Mechanism of mercurial inhibition of sodium-coupled alanine uptake in liver plasma membrane vesicles from Raja erinacea

Multiple effects of mercury on cell volume regulation, plasma membrane permeability, and thiol content in the human intestinal cell line Caco-2

In a previous study, we characterized Cd-Hg interactions for uptake in human intestinal Caco-2 cells. We pursued our investigations on metal uptake from metal mixtures, focusing on the effects of Hg on cellular homeostasis. A 4-fold higher equilibrium accumulation value of 0.3 micromol/L (203)Hg was measured in the presence of 100 micromol/L unlabeled Hg in the serum-free exposure medium without modification in the initial uptake rate. This phenomenon was eliminated at 4 degrees C. Mercury induced an increase in tritiated water and [(3)H]mannitol uptakes for exposure times greater than 20 min. Incubations for 20 min and 30 min with 100 micromol/L Hg and 2 mmol/L N-ethylmaleimide (NEM) resulted in a 34% and 50% reductions in cellular thiol staining, respectively, with additive effects. Lactate dehydrogenase leakage and live/dead assays confirmed the maintenance of cell membrane integrity in Hg- or NEM-treated cells. We conclude that Hg may alter membrane permeability and increase cell volume without any loss in cell viability. This phenomenon is sensitive to temperature and could involve Hg interaction with membrane thiols, possibly related to solute transport. During metal uptake from metal mixtures, Hg may thus promote the uptake of other toxic metals by increasing cell volume and consequently cell capacity.

ATP-dependent GSH and glutathione S-conjugate transport in skate liver: role of an Mrp functional homologue

Multidrug resistance-associated proteins 1 and 2 (Mrp1 and Mrp2) are thought to mediate low-affinity ATP-dependent transport of reduced glutathione (GSH), but there is as yet no direct evidence for this hypothesis. The present study examined whether livers from the little skate (Raja erinacea) express an Mrp2 homologue and whether skate liver membrane vesicles exhibit ATP-dependent GSH transport activity. Antibodies directed against mammalian Mrp2-specific epitopes labeled a 180-kDa protein band in skate liver plasma membranes and stained canaliculi by immunofluorescence, indicating that skate livers express a homologous protein. Functional assays of Mrp transport activity were carried out using (3)H-labeled S-dinitrophenyl-glutathione (DNP-SG). DNP-SG was accumulated in skate liver membrane vesicles by both ATP-dependent and ATP-independent mechanisms. ATP-dependent DNP-SG uptake was of relatively high affinity [Michaelis-Menten constant (K(m)) = 32 +/- 9 microM] and was cis-inhibited by known substrates of Mrp2 and by GSH. Interestingly, ATP-dependent transport of (3)H-labeled S-ethylglutathione and (3)H-labeled GSH was also detected in the vesicles. ATP-dependent GSH transport was mediated by a low-affinity pathway (K(m) = 12 +/- 2 mM) that was cis-inhibited by substrates of the Mrp2 transporter but was not affected by membrane potential or pH gradient uncouplers. These results provide the first direct evidence for ATP-dependent transport of GSH in liver membrane vesicles and support the hypothesis that GSH efflux from mammalian cells is mediated by members of the Mrp family of proteins.

Bile salt excretion in skate liver is mediated by a functional analog of Bsep/Spgp, the bile salt export pump

Biliary secretion of bile salts in mammals is mediated in part by the liver-specific ATP-dependent canalicular membrane protein Bsep/Spgp, a member of the ATP-binding cassette superfamily. We examined whether a similar transport activity exists in the liver of the evolutionarily primitive marine fish Raja erinacea, the little skate, which synthesizes mainly sulfated bile alcohols rather than bile salts. Western blot analysis of skate liver plasma membranes using antiserum raised against rat liver Bsep/Spgp demonstrated a dominant protein band with an apparent molecular mass of 210 kDa, a size larger than that in rat liver canalicular membranes, approximately 160 kDa. Immunofluorescent localization with anti-Bsep/Spgp in isolated, polarized skate hepatocyte clusters revealed positive staining of the bile canaliculi, consistent with its selective apical localization in mammalian liver. Functional characterization of putative ATP-dependent canalicular bile salt transport activity was assessed in skate liver plasma membrane vesicles, with [(3)H]taurocholate as the substrate. [(3)H]taurocholate uptake into the vesicles was mediated by ATP-dependent and -independent mechanisms. The ATP-dependent component was saturable, with a Michaelis-Menten constant (K(m)) for taurocholate of 40+/-7 microM and a K(m) for ATP of 0.6+/-0.1 mM, and was competitively inhibited by scymnol sulfate (inhibition constant of 23 microM), the major bile salt in skate bile. ATP-dependent uptake of taurocholate into vesicles was inhibited by known substrates and inhibitors of Bsep/Spgp, including other bile salts and bile salt derivatives, but not by inhibitors of the multidrug resistance protein-1 or the canalicular multidrug resistance-associated protein, indicating a distinct transport mechanism. These findings provide functional and structural evidence for a Bsep/Spgp-like protein in the canalicular membrane of the skate liver. This transporter is expressed early in vertebrate evolution and transports both bile salts and bile alcohols.

Heavy metals mercury, cadmium, and chromium inhibit the activity of the mammalian liver and kidney sulfate transporter sat-1

Heavy metal intoxication leads to defects in cellular uptake mechanisms in the mammalian liver and kidney. We have studied the effects of several heavy metals, including mercury, lead, cadmium, and chromium (at concentrations of 1 to 1000 microM), on the activity of the mammalian sulfate transporter sat-1(2) in Xenopus oocytes. sat-1 encodes a sulfate/bicarbonate anion exchanger expressed in the rat liver and kidney. Mercury (10 microM) strongly inhibited sat-1 transport by reducing Vmax by eightfold but not its Km for inorganic sulfate (Si). Lead (up to 1 mM) was unable to significantly inhibit sat-1 transporter activity. Cadmium (500 microM) showed weak inhibition of sat-1 transport by decreasing only sat-1 Vmax. Chromium (100 microM) strongly inhibited sat-1 transport by reducing Km for Si by sevenfold, most probably by binding to the Si site, due to the strong structural similarity between the CrO2-4 and SO2-4 substrates. This study presents the first characterization of heavy metal inhibition of the hepatic and renal sulfate/bicarbonate transporter sat-1, through various mechanisms, which may lead to sulfaturia following heavy metal intoxication.

Effects of Hg2+ on cytosolic Ca2+ in isolated skate hepatocytes

Hg2+ is an environmental pollutant that adversely affects a range of cellular functions, including those that regulate free cytosolic Ca2+ (Ca(i)2+). To investigate the mechanism of Hg(2+)-induced Ca(i)2+ signaling, we examined the effects of Hg2+ on Ca(i)2+ in isolated skate hepatocytes, and developed a method to assess cytosolic Hg2+ (Hgi2+) in these cells as well. At lower concentrations (1-5 microM), Hg2+ induced little detectable change in Ca(i)2+. At higher concentrations (10 microM-1 mM), Hg2+ induced a dose-dependent, progressive increase in Ca(i)2+, which occurred even in Ca(2+)-free medium. Pretreatment of hepatocytes with the membrane-impermeant Hg2+ chelator glutathione (GSH) blocked the Hg(2+)-induced Ca(i)2+ increase, whereas addition of GSH after exposure to Hg2+ slowed but did not prevent further increases in Ca(i)2+. Pretreatment with the membrane-permeant Hg2+ chelator dithiothreitol (DTT) also blocked Hg(2+)-induced increases in Ca(i)2+. Unlike GSH, however, addition of DTT after Hg2+ significantly decreased Ca(i)2+, returning it to near-baseline levels. Thapsigargin induced a sustained increase in Ca(i)2+, but subsequent addition of Hg2+ resulted in a further, progressive Ca(i)2+ increase. We also describe the use of the fluorescent dye BTC-5N to measure Hgi2+, and with it found that Hgi2+ reaches nanomolar levels within minutes of extracellular application, but that these measurable levels of Hgi2+ do not precede elevations in Ca(i)2+. Hg2+ did not irreversibly damage the hepatocytes over this time period (< 5 min), as determined both by propidium iodide permeability and light microscopic appearance. Together, these findings suggest: (i) Hg2+ increases Ca(i)2+ in skate hepatocytes; (ii) Hg2+ must enter the hepatocytes for this Ca(i)2+ increase to occur; (iii) this increase is mediated by release of Ca2+ from endogenous stores that are distinct from the thapsigargin-sensitive Ca2+ stores; and (iv) this increase occurs in association with measureable levels of Hg2+ in the cytosol. Adverse cellular effects of Hg2+ may be mediated by changes in Ca(i)2+ that result from intracellular accumulation of this toxic metal.

Comparison of cadmium, mercury and calcium accumulations by isolated hepatocytes of the small skate (Raja erinacea) and rat

1. Accumulation of calcium, cadmium and mercury by isolated hepatocytes of the small skate (Raja erinacea) and rat was examined at 14 and 37 degrees C, respectively. 2. Metal uptakes by both species were biphasic, with rat cells accumulating more metal than the skate cells. 3. Total accumulation after 30 min was in the order: mercury = cadmium much greater than calcium. 4. In both species calcium and cadmium accumulations were reduced at 4 degrees C, while mercury accumulation was not. 5. Cd accumulation was increased by Cu and Hg in both species. 6. Hg accumulation was inhibited by Cu in both species, and increased by Cd only in the rat cells.