Cystathionase activity and glutathione metabolism in redifferentiating rat hepatocyte primary cultures

The Impact of Selenium Deficiency on Cardiovascular Function

Selenium (Se) is an essential trace element that is necessary for various metabolic processes, including protection against oxidative stress, and proper cardiovascular function. The role of Se in cardiovascular health is generally agreed upon to be essential yet not much has been defined in terms of specific functions. Se deficiency was first associated with Keshan’s Disease, an endemic disease characterized by cardiomyopathy and heart failure. Since then, Se deficiency has been associated with multiple cardiovascular diseases, including myocardial infarction, heart failure, coronary heart disease, and atherosclerosis. Se, through its incorporation into selenoproteins, is vital to maintain optimal cardiovascular health, as selenoproteins are involved in numerous crucial processes, including oxidative stress, redox regulation, thyroid hormone metabolism, and calcium flux, and inadequate Se may disrupt these processes. The present review aims to highlight the importance of Se in cardiovascular health, provide updated information on specific selenoproteins that are prominent for proper cardiovascular function, including how these proteins interact with microRNAs, and discuss the possibility of Se as a potential complemental therapy for prevention or treatment of cardiovascular disease.

Gamma-glutamyl transpeptidase: redox regulation and drug resistance

The expression of gamma-glutamyl transpeptidase (GGT) is essential to maintaining cysteine levels in the body. GGT is a cell surface enzyme that hydrolyzes the gamma-glutamyl bond of extracellular reduced and oxidized glutathione, initiating their cleavage into glutamate, cysteine (cystine), and glycine. GGT is normally expressed on the apical surface of ducts and glands, salvaging the amino acids from glutathione in the ductal fluids. GGT in tumors is expressed over the entire cell membrane and provides tumors with access to additional cysteine and cystine from reduced and oxidized glutathione in the blood and interstitial fluid. Cysteine is rate-limiting for glutathione synthesis in cells under oxidative stress. The induction of GGT is observed in tumors with elevated levels of intracellular glutathione. Studies in models of hepatocarcinogenesis show that GGT expression in foci of preneoplastic hepatocytes provides a selective advantage to the cells during tumor promotion with agents that deplete intracellular glutathione. Similarly, expression of GGT in tumors enables cells to maintain elevated levels of intracellular glutathione and to rapidly replenish glutathione during treatment with prooxidant anticancer therapy. In the clinic, the expression of GGT in tumors is correlated with drug resistance. The inhibitors of GGT block GGT-positive tumors from accessing the cysteine in extracellular glutathione. They also inhibit GGT activity in the kidney, which results in the excretion of GSH in the urine and a rapid decrease in blood cysteine levels, leading to depletion of intracellular GSH in both GGT-positive and GGT-negative tumors. GGT inhibitors are being developed for clinical use to sensitize tumors to chemotherapy.

Modulation of hepatocyte thiol content by medium composition: implications for toxicity studies

Toxicity of compounds requiring glutathione for detoxification, thiol content and synthesis were determined in 24-h rat hepatocytes cultured in medium containing different concentrations of the sulphur amino acids. Glutathione synthesis was determined following prior depletion of glutathione with diethylmaleate. L-15 medium, which has high levels of cysteine and methionine (1 mM of each), provided some protection against dichloroacetone, dibromopropanol and dichloropropanol toxicity, and had a small effect on increasing glutathione content and synthesis, relative to Williams' medium E (WE) which has low levels (less than 0.5 mM) of both amino acids. However, WE containing N-acetylcysteine (NAC) (1 mM final cysteine concentration), with or without methionine (final concentration 1 mM), was a better cytoprotectant medium than L-15, markedly reducing toxicity of all three compounds, and rapidly (within 1.5 h) increasing cellular glutathione content. WE supplemented with methionine alone stimulated glutathione synthesis after an initial lag phase, and protected cultures against dichloropropanol, but not dibromopropanol or dichloroacetone, both of which are highly reactive in these cultures. There was a clear association between glutathione content at early time points in culture and toxicity observed at later time points, and overall these results indicate that differences in culture medium composition can alter intracellular glutathione content and xenobiotic toxicity.

Expression of Bcl-2 increases intracellular glutathione by inhibiting methionine-dependent GSH efflux

Overexpression of Bcl-2 and related anti-apoptotic gene products has been shown to increase the intracellular concentration of the antioxidant tripeptide glutathione in neuronal and hematopoietic cells. A similar examination of HeLa cells that stably overexpress Bcl-2 (Bcl-2/HeLa) demonstrated that the reduced form of glutathione (GSH) was increased by 60% compared to control cells (80 nmol GSH/mg protein compared to 50 nmol GSH/mg). Expression of gamma-glutamylcysteine synthetase, the rate limiting enzyme for glutathione synthesis was found to be independent of Bcl-2 overexpression, as determined by Northern blot analysis and immunoprecipitation of [35-S]-labeled enzyme. Bcl-2 overexpression did not alter the rate of GSH biosynthesis, measured under steady state conditions. Thus, the increase in GSH concentration was not the result of increased synthesis. Two activities have been described which govern efflux of reduced glutathione (GSH), RsGshT known as the sinusoidal transporter and RcGshT, known as the canalicular transporter. Both are low affinity, bidirectional, ATP and Na-independent. Consistent with expression of sinusoidal activity, DTT was found to stimulate GSH efflux while the amino acid methionine inhibited efflux in both HeLa and Bcl-2/HeLa cells. However, methionine-dependent inhibition of efflux was found to be significantly increased by expression of Bcl-2. To test the prediction that the increase in GSH observed in Bcl-2/HeLa cells was mediated by methionine; Bcl-2/HeLa cells were cultured for 24 hrs in methionine-free growth medium. Under these conditions, the GSH concentration of the Bcl-2/HeLa cells dropped to the level observed in HeLa cells (50 nmol GSH/mg protein). These studies suggest that overexpression of Bcl-2 increases GSH levels by altering methionine-dependent GSH efflux, an activity associated in HeLa cells with expression of the RsGshT transporter.

The influence of medium composition on the maintenance of cytochrome P-450, glutathione content and urea synthesis: a comparison of rat and sheep primary hepatocyte cultures

Rat and sheep primary hepatocytes have been cultured in four different medium formulations: Williams' E, Chee's, Medium 199 and Modified Earle's. The total cytochrome P450 content, intracellular concentration of reduced glutathione, rate of urea synthesis and total protein content of cultures of cells from both species in each medium have been determined. Modified Earle's and Chee's medium proved to be the most favourable formulations for the culture of rat hepatocytes. After 48 h, cells cultured in Modified Earle's had significantly more cytochrome P450 and a significantly greater rate of urea synthesis than cells in any other medium. After 6 days in culture the difference in cytochrome P450 levels between rat hepatocytes in Chee's medium and those in Modified Earle's medium was abrogated. The difference in the rate of urea synthesis between rat hepatocytes cultured in each of these two media was shown to be more dependent on the medium in which the cells were maintained during the period of urea synthesis measurement than on the medium in which the cells had been previously cultured. Sheep hepatocytes cultured in Chee's medium ruptured and died within 24 h. Apart from this, sheep cells were less sensitive to changes in medium formulation than were rat hepatocytes. The initial plating efficiency was lower in sheep cells. Total cytochrome P450 content was the most discriminatory of the four parameters for evaluating the status of rat hepatocyte cultures. However, urea synthesis may be the most useful parameter for assessment of hepatocyte function in hybrid liver devices such as bioartificial liver support systems where access to the cells during operation of the device is restricted.

Comparison of sulfur amino acid utilization for GSH synthesis between HepG2 cells and cultured rat hepatocytes

HepG2 cells are widely used as a model of human hepatocytes for studies of drug metabolism and toxicity. However, GSH metabolism in HepG2 cells is poorly characterized. This report describes the utilization of sulfur amino acids for GSH synthesis in HepG2 cells. In contrast to primary cultures of rat hepatocytes, which rely mostly on methionine for GSH synthesis, HepG2 cells use cystine. Their inability to utilize methionine for GSH synthesis was not due to lack of methionine uptake or low cellular ATP levels, but rather to the lack of S-adenosyl-methionine synthetase activity. When HepG2 cells were cultured overnight in medium containing cystine as the only sulfur amino acid, addition of glutamate or acivicin had minimal to no effect on cell GSH; however, addition of threonine significantly depleted cell GSH. When cystine (0.18 mM) uptake was measured, glutamate (2.5 mM), which inhibited cystine uptake in cultured rat hepatocytes, had a minimal effect in HepG2 cells. Instead, threonine (20 mM) strongly inhibited the apparent uptake of cystine by HepG2 cells. Strong inhibition by threonine of apparent cystine uptake was actually due to inhibition of cysteine uptake, which resulted from GSH-cystine mixed disulfide exchange. Radio-HPLC confirmed this. After incubating cells with [35S]cystine (0.18 mM) for 10 min, the total counts inside the cell matched the counts in the uptake medium in the form of GSH-cysteine mixed disulfide. Finally, HepG2 cells took up cysteine by both Na(+)-dependent and -independent mechanisms. The former exhibited high affinity and low capacity, whereas the latter exhibited the opposite. At a physiologic concentration of cysteine (10 microM), 68% of cysteine uptake occurred via the Na(+)-dependent system and 32% via system L1.

Influence of the isolation method on the stability of differentiated phenotype in cultured rat hepatocytes

Primary cultures of adult rat hepatocytes were established using two different isolation procedures: a two-step collagenase perfusion and a method using ethylenediaminetetraacetate (EDTA) as the dissociating agent. Both techniques provided good yields of hepatocytes with comparable viability. The evolution of hepato-specific protein levels and several drug-metabolizing enzyme activities were followed for 8 days in cultured hepatocytes obtained by both methods. EDTA-isolated hepatocytes maintained a low gamma glutamyltransferase (GGT) activity, whereas collagenase-treated cells acquired a high GGT level. Transferrin secretion and tyrosine aminotransferase (TAT), alanine aminotransferase (ALT), and microsomal epoxide hydrolase (mEH) activities were stable in both EDTA- and collagenase-isolated hepatocytes, whereas albumin secretion, aspartate amino transferase (AST) activity, total cytochromes P-450 content, IA1 and IIB1 P-450 isoenzymes, NADPH-cytochrome P-450 reductase (EC 1.6.2.4) levels, and bilirubin glucuronidation decreased faster in collagenase-treated cells. The most important difference observed was the maintainance of the mixed-function oxidase system in EDTA-isolated hepatocytes. These results emphasize the critical role of isolation technique in stabilization of differentiated hepatocytes in primary culture.

Glutathione and glutathione conjugate efflux from cultured liver cells

Efflux of glutathione (GSH) and GSH-conjugates from cultured rat liver epithelial cell lines; the non-tumorigenic ARL-15C1 and the gamma-glutamyl transpeptidase containing, tumorigenic ARL-16T2, has been assessed under basal condition and during chronic treatment with 75 and 150 microM ethacrynic acid (EA). The intracellular level of GSH increased in proportion to EA concentration during chronic exposure. The rates of GSH and GSH-EA conjugate efflux increased with intracellular GSH in both ARL cell lines. Glutathione-S-transferase activity measured with EA as substrate increased over the experimental time course after treatment with 150, but not 75 microM EA. When intracellular GSH content was increased by treatment with the cysteine pro-drug, 2-L-oxothiazolidine 4-carboxylic acid, the rate of GSH efflux was increased, but not the rate of GS-EA conjugate export. Inhibition of gamma-glutamyl transpeptidase by acivicin (AT-125) increased the GSH and GS-EA conjugate efflux rate in ARL-16T2 cells by factors of approximately 2 and 15, respectively. Acivicin treatment of ARL-16T2 cells chronically treated with EA elevated GSH efflux rate by 10-fold and GS-EA efflux by 40-fold versus control samples. These studies show that GSH and GSH conjugate efflux are accomplished as independently regulated processes. Efflux of GSH is enhanced by increased intracellular GSH, but increase in the conjugate transport rate requires the presence of the GSH conjugate. The response of the efflux process to treatment with a chronic GSH depleting agent was identical in two cell lines in which the metabolic fate of glutathione is known to differ fundamentally.

Rat hepatocytes prepared without collagenase: prolonged retention of differentiated characteristics in culture

Rat hepatocytes prepared by collagenase digestion or EDTA dissociation were examined in culture for comparison of culture stability and morphology, and retention of selected adult rat liver characteristics. Cells prepared by EDTA perfusion followed by Percoll centrifugation were deemed to form confluent monolayer cultures more rapidly and monolayers remained intact for up to 21 days without signs of nonparenchymal cell growth or loss of primary hepatocyte appearance. The spectrally determined cytochrome P-450 content remained constant through eight days in culture. Collagenase-prepared cells contained an identical amount of P-450 but within 72 hr lost greater than 80% of the spectrally detectable P-450. Glutathione (GSH) content was higher in the EDTA-prepared hepatocytes and remained constant with only a modest effect of transferrin and selenium (T/S) supplementation, while GSH levels in collagenase-prepared cells increased, thereafter decreased with time in culture and was dependent on T/S supplementation. Cells prepared with EDTA also displayed an increase in GSH efflux rate in response to chronic GSH depletion by ethacrynic acid. gamma-Cystathionase (CNase) activity was retained at initial levels in EDTA-prepared hepatocytes supplemented with T/S and declined only about 25% in unsupplemented cells. Collagenase-prepared cells lost 75% of CNase activity by 72 hr. The established marker of hepatocyte neoplastic transformation, gamma-glutamyl transpeptidase (GGT), increased rapidly in collagenase-prepared cells. The accumulation of GGT was slowed by T/S supplementation. GGT activity did not increase in EDTA-prepared hepatocytes. Evaluation of morphological and biochemical criteria suggest that hepatocytes prepared without collagenase present superior model systems for the study of biochemical events through more extended culture times.