Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.3.1.28 (chloramphenicol acetyltransferase)
 5,100 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The detailed mechanisms leading to transcriptional activation of the human MYC oncogene in general as well as in certain tumor cells are poorly understood. In view of the ability of a number of viral oncogenes to stimulate transcription in trans, the identification of cellular target genes could contribute to the understanding of components of the transformation process. It is demonstrated that the human MYC promoter is such an efficient target for the trans-acting activity mediated by E1a proteins of adenoviruses (Ad). Using the chloramphenicol acetyltransferase (CAT) gene as a marker for promoter activity, co-transfection of constructs containing both MYC promoters and most of the untranslated first exon with plasmids expressing the E1a gene of different adenoviruses stimulates CAT activity up to 24-fold. Trans-activation depends upon the presence of the second promoter (P2), and transcription is initiated at the authentic cap site of P2. This observation is confirmed by the behaviour of stably transformed cell lines carrying single or multiple copies of MYC-cat constructs, which were transfected either with E1a-expressing plasmids, infected with Ad5, or fused with 293 cells constitutively expressing E1a protein. These results suggest that E1a proteins can lead to an imbalance of the regulation of the human MYC gene, which might be a sufficient prerequisite for initiation and progression of transformation.
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PMID:Trans-activation of human MYC: the second promoter is target for the stimulation by adenovirus E1a proteins. 247 Nov 29

We have used a competition assay to identify the targets of trans-acting elements that modulate the expression of the human c-myc gene (designated MYC in human gene nomenclature). For this purpose, a c-myc hybrid indicator gene was formed by joining the c-myc promoter region, first noncoding exon, and intron to the bacterial gene for chloramphenicol acetyltransferase (CAT). The test assay consisted of cotransfecting the indicator gene with competing fragments of DNA derived from suspected control regions of the c-myc gene. Such experiments test the hypothesis that control regions are often targets for the binding of trans-acting regulatory factors that can be diverted to competing fragments of DNA. A negatively acting element will be diverted from the indicator gene, allowing the gene's enhanced expression, whereas a positively acting element will behave oppositely. Control indicator genes driven by non-myc promoters assess the specificity of the effect. Using this approach, we find three c-myc regions that are capable of enhancing the expression of the indicator gene in competition assays (i.e., putative sites of negative modulation). In addition, we find sequences near the c-myc promoters that suppress expression in competition assays (i.e., putative binding sites of positively acting factors). These results, with appropriate controls, suggest the existence of target sites near the c-myc gene that specifically modulate its expression both positively and negatively. Their locations fit well with regions damaged or lost in many Burkitt lymphoma and murine plasmacytoma translocations.
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PMID:Trans-acting elements modulate expression of the human c-myc gene in Burkitt lymphoma cells. 346 6

Murine C2C12 myoblasts induced to differentiate into multinucleated myotubes decrease their levels of c-myc mRNA 3-10-fold through posttranscriptional mechanisms that recognize regulatory elements contained in protein-coding sequences in exons 2 and 3 of the mRNA. To determine the mechanism by which these elements mediate c-myc mRNA down-regulation, we examined the regulation of mutant MYC and human beta-globin-MYC fusion mRNAs. Regulation of mRNAs containing MYC exon 2 or 3 is abolished by insertion of an upstream termination codon indicating that regulatory function depends on their translation. Exploiting this translation dependence, we show that pharmacologic inhibition of translation with cycloheximide abolishes the down-regulation of regulated MYC and globin-MYC mRNAs and induces their levels in differentiating C2C12 cells. We exclude the possibility that this induction in mRNA levels results from cycloheximide effects on transcription or processing of parts of the RNA other than the regulatory elements, leading to the conclusion that cycloheximide induction results from mRNA stabilization. We show that the magnitude of cycloheximide induction can be used to estimate turnover rates of mRNAs whose decay is translation-dependent. By using cycloheximide inducibility to examine turnover rates of MYC and globin-MYC mRNAs, we show that the MYC exon 2 and exon 3 regulatory elements, but not MYC 3'-untranslated region or chloramphenicol acetyltransferase coding sequences, mediate accelerated mRNA decay in differentiating, but not undifferentiated, C2C12 cells. We show that these regulatory elements must be translated to confer accelerated mRNA decay and that increased turnover occurs in the cytoplasm and not in the nucleus. Finally, using cycloheximide induction to examine mRNA half-lives, we show that mRNA turnover is increased sufficiently by mechanisms targeting the exon 2 and 3 regulatory elements to account for the magnitude of c-myc mRNA down-regulation during differentiation. We conclude from these results that c-myc mRNA down-regulation during myogenic differentiation is due to translation-dependent mechanisms that target mRNAs containing myc exon 2 and 3 regulatory elements for accelerated decay.
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PMID:c-myc mRNA is down-regulated during myogenic differentiation by accelerated decay that depends on translation of regulatory coding elements. 962 73

One of the advantages of viral-directed enzyme prodrug therapy (VDEPT) is its potential for tumor-specific cytotoxicity. However, the viruses used to deliver cDNAs encoding prodrug-activating enzymes transduce normal cells as well as tumor cells, and several approaches to achieve tumor-specific expression of the delivered cDNAs are being investigated. One such approach is to regulate transcription of the prodrug-activating enzyme with a promoter that is preferentially activated by tumor cells. Published data suggest that the most promising transcription factor/promoter/enhancer combinations are those activated by a tumor-specific transcription factor to retain tumor cell specificity but that are equal in strength to nonspecific viral promoters in their ability to up-regulate target cDNAs. This report identifies MYC-responsive, modified ornithine decarboxylase (ODC) promoter/enhancer sequences that up-regulate target protein expression in tumor cells overexpressing either N-MYC or c-MYC protein. The most efficient of the four constructs assessed contained six additional CACGTG MYC binding sites 5' to the endogenous ODC promoter (R6ODC). Reporter assays with this chimeric promoter/enhancer regulating expression of chloramphenicol acetyltransferase demonstrated 50-250-fold more activity in MYC-expressing cells compared with similar assays with promoterless plasmids. The R6ODC regulatory sequence was approximately equivalent to the CMV promoter in inducing expression of the neomycin resistance gene in c-MYC-expressing SW480 and HT-29 colon carcinoma cells and in N-MYC-expressing NB-1691 neuroblastoma cells. The modified ODC promoter may, therefore, be useful in achieving tissue-specific expression of target proteins in tumor cells that overexpress c- or N-MYC.
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PMID:Use of a modified ornithine decarboxylase promoter to achieve efficient c-MYC- or N-MYC-regulated protein expression. 1130 86