Sinusoidal efflux of glutathione in the perfused rat liver. Evidence for a carrier-mediated process.

Abstract

Turnover of hepatic glutathione in vivo in the rat is almost entirely accounted for by cellular efflux, of which 80-90% is sinusoidal. Thus, sinusoidal efflux play a major quantitative role in homeostasis of hepatic glutathione. Som preliminary observations from our laboratory (1983. J. Pharmacol. Exp. Ther. 224:141-147.) and circumstantial evidence in the literature seemed to imply that the raising of the hepatic glutathione concentration above normal was not accompanied by a rise in the rate of sinusoidal efflux. Based on these observations, we hypothesized that the sinusoidal efflux was probably a saturable process and that at normal levels of hepatic glutathione the efflux behaved as a zero-order process (near-saturation). We tested our hypothesis by the use of isolated rat livers perfused in situ, single pass, with hemoglobin-free, oxygenated buffer medium at pH 7.4 and 37 degrees C. Preliminary experiments established a range of perfusion rates (3-4 ml/min per g) for adequacy of oxygenation, lack of cell injury, and minimization of variability contributed by perfusion rates. Hepatic glutathione was lowered to below normal by a 48-h fast, diethylmaleate (0.1-1.0 ml/kg i.p.), and buthionine sulfoximine (8 mmol/kg i.p.), and raised to above normal by 3-methylcholanthrene (20 mg/kg x 3 d i.p.) and cobalt chloride (0.05-0.27 g/kg-1 subcutaneously). Steady state sinusoidal efflux from each liver was measured over a 1-h perfusion, during which the coefficient of variation of glutathione in perfusates stayed within 10%. Hepatic glutathione efflux as a function of hepatic concentration was characterized by saturable kinetics with sigmoidal (non-hyperbolic) features. The data were fitted best with the Hill model and the following parameter values were estimated: Vmax = 20 nmol/min per g, Km = 3.2 mumol/g, and n = 3 binding/transport sites. The efflux could be inhibited reversibly by sulfobromophthalein-glutathione conjugate but was not affected by the addition of glutathione to the perfusion medium. The results support our hypothesis that sinusoidal efflux of glutathione is near saturation (approximately equal to 80% of Vmax) at normal (fed and fasted) liver glutathione concentrations. The phenomenon of saturability coupled with the ability to inhibit the efflux leads us to propose that sinusoidal efflux from hepatocytes appears to be a carrier-mediated process. Some recent studies by others, using sinusoidal membrane-enriched vesicles, also support these conclusions.