Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.5.1.18 (glutathione S-transferase)
 22,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The PHO81 gene is thought to encode an inhibitor of the negative regulators (Pho80p and Pho85p) in the phosphatase (PHO) regulon. Transcription of PHO81 is regulated by Pi signals through the same PHO regulatory system. Elimination of the PHO81 promoter or its substitution by the GAL1 promoter revealed that stimulation of the PHO regulatory system requires both increased transcription of PHO81 and a Pi starvation signal. The predicted Pho81p protein contains 1,179 amino acids (aa) and has six repeats of an ankyrin-like sequence in its central region. The minimum amino acid sequence required for Pho81p function was narrowed down to a 141-aa segment (aa 584 to 724), which contains the fifth and sixth repeats of the ankyrin-like motif. The third to sixth repeats of the ankyrin-like motif of Pho81p have significant similarities to that of p16INK4, which inhibits activity of the human cyclin D-CDK4 kinase complex. Deletion analyses revealed that the N- and C-terminal regions of Pho81p behave as negative and positive regulatory domains, respectively, for the minimal 141-aa region. The negative regulatory activity of the N-terminal domain was antagonized by a C-terminal segment of Pho81p supplied in trans. All four known classes of PHO81c mutations that show repressible acid phosphatase activity in high-Pi medium affect the N-terminal half of Pho81p. An in vitro assay showed that a glutathione S-transferase-Pho81p fusion protein inhibits the Pho85p protein kinase. Association of Pho81p with Pho85p or with the Pho80p-Pho85p complex was demonstrated by the two-hybrid system.
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PMID:Functional domains of Pho81p, an inhibitor of Pho85p protein kinase, in the transduction pathway of Pi signals in Saccharomyces cerevisiae. 782 64

Cyclin-dependent kinase 4 (CDK4) is a key molecule in the regulation of cell cycle progression at the G1-S phase restriction point. Its activity is specifically regulated by p16 (also known as p16/CDKN2A, p16(INK4a), and MTS1), a tumor suppressor frequently altered in human cancers. A specific mutation in CDK4 codon 24 (Arginine to Cysteine) prevents p16 binding and thus inhibition by p16. This mutated CDK4 acts as a dominant oncogene and has been found in both sporadic and familial melanoma. To study the effects of other mutations in CDK4, we generated a panel of 18 CDK4 mutants using Charged-to-Alanine scanning mutagenesis, and investigated the p16-binding capacity of these mutants to identify novel sites involved in p16 binding. The mutant CDK4 proteins were generated by direct coupled transcription-translation in vitro and tested for binding to p16 using a p16-GST fusion protein. Several mutants demonstrated loss of p16 binding. In addition to the previously identified codon 24 mutants, alterations in and around codon 22, 25, 97, and 281 all showed loss of p16 binding capacity. These results indicate that several noncontiguous amino acid sequences on CDK4 are required for binding to p16, which suggests the existence of multiple sites of interaction with p16. Since p16-binding deficient CDK4 has oncogenic potential, these mutations may be present in melanomas or other human neoplasms.
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PMID:Several noncontiguous domains of CDK4 are involved in binding to the P16 tumor suppressor protein. 971 35

Since the structures of several ankyrin-repeat proteins including the INK4 (inhibitor of cyclin-dependent kinase 4) family have been reported recently, the detailed structures and the functional roles of the loops have drawn considerable interest. This paper addresses the potential importance of the loops of ankyrin-repeat proteins in three aspects. First, the solution structure of p18INK4C was determined by NMR, and the loop structures were analyzed in detail. The loops adapt nascent antiparallel beta-sheet structures, but the positions are slightly different from those in the crystal structure. A detailed comparison between the solution structures of p16 and p18 has also been presented. The determination of the p18 solution structure made such detailed comparisons possible for the first time. Second, the [1H,15N]HSQC NMR experiment was used to probe the interactions between p18INK4C and other proteins. The results suggest that p18INK4C interacts very weakly with dna K and glutathione S-transferase via the loops. The third aspect employed site-specific mutagenesis and functional assays. Three mutants of p18 and 11 mutants of p16 were constructed to test functional importance of loops and helices. The results suggest that loop 2 is likely to be part of the recognition surface of p18INK4C or p16INK4A for CDK4, and they provide quantitative functional contributions of specific residues. Overall, our results enhance understanding of the structural and functional roles of the loops in INK4 tumor suppressors in particular and in ankyrin-repeat proteins in general.
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PMID:Tumor suppressor INK4: determination of the solution structure of p18INK4C and demonstration of the functional significance of loops in p18INK4C and p16INK4A. 1007 45

Epigenetic mechanisms may be the main driving force for critical changes in gene expression that are responsible for progression of prostate cancers. The three most extensively characterized mechanisms for epigenetic gene-regulation are (i) changing patterns of DNA methylation, (ii) histone acetylations/deacetylations, and (iii) alterations in regulatory feedback loops for growth factors. Several studies have indicated that DNA hypermethylation is an important mechanism in prostate cancer for inactivation of key regulatory genes such as E-cadherin, pi-class glutathione S-transferase, the tumor suppressors CDKN2 and PTEN, and IGF-II. Similarly, histone acetylations and deacetylations are frequently associated respectively with transcriptional activation (e.g. IGFBP-2 and p21) and repression (e.g. Mad:Max dimers) of genes linked to prostate cancer progression. Recently, histone acetyltransferase and deacetylase activities have been shown to be intrinsic with transcriptional coregulator proteins that bind to steroid receptors (e.g. SRC-1 and PCAF). Changes in regulatory feedback loops for growth factors with prostate cancer progression tend toward shifts from paracrine to autocrine control where the receptor and ligand are produced by the same cell. While there are several examples of this progression pattern in prostate tumors such as with IGF, FGF, TGF-alpha and their respective receptors, the precise mechanism (i.e. epigenetic or mutational) is less certain. In the context of treatment options, the contribution of mutational versus epigenetic events to prostate cancer progression is an important consideration. Irreversible genetic changes are likely to be less amenable to therapeutic control than are epigenetic ones.
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PMID:Epigenetic mechanisms for progression of prostate cancer. 1045 84

The existence of genetic alterations affecting genes involved in cellular proliferation and death, such as TP53 and K-ras, is one of the most common features of tumour cells. Recently, gene inactivation by promoter hypermethylation has been demonstrated. Methylation is the main epigenetic modification in mammals and abnormal methylation of the CpG islands located in the promoter region of the genes leads to transcriptional silencing. Examples include the p16INK4a, p15INK4B, p14ARF, Von Hippel-Lindau (VHL), the oestrogen and progesterone receptors, E-cadherin, death associated protein (DAP) kinase and the first tumour suppressor gene described, retinoblastoma (Rb) gene. In most cases, methylation involves loss of expression, absence of a coding mutation and restoration of transcription by the use of demethylating agents. However, is there a linkage between genetic and epigenetic alterations? Our results show one side of this puzzle demonstrating that epigenetic lesions drive genetic lesions in cancer. Four specific epigenetic lesions, promoter hypermethylation of the DNA mismatch repair gene hMLH1, the DNA alkyl-repair gene O(6)-methylguanine-DNA methyltransferase (MGMT), the detoxifier glutathione S-transferase P1 (GSTP1) and the familial breast cancer gene BRCA1 may lead to four specific genetic lesions, microsatellite instability, G to A transitions, steroid-related adducts and double-strand breaks in DNA. This is probably only the beginning of an extensive list of epigenetic events that change and make the genetic environment of the transformed cell unstable.
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PMID:Epigenetic lesions causing genetic lesions in human cancer: promoter hypermethylation of DNA repair genes. 1109 2

Aberrant methylation of CpG islands acquired in tumor cells in promoter regions is one method for loss of gene function. We determined the frequency of aberrant promoter methylation (referred to as methylation) of the genes retinoic acid receptor beta-2 (RARbeta), tissue inhibitor of metalloproteinase 3 (TIMP-3), p16INK4a, O6-methylguanine-DNA-methyltransferase (MGMT), death-associated protein kinase (DAPK), E-cadherin (ECAD), p14ARF, and glutathione S-transferase P1 (GSTP1) in 107 resected primary non-small cell lung cancers (NSCLCs) and in 104 corresponding nonmalignant lung tissues by methylation-specific PCR. Methylation in the tumor samples was detected in 40% for RARbeta, 26% for TIMP-3, 25% for p16INK4a, 21% for MGMT, 19% for DAPK, 18% for ECAD, 8% for p14ARF, and 7% for GSTP1, whereas it was not seen in the vast majority of the corresponding nonmalignant tissues. Moreover, p16INK4a methylation was correlated with loss of p16INK4a expression by immunohistochemistry. A total of 82% of the NSCLCs had methylation of at least one of these genes; 37% of the NSCLCs had one gene methylated, 22% of the NSCLCs had two genes methylated, 13% of the NSCLCs had three genes methylated, 8% of the NSCLCs had four genes methylated, and 2% of the NSCLCs had five genes methylated. Methylation of these genes was correlated with some clinicopathological characteristics of the patients. In comparing the methylation patterns of tumors and nonmalignant lung tissues from the same patients, there were many discordancies where the genes methylated in nonmalignant tissues were not methylated in the corresponding tumors. This suggests that the methylation was occurring as a preneoplastic change. We conclude that these findings confirm in a large sample that methylation is a frequent event in NSCLC, can also occur in smoking-damaged nonmalignant lung tissues, and may be the most common mechanism to inactivate cancer-related genes in NSCLC.
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PMID:Aberrant promoter methylation of multiple genes in non-small cell lung cancers. 1119 70

Multiple genetic mutations and epigenetic methylation are believed to be involved in prostate carcinogenesis, but it is not known whether these events are independent or correlated in some fashion. We therefore studied 32 prostate adenocarcinomas not only for deletions and / or mutations of multiple suspect genes, but also for aberrant DNA methylation using methylation-specific PCR (MSP). Of those genes examined, p16(INK4a), O(6)-MGMT, and GST-P were found to be the most frequently methylated (66%, 25% and 75% of cases, respectively), while methylations of p14(ARF), RB1, p21(Waf1), and p27(Kip1) were far less common (3%, 6%, 6% and 6% of cases, respectively). Methylation of O(6)-MGMT and GST-P genes was defective in about 19% of the cases and there were occasional simultaneous deletions and methylations of p14(ARF) and p16(INK4a) genes (13% and 3% of cases, respectively). In p16(INK4a), methylation occurred in the promoter region in 9% of samples and in exon 2 in 66% of tumors. Hypermethylation of O(6)-MGMT with concurrent p53 and ras gene mutations were found in 6% and 13% of specimens, respectively; among those tumors with high Gleason scores were 2 carcinomas showing hypermethylated O(6)-MGMT with G-to-A transitions in K-ras. Our results demonstrate that multiple genes of a subset common in prostate carcinomas are methylated and not infrequently show concurrent deletions. Further, there is a suggestion that specific combinations of hypermethylation and mutation correlate to tumor malignancy.
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PMID:DNA hypermethylation status of multiple genes in prostate adenocarcinomas. 1214 42

Epstein-Barr virus (EBV) carrying lymphoblastoid cells of normal origin express the full program of all 9 virus-encoded, growth transformation associated proteins. They have an intact p53 pathway as a rule. This raises the question of whether any of the viral proteins impair the pathway functionally. Using a yeast 2-hybrid system, we have shown that EBNA-5 but not the other EBNAs interacts with the p14ARF protein, a regulator of the p53 pathway. The interaction was confirmed in vitro using a GST pull-down assay. Moreover, expression of EBNA-5 increased the survival of p14ARF-transfected cells. EBV infection of resting B cells induced the expression of p14ARF mRNA without increased level of the protein. A fraction of the p14ARF localized to the nucleoli but the bulk of the protein accumulated in nuclear but extranucleolar inclusions. Formation of the extranucleolar inclusions led to complete relocalization of EBNA-5 from nucleoplasm to these structures. The inclusions also contained p53 and HDM2, and were surrounded by PML bodies and proteasomes, which suggests that these inclusions could be targets for proteasome dependent protein degradation.
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PMID:EBV-encoded EBNA-5 associates with P14ARF in extranucleolar inclusions and prolongs the survival of P14ARF-expressing cells. 1274 Sep 13

Aberrant hypermethylation occurs in tumour cell CpG islands and is an important pathway for the repression of gene transcription in cancers. We investigated aberrant hypermethylation of 11 genes by methylation-specific polymerase chain reaction (PCR), after treatment of the DNA with bisulphite, and correlated the findings with MYCN amplification and allelic status at 1p in a series of 44 neuroblastic tumours. This tumour series includes five ganglioneuromas (G), one ganglioneuroblastoma (GN) and 38 neuroblastomas (six stage 1 tumours; five stage 2 tumours; six stage 3 cases; 19 stage 4 tumours, and two stage 4S cases). Aberrant methylation of at least one of the 11 genes studied was detected in 95% (42 of 44) of the cases. The frequencies of aberrant methylation were: 64% for thrombospondin-1 (THBS1); 30% for tissue inhibitor of metalloproteinase 3 (TIMP-3); 27% for O6-methylguanine-DNA methyltransferase (MGMT); 25% for p73; 18% for RB1; 14% for death-associated protein kinase (DAPK), p14ARF, p16INK4a and caspase 8, and 0% for TP53 and glutathione S-transferase P1 (GSTP1). No aberrant methylation was observed in four control normal tissue samples (brain and adrenal medulla). MYCN amplification was found in 11 cases (all stage 4 neuroblastomas), whereas allelic loss at 1p was identified in 16 samples (13 stage 4 and two stage 3 neuroblastomas, and one ganglioneuroma). All but one case with caspase 8 methylation also displayed MYCN amplification. Our results suggest that promoter hypermethylation is a frequent epigenetic event in the tumorigenesis of neuroblastic tumours, but no specific pattern of hypermethylated genes could be demonstrated.
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PMID:Aberrant methylation of multiple genes in neuroblastic tumours. relationship with MYCN amplification and allelic status at 1p. 1282 52

The aberrant methylation of the CpG island promoter regions acquired by tumor cells is one mechanism for loss of gene function. The high methylation rate for RB1 and death-associated protein-kinase gene (DAP-kinase) (60 and 90%, respectively) previously found in brain metastases suggests this mechanism could be non-randomly associated to tumor progression and metastasis. Thus, in addition to these two genes, we determined the methylation status of the genes p16INK4a, glutathione S-transferase P1 (GSTP1), O6-methylguanine DNA methyltransferase (MGMT), thrombospondin-1 (THBS1), p14ARF, TP53, p73, and tissue inhibitor of metalloproteinase 3 (TIMP-3), in 18 brain metastases of solid tumors, with methylation specific PCR. The metastases were derived from malignant melanoma (three cases), lung carcinoma (six cases), breast carcinoma (three cases), ovarian carcinoma (two cases) and one each from colon, kidney, bladder and undifferentiated carcinoma. We detected methylation levels in the tumor samples of 83% in p16INK4a, 72% in DAP-kinase, 56% in THBS1, 50% in RB1, 39% in MGMT, 33% in GSTP1 and p14ARF each, 22% in p73 and TIMP-3 each, and 11% in TP53. The methylation index (number of genes methylated/number of genes tested) varied between 0.1 and 0.6, with an average of 0.42, indicating that a high grade of gene methylation accumulates parallel to the tumor metastasis process. Our data suggest an important role for gene methylation in the development of brain metastases, primarily involving epigenetic silencing of DAP-kinase, THBS1 and the cell-cycle regulators RB1/p16INK4a.
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PMID:Promoter methylation status of multiple genes in brain metastases of solid tumors. 1465 77


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