid into corneal cell membranes. Highly unsaturated fatty acids were found to have the greatest ability to stimulate chloride transport. Saturated fatty acids were tested and were found to have no effect on chloride transport at any concentration. It is proposed that unsaturated fatty acids activate chloride transport by increasing membrane lipid fluidity. The relationship of these parameters is discussed in terms of a mobile receptor model. We speculate that an increase in membrane lipid fluidity promotes lateral diffusion of membrane receptor proteins and enzymes, increasing protein-protein interactions within the membrane, ultimately resulting in the enhancement of cyclic AMP synthesis.

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