Biphasic effects of 15-deoxy-delta(12,14)-prostaglandin J(2) on glutathione induction and apoptosis in human endothelial cells.

The lipid products derived from the cyclooxygenase pathway can have diverse and often contrasting effects on vascular cell function. Cyclopentenone prostaglandins (cyPGs), such as 15-deoxy-Delta(12,14)-prostaglandin-J(2) (15d-PGJ(2)), a peroxisome proliferator-activated receptor-gamma (PPARgamma) agonist, have been reported to cause endothelial cell apoptosis, yet in other cell types, cyPGs induce cytoprotective mediators, such as heat shock proteins, heme oxygenase-1, and glutathione (GSH). Herein, we show in human endothelial cells that low micromolar concentrations of 15d-PGJ(2) enhance GSH-dependent cytoprotection through the upregulation of glutamate-cysteine ligase, the rate-limiting enzyme of GSH synthesis, as well as GSH reductase. The effect of 15d-PGJ(2) on GSH synthesis is attributable to the cyPG structure but is independent of PPAR, inasmuch as the other cyPGs, but not PPARgamma or PPARalpha agonists, are able to increase GSH. The increase in cellular GSH is accompanied by abrogation of the proapoptotic effects of 4-hydroxynonenal, a product of lipid peroxidation present in atherosclerotic lesions. However, higher concentrations of 15d-PGJ(2) (10 micromol/L) cause endothelial cell apoptosis, which is further enhanced by depletion of cellular GSH by buthionine sulfoximine. We propose that the GSH-dependent cytoprotective pathways induced by 15d-PGJ(2) contribute to its antiatherogenic effects and that these pathways are distinct from those leading to apoptosis.

Cell-type specific differences in glutamate cysteine ligase transcriptional regulation demonstrate independent subunit control.

Glutamate cysteine ligase (GCL; also referred to as gamma-glutamylcysteine synthetase, GCS) catalyzes the rate-limiting step of glutathione synthesis. The GCL holoenzyme is composed of a catalytic (GCLC; also called GCS(h)) and a modifier (GCLM; also called GCS(l)) subunit, each encoded by a unique gene. Wild-type and mutant promoter/luciferase reporter transgenes containing the promoter region of each GCL subunit gene were transfected into A549 (lung carcinoma), HEK 293 (transformed embryonic kidney), HepG2 (hepatocellular carcinoma), and RD (skeletal muscle rhabdomyosarcoma) cells to examine potential cell-type related differences in transcriptional regulation. In A549, HepG2, and RD cells, maximal basal expression of the GCLC transgene required the full-length (-3802 bp) promoter. Maximal expression in HEK 293 cells was uniquely directed by cis-elements contained within the -2752 to -1286 bp fragment of the promoter. No differences in GLCM promoter function were detected among these 4 cell lines. GCL subunit induction in each cell line by pyrrolidine dithiocarbamate (PDTC), phenethyl isothiocyanate (PEITC), and beta-naphthoflavone (beta-NF) was examined by RNAse protection assays. Although both genes were similarly induced in HepG2 cells by beta-NF, PDTC, and PEITC, neither was induced by beta-NF in A549, HEK 293, and RD cells. PDTC and PEITC induced GCLM to a much greater extent than GCLC in HEK 293 cells and failed to induce GCLC in RD cells. Neither subunit was induced by any of the agents in A549 cells. These studies indicate that the GCL subunit genes are independently regulated and display cell-type specific differences in both basal and inducible expression.

Inhibition of ERK and p38 MAP kinases inhibits binding of Nrf2 and induction of GCS genes.

Genes encoding the catalytic (GCS(h)) and regulatory (GCS(l)) subunits of human gamma-glutamylcysteine synthetase (gammaGCS), which catalyzes the rate limiting step in glutathione synthesis, are up-regulated in response to xenobiotics through Electrophile Response Elements (EpREs). Exposure of HepG2 cells to the GCS-inducing agent, Pyrrolidine dithiocarbamate (PDTC), results in ERK and p38 MAP kinase activation. Inhibition of ERK or p38 kinases by PD98059 or SB202190, respectively, results in approximately 50% reduction in GCS gene induction, while simultaneous inhibition completely eliminates induction. Induction of GCS expression is associated with an increase in Nrf2 and JunD binding to GCS EpREs. Pretreatment with the MAPK inhibitors significantly reduces binding of both transcription factors. These studies indicate that ERK and p38 contribute to the transcriptional up-regulation of the GCS subunit genes following PDTC treatment. Furthermore, supershift analyses suggest that binding of Nrf2 and JunD to the EpRE is a downstream consequence of ERK and p38 phosphorylation events.

Synthesis and evaluation of nitroheterocyclic phosphoramidates as hypoxia-selective alkylating agents.

A series of novel nitroheterocyclic phosphoramidates has been prepared, and the cytotoxicity of these compounds has been evaluated in clonogenic assays against B16, wild-type and cyclophosphamide-resistant MCF-7, and HT-29 cells under aerobic conditions and HT-29 cells under hypoxic conditions. All compounds were comparable in toxicity to wild-type and resistant MCF-7 cells and were also selectively toxic to HT-29 cells under hypoxic conditions (selectivity ratios 1.7 to >20). Analogues lacking the nitro group were not cytotoxic. Electron-withdrawing substituents increased cytotoxicity under aerobic conditions and thereby decreased hypoxic selectivity. In contrast, an electron-donating substituent markedly decreased both aerobic and hypoxic cytotoxicity but enhanced hypoxic selectivity. Chemical reduction of the nitro group resulted in rapid expulsion of the cytotoxic phosphoramide mustard. The most potent of these compounds show significant cytotoxicity under both aerobic and hypoxic conditions.

Structure of the human glutamate-L-cysteine ligase catalytic (GLCLC) subunit gene.

Glutamate-L-cysteine ligase (GLCL [EC 6.3.2.2], also referred to as gamma-glutamylcysteine synthetase) catalyzes the rate-limiting reaction in the synthesis of the important cellular antioxidant glutathione. GLCL is a heterodimer consisting of a catalytic (GLCLC) and a regulatory (GLCLR) subunit. The structure of the human GLCLC subunit gene, GLCLC, which has been mapped to chromosome 6p12, spans 51.4 kb and consists of 16 exons separated by 15 introns.

Regulation of gamma-glutamylcysteine synthetase subunit gene expression: insights into transcriptional control of antioxidant defenses.

Gamma-glutamylcysteine synthetase (GCS; also referred to as glutamate-cysteine ligase, GLCL) catalyzes the rate-limiting reaction in glutathione (GSH) biosynthesis. The GCS holoenzyme is composed of a catalytic and regulatory subunit, each encoded by a unique gene. In addition to some conditions which specifically upregulate the catalytic subunit gene, expression of both genes is increased in response to many Phase II enzyme inducers including oxidants, heavy metals, phenolic antioxidants and GSH-conjugating agents. Electrophile Response Elements (EpREs), located in 5'-flanking sequences of both the GCSh and GCSl subunit genes, are hypothesized to at least partially mediate gene induction following xenobiotic exposure. Recent experiments indicate that the bZip transcription factor Nrf2 participates in EpRE-mediated GCS subunit gene activation in combination with other bZip proteins. An AP-1-like binding sequence and an NF-kappaB site have also been implicated in regulation of the catalytic subunit gene following exposure to certain pro-oxidants. Potential signaling mechanisms mediating GCS gene induction by the diverse families of Phase II enzyme inducers include thiol modification of critical regulatory sensor protein(s) and the generation of the reactive oxygen species. This review summarizes recent progress in defining the molecular mechanisms operative in transcriptional control of the genes encoding the two GCS subunits, identifying areas of agreement and controversy. The mechanisms involved in GCS regulation might also be relevant to the transcriptional control of other components of the antioxidant defense battery.

Regulation of gamma-glutamylcysteine synthetase subunit gene expression by the transcription factor Nrf2.

Exposure of HepG2 cells to beta-naphthoflavone (beta-NF) or pyrrolidine dithiocarbamate (PDTC) resulted in the up-regulation of the gamma-glutamylcysteine synthetase catalytic (GCS(h)) and regulatory (GCS(l)) subunit genes. Increased expression was associated with an increase in the binding of Nrf2 to electrophile response elements (EpRE) in the promoters of these genes. Nrf2 overexpression increased the activity of GCS(h) and GCS(l) promoter/reporter transgenes. Overexpression of an MafK dominant negative mutant decreased Nrf2 binding to GCS EpRE sequences, inhibited the inducible expression of GCS(h) and GCS(l) promoter/reporter transgenes, and reduced endogenous GCS gene induction. beta-NF and PDTC exposure also increased steady-state levels of MafG mRNA. In addition to Nrf2, small Maf and JunD proteins were detected in GCS(h)EpRE-protein complexes and, to a lesser extent, in GCS(l)EpRE-protein complexes. The Nrf2-associated expression of GCS promoter/reporter transgenes was inhibited by overexpression of MafG. Inhibition of protein synthesis by cycloheximide partially decreased inducibility by PDTC or beta-NF and resulted in significant increases in GCS mRNA at late time points, when GCS mRNA levels are normally declining. We hypothesize that, in response to beta-NF and PDTC, the GCS subunit genes are transcriptionally up-regulated by Nrf2-basic leucine zipper complexes, containing either JunD or small Maf protein, depending on the particular GCS EpRE target sequence and the inducer. Following maximal induction, down-regulation of the two genes is mediated via a protein synthesis-dependent mechanism.

Up-regulation of the human gamma-glutamylcysteine synthetase regulatory subunit gene involves binding of Nrf-2 to an electrophile responsive element.

The rate-limiting step in the de novo synthesis of the cellular protectant glutathione is catalyzed by gamma-glutamylcysteine synthetase (GCS; also known as glutamine-L-cysteine ligase, GLCL), a heterodimer consisting of catalytic (GCS(h)) and regulatory (GCS(l)) subunits. Regulation of expression of the human gamma-glutamylcysteine synthetase regulatory subunit gene in response to beta-NF is mediated by an Electrophile Responsive Element (EpRE) [Moinova, H., and Mulcahy, R. T. (1998) J. Biol. Chem. 273, 14683-14689]. Oligonucleotide probes corresponding to wild-type and mutant EpRE sequences were used in gel-shift and super-shift analyses to identify proteins binding. Four protein:DNA complexes (a-d) with distinct mobilities were detected when the wild-type EpRE probe was incubated with nuclear extracts from control or beta-NF-treated HepG2 cells. Following beta-NF treatment, there was an increase in the intensity of a single band, band b. This band was eliminated in gel shifts employing mutant EpRE probes which abolish beta-NF inducibility, demonstrating a correlation between band b and transactivation. Super-shift analysis identified JunD, Nrf1, and Nrf2 in the EpRE-binding complexes. Antibodies to Nrf2 completely super-shifted the band b protein:DNA complex. These studies demonstrate that Nrf2 proteins recognize and bind the GCS(l) EpRE sequence to affect transactivation of the gene.

The enzymes of glutathione synthesis: gamma-glutamylcysteine synthetase.

The metabolite glutathione fulfills many important and chemically complex roles in protecting cellular components from the deleterious effects of toxic species. GSH combines with hydroxyl radical, peroxynitrite, and hydroperoxides, as well as reactive electrophiles, including activated phosphoramide mustard. This thiol-containing reductant also maintains so-called thiol-enzymes in their catalytically active form, and maintains vitamins C and E in their biologically active forms. The key step in glutathione synthesis, namely the ATP-dependent synthesis of gamma-glutamylcysteine, is the topic of this review. Details are presented on (a) the enzyme's purification and protein chemistry, (b) the successful cDNA cloning, and characterization of the genes responsible for the biosynthesis of this enzyme. After considering aspects of the role of overexpression of this synthetase in terms of cancer chemotherapy, attention is focused on post-translational regulation. The remainder of the review deals with the catalytic mechanism (including substrate specificity, reactions catalyzed, steady-state kinetics, and chemical mechanism) as well as the inhibition of the enzyme (via feedback inhibition, reaction with S-alkyl homocysteine sulfoximine inhibitors, the clinical use of buthionine sulfoximine with cancer patients, and inactivation by cystamine, chloroketones, and various nitric oxide donors).

The induction of GSH synthesis by nanomolar concentrations of NO in endothelial cells: a role for gamma-glutamylcysteine synthetase and gamma-glutamyl transpeptidase.

Nitric oxide protects cells from oxidative stress through a number of direct scavenging reactions with free radicals but the effects of nitric oxide on the regulation of antioxidant enzymes are only now emerging. Using bovine aortic endothelial cells as a model, we show that nitric oxide, at physiological rates of production (1-3 nM/s), is capable of inducing the synthesis of glutathione through a mechanism involving gamma-glutamylcysteine synthetase and gamma-glutamyl transpeptidase. This novel nitric oxide signalling pathway is cGMP-independent and we hypothesize that it makes an important contribution to the anti-atherosclerotic and antioxidant properties of nitric oxide.

Pyrrolidine dithiocarbamate up-regulates the expression of the genes encoding the catalytic and regulatory subunits of gamma-glutamylcysteine synthetase and increases intracellular glutathione levels.

Time- and dose-dependent increases in the steady-state mRNA levels of the genes encoding the catalytic and regulatory subunits of the enzyme gamma-glutamylcysteine synthetase (GCS) were observed in HepG2 human hepatocarcinoma cells after exposure to pyrrolidine dithiocarbamate (PDTC). PDTC was demonstrated to manifest both antioxidant and pro-oxidant properties in HepG2 cells, as assessed by the decreased fluorescence of the redox-sensitive dye Dihydrorhodamine 123 and by the oxidation of glutathione respectively. Attempts to characterize the signalling pathway from PDTC exposure to increases in the expression of the GCS catalytic and regulatory subunit genes demonstrated that induction by PDTC could be partially blocked by treatment with the thiol agent N-acetylcysteine and by the copper chelator bathocuproine disulphonic acid. These findings suggested that the up-regulation of the two genes resulted from a PDTC-induced pro-oxidant signal, which was partially copper-dependent. In summary, these studies demonstrate that PDTC exposure elicits a cellular response in HepG2 cells, characterized by the induction of the genes encoding the two subunits of the enzyme GCS and increased de novo synthesis of the cellular protectant GSH.

Expression of multidrug resistance protein/GS-X pump and gamma-glutamylcysteine synthetase genes is regulated by oxidative stress.

Expression of the MRP1 gene encoding the GS-X pump and of the gamma-GCSh gene encoding the heavy (catalytic) subunit of the gamma-glutamylcysteine synthetase is frequently elevated in many drug-resistant cell lines and can be co-induced by many cytotoxic agents. However, mechanisms that regulate the expression of these genes remain to be elucidated. We report here that like gamma-GCSh, the expression of MRP1 can be induced in cultured cells treated with pro-oxidants such as tert-butylhydroquinone, 2,3-dimethoxy-1, 4-naphthoquinone, and menadione. Intracellular reactive oxygen intermediate (ROI) levels were increased in hepatoma cells treated with tert-butylhydroquinone for 2 h as measured by flow cytometry using an ROI-specific probe, dihydrorhodamine 123. Elevated GSH levels in stably gamma-GCSh-transfected cell lines down-regulated endogenous MRP1 and gamma-GCSh expression. ROI levels in these transfected cells were lower than those in the untransfected control. In the cell lines in which depleting cellular GSH pools did not affect the expression of the MRP1 and gamma-GCSh genes, only minor increased intracellular levels of ROIs were observed. These results suggest that intracellular ROI levels play an important role in the regulation of MRP1 and gamma-GCSh expression. Our data also suggest that elevated intracellular GSH levels not only facilitate substrate transport by the MRP1/GS-X pump as previously demonstrated, but also suppress MRP1 and gamma-GCSh expression.

An electrophile responsive element (EpRE) regulates beta-naphthoflavone induction of the human gamma-glutamylcysteine synthetase regulatory subunit gene. Constitutive expression is mediated by an adjacent AP-1 site.

Exposure of HepG2 cells to beta-naphthoflavone (beta-NF) results in time- and dose-dependent increase in the steady-state mRNA levels for both the catalytic (GCSh) and regulatory (GCS1) subunits of gamma-glutamylcysteine synthetase (GCS) which catalyzes the rate-limiting step in the de novo synthesis of the cellular antioxidant glutathione (GSH) (Mulcahy, R. T., Wartman, M. A., Bailey, H. B., and Gipp, J. J. (1997) J. Biol. Chem. 272, 7445-7454). Cloning and sequencing of the GCS1 promoter region is reported. Regulatory sequences mediating basal and beta-NF induced expression of the GCSl gene were identified using a series of promoter/reporter fusion genes transfected into HepG2 cells. Sequences directing basal and beta-NF induced expression were localized between nucleotides -344 and -242 (numbered relative to the translation start site). Mutational analyses indicate that basal expression of the GCSl gene is directed by a consensus AP-1-binding site located 33 base pairs upstream of a consensus electrophile responsive element (EpRE) sequence; both cis-elements are capable of supporting beta-NF inducibility. Elimination of the inducible response requires simultaneous mutation of both sequences, however, in the presence of an intact EpRE the upstream AP-1 site is irrelevant to induction. Regulation of expression of both human GCS subunit genes in response to beta-NF is therefore mediated by cis-elements satisfying the consensus core EpRE motif.

Phase I study of continuous-infusion L-S,R-buthionine sulfoximine with intravenous melphalan.

BACKGROUND: Increased intracellular glutathione has long been associated with tumor cell resistance to various cytotoxic agents. An inhibitor of glutathione biosynthesis, L-S,R-buthionine sulfoximine (BSO), has been shown to enhance the cytotoxicity of chemotherapeutic agents in vitro and in vivo. We performed a phase I study of BSO administered with the anticancer drug melphalan to determine the combination's safety/tolerability and to determine clinically whether BSO produced the desired biochemical end point of glutathione depletion (<10% of pretreatment value). METHODS: Twenty-one patients with advanced cancers received an initial 30-minute infusion of BSO totaling 3.0 g/m2 and immediately received a continuous infusion of BSO on one of the following schedules: 1) 0.75 g/m2 per hour for 24 hours (four patients); 2) the same dose rate for 48 hours (four patients); 3) the same dose rate for 72 hours (10 patients); or 4) 1.5 g/m2 per hour for 48 hours (three patients). During week 1, the patients received BSO alone; during weeks 2 or 3, they received BSO plus melphalan (15 mg/m2); thereafter, the patients received BSO plus melphalan every 4 weeks. Glutathione concentrations in peripheral blood lymphocytes were determined for all patients; in 10 patients on three of the administration schedules, these measurements were made in multiple sections from tumor biopsy specimens taken before, during, and after continuous-infusion BSO. RESULTS: Continuous-infusion BSO alone produced minimal toxic effects, although BSO plus melphalan produced occasional severe myelosuppression (grade 4) and frequent low-grade nausea/vomiting (grade 1-2). This treatment also produced consistent, profound glutathione depletion (<10% of pretreatment value). The degree of glutathione depletion in peripheral lymphocytes was considerably less than that observed in tumor sections. CONCLUSIONS: Continuous-infusion BSO is relatively nontoxic and results in depletion of tumor glutathione.

Constitutive and beta-naphthoflavone-induced expression of the human gamma-glutamylcysteine synthetase heavy subunit gene is regulated by a distal antioxidant response element/TRE sequence.

Glutathione (GSH) is an abundant cellular non-protein sulfhydryl that functions as an important protectant against reactive oxygen species and electrophiles, is involved in the detoxification of xenobiotics, and contributes to the maintenance of cellular redox balance. The rate-limiting enzyme in the de novo synthesis of glutathione is gamma-glutamylcysteine synthetase (GCS), a heterodimer consisting of heavy and light subunits expressing catalytic and regulatory functions, respectively. Exposure of HepG2 cells to beta-naphthoflavone (beta-NF) resulted in a time- and dose-dependent increase in the steady-state mRNA levels for both subunits. In order to identify sequences mediating the constitutive and induced expression of the heavy subunit gene, a series of deletion mutants created from the 5'-flanking region (-3802 to +465) were cloned into a luciferase reporter vector (pGL3-Basic) and transfected into HepG2 cells. Constitutive expression was maximally directed by sequences between -202 and +22 as well as by elements between -3802 to -2752. The former sequence contains a consensus TATA box. Increased luciferase expression following exposure to 10 microM beta-NF was only detected in cells transfected with a reporter vector containing the full-length -3802:+465 fragment. Hence, elements directing constitutive and induced expression of the GCS heavy subunit are present in the distal portion of the 5'-flanking region, between positions -3802 and -2752. Sequence analysis revealed the presence of several putative consensus response elements in this region, including two potential antioxidant response elements (ARE3 and ARE4), separated by 34 base pairs. When cloned into the thymidine kinase-luciferase vector, pT81-luciferase, and transfected into HepG2 cells, both ARE3 and ARE4 increased basal luciferase expression approximately 20-fold. When cloned in tandem in their native arrangement the increase in luciferase activity was in excess of 100-fold, suggesting a strong interaction between the two sequences. Luciferase expression was elevated in beta-NF-treated cells transfected with the ARE4-tk-luciferase vector and all DNA fragments containing ARE4. In contrast, ARE3 did not direct increased luciferase expression in response to beta-NF nor did it significantly modify the magnitude of induction directed by ARE4. The influence of the ARE4 oligonucleotide on constitutive and induced expression was eliminated by introduction of a single base mutation, converting the core ARE sequence in ARE4 from 5'-GTGACTCAGCG-3' to 5'-GGGACTCAGCG-3'. When introduced into the full-length -3802:+465 segment, the same single base mutation also eliminated both functions. Collectively the data indicate that the constitutive and beta-NF-induced expression of the human GCS heavy subunit gene is mediated by a distal ARE sequence containing an embedded tetradecanoylphorbol-13-acetate-responsive element.

Transfection of complementary DNAs for the heavy and light subunits of human gamma-glutamylcysteine synthetase results in an elevation of intracellular glutathione and resistance to melphalan.

Although glutathione (GSH) has long been implicated in resistance to certain common chemotherapeutic agents, including alkylating agents, platinum analogues, and doxorubicin, evidence establishing a direct role in the resistant phenotype has been lacking. We cotransfected COS cells with the cDNAs for the two subunits of gamma-glutamylcysteine synthetase (GCS), which catalyzes the rate-limiting step in the de novo synthesis of GSH and is itself up-regulated in some drug-resistant tumor cells. Transfection resulted in increased GCS activity and elevated GSH levels (up to 2.6-fold). Cotransfection with the two subunits greatly enhanced the synthetic efficiency of the heavy subunit. A direct correlation (P < 0.01) between intracellular GSH levels and the LD99 dose of melphalan was observed, signifying that elevation of the thiol secondary to GCS expression is sufficient to confer the resistance phenotype.

Identification of a putative antioxidant response element in the 5'-flanking region of the human gamma-glutamylcysteine synthetase heavy subunit gene.

We have cloned the human gamma-glutamylcysteine synthetase heavy subunit gene (GCSh) from a P1 library and isolated a 5.5kb fragment (P1-GCS5') from the 5'-end of the P1 clone. P1-GCS5' has been sequenced from -1460 to +547. Multiple transcription start sites were identified by primer extension and S1 nuclease protection. Two start sites were identified by primer extension analysis within 23 bp (+1 and +10) of a consensus TATAAAA box; all sequences were numbered relative to the 5'-most of these two sites. Two additional major start sites were identified at -106 and +398. This latter site was the most prominent of all the initiation sites. In addition to a TATA box, the promoter contains a CCAAT box at -125 and GC boxes up- and down-stream of the TATAAAA. In addition, the first few hundred base pairs of the sequence are highly GC-rich (approximately 75%). This sequence also contains several Sp-1 binding sites, a consensus AP-1 site and several AP-1-like binding sites, as well as putative AP-2 sites. A consensus metal responsive element (MRE) was identified at position +198. Sequence analysis also identified a putative core (5'-TGACnnnGCA-3') antioxidant response element (ARE) at -862 to -853. As is typical of other AREs, a second AP-1-like sequence is located adjacent to the core sequence. These results suggest that GCSh gene expression in response to oxidative challenge may be regulated through an antioxidant response element similar to those recently detected in the promoter region of several Phase II enzymes.

The decreased influence of overall treatment time on the response of human breast tumor xenografts following prolongation of the potential doubling time (Tpot).

PURPOSE: Repopulation during fractionated radiotherapy has been postulated to result in a significant loss in local control in rapidly proliferating tumors. Clinical data suggest that accelerated fractionation schedules can overcome the influence of repopulation by limiting the overall treatment time. Unfortunately, accelerated therapy frequently leads to increased acute reactions, which may become dose limiting. An alternative to accelerated fractionation would be to decrease the rate of repopulation during therapy. To test the potential efficacy of this alternative, we examined the effect of reducing tumor proliferation rate on the response of MCF-7 human breast carcinoma xenografts treated with a short vs. a long course of fractionated therapy. To reduce the proliferation rate, we deprived nude mice transplanted with MCF-7 xenografts of the growth-stimulating hormone estradiol (E2). We have previously reported that E2 deprivation increases the potential doubling time (Tpot) for MCF-7 xenografts from a mean of 2.6 days to 5.3 days (p < 0.001). METHODS AND MATERIALS: E2-stimulated and E2-deprived MCF-7 breast carcinoma xenografts were clamped hypoxically and irradiated with four fractions of 5 Gy each, using either a short (3-day) or long (9-day) treatment course. E2 stimulation was restored in all animals at the completion of irradiation. Radiation response was determined by regrowth time and regrowth delay of the irradiated tumors as compared to unirradiated controls. RESULTS: Prolongation of therapy in rapidly proliferating, E2-stimulated tumors (Tpot approximately 2.6 days) resulted in a significant decrease in regrowth time in two identical experiments. With results pooled for analysis, the regrowth times for the short and long treatments were 62 and 32 days, respectively (combined p < 0.001). The shorter regrowth times suggest that there was less overall tumor damage with the longer fractionated radiotherapy course. No significant difference in regrowth time was observed in the more slowly proliferating, E2-deprived tumors (Tpot approximately 5.3 days) treated with either the short or long regimen. Median regrowth times were 48 and 54.5 days for the short and long treatments, respectively (combined p = 0.14). Similar changes were observed in regrowth delay. CONCLUSIONS: Reduction in the rate of cell proliferation, induced by E2 deprivation in MCF-7 human breast xenografts during fractionated radiotherapy, resulted in a significantly decreased dependence on overall treatment time in comparison to the more rapidly proliferating E2-stimulated tumors. This model suggests that pharmacologically induced reduction in the rate of tumor cell proliferation during a course of fractionated radiotherapy may be a viable alternative to accelerated fractionation for the treatment of rapidly proliferating tumors.

Cloning and sequencing of the cDNA for the light subunit of human liver gamma-glutamylcysteine synthetase and relative mRNA levels for heavy and light subunits in human normal tissues.

We have cloned and sequenced a full length cDNA for the light subunit of human liver gamma-glutamylcysteine synthetase (GCS1). The GCS1 cDNA consists of 1628 bp, containing an open reading frame of 822 bp which encodes a protein of 274 amino acids having a calculated M(r) of 30,729 Daltons. Human liver GCS1 shares 91% and 96% sequence homology at the nucleotide and amino acid levels, respectively, with its rat counterpart (Huang, Anderson and Meister, J. Biol. Chem. 268:20578-20583, 1993). Transcripts of 1.4 and 4.1 kb in length were detected by Northern blot analysis of mRNA isolated from each of sixteen different human tissues. Relative expression of the two GCS1 RNA transcripts was highly tissue-dependent. High steady-state levels of the smaller transcript were detected in colon, while very high levels of both transcripts were found in skeletal muscle. Expression of mRNA transcripts for the GCS heavy subunit were likewise tissue-dependent, and did not necessarily correlate with the level of GCS1 transcripts in any tissue.