UMLS:C0684249 - FACTA Search

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Query: UMLS:C0684249 (lung carcinoma)
23,830 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Misonidazole is a metabolically active drug. Its addition to cells causes an immediate alteration in cellular electron transfer pathways. Under aerobic conditions the metabolic alterations can result in futile cycling with electron transfer to oxygen and production of peroxide. Thiol levels are extremely important in protecting the cell against the peroxide formation and potentially hazardous conditions for hydroxyl radical production. Nevertheless such electron shunting out of cellular metabolism will result in alterations in pentose cycle, glycolysis and cellular capacity to reduce metabolites to essential intermediates needed in DNA metabolism (i.e. deoxyribonucleotides). Glutathione must be depleted to very low levels before toxic effects of misonidazole and other nitro compounds are manifested in cell death via peroxidative damage. Under hypoxic conditions misonidazole also diverts the pentose cycle via its own reduction; however, unlike the aerobic conditions, there are a number of reductive intermediates produced that react with non-protein thiols such as GSH as well as protein thiols. The reaction with protein thiols results in the inhibition of glycolysis and other as yet undetermined enzyme systems. The consequences of the hypoxic pretreatment of cells with nitro compounds are increased vulnerability to radiation and chemotherapeutic drugs such as L-PAM, cis-platinum and bleomycin. The role that altered enzyme activity has in the cellular response to misonidazole and chemotherapeutic agents remains to be determined. It is also clear that the GSH depleted state not only makes cells more vulnerable to oxidative stress but also to hypoxic intermediates produced by the reduction of misonidazole beyond the one electron stage. The relevancy of the present work to the proposed use of thiol depletion in vivo to enhance the radiation or chemotherapeutic response of tumor tissue lies with the following considerations. Apparently, spontaneous peroxidative damage to normal tissue such as liver can occur with GSH depletion to 10-20% of control and with other normal tissue when GSH reaches 50% of control. This situation can obviously become more critical if peroxide producing drugs are administered. The only advantage to such combined drug treatments would lie in the possibility that tumors vary in their catalase and peroxidase activity and consequently may be more vulnerable to oxidative stress (cf. review by Meister. Our tumor model, the A549 human lung carcinoma cell in vitro, appears to be an exception because it has catalase, peroxidase and a high content of GSH.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Biochemistry of reduction of nitro heterocycles. 293 68

Chronic aerobic exposure of A549 human lung carcinoma cell cultures to 0.1 mM L-buthionine-S,R-sulfoximine and 1 mM misonidazole, or 1 mM SR-2508 results in inhibition of cell growth and decreased clonogenic survival. These patterns are not apparent with the individual drug treatments. Both parameters demonstrate maximum toxicity after 72 hr in culture, which parallels the time required to deplete A549 cells of glutathione with 0.1 mM L-BSO under these growth conditions. Toxicity appears to be related to hydrogen peroxide-produced during 1 electron reduction of the nitro compounds in the presence of oxygen. A549 cells have a lowered capacity to reduce peroxide due to the effect of thiol depletion on the enzymes GSH-peroxidase and GSH-S-transferase, which require the tripeptide as a substrate. The addition of catalase, another important enzyme involved in peroxide reduction, partially reverses the observed toxicity. 4-Hydroxypyrazole, which inhibits endogenous catalase activity, causes an increase in the observed cytotoxicity. Similar effects of L-BSO and 4-hydroxypyrazole are seen for toxicity due to hydrogen peroxide being added directly to cell cultures.
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PMID:Enhancement in the aerobic toxicity of misonidazole and SR-2508 by buthionine sulfoximine and 4-hydroxypyrazole: the role of hydrogen peroxide. 294 13

In two Adriamycin (Adr) resistant sublines (GLC4-Adr1 and GLC4-Adr2) of a human small cell lung carcinoma cell line, GLC4, cross-resistance for radiation was found. GLC4-Adr1 has an acquired Adr resistance factor of 44 after culturing without Adr for 20 days and GLC4-Adr2, the same subline cultured without Adr for 3 months, has a decreased but stable resistance factor of 8. One of the assumed mechanisms of Adr is that the effect is mediated through the formation of free radicals. Therefore free radical scavenging might play a role in these Adr resistant cell lines. Adr, H2O2, and X-ray induced cytotoxicity were evaluated. Glutathione (GSH) levels and activities of associated enzymes were determined as well as Adr, H2O2, and X-ray induced DNA breaks and repair. GSH level was decreased in GLC4-Adr1, but restored to the normal level in GLC4-Adr2. Superoxide dismutase, catalase, glutathione-peroxidase, and glutathione S-transferase were not elevated in the resistant sublines. Adr induced a decreased amount of DNA breaks in GLC4-Adr1 compared to GLC4. For X-ray and H2O2 a comparable amount of DNA damage was found. GLC4-Adr1 was able to repair DNA breaks induced by Adr, X-ray, and H2O2 better than GLC4. In conclusion, no increased enzyme capacity for detoxification of free radicals could be detected in the cytosol of the resistant cells. The resistance against free radicals in the GLC4-Adr1 line may at least in part be a result of increased DNA repair.
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PMID:Role of free radicals in an adriamycin-resistant human small cell lung cancer cell line. 304 Feb 27

Intracellular glutathione (GSH) content of human lung carcinoma cells, A549, in log phase was 25 +/- 5 nmol/10(6) cells, which is considerably higher than that reported in other tumor cells. After partial depletion of GSH with diethyl maleate (DEM), addition of cystine to the medium allowed full resynthesis of GSH in 4 hr, cysteine in the same time period led to less resynthesis, and methionine provided minimal resynthesis. Using cystine as the sole sulfur source and with buthionine sulfoximine (BSO, 5 mM) included in the medium after cells were depleted with DEM, inhibition of both cystine uptake and resynthesis of GSH occurred. BSO inhibited [35S]cystine uptake (as early as 10 min) in a concentration-dependent process, ranging from a 28% decrease for 1 microM BSO to an 85% decrease for 100 microM BSO compared to the control cells after 240 min of incubation. In addition, GSH resynthesis from [35S]cystine for 240 min was inhibited in a parallel dose-dependent manner, in that 1 microM BSO caused a 27% decrease and 100 microM BSO provided a 75% decrease from control values. BSO did not inhibit the uptake of [35S]methionine, but inhibited the low amount of resynthesis of GSH when methionine was the sole sulfur source. BSO did not inhibit the uptake of arginine, phenylalanine, and leucine. DL-, L-, and methyl ester-BSO each inhibited [35S]cystine uptake and incorporation into GSH to a similar extent. The half-life of GSH was 3.5 +/- 0.4 hr in A549 cells that were grown in complete medium with GSH synthesis occurring.
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PMID:Buthionine sulfoximine inhibition of cystine uptake and glutathione biosynthesis in human lung carcinoma cells. 397 6

We have measured the rate of GSH resynthesis in plateau phase cultures of A549 human lung carcinoma cells subjected to a fresh medium change. Buthionine sulfoximine (BSO) blocks this resynthesis. Diethyl maleate (DEM) causes a decrease in accumulation of GSH. If DEM is added concurrently with BSO there is a rapid decline in GSH that is maximal in the presence of 0.5 mM DEM. GSH depletion rapidly occurs when BSO is added to log phase cultures which initially are higher in GSH content. Twenty-four hr treatment of A549 cells with BSO results in cells that are more radiosensitive in air and show a slight hypoxic radiation response. A 2 hr treatment with either 0.25 mM or 0.5 mM DEM results in some hypoxic sensitization and little increase in the aerobic radiation response. The 24 hr BSO + 2 hr DEM treatment sensitizes hypoxic cells to a greater degree than either agent alone but does not increase the aerobic response more than is seen with BSO alone. Cells treated simultaneously with BSO + DEM show little increase in the hypoxic radiation response, compared to DEM alone, but are more sensitive under aerobic conditions. Decreased cell survival for aerobically irradiated log phase A549 cells occurs within minutes after addition of a mixture of BSO + DEM. The decreased cell survival following aerobic irradiation, after prolonged treatment with BSO or acute exposure to BSO + DEM, may be in part due to inhibition of glutathione peroxidases. For example, glutathione-S-transferase, known to have glutathione peroxidase activity (non-selenium), is nearly completely inhibited by the BSO treatments. In addition, cellular capacity to react with peroxide (glutathione peroxidase, selenium containing) was also inhibited. We suggest that the enhanced aerobic radiation response is related to an inability of GSH depleted cells to inactivate either peroxy radicals or hydroperoxides that may be produced during irradiation of BSO treated cells. Furthermore, enhancement of the aerobic radiation response may be useful in vivo if normal tissue responses are not also increased.
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PMID:Factors involved in depletion of glutathione from A549 human lung carcinoma cells: implications for radiotherapy. 646 42

Many investigators have observed aerobic sensitization of V79, CHO and A549 (human lung carcinoma) cells upon depletion of GSH using buthionine sulfoximine (BSO). Recently we discovered that this aerobic sensitization can be reversed if WR-2721 or N-acetylcysteine is added to the cells just prior to irradiation. Reversal requires that the exogenous thiols be present during the time of irradiation. One possible explanation was that these thiols entered the cells and either increased the pool of cellular nonprotein thiols or reversed the thiol-depleted state by stimulation of GSH synthesis. Cells treated with BSO do not readily regenerate intracellular GSH because this agent irreversibly inhibits gamma-glutamyl synthetase. For A549 monolayer cultures, there is approximately 50% regeneration 6 hr after removal of 0.01 mM BSO, 20% 6 hr after 0.1 mM BSO, and only 5% 6 hr after 0.5 mM BSO. We found that addition of WR-2721 or N-acetylcysteine to BSO-treated cells did not affect the rate of regeneration of intracellular GSH. Thus, reversal of the aerobic sensitization of A549 cells by BSO cannot be explained on the basis of intracellular thiol levels alone, or by rapid reversal of BSO inhibition. In addition, diethylmaleate (DEM)-treated cells are considerably different from BSO-treated cells with respect to the ability to regenerate GSH. After removal of DEM, A549 cells immediately begin GSH resynthesis, and return to control levels occurs within 2 hr. Exogenous 5 mM GSH increases the rate of resynthesis of GSH in DEM-treated cells, but not in BSO-treated cells.
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PMID:Depletion of intracellular GSH and NPSH by buthionine sulfoximine and diethyl maleate: factors that influence enhancement of aerobic radiation response. 646 43

The hypoxic and euoxic radiation response for Chinese hamster lung and A549 human lung carcinoma cells was obtained under conditions where their nonprotein thiols, consisting primarily of glutathione (GSH), were depleted by different mechanisms. The GSH conjugating reagent diethylmaleate (DEM) was compared to DL-buthionine-S,R-sulfoximine (BSO), an inhibitor of glutathionine biosynthesis. Each reagent depleted cellular GSH to less than 5% of control values. A 2-hr exposure to 0.5 mM DEM or a 4- or 24-hr exposure to BSO at 10 or 1 mM, respectively, depleted cellular GSH to less than 5% of control values. Both agents sensitized cells irradiated under air or hypoxic conditions. When GSH levels are lowered to less than 5% by both agents, hypoxic DEM-treated cells exhibited slightly greater X-ray sensitization than hypoxic BSO-treated cells. The D0's for hypoxic survival curves were as follows: control, 4.87 Gy; DEM, 3.22 Gy; and BSO, 4.30 Gy for the V79 cells and 5.00 Gy versus 4.02 Gy for BSO-treated A549 cells. The D0's for aerobic V79 cells were 1.70 Gy versus 1.13 Gy, DEM, and 1.43 Gy for BSO-treated cells. The D0's for the aerobic A549 were 1.70 and 1.20 for BSO-treated cells. The aerobic and anoxic sensitization of the cells results in the OER's of 2.8 and 3.0 for the DEM- and BSO-treated cells compared to 2.9 for the V79 control A549. BSO-treated cells showed an OER of 3.3 versus 3 for the control. Our results suggest that GSH depletion by either BSO or DEM sensitizes aerobic cells to radiation but does not appreciably alter the OER.
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PMID:Cellular glutathione depletion by diethyl maleate or buthionine sulfoximine: no effect of glutathione depletion on the oxygen enhancement ratio. 664 69

Cellular nonprotein thiols (NPSH) consist of glutathione (GSH) and other low molecular weight species such as cysteine, cysteamine, and coenzyme A. GSH is usually less than the total cellular NPSH, and with thiol reactive agents, such as diethyl maleate (DEM), its rate of depletion is in part dependent upon the cellular capacity for its resynthesis. If resynthesis is blocked by buthionine-S,R-sulfoximine(BSO), the NPSH, including GSH, is depleted more rapidly, Cellular thiol depletion by diamide, N-ethylmaleimide, and BSO may render oxygenated cells more sensitive to radiation. These cells may or may not show a reduction in the oxygen enhancement ratio (OER). Human A549 lung carcinoma cells depleted of their NPSH either by prolonged culture or by BSO treatment do not show a reduced OER but do show increased aerobic responses to radiation. Some nitroheterocyclic radiosensitizing drugs also deplete cellular thiols under aerobic conditions. Such reactivity may be the reason that they show anomalous radiation sensitization (i.e., better than predicted on the basis of electron affinity). Other nitrocompounds, such as misonidazole, are activated under hypoxic conditions to radical intermediates. When cellular thiols are depleted peroxide is formed. Under hypoxic conditions thiols are depleted because metabolically reduced intermediates react with GSH instead of oxygen. Thiol depletion, under hypoxic conditions, may be the reason that misonidazole and other nitrocompounds show an extra enhancement ratio with hypoxic cells. Thiol depletion by DEM or BSO alters the radiation response of hypoxic cells to misonidazole. In conclusion, we propose an altered thiol model which includes a mechanism for thiol involvement in the aerobic radiation response of cells. This mechanism involves both thiol-linked hydrogen donation to oxygen radical adducts to produce hydroperoxides followed by a GSH peroxidase-catalyzed reduction of the hydroperoxides to intermediates entering into metabolic pathways to produce the original molecule.
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PMID:The role of thiols in cellular response to radiation and drugs. 668 10

The thiol N-acetylcysteine (NAC) is currently considered one of the most promising cancer chemopreventive agents by virtue of its multiple and coordinated mechanisms affecting the process of chemical carcinogenesis. Recent studies have shown that an unpaired cysteine residue in the propeptide plays a key role in inactivation of latent metastasis-associated metalloproteinases: the present study was designed to assess whether NAC could also affect tumor take, invasion and metastasis of malignant cells. As assessed by zymographic analysis, NAC completely inhibited the gelatinolytic activity of type-IV collagenases in the cells tested (gelatinases A and B). Moreover, NAC was efficient in inhibiting the chemotactic and invasive activities of tumor cells of human (A2058 melanoma) and murine origin (K1735 and B16-F10 melanoma cells as well as C87 Lewis lung carcinoma cells) in Boyden-chamber assays, which are predictive of the invasive and metastatic properties. Reduced glutathione (GSH) had a similar, although less effective activity. The number of lung metastases decreased sharply when B16-F10 murine melanoma cells, injected i.v. into nude mice, were pre-treated with NAC and resuspended in medium supplemented with 10 mM NAC. In other experiments NAC was given in drinking water, starting 48-72 hr before subcutaneous inoculation of either B16-F10 cells or of their highly metastatic variant B16-BL6, or intramuscular injection of LLC cells. In all experiments NAC treatment decreased the weight of the locally formed primary tumor and produced a dose-related delay in tumor formation. Spontaneous metastasis formation by B16-F10 and B16-BL6 tumors was slightly yet significantly reduced by oral administration of NAC. However, this was not observed for Lewis lung tumors. These data indicate that NAC affects the process of tumor-cell invasion and metastasis, probably due to inhibition of gelatinases by its sulfhydryl group, with the possible contribution of other mechanisms, including the potent antioxidant activity of this thiol.
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PMID:Inhibition of invasion, gelatinase activity, tumor take and metastasis of malignant cells by N-acetylcysteine. 770 24

Extracellular glutathione (GSH) is degraded by an external cell-surface enzyme, gamma-glutamyltranspeptidase (gamma-GT). The products are transported into cells to participate in important cellular processes. In the present study, we tested the hypothesis that extracellular GSH is a source of glutamic acid for cells that express gamma-GT. Under a glutamine-deficient culture condition, the extracellular GSH-supplemented glutamic acid would enhance intracellular glutamine synthesis, thereby stimulating cell proliferation. Human lung carcinoma A549 cells were cultured in glutamine-deficient Dulbecco's modified Eagle medium, and they did not proliferate unless glutamine was supplemented. Extracellular GSH, however, provoked a partial proliferation. The GSH effect correlated with a high level of gamma-GT activity and an increased intracellular level of glutamic acid. A constituent amino acid of GSH, glutamic acid but not cysteine, produced the same growth-stimulatory effect as GSH. Furthermore, neither oxothiazolidine-4-carboxylate (OTC), a cellular cysteine-delivery compound, nor cysteinylglycine, a dipeptide released from the gamma-GT reaction, stimulated cell proliferation. Moreover, buthionine sulfoximine (BSO), a selective inhibitor of gamma-glutamylcysteine synthetase, enhanced the GSH growth stimulatory effect, suggesting that increased cellular GSH synthesis does not correlate with cell growth stimulation. The results obtained demonstrated that glutamine is required for A549 cell proliferation and exogenous GSH partially substitutes for the growth stimulatory action of glutamine. It also suggests that the glutamic acid rather than the cysteine released from the GSH is responsible for the cell proliferation.
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PMID:Glutathione stimulates A549 cell proliferation in glutamine-deficient culture: the effect of glutamate supplementation. 796 40

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