EC:2.5.1.18 - FACTA Search

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Query: EC:2.5.1.18 (glutathione S-transferase)
22,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Activated c-Ha-ras DNA sequences were introduced by transfection into a low passage simian virus 40 (SV40)-immortalized rat hepatocyte cell line, CWSV1, and stable ras transfectant cell lines were established to determine the effect of the addition of the activated c-Ha-ras oncogene on growth properties and differentiation. Control transfectant cell lines were generated by transfection with neo alone. CWSV1 cells at low passage and the control transfectants were not tumorigenic. The ras transfectants demonstrated anchorage-independent growth and were highly tumorigenic in syngeneic hosts. CWSV1 cells produce liver-like levels of albumin and express other liver-specific genes. The ras transfectants expressed RNA for albumin, transferrin, and the transcription factor HNF-1 at similar levels to the parental CWSV1 cells, indicating that the alterations in growth properties and tumorigenic potential of these cells did not decrease the ability of the cells to express several genes that are associated with hepatocyte differentiation. The addition of the ras oncogene did not induce the expression of alpha-fetoprotein and had no specific effect on expression of glutathione S-transferase-P. The tumors produced by the ras transfectants were not well differentiated; however, the cells in the tumors and tumor cell lines derived from the tumors continued to produce albumin and did not produce alpha-fetoprotein. We conclude that the addition of the activated c-Ha-ras oncogene to immortalized CWSV1 cells transformed these cells as measured by morphology, growth properties, and tumorigenicity without reducing their ability to express albumin and other significant liver-specific genes.
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PMID:Introduction of the ras oncogene transforms a simian virus 40-immortalized hepatocyte cell line without loss of expression of albumin and other liver-specific genes. 137 Oct 91

The ras GTPase-activating protein (GAP), identified and characterized in mammalian cells, stimulates the intrinsic GTPase activity of ras proteins. We have previously proposed that the IRA genes, negative regulators of RAS genes in Saccharomyces cerevisiae, encode yeast homologs of the mammalian GAP. In this paper, we present the following evidence that a product of the IRA2 gene exhibits GAP activity similar to that of the mammalian GAP protein. (i) Extracts of yeast cells overexpressing IRA2 stimulated the GTPase activity of the yeast RAS2 protein. (ii) An epitope for a monoclonal antibody (12CA5) was added to the N terminus of the IRA2 protein. The GAP activity of extracts prepared from cells expressing this fusion protein was shown to be immunoprecipitable by 12CA5. (iii) An IRA2 protein fused to glutathione S-transferase (GST) was produced and partially purified from Escherichia coli cells. GAP activity was detected with this purified GST-IRA2 fusion protein. (iv) The GAP activity of IRA2 proteins described above did not stimulate the GTPase activity of the RAS2Val19 protein, a protein having an amino acid alteration analogous to that found in mammalian oncogenic ras proteins. This result parallels studies showing that mammalian GAP is incapable of stimulating the GTPase activity of mammalian oncogenic proteins. The remarkable conservation between the GAP activity in mammalian and yeast cells supports the idea that the function of GAP is to negatively regulate ras proteins in mammalian cells.
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PMID:IRA2, an upstream negative regulator of RAS in yeast, is a RAS GTPase-activating protein. 198 46

Sequencing of the neurofibromatosis gene (NF1) revealed a striking similarity among NF1, yeast IRA proteins, and mammalian GAP (GTPase-activating protein). Using both genetic and biochemical assays, we demonstrate that this homology domain of the NF1 protein interacts with ras proteins. First, expression of this NF1 domain suppressed the heat shock-sensitive phenotype of yeast ira1 and ira2 mutants. Second, this NF1 domain, after purification as a glutathione S-transferase (GST) fusion protein, strongly stimulated the GTPase activity of yeast RAS2 and human H-ras proteins. The GST-NF1 protein, however, did not stimulate the GTPase activity of oncogenic mutant ras proteins, H-rasVal-12 and yeast RAS2Val-19 mutants, or a yeast RAS2 effector mutant. These results establish that this NF1 domain has ras GAP activity similar to that found with IRA2 protein and mammalian GAP, and therefore may also regulate ras function in vivo.
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PMID:The catalytic domain of the neurofibromatosis type 1 gene product stimulates ras GTPase and complements ira mutants of S. cerevisiae. 212 69

We compared the regulation of gamma-glutamyl transferase (gamma GT) and glutathione-S-transferase-P (GST-P) expression in rat liver epithelial cells (228 cells) and a line derived from them (C5 cells) by stable transfection with a metallothionein-activated ras fusion gene (MTrasT24). Earlier studies demonstrated that steady state RNA levels of these genes are increased after transformation of liver cells by MTrasT24 (Proc. Natl. Acad. Sci., 85, 344-348, 1988). In the present study, we found that the rate of gamma GT transcription increased approximately 20 fold after transformation by MTrasT24 while the rate of GST-P transcription increased no more than two fold. However, the stability of GST-P RNA was increased about 3 fold in these cells. Comparisons of gamma GT RNA stability were not possible since nontransformed liver cells (228) contain little or no gamma GT RNA. Thus, the accumulation of gamma GT RNA in C5 cells is heavily dependent on increased rates of transcription while the more modest increases in GST-P RNA levels result in large part from increased RNA stability. In ras transformed cells both transcriptional and post-transcriptional events contribute to the increased steady state RNA levels of cellular genes.
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PMID:Two genes associated with liver cancer are regulated by different mechanisms in rasT24 transformed liver epithelial cells. 256

We have examined regulation of the glutathione S-transferase pi gene by transient expression assay, and find that a fragment from 8 to 99 bp upstream of the cap site promotes transcription, but there is no evidence for any enhancer activity in a further 6 kb of flanking sequence. Analysis of this sequence by reference to a primate sequence database and Southern blotting revealed that as much as 5 kb of this flanking DNA were composed of repetitive insertion elements including an Alu and a LINE 1 repeat. The promoter fragment has been sequenced (Cowell et al (1988) Biochem. J. 255, 79-83) and contains a consensus AP1 binding site; in some cases, these have been associated with transcriptional induction by phorbol esters and ras oncogenes. We measured the steady state levels of glutathione S-transferase pi mRNA in human cell lines which were known to express ras oncogenes and compared them to human cell lines which have not been identified with ras activation. There was no correlation between expression of activated ras and expression of glutathione S-transferase pi mRNA. Treatment of HeLa cells, HepG2 cells and a small cell lung carcinoma line, GLC 8, with the phorbol ester 12-O-tetradecanoylphorbol 13-acetate failed to alter the steady state levels of endogenous glutathione S-transferase pi mRNA. The differences between these results and those of similar studies on rat glutathione S-transferase subunit 7, a structural orthologue of glutathione S-transferase pi, are discussed.
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PMID:Control of expression of the human glutathione S-transferase pi gene differs from its rat orthologue. 278 23

We studied the effects of a zinc-inducible metallothionein-ras fusion gene (MTrasT24) in cultured rat liver epithelial (RLE) cells on expression of two genes induced during liver carcinogenesis in vivo: gamma-glutamyltransferase [(5-glutamyl)-peptide:amino acid 5-glutamyltransferase, EC 2.3.2.2] and glutathione S-transferase-P (RX:glutathione R-transferase, EC 2.5.1.18). Expression of MTrasT24 increased steady-state RNA levels of gamma-glutamyltransferase and glutathione transferase-P 6- to 100-fold and 1.6- to 6-fold, respectively; in contrast, levels of alpha-tubulin RNA fell slightly or were unchanged. RNA gel blots verified that gamma-glutamyltransferase and glutathione transferase-P RNAs were of the appropriate size, and results from immunocytochemistry on transfected cells demonstrated that RLE cells carrying MTrasT24 synthesized immunoreactive, appropriately localized gamma-glutamyltransferase and glutathione transferase-P. Zinc induction studies indicated that gamma-glutamyltransferase and glutathione transferase-P RNA levels were directly dependent on MTrasT24 RNA levels. These data suggest that expression of gamma-glutamyltransferase and glutathione transferase-P expression are part of a reorientation of cellular gene expression during carcinogenesis and that activated ras expression, like chemical carcinogens, can bring about this change.
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PMID:MTrasT24, a metallothionein-ras fusion gene, modulates expression in cultured rat liver cells of two genes associated with in vivo liver cancer. 289 74

A neutral isoenzyme of glutathione transferase designated glutathione-S-transferase 7-7, but also referred to as glutathione-S-transferase P (GST-P) is absent from adult rat liver hepatocytes, but expressed at a very early stage in chemically induced in vivo hepatocarcinogenesis. The expression of this enzyme in a range of aflatoxin B1 (AFB1) associated hepatocarcinogenic systems has been examined, including in vivo induced preneoplastic and neoplastic liver tissue, cell lines derived from hepatomas, primary hepatocytes in culture and an immortalized rat liver cell line before and after transformation in vitro either by transfection with ras oncogenes or by treatment with metabolically activated AFB1. Analyses of total cytosol proteins using a polyclonal antibody to GST-P did not detect the presence of GST-P protein in cytosols from control or regenerating liver. A low level of expression was detected in the immortalized, non-transformed epithelial cell line, but a greatly induced level occurred subsequent to transformation of these cells by either of the two techniques used. High levels of the protein were detected in in vivo induced preneoplastic and neoplastic tissues, and in the cell lines derived from them. Total RNA fractions isolated from the various cells or tissues, when examined with a cDNA probe for GST-P mRNA, showed it to be absent from control and regenerating rat liver. It was present at low levels in the untransformed cell line and primary hepatocytes after 48 h in culture, but present at greatest abundance in the in vivo and in vitro transformed cells. The results indicate that the highest elevation in expression of this protein is associated with the stage of definitive malignant transformation in in vitro carcinogenesis, and this could have relevance in defining comparable events in the in vivo multistage sequence.
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PMID:Transformation related expression of glutathione-S-transferase P in rat liver cells. 311 38

We have previously reported that the hyaluronan (HA) receptor RHAMM (Receptor for HA Mediated Motility) [Turley et al., 1991] contains two HA binding motifs located within a 35 amino acid region of its C-terminus end [Yang et al., 1993] and that HA stimulation of the motility of ras-transformed fibroblasts is mediated via its interaction with RHAMM. Here we show that RHAMM also contains binding sites for heparin (HP) and that interaction of HP with these sites can regulate the locomotion of ras-transformed fibroblasts. At low concentrations (0.01 mg/ml), HP inhibited HA-induced locomotion of ras-transformed cells in a manner independent of RHAMM. At higher, but still physiological concentrations (0.1 mg/ml), HP alone stimulated cell locomotion and this stimulation appeared to be RHAMM-dependent as it was blocked by anti-RHAMM antibodies. Other related glycosaminoglycans such as chondroitin sulfate and dermatin sulfate had no effect on cell motility. In ligand blotting assays, GST-RHAMM fusion protein was shown to bind biotin-labelled HP and this binding was displaceable with unlabelled HP. In similar ligand binding analyses conducted with truncations of RHAMM fusion protein, the HP binding region was found to be localized in the same 35 amino acid segment of RHAMM that contains the two HA binding domains. Synthetic peptides corresponding to these HA binding domains were retained on and bound effectively to an HP-Sepharose affinity column. Fusion proteins generated by linkage of these peptides to the non-HP binding amino terminus of RHAMM conferred HP binding capacity to the genetically engineered proteins. Conversely, deletion of the HA binding domains of RHAMM resulted in fusion proteins devoid of HP binding activity. The relative affinities of RHAMM for HA and HP, as determined by competition and transblot assays as well as quantification of binding at various salt concentrations, indicated that RHAMM had lower affinity for HP than that for HA. These results demonstrate the existence of a new HP binding motif that has biological relevance to cell locomotion.
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PMID:Identification of a novel heparin binding domain in RHAMM and evidence that it modifies HA mediated locomotion of ras-transformed cells. 753 13

We have cloned a protein tyrosine kinase, MATK, which is expressed abundantly in megakaryocytes and the brain. We investigated whether MATK participates in the c-Kit ligand/stem cell factor (KL/SCF) signaling pathway in the megakaryocytic cell line CMK. After KL/SCF stimulation, five major proteins of molecular masses of 145, 113, 92, 76, and 63 kDa were rapidly and transiently tyrosine-phosphorylated in a time-dependent manner, peaking within 5 min, and returning to basal levels within 60 min. To study the role of MATK in the KL/SCF signaling pathway, glutathione S-transferase (GST) fusion proteins containing SH2 and SH3 domains of MATK were cloned, expressed in Escherichia coli, and purified. MATK-SH2, but not MATK-SH3, precipitated the tyrosine-phosphorylated c-Kit (molecular mass of 145 kDa) in KL/SCF-stimulated CMK cells. Other GST fusion proteins containing the SH2 domain of p85 of phosphatidylinositol 3-kinase, phospholipase C gamma-1, and ras-GAP also precipitated c-Kit. The tyrosine-phosphorylated c-Kit was co-immunoprecipitated with anti-MATK and anti-p85 antibodies in KL/SCF-stimulated CMK cells, but not in granulocyte-macrophage colony stimulating factor or interleukin-6-stimulated cells, suggesting receptor specificity. These results indicate that MATK associates with the c-Kit receptor following specific stimulation by KL/SCF via its SH2 domain and likely participates in transduction of growth signals induced by this cytokine in megakaryocytes.
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PMID:The MATK tyrosine kinase interacts in a specific and SH2-dependent manner with c-Kit. 753 44

We examined the incidence of proliferative lesions, hyperplastic nodules and altered hepatic foci, in male F344 rat liver, to determine their preneoplastic potential during dichloroacetic acid (DCA)-induced hepatocarcinogenesis. Immunohistochemical and image analysis methods were used to detect the expression of 6 histochemical markers of neoplastic cells; p21 ras, p39 c-jun, p55 c-fos, aldehyde dehydrogenase (ALDH), glutathione s-transferase (GST-p), and alpha fetoprotein (AFP) during DCA-induced hepatocarcinogenesis. Our results were consistent with our previous data and suggested that the hyperplastic nodules, rather than altered hepatic foci, is a putative preneoplastic lesion during DCA-induced hepatocarcinogenesis in the male F344 rat.
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PMID:Immunohistochemical analysis of dichloroacetic acid (DCA)-induced hepatocarcinogenesis in male Fischer (F344) rats. 753 96

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