Effects of culture conditions on glutathione content in A549 cells

Virucidal mechanism of action of NVC-422, a novel antimicrobial drug for the treatment of adenoviral conjunctivitis

Human adenoviral conjunctivitis is a highly contagious eye infection affecting millions of people world-wide. If untreated, it can further develop into keratitis, corneal ulceration, scarring and possible blindness. Despite the significant patient morbidity and socio-economic costs, it is an unmet medical need with no FDA approved treatment. Here, we demonstrate the virucidal activity of NVC-422 (N,N-dichloro-2,2-dimethyltaurine) against adenovirus type 5 (Ad5) and investigated its mechanism of action of Ad5 inactivation. NVC-422 inhibits Ad5-induced loss of cell viability in vitro with 50% inhibitory concentration (IC(50)) ranging from 9 to 23 μM. NVC-422 does not cause any cytotoxicity at concentrations as high as 250 μM. Invitro, NVC-422 inactivates Ad5 but does not interfere with viral replication, indicating that NVC-422 acts on the extracellular adenovirus as a virucidal agent. NVC-422 inactivates Ad5 by oxidative inactivation of key viral proteins such as fiber and hexon as evidenced by SDS-PAGE, Western blotting and reversed-phase HPLC. These data, combined with measurements of the kinetics of the NVC-422 reactivity with selected amino acids, indicate that the changes in the viral proteins are caused by the selective oxidation of sulfur-containing amino acids. The conformational changes of the viral proteins result in the destruction of the viral morphology as shown by transmission electron microscopy. In summary, NVC-422 exhibits virucidal activity against Ad5 by the oxidative inactivation of key viral proteins, leading to the loss of viral integrity and infectivity.

Local glutathione redox status does not regulate ileal mucosal growth after massive small bowel resection in rats

Glutathione (GSH) concentration affects cell proliferation and apoptosis in intestinal and other cell lines in vitro. However, in vivo data on gut mucosal GSH redox status and cell turnover are limited. We investigated the effect of altered GSH redox status on the ileal mucosa in a rat model of short bowel syndrome following massive small bowel resection (SBR). Rats underwent 80% mid-jejunoileal resection (RX) or small bowel transection (TX; as operative controls), with administration of either saline or D, L-buthionine-sulfoximine (BSO), a specific inhibitor of cellular GSH synthesis. Ileal mucosal redox, morphology, and indices of cell proliferation and apoptosis were determined at different days after surgery. Ileal GSH redox status was assessed by GSH and GSH disulfide (GSSG) concentrations and the redox potential of GSH/GSSG (Eh). Ileal lipid peroxidation [free malondialdehyde (MDA)] was measured as an index of lipid peroxidation. BSO markedly decreased ileal mucosal GSH, oxidized GSH/GSSG Eh, and increased MDA content without inducing morphological damage as assessed by light or electron microscopy. As expected, SBR stimulated adaptive growth of ileal villus height and total mucosal height at 7 d after surgery, but this response was unaffected by BSO treatment despite a modest increase in crypt cell apoptosis. Ileal cell proliferation (crypt cell bromodeoxyuridine incorporation) increased at 2 d after SBR but was unaffected by BSO. Collectively, our in vivo data show that marked depletion of ileal GSH and oxidation of the GSH redox pool does not alter indices of ileal epithelial proliferation or SBR-induced ileal mucosal adaptive growth.

Decreased GSSG reductase activity enhances cellular zinc toxicity in three human lung cell lines

Cellular reduced glutathione (GSH) levels have been identified as an essential determinant in zinc-induced cytotoxicity. However, cytotoxic effects of zinc have also been observed without depletion of GSH stores. In a previous study, the intracellular activity of GSSG reductase (GR) has come into focus (Walther et al. 2000, Biol Trace Elem Res 78:163-177). In the present paper we have tried to address this issue more deeply by inhibiting the activity of cellular GR without any appreciable decreases of cellular glutathione. In three pulmonary cell lines, GR activity was inhibited in a dose-dependent manner by the alkylating agent carmustine (BCNU), a known inhibitor of GR. Cells were pretreated with BCNU for 14 h, followed by exposure to various concentrations of zinc chloride. Then we determined the incorporation of radiolabelled methionine (to assess protein synthesis), and measured the GSH and oxidized glutathione (GSSG) levels. Additionally, GR activity of controls was measured. IC(50) values for zinc-induced inhibition of methionine incorporation, as well as GSH contents, was strongly correlated to the decreased GR activity. These results firmly suggest that GR is an important factor in the event chain of zinc cytotoxicity. Together with the results from our previously cited study where impaired regeneration of GSH levels were accompanied by a decrease in total cellular glutathione (GSH + GSSG) we conclude that GSSG itself is an important effector in zinc cytotoxicity.

Micronucleus distribution in human peripheral blood lymphocytes treated in vitro with cadmium chloride in G0 and S phase of the cell cycle

Cadmium chloride (CdCl2 x H2O) in concentrations 10(-3) - 10(-6) M was tested for genotoxicity in human lymphocytes in vitro. The DNA damage was expressed through the occurrence of micronuclei (MN) and was detected using the cytochalasin-B-blocked MN assay. Human blood was treated in the G0 and S phase of the cell cycle. All except the highest concentration of cadmium chloride of 10(-3) M applied in the G0 phase of the cell cycle resulted in the increase in MN cells, but it was not statistically significant. Cadmium chloride added to the cultures in the concentration of 10(-3) M affected the cell growth regardless of the phase. Cadmium chloride added to cultures 24 h after their initiation (early S phase) was found to significantly increase the MN frequency in 10(-4) - 10(-6) M concentrations (P > 0.05).

Redox environment of the cell as viewed through the redox state of the glutathione disulfide/glutathione couple

Redox state is a term used widely in the research field of free radicals and oxidative stress. Unfortunately, it is used as a general term referring to relative changes that are not well defined or quantitated. In this review we provide a definition for the redox environment of biological fluids, cell organelles, cells, or tissue. We illustrate how the reduction potential of various redox couples can be estimated with the Nernst equation and show how pH and the concentrations of the species comprising different redox couples influence the reduction potential. We discuss how the redox state of the glutathione disulfide-glutathione couple (GSSG/2GSH) can serve as an important indicator of redox environment. There are many redox couples in a cell that work together to maintain the redox environment; the GSSG/2GSH couple is the most abundant redox couple in a cell. Changes of the half-cell reduction potential (E(hc)) of the GSSG/2GSH couple appear to correlate with the biological status of the cell: proliferation E(hc) approximately -240 mV; differentiation E(hc) approximately -200 mV; or apoptosis E(hc) approximately -170 mV. These estimates can be used to more fully understand the redox biochemistry that results from oxidative stress. These are the first steps toward a new quantitative biology, which hopefully will provide a rationale and understanding of the cellular mechanisms associated with cell growth and development, signaling, and reductive or oxidative stress.

Helicobacter pylori decreases gastric mucosal glutathione

Activation of oxidative stress pathways may contribute to gastric epithelial damage and mutagenesis caused by Helicobacter pylori. We measured the effect of H. pylori on the concentrations of reduced glutathione (GSH), an important endogenous defense against oxidant damage, in gastric epithelial cells in vivo and in vitro. GSH concentrations were significantly lower in gastric biopsies from 19 H. pylori-infected patients than 38 normal controls, and correlated inversely with inflammatory cell numbers. In vitro, H. pylori initially increased GSH levels in AGS cells, but subsequently depleted intracellular GSH stores completely after 24 h. No GSH was detected in H. pylori. Our data suggest that diminished GSH levels with H. pylori colonization of the gastric mucosa may be due to a direct effect of the bacterium as well as through the associated inflammatory response.

Glutathione content of V79 cells in two- or three-dimensional culture

The cellular glutathione (GSH) content of two- and three-dimensional cell cultures of V79 hamster lung cells has been studied. As previously described, cells in monolayer cultures show a decrease in GSH when they reach the confluent state. Three-dimensional cell cultures (multicell spheroids) allow a smoother transition from the initial proliferating to the nonproliferating status, and they show a central area of necrosis when a certain diameter is reached. Cellular GSH content in spheroids is variable throughout the culturing period: 1) GSH content (expressed per mg protein) is lower in spheroids with central necrotic areas than in smaller spheroids without necrosis, and 2) results expressed per cell number show a sharp increase around the diameter where necrosis appears. Once a relatively large necrotic area has been established, GSH decreases again to approximately the prenecrotic level. Interestingly, this GSH "peak" is not dependent on the time in culture but on the spheroid size. Acute hypoxia occurs in central areas of spheroids at a much higher size range than those described herein. Thus we suggest a combination of factors, which may include oxidative stress among others, as the explanation for these cellular GSH variations.

Cysteine concentrations in rodent tumors: unexpectedly high values may cause therapy resistance

Thiol-containing compounds of low m.w. play a key role in protecting cells from the toxic effects of ionizing radiation, other free-radical-generating reactions, reactive oxygen species and chemical toxins. Previous studies have emphasized the importance of the tripeptide glutathione, which is the most abundant soluble thiol in cells. Cysteine is more difficult to quantitate than glutathione, with reported concentrations only 1-10% that of glutathione in most normal tissues and tissue culture cells. Using an electrochemical method (oxidation of the functional -SH group) which allows the direct assay of thiols after acid extraction of cells or tissue, our measurements confirm the above indicated distribution of glutathione and cysteine in cells and normal tissues. However, in several rat and mouse tumors grown in vivo, we found a much higher proportion of cysteine, sometimes exceeding the millimolar concentrations often found for glutathione. Our results have important implications for predicting tumor radiation resistance since cysteine is a much better radiation-protecting agent than glutathione. Since thiols and oxygen have interacting and opposite effects on the net radiation response, high cysteine levels would directly increase the proportion of radio-resistant cells in tumors.

Intracellular metabolism of the orally active platinum drug JM216: influence of glutathione levels

JM216 (bis-acetato ammine dichloro cyclohexylamine Pt IV) is an oral platinum complex presently undergoing phase II clinical trials. Previous studies have identified some of its biotransformation products in clinical materials. This study evaluated the nature of JM216 biotransformation products intracellularly in two different human ovarian carcinoma cell lines, one relatively sensitive to platinum agents (CH1: JM216 4 h IC50 of 5.8 microM) and the other relatively resistant (SKOV3: JM216 4 h IC50 of 60.7 microM). Metabolic profiles were also evaluated at different growth status and in cells pretreated with buthionine sulphoximine (BSO), an agent known to decrease intracellular glutathione levels. Results showed that JM216 enters the cells and that the nature and percentage of biotransformation products was dependent upon glutathione levels. Furthermore, results support the view that the previously reported peak A biotransformation product contains a glutathione adduct. In exponentially growing SKOV3 cells which contain higher glutathione levels than CH1, (82.5 vs 37.8 nmol mg-1 protein), peak A represented 89% of total platinum 4 h after JM216 exposure compared with only 24% in CH1. Moreover, 60-70% depletion of glutathione achieved by 24 h pretreatment of cells with BSO resulted in a significant decrease in peak A in both cell lines and increased the cytotoxicity of JM216 in both CH1 and SKOV3 by approximately 2-fold. Following a 4 h exposure of exponentially growing SKOV3 cells to JM216, only peak A (89%) and JM216 (11%) could be detected whereas in CH1 cells, peak A (24%), JM216 (73%) and JM118 [cis-ammine dichloro (cyclohexylamine) platinum II] (3%) were detected. However, in CH1 cells at confluence, where glutathione is lower (8 nmol mg-1 protein) four metabolites (plus JM216 itself) were detected following exposure to 50 microM JM216; peak A, JM118, JM383 (bis-acetato ammine (cyclohexylamine) dihydroxy platinum IV) and an unidentified metabolite (D), also observed in patient's plasma ultrafiltrate. In confluent SKOV3 cells exposed to 50 microM JM216, peak A, JM216 and JM118 were detected. A further unidentified metabolite observed in patients receiving JM216 (metabolite F) was not formed inside these tumour cells. Overall, these data suggest that glutathione conjugation represents a major deactivation pathway for JM216.

Glutathione determination by the Tietze enzymatic recycling assay and its relationship to cellular radiation response

Large fluctuations in glutathione content were observed on a daily basis using the Tietze enzyme recycling assay in a panel of six human cell lines of varying radiosensitivity. Glutathione content tended to increase to a maximum during exponential cell proliferation, and then decreased at different rates as the cells approached plateau phase. By reference to high-performance liquid chromatography and flow cytometry of the fluorescent bimane derivative we were able to verify that these changes were real. However, the Tietze assay was occasionally unable to detect glutathione in two of our cell lines (MGH-U1 and AT5BIVA), although the other methods indicated its presence. The existence of an inhibitory activity responsible for these anomalies was confirmed through spiking our samples with known amounts of glutathione. We were unable to detect a direct relationship between cellular glutathione concentration and aerobic radiosensitivity in our panel of cell lines.

Glutathione and GSH-dependent enzymes in bronchoalveolar lavage fluid cells in response to ozone

The purpose of this study was to determine if in vivo ozone exposure results in elevations in the levels of glutathione and glutathione-dependent enzymes in cells derived from bronchoalveolar lavage fluid (BALF). Our hypothesis was that, as part of a defense mechanism against oxygen toxicity, such cells would have increased levels of glutathione (GSH) in response to an oxidant stress. Female F344/N rats were exposed to 0.8 ppm ozone, 6 hr/day, for 1, 3, or 7 days, after which cells were collected by lung lavage. The GSH and GSH-peroxidase activity per milligram of protein in the cellular fraction, both necessary for reducing cellular peroxides, were elevated after 3 days of ozone exposure. After 7 days of exposure, cellular GSH had returned to control values, but the activity of glutathione reductase, the enzyme that reduces oxidized glutathione to GSH, was increased. Extracellular GSH concentration and glutathione reductase activity in BALF were also increased after 7 days of exposure. The total glutathione equivalents (GSH and GSSG, both cellular and extracellular) in BALF increased throughout the 7-day exposure, with GSH increasing first in the cells, and then in the extracellular fluid. This study demonstrated that the glutathione anti-oxidant system of BALF cells is stimulated by exposure to ozone. This response may serve to protect cells from the toxic effects of oxidant stress.

Increased glutathione levels in quiescent, serum-stimulated NRK-49F cells are associated not with a response to growth factors but with nutrient repletion

Treatment of quiescent cells with serum results concomitantly in an increase in cellular glutathione (GSH) content and growth stimulation. A possible association between the GSH increase and the growth response was examined by studying separately the effects of nutrients and growth factors on the levels of cellular GSH and proliferation of quiescent NRK-49F cells. The addition of fresh medium with 10% calf serum was found to result in both a twofold increase in cellular GSH and growth stimulation (DNA synthesis and cell proliferation). 10% calf serum alone, without fresh medium, stimulated cell growth but failed to cause a comparable increase in cellular GSH. The addition of fresh medium without 10% serum, and of 0.5 mM cysteine and glutamate, resulted in both instances in a marked increase in cellular GSH, but failed to stimulate cell growth. EGF, in contrast, induced a complete mitogenic response but did not increase cellular GSH. Finally, pretreatment with L-buthionine-(S,R)-sulfoximine (BSO), a specific inhibitor of GSH synthesis, decreased cellular GSH and inhibited EGF-induced DNA synthesis, but these two responses do not, in their dose dependency, correlate. The results obtained thus show that the increase in cellular GSH that occurs in quiescent, serum-stimulated NRK-49F cells is a result of nutrient repletion rather than mitogenic stimulation, and increased GSH levels do not necessarily precede DNA synthesis and mitosis.

The relationships between glutathione, glutathione-S-transferase and cytotoxicity of platinum drugs and melphalan in eight human ovarian carcinoma cell lines

The role of glutathione (GSH) and GSH-S-transferase (GST) activity in modulating the cytotoxicity of four platinum drugs and melphalan was evaluated in eight human ovarian carcinoma cell lines. The cell lines were established from solid and ascitic tumours from pretreated and untreated patients, and showed a wide spectrum of sensitivity to several platinum II and platinum IV drugs; cisplatin, carboplatin, CHIP and tetraplatin. Intracellular glutathione concentration measured in the cell lines showed a significant (P = 0.05) correlation with IC50 values for cisplatin (r = 0.91), carboplatin (r = 0.87) and CHIP (r = 0.88). The correlation between GSH levels and IC50 values for melphalan (r = 0.76) or tetraplatin (r = 0.60) was not as significant. GST activity showed no correlation with IC50 values, for the four platinum drugs. To determine the significance of the elevated GSH concentration in the refractory cell lines, the effect of D,L-buthionine-S, R-sulfoximine (BSO) mediated GSH depletion on platinum drug cytotoxicity was examined in one of the most sensitive (CH1) and two of the least sensitive (relatively resistant; SKOV-3, HX/62) cell lines. Comparison was made with the effect of GSH depletion on melphalan cytotoxicity in these three lines. These lines were differentially sensitive to BSO, with the two most platinum drug resistant lines being more tolerant to BSO than the sensitive CH1 line. Depletion of cellular GSH, ranging between 61 and 88%, had a differential effect on the sensitivity to PtII vs PtIV drugs in the three cell lines: cytotoxicity of the PtIV drugs, tetraplatin and CHIP, was substantially enhanced in both the resistant and sensitive cell lines; in contrast, the cytotoxicity of the PtII drugs, cisplatin and carboplatin, was only significantly increased in one of the two relatively resistant lines (SKOV-3) and in the sensitive (CH1) line after GSH depletion. Moreover the dose modification factor (DMF) for the PtII agents were lower than those for PtIV agents in the three cell lines. The dose modification factor for tetraplatin after BSO treatment was similar to that observed for melphalan in all three cell lines. In the SKOV-3 cell line extending the BSO pretreatment period to 48 h from 24 h marginally reduced the cytotoxicity of cisplatin, whereas the cytotoxicity of the other three drugs remained similar to that observed after 24 h BSO pretreatment. In contrast, extending the BSO treatment to 24 h after drug exposure potentiated the cytotoxicity of cisplatin, CHIP and tetraplatin.(ABSTRACT TRUNCATED AT 400 WORDS)

Buthionine sulfoximine induced growth inhibition in human lung carcinoma cells does not correlate with glutathione depletion

Treatment of A549 human lung carcinoma cells with L-buthionine-[S,R]-sulfoximine (BSO) results concomitantly in cellular glutathione (GSH) depletion and growth inhibition. The nature of BSO effects on cell growth and the relationships between BSO inhibition of cell growth and BSO effects on cellular GSH levels were determined in this study. A dose dependent effect of BSO on cell growth was observed, but this effect was found not to correlate with BSO effects on cellular GSH levels. Treatment with BSO for 60 h at concentrations of 5 and 10 mM was found to deplete cellular GSH at similar rates and to an undetectable level (below 0.5 nmol/mg protein). However, cessation of growth occurred in 10 mM BSO whereas growth continued at better than one half the control rate in 5 mM BSO. The results suggest there may be a distinct threshold level of intracellular GSH (on the order of or less than 0.5 nmol/mg protein) required for cell growth and for cells to protect themselves from the antiproliferative effects of BSO. At a concentration of 10 mM, BSO inhibited both DNA and protein synthesis and arrested growth of A549 cells throughout rather than at a specific phase of the cell cycle. BSO inhibition of growth was not, as indicated by colony-forming efficiency (CFE) and electron microscopy studies, accompanied by indications of cytotoxic effects. A stimulatory effect of 0.1 mM BSO on the growth of A549 cells was found also.

Cellular cadmium responses in subpopulations T20 and T27 of human lung carcinoma A549 cells

Subpopulations T20 and T27, cloned from the human lung carcinoma line A549, differ significantly in their Cd2+ cytotoxic response. T27 has an LC50 of 31 microM Cd2+ and a cytotoxic response threshold of 5 microM Cd2+, whereas the T20s LC50 is 15 microM Cd2+ and there is no observed threshold for cytotoxicity. Cadmium-induced metallothionein (MT) synthesis, cadmium accumulation, glutathione (GSH) content, and Cd2(+)-induced changes in GSH content were studied in T20 and T27 in an attempt to determine the mechanism(s) causing differential cytotoxic response. MT synthesis measured by following Cd2(+)-induced [35S] incorporation into MT was found not to differ between T20 and T27. There is, however, a difference in Cd2+ accumulation between the two subclones. T20 and T27 cells were exposed to 5 microM Cd2+ for different times or to different concentrations of Cd2+ for 8 h. The T27 subline, which is the more Cd2+ resistant, was found to accumulate significantly more Cd2(+)-both as a function of time exposed to Cd2+ and as a function of Cd2+ concentration. The two subpopulations were found to have comparable initial GSH contents, but showed different Cd2(+)-induced changes in [GSH] when the cells were exposed to 5 microM Cd2+. T27 cells maintained their GSH content following Cd2+ exposure but T20 cells showed a Cd2(+)-induced decrease in GSH content. The results indicate that the difference in Cd2+ cytotoxic response between A549--T20 and A549--T27 cells is not attributable to alterations in MT synthesis nor to a difference in initial GSH content. Relative Cd2+ cytotoxicity also does not in these cells correlate with relative Cd2+ accumulation. The fact that T27 cells accumulate more Cd2+ and yet are more Cd2+ resistant than T20 cells suggests that T27 cells have a much more effective non-MT mechanism to handle intracellular Cd2+. This may involve different GSH metabolism and/or yet undefined molecular factors.

Growth-associated modifications of low-molecular-weight thiols and protein sulfhydryls in human bronchial fibroblasts

The thiol redox status of cultured human bronchial fibroblasts has been characterized at various growth conditions using thiol-reactive monobromobimane, with or without the combination of dithiotreitol, a strong reducing agent. This procedure has enabled measurement of the cellular content of reduced glutathione (GSH), total glutathione equivalents, cysteine, total cysteine equivalents, protein sulfhydryls, protein disulfides, and mixed disulfides. Passage of cells with trypsin perturbs the cellular thiol homeostasis and causes a 50% decrease in the GSH content, whereas the total cysteine content is subsequently increased severalfold during cell attachment. During subsequent culture, transient severalfold increased levels of GSH, protein-bound thiols, and protein disulfides are reached, whereas the total cysteine content gradually declines. These changes in the redox balance of both low-molecular-weight thiols and protein-bound thiols correlate with cell proliferation and mostly precede the major growth phase. When the onset of proliferation is inhibited by maintenance of cells in medium containing decreased amounts of serum, the GSH content remains significantly increased. Subsequent stimulation of growth by addition of serum results in decreased GSH levels at the onset of proliferation. In thiol-depleted medium, proliferation is also inhibited, whereas GSH levels are increased to a lesser extent than in complete medium. Exposure to buthionine sulfoximine inhibits growth, prevents GSH synthesis, and results in accumulation of total cysteine, protein-bound cysteine, and protein disulfides. For extracellular cystine, variable rates of cellular uptake correlate with the initial increase in the total cysteine content observed following subculture and with the GSH peak that precedes active proliferation. The results strongly suggest that specific fluctuations in the cellular redox balance of both free low-molecular-weight thiols and protein sulfhydryls are involved in growth regulation of normal human fibroblasts.

Glutathione content and growth in A549 human lung carcinoma cells

The relationship between glutathione content and cell growth was investigated in A549 human lung carcinoma cells. A decreased cellular glutathione content was achieved by exposing the cells to L-buthionine-SR-sulfoximine (BSO). It also occurred in these cells as they approached their plateau phase of growth. During exponential growth, a lower initial glutathione content correlated with a longer lag phase in subcultured cells. Further, depletion of cellular glutathione by BSO inhibited cell growth. This inhibition became apparent 36 h after the addition of BSO. These observations raise the possibility that a critical concentration of GSH may be required for optimal growth of A549 human lung carcinoma cells.

Cadmium cytotoxicity correlates with the changes in glutathione content that occur during the logarithmic growth phase of A549-T27 cells

Correlation of cadmium cytotoxicity with cellular glutathione content as it changes during cell growth was examined in human lung carcinoma A549-T27 cells. Cellular glutathione content was found to increase rapidly during the first 24 h of subculture, which includes the lag and early log phases of growth, and to decrease continuously thereafter. Glutathione content reached its lowest level at 108 h of subculture. This period of glutathione decrease represented most of the logarithmic phase of cell growth. Cells exposed to cadmium at different times during the logarithmic growth phase showed differential sensitivity. Cells with the higher initial glutathione content that occurs at the early period of the logarithmic growth phase were cadmium-resistant relative to those of lower glutathione content found at the later period of the logarithmic phase. A high correlation (r = 0.82) between cadmium sensitivity and glutathione content was found, which suggests that intracellular glutathione content is an important determinant of overall cadmium cytotoxicity.

Effects of sulfite on glutathione S-sulfonate and the glutathione status of lung cells

A mechanistic study was performed to elucidate the biochemical events connected with the cocarcinogenic effect of sulfur dioxide (SO2). Glutathione S-sulfonate (GSSO3H), a competitive inhibitor of the glutathione S-transferases, forms in lung cells exposed in culture to sulfite, the hydrated form of SO2. Changes in glutathione status (total GSH) were also observed during a 1-h exposure. Some cells were pretreated with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) to inhibit glutathione reductase. In human lung cells GSSO3H formed in a concentration-dependent manner, while glutathione (GSH) increased and glutathione disulfide (GSSG) decreased as the extracellular sulfite concentration was increased from 0 to 20 mM. The ratio of GSH/GSSG increased greater than 5-fold and the GSH/GSSO3H ratio decreased to 10 with increasing sulfite concentration. GSSO3H formed in rat lung cells exposed to sulfite, with no detectable effect on GSH and GSSG. GSSO3H also formed from cellular GSH mixed disulfides. GSSO3H formed rapidly, reaching its maximum value in 15 min. The viability of both cell types was unaffected except at 20 mM sulfite. GSSO3H incubated with human lung cells did not affect cellular viability. BCNU inhibited cellular GSSO3H reductase to the same extent as GSSG reductase. These results indicate that GSSO3H is formed in cells exposed to sulfite, and could be the active metabolite of sulfite responsible for the cocarcinogenic effect of SO2 by inhibiting conjugation of electrophiles by GSH.

An in vitro study comparing the cytotoxicity of three platinum complexes with regard to the effect of thiol depletion

The cytotoxicity of three platinum complexes, cis-diamminedichloroplatinum(II) (cis-platin), cis-dichloro-trans-dihydroxy-cis-bis (isopropylamine) platinum(IV), (CHIP) and diammine (1, 1-cyclobutane-dicarboxylato) platinum(II) (carboplatin) on Chinese Hamster ovary (CHO) and mouse sarcoma RIF-1 cells cultured in vitro has been compared. The tumour cell line was much more sensitive to the cytotoxic action of the three agents compared to the CHO cell line. CHIP and carboplatin gave similar dose-response curves, both being much less toxic than cis-platin. The effect of thiol modification on platinum toxicity was also investigated. Substantial reduction in the intracellular non-protein sulphydryl content markedly enhanced the cytotoxicity of CHIP but had much less effect on carboplatin and cis-platin. Thiol depletion by diethylmaleate had a negligible effect on cis-platin toxicity.

Growth phase related variation in the radiation sensitivity of human colon adenocarcinoma cells

Changes in radiation sensitivity with length of time in culture are described for an early passage human colon adenocarcinoma cell line (WiDr). The cells were most radioresistant at the end of lag-phase, 2 days after subculture (Do = 1.7 Gy; n = 10). Radiation sensitivity then increased with time reaching a maximum during plateau-phase, between days 8 and 10 (Do = 1.0 Gy; n = 13). The oxygen enhancement ratio remained constant across the different growth phases of the culture. Cell volume decreased with time in culture as did the proportion of S- and G2M-phase cells. Flow cytometric analyses revealed an increase in the proportion of G1 type cells with a plateau between days 8 and 12 of around 75%. The cell age response measured from synchronized cells following 8 Gy showed that WiDr cells were most radiation resistant in mid S-phase with maximal sensitivity during G1. These cells did not show repair of potentially-lethal radiation damage but were efficient in the repair of sub-lethal damage. The ability to repair sub-lethal damage did not change with culture age.

Antioxidant status of Fanconi anemia fibroblasts

Several observations in the recent literature have indicated that Fanconi anemia (FA) cells may be primarily deficient in the detoxification of activated oxygen species. To evaluate the antioxidant status of FA fibroblasts, we measured Mn-containing superoxide dismutase (Mn-SOD), CuZn-containing superoxide dismutase (CuZn-SOD), catalase, and glutathione peroxidase activities, as well as cellular glutathione contents and total nonenzymatic antioxidant potential in FA and control fibroblasts at multiple time points during a single passage. All parameters exhibited a characteristic pattern of changes during a period of 19 days following trypsinization. Unlike FA erythrocytes, which are known to be deficient in CuZn-SOD, FA fibroblasts exhibited normal CuZn-SOD activities. Also, the nonenzymatic "antioxidant potential" as well as glutathione levels were similar in FA and control fibroblasts. However, Mn-SOD, catalase, and glutathione peroxidase activities were consistently higher in FA fibroblasts. We hypothesize that the elevation of these enzyme activities might reflect a cellular "prooxidant" state in FA resulting from an increased formation of endogenous oxidizing molecular species that trigger enhanced synthesis of certain enzymatic antioxidant defenses.

Oxidative damage to DNA and replicative lifespan in cultured adrenocortical cells

Oxidative damage to DNA in cultured bovine adrenocortical cells was investigated by exposing cells to a sublethal concentration (10 microM) of cumene hydroperoxide under conditions previously shown to be deficient in the biological antioxidants selenium and alpha-tocopherol (vitamin E). DNA prepared from cells incubated for 4 h with 10 microM cumene hydroperoxide had a greater fraction showing resistance to S1 nuclease after denaturation and reassociation to a log C0t of -3. Cross-linking by cumene hydroperoxide was abolished in cells that had been grown in the presence of 20 nM selenite or 1 microM alpha-tocopherol for 96 h prior to peroxide addition, whereas such cells remained susceptible to cross-linking by nitrogen mustard. Extensive strand breaks in DNA from peroxide-treated cells as assessed by alkaline sucrose gradient centrifugation were greatly reduced in cells grown in selenite or alpha-tocopherol. Despite the evidence of damage to DNA, cumene hydroperoxide was not detectably mutagenic, in contrast to 5 microM methylnitronitrosoguanidine (MNNG), when assessed as the incidence of resistance to 25 microM ouabain. We confirmed that cumene hydroperoxide at greater than 10 microM lowers cloning efficiency and that this is largely prevented by selenite or alpha-tocopherol. Additionally, selenite or alpha-tocopherol produced increased clonogenicity in cells not incubated with peroxide. To examine effects of the biological antioxidants on replicative lifespan, cells were grown continuously in fetal bovine serum (FBS), fibroblast growth factor (FGF), and selenite or alpha-tocopherol. Selenium increased replicative lifespan by 10-20% and alpha-tocopherol by 22-30%. Levels of DNA cross-links and strand breaks did not differ under any circumstances between early (second) passage and late (30th) passage cells. The experiments on replicative potential were all performed in the presence of FGF. When FGF was omitted from the culture medium, replicative lifespan was reduced by 85%. We conclude that types of damage to DNA resulting from peroxide exposure are not present in cells under standard culture conditions at early or late stages of the lifespan. Other work has noted a relationship between clonogenicity and replicative lifespan; thus, the increase in cloning efficiency seen with selenium and alpha-tocopherol may cause the observed slight increase in replicative lifespan. Oxidative damage does not appear to be a major determinant of cellular senescence in adrenocortical cells.

Elevation of intracellular glutathione content associated with mitogenic stimulation of quiescent fibroblasts

The relationship between total glutathione (GSH) content and cell growth was examined in 3T3 fibroblasts. The intracellular GSH level of actively growing cultures gradually decreases as these cells become quiescent by either serum deprivation or high cell density. Upon mitogenic stimulation of sparse, quiescent (G0/G1) cultures with serum, there is a rapid 2.3-fold elevation in intracellular GSH levels which is maximal by 1 h and returns to baseline by 2 h. This is followed by a more gradual increase in GSH content as cells enter the S phase. In addition, the elevation in GSH content is required for maximum induction of DNA synthesis. Treatments that prevent the early increase in intracellular GSH levels do not affect protein synthesis but result in a reversible dose-dependent decrease in the percent of cells capable of entering S phase. These results indicate that GSH may be important in the regulation of cellular proliferation.

Possible mechanism for differences in sensitivity to cis-platinum in human prostate tumor cell lines

Two human prostate tumor cell lines which exhibit a 2.4-fold difference in sensitivity to cis-platinum (cis-Pt) were found to possess slightly different sulphydryl contents, and the presence of a metallothionein-like zinc-binding protein was demonstrated in the line exhibiting relative resistance to cis-Pt. Although these factors have been postulated to play a role in the mechanism(s) of resistance to cis-Pt in other cell types, preliminary data in this report suggest that differences found in drug uptake and subsequent binding to DNA are most likely responsible for variations in cis-Pt sensitivity displayed by these prostate tumor cell lines.

Covalent reactions in the toxicity of SO2 and sulfite

Toxic effects of SO2 and sulfite such as bronchitis and bronchoconstriction have been well documented. SO2 has also been suggested to potentiate carcinogenic effects of PAH. However, the molecular basis of these toxic effects is unclear. We have examined the covalent reaction of SO2 and sulfite with cellular proteinacious and nonproteinaceous sulfhydryl compounds using rat liver, and lung and human lung derived A549 cells. Reactions of sulfite and protein in rat and human lung cells reveals at least three proteins with sulfite-reactive disulfide bonds. Besides fibronectin and serum albumin, which had been reported to contain sulfonated products following exposure to sulfite, we have found one other protein with sulfite-binding capabilities. Since the integrity of disulfide bonds is crucial to the tertiary structure and thus protein function, the disruption of protein structure by sulfitolysis may result in altered cellular activities leading to biochemical lesions. Using carefully controlled conditions, reproducible GSH contents can be found in cultured cells and used as an experimental basis for studying alterations in the GSH and GSSG content of cells. Sulfitolysis of GSSG results in the formation of GSSO3H in A549 cells, and possibly in the lung. GSSO3H can be reduced enzymatically by GSSG reductase. However, the Km of GSSO3H is high compared to that of GSSG, suggesting the existence of a transient concentration of GSSO3H once it is formed. Cysteine S-sulfonate is, however, not reduced by cytosolic extracts in the presence of NADPH and would have to be eliminated from the cell by other means. GSSO3H is a strong competitive inhibitor of GST in rat liver and lung and A549 cells, using 1-chloro-2,4-dinitrobenzene as a substrate. It also inhibits the formation of GSH conjugates of BP 4,5-oxide, anti and syn BPDE, but to a lesser extent. These results suggest that SO2 may affect the detoxification of xenobiotic compounds by inhibiting, via formation of GSSO3H, the enzymatic conjugation of GSH and reactive electrophiles. Since GSH conjugation represents the major pathway of elimination of BP epoxides in the lung, our results offer a possible explanation for the cocarcinogenicity of SO2 with PAHs. These data suggest that the sulfitolysis reaction of sulfite is the common reaction mechanism mediating the underlying biochemical reactions leading to both the toxic and cocarcinogenic properties of SO2. Quantitation of sulfitolysis products and their interaction with cellular processes should provide a coherent scheme relating SO2 and sulfite toxicity among animal species and humans.

Picomole analysis of glutathione, glutathione disulfide, glutathione S-sulfonate, and cysteine S-sulfonate by high-performance liquid chromatography

A method for simultaneous detection of picomole quantities of glutathione (GSH), glutathione disulfide (GSSG), glutathione S-sulfonate (GSSO3H), and cysteine S-sulfonate (CYSSO3H) by high-performance liquid chromatography has been developed. Compounds are separated by anion-exchange chromatography using a citric acid buffer system, and then derivatized postcolumn using o-phthalaldehyde with 2-mercaptoethanol, heated to 70 degrees C, and detected by fluorescence. The compounds elute with retention times of 12.5 min for GSH, 27.5 min for CYSSO3H, 29.8 min for GSSG, and 33.0 minutes for GSSO3H, with detection limits of 10, 200, 10, and 50 pmol, respectively. Recoveries are 103% for GSH, 102% for GSSG, 100% for CYSSO3H, and 96% for GSSO3H. Determination of target compounds in cells is described.

Detoxification of H2O2 by cultured rabbit lens epithelial cells: participation of the glutathione redox cycle

Although it has been shown that cultured rabbit lenses can adequately defend against the 0.03-0.05 mM level of H2O2 normally found in aqueous humor, the contribution of the epithelium in this process has not been well defined. In the present study, the peroxide-detoxifying ability of the epithelium is evaluated in cultured rabbit lens cells established from 4-6-day-old rabbits and compared to that of skin fibroblasts from rabbits of the same age. When cells were cultured in medium containing H2O2, the concentration of peroxide rapidly decreased; however, various concentrations could be maintained for 3-hr periods by using glucose oxidase to enzymically generate H2O2. At an extracellular level of 0.03 mM H2O2, the rate of detoxification of peroxide by epithelial cells was 2 mumol H2O2 (8 x 10(5) cells)-1 3 hr-1, twice as fast as that for fibroblasts. Epithelial cells contained a high level of reduced glutathione (GSH) equal to 36 nmol (8 x 10(5) cells)-1, twice that present in the fibroblasts. The concentration of GSH in 8 x 10(5) epithelial cells, a number of cells normally present in one intact rabbit lens epithelium, remained constant during 3 hr of exposure to H2O2 levels as high as 0.03 mM, even though the amount of H2O2 taken up under these conditions was sufficient to oxidize completely the cellular GSH every 2 min. In contrast, the GSH content of fibroblasts declined at levels of peroxide above 0.01 mM. Participation of the glutathione redox cycle in the H2O2-detoxification process was demonstrated from studies of hexose monophosphate shunt (HMPS) activity as measured by oxidation of [1-14C]-labeled glucose. The oxidation of [1-14C]-glucose in epithelial cells was stimulated 13 times that of controls during exposure to 0.04-0.05 mM H2O2, while the corresponding increase in oxidation of [6-14C]-labeled glucose was only 1.6 times. In contrast, maximum shunt activity in fibroblasts occurred at 0.03-0.04 mM H2O2 and was six times the control value. The growth potential of the cells following a 3-hr exposure to H2O2 was also used as a measure of oxidant toxicity in both cell types. Concentrations of H2O2 up to 0.03 mM had no effect on the growth of 8 x 10(5) epithelial cells but did diminish the growth of the same number of fibroblasts. Cell density was found to be an important parameter in the ability of the cells to tolerate H2O2.(ABSTRACT TRUNCATED AT 400 WORDS)

Glutathione S-sulfonate, a sulfur dioxide metabolite, as a competitive inhibitor of glutathione S-transferase, and its reduction by glutathione reductase

Glutathione S-sulfonate (GSSO3H) is a reaction product of glutathione disulfide (GSSG) and sulfite, the hydrated form of sulfur dioxide. In the present study, GSSO3H was found to be a potent competitive inhibitor of the glutathione S-transferases (GST) in the rat liver (Ki = 14 microM) and lung (Ki = 9 microM), and in human lung tumor-derived A549 cells (Ki = 4 microM). GSSO3H was also reduced by a cytosolic enzyme in the rat liver (Km = 313 microM) and lung (Km = 200 microM), and human lung A549 cells (Km = 400 microM). These results suggest that SO2 may affect the detoxification of xenobiotic compounds by inhibiting, via formation of GSSO3H, the enzymatic conjugation of glutathione (GSH) and reactive electrophiles. Although GSSO3H can be enzymatically degraded, the high substrate Km value suggests that this compound may not be readily reduced at low concentrations.

Glutathione content of cultured human fibroblasts during in vitro ageing

The glutathione level of cultured human fibroblasts was determined with a micromodification of a spectrophotometric glutathione cycling method. There was a slight increase in reduced glutathione (GSH) content during in vitro ageing of normal human fibroblasts. Fibroblasts from patients with Werner's syndrome or ceroid lipofuscinosis (Spielmeyer-Vogt syndrome) and healthy individuals exhibited similar patterns of GSH levels during in vitro ageing. The GSH content of non-proliferating confluent cultures of normal fibroblasts and of proliferating normal fibroblasts was identical. Moreover, autofluorescent "aged" cells isolated by cell sorting did not differ in GSH content from the non-autofluorescent cells in the same culture. It was concluded that the GSH content does not play a role in in vitro ageing, nor in the accumulation of autofluorescent material in human skin fibroblasts.

L1210(A) mouse lymphoma cells depleted of glutathione with L-buthionine-S-R-sulfoximine proliferate in tissue culture

L1210(A) mouse lymphoma cells have been adapted to long-term tissue culture in the presence of L-buthionine-S-R-sulfoximine in concentrations of 1-10 mM. As a result of the inhibitory action of this compound on the synthesis of gamma-glutamylcysteine, the dipeptide precursor of glutathione, the cells are depleted of more than 90% of their normal cellular glutathione content. The residual 10% seems to resist depletion at high concentrations of buthionine sulfoximine. Glutathione depleted cells proliferate at a rate similar to that of non-depleted cells, and show full viability. Upon transfer of cells into inhibitor-free medium, they fully regain their original glutathione content. It is concluded that these cells contain at least two pools of glutathione: a large cytoplasmic pool and a smaller, possibly mitochondrial, pool. It is further concluded that the large pool of cytoplasmic glutathione is not obligatory for cell growth and mitosis.