EC:2.3.1.28 - FACTA Search

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Query: EC:2.3.1.28 (chloramphenicol acetyltransferase)
5,100 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have previously demonstrated in transient expression assay systems that a human multidrug resistance 1 (MDR1) promoter can be directly activated by cytotoxic anticancer agents. In this study, we examined whether the MDR1 promoter could be regulated in response to growth arrest induced by serum starvation. We have established human and rodent cell lines which stably expressed the chloramphenicol acetyltransferase (CAT) gene driven by various lengths of the MDR1, the viral thymidine kinase (TK) and the simian virus 40 (SV40) promoters. Serum starvation caused enhanced expression of CAT gene with MDR1 promoter, but not with two viral gene promoters in human cancer KB cells. Hydroxyurea activated the MDR1 promoter, but not TK and SV40 promoters. By contrast, the DNA topoisomerase II inhibitor, etoposide, equally activated the MDR1, TK and SV 40 promoters. Increased CAT gene expression by serum starvation was also specifically observed in stable transfectants of human adrenal SW-13 cell lines, but not in stable transfectants of mouse fibroblast NIH3T3 and adrenal Y-1 cell lines when the human MDR1 promoter-CAT was introduced. Etoposide, however, effectively induced CAT activity in both human and rodent cells. Assays with deletion constructs of the MDR1 promoter showed that serum starvation activated the MDR1 promoter carrying -258 approximately +121 base sequence of the promoter, but not -198 approximately +121 of the promoter. These results suggest that the expression of the MDR1 gene induced by serum starvation is regulated at the transcriptional level in a promoter sequence-specific manner in human cells.
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PMID:The human multidrug resistance 1 promoter has an element that responds to serum starvation. 155 May 97

The ugp operon of Escherichia coli includes genes involved in the uptake of sn-glycerol-3-phosphate and glycerophosphoryl diesters and belongs to the pho regulon which is induced by phosphate limitation. This operon has two transcriptional initiation sites, as determined by S1 nuclease mapping of the in vivo transcripts. The downstream promoter has multiple copies of the pho box, the consensus sequence shared by the pho promoters; the upstream promoter has a consensus sequence for the promoters regulated by cyclic AMP and its receptor protein, CRP. PhoB protein, which is the transcriptional activator for the pho regulon, protected the regulatory region with the pho boxes in DNase I footprinting experiments and activated transcription from the downstream promoter in vitro. Studies with transcriptional fusions between ugp and a promoterless gene for chloramphenicol acetyltransferase show that the upstream promoter is induced by carbon starvation in a manner that required the cya and crp genes. PhoB protein may act as a repressor for this upstream promoter, which also overlaps the upstream third pho box. The downstream promoter was induced by phosphate starvation and requires the PhoB protein for its activation as do the other pho regulon promoters. These results suggest that the two promoters function alternately in responding to phosphate or carbon starvation, thus providing the cell with a means to adapt to these physiological stresses.
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PMID:Dual regulation of the ugp operon by phosphate and carbon starvation at two interspaced promoters. 198 50

Hybrid promoter constructs were used to determine the DNA sequence requirements for stringent and growth rate control within a promoter region. The promoters were obtained by fusing complementing sequence regions located upstream and downstream from the GCGC discriminator motif of the growth rate regulated rRNA P1 promoter and a non-regulated tac promoter variant. The activities and the regulatory response of the hybrid promoters were determined in vivo using a promoter test vector system with the chloramphenicol acetyltransferase (CAT) reporter gene. Measurements were made at different growth rates and after starvation for isoleucine to induce the stringent response. Neither the upstream nor the downstream sequence of P1 relative to the GCGC discriminator motif conferred comparable regulatory features when fused to the complementing sequences of the non-regulated mutant tac promoter. A minor response to amino acid deprivation or changes in the growth rate was noted for the hybrid promoter with the rrnB P1 upstream segment and the tac downstream element, pointing to a slightly different importance of the two sequence elements for regulation. The parallel effects for stringent as well as growth rate regulation of the hybrid promoters supports the view of a common mechanism for both types of control. However, none of the promoter sequence elements on its own was able to restore the complete regulatory behaviour of their 'parent' promoters.
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PMID:The signal for growth rate control and stringent sensitivity in E. coli is not restricted to a particular sequence motif within the promoter region. 224 74

The synthesis of stable RNA in bacteria is known to be regulated by a stringent control mechanism. Characteristic of stringent-regulated promoters, all ribosomal RNA promoters P1, but not P2, contain a GC-rich discriminator sequence assumed to be important for such a control. Using site-directed mutagenesis we have altered both the rrnB P2 and the synthetic tac promoter to the consensus GCGC discriminator motif. The modified promoters were placed upstream of the structural gene encoding the chloramphenicol acetyltransferase. The response of the modified promoters to amino acid starvation, changes in the growth rate or differences in the basal level of guanosine tetraphosphate (ppGpp) were determined in vivo. The results clearly show, that the discriminator motif is sufficient to convert the ribosomal RNA promoter P2 to a stringent, as well as growth-rate regulated, promoter. By contrast, the same discriminator sequence linked to the synthetic tac promoter does not convert this promoter to either stringency or growth-rate regulation. Finally, the results presented in this study reinforce the view that stringent and growth-rate regulation utilize the same mechanism, with ppGpp being the common mediator.
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PMID:Influence of the GCGC discriminator motif introduced into the ribosomal RNA P2- and tac promoter on growth-rate control and stringent sensitivity. 247 45

We have characterized a cDNA and the corresponding gene for a cyclic AMP-inducible gene expressed during Dictyostelium development. This gene, BP74, was found to be first expressed about the time of aggregate formation, approximately 6 h after starvation. Accumulation of BP74 mRNA did not occur in Dictyostelium cells that had been starved in fast-shaken suspension cultures but was induced in similar cultures to which cyclic AMP pulses had been added. The BP74 cDNA and gene were characterized by DNA sequence analysis and transcriptional mapping. When the BP74 promoter region was fused with a chloramphenicol acetyltransferase reporter gene and reintroduced into Dictyostelium cells, the transfected chloramphenicol acetyltransferase gene displayed the same developmentally regulated pattern of expression as did the endogenous BP74 gene, suggesting that all of the cis-acting elements required for regulated expression were carried by a 2-kilobase cloned genomic fragment. On the basis of sequence analysis, the gene appeared to encode a protein containing a 20-residue hydrophobic sequence at the amino-terminal end and 26 copies of a 20-amino-acid repeat.
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PMID:Expression and organization of BP74, a cyclic AMP-regulated gene expressed during Dictyostelium discoideum development. 255 85

The pstS gene belongs to the phosphate regulon whose expression is induced by phosphate starvation and regulated positively by the PhoB protein. The phosphate (pho) box is a consensus sequence shared by the regulatory regions of the genes in the pho regulon. We constructed two series of deletion mutations in a plasmid in vitro, with upstream and downstream deletions in the promoter region of pstS, which contains two pho boxes in tandem, and studied their promoter activity by connecting them with a promoterless gene for chloramphenicol acetyltransferase. Deletions extending into the upstream pho box but retaining the downstream pho box greatly reduced promoter activity, but the remaining activity was still regulated by phosphate levels in the medium and by the PhoB protein, indicating that each pho box is functional. No activity was observed in deletion mutants which lacked the remaining pho box or the -10 region. Therefore, the pstS promoter was defined to include the two pho boxes and the -10 region. The PhoB protein binding region in the pstS regulatory region was studied with the deletion plasmids by a gel-mobility retardation assay. The results suggest the protein binds to each pho box on the pstS promoter. A phoB deletion mutant was constructed, and we demonstrated that expression of pstS was strictly dependent on the function of the PhoB protein.
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PMID:Regulation of the phosphate regulon of Escherichia coli: characterization of the promoter of the pstS gene. 265 88

The phoB gene product of Escherichia coli is the transcriptional activator for the genes in the phosphate regulon as well as for phoB itself, all of which are induced by phosphate starvation. The phoR gene product modulates PhoB function in response to the phosphate concentrations in the medium. We quantitatively compared the levels of expression of the phoA, phoB, phoE, and pstS genes in several phoB mutants with different phenotypes by constructing operon fusions of these genes with the gene for chloramphenicol acetyltransferase. Although all the phoB mutants examined had little activator function for phoA, three among the four mutants showed various levels of the activator function for phoB, pstS, and phoE. To study the functional motifs of the PhoB and PhoR proteins, we cloned and sequenced the four classical phoB and six phoR mutant genes. All of the phoB mutations and one of the phoR mutations were missense mutations, and most of the altered amino acids were in the highly conserved amino acids among the regulatory proteins homologous to PhoB or PhoR protein, such as the OmpR, SfrA, and VirG proteins or the EnvZ, CpxA, and VirA proteins. The other five phoR mutations were nonsense mutations.
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PMID:Regulation of the phosphate regulon of Escherichia coli: analysis of mutant phoB and phoR genes causing different phenotypes. 267 81

Treatment of the rat pancreatic acinar cell line AR4-2J with the calcium ionophore A23187 selectively increases, within a few hours, the steady-state level of trypsin mRNA. Addition of the tumor-promoting phorbol ester phorbol 12-myristate 13-acetate potentiates the calcium-induced increase. The mRNA level of the other tested exocrine pancreatic genes decreases. These results were confirmed by DNA transfection experiments, using the 5' flanking region of the trypsin and chymotrypsin genes linked to the coding sequence of the chloramphenicol acetyltransferase (CAT) gene. In calcium-induced cells transfected with the trypsin constructs, an increase in CAT activity was observed, whereas the chymotrypsin constructs revealed a decreased CAT activity. Glucose starvation of AR4-2J cells similarly elicited a selective increase in trypsin mRNA. This selective regulation of trypsin may reflect its role as the key activator of the other zymogen species.
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PMID:Selective regulation of trypsin gene expression by calcium and by glucose starvation in a rat exocrine pancreas cell line. 308 79

The plasmid gene cat-86 is induced by chloramphenicol in Bacillus subtilis, resulting in the synthesis of the gene product chloramphenicol acetyltransferase. Induction is due to a posttranscriptional regulatory mechanism in which the inducer, chloramphenicol, activates translation of cat-86 mRNA. We have suggested that chloramphenicol allows ribosomes to destabilize a stem-loop structure in cat-86 mRNA that sequesters the ribosome-binding site for the coding sequence. In the present report we show that cat-86 expression can be activated by stalling ribosomes in the act of translating a regulatory leader peptide. Stalling was brought about by starving host cells for specific leader amino acids. Ribosomal stalling, which led to cat-86 expression, occurred upon starvation for the amino acid specified by the leader codon located immediately 5' to the RNA stem-loop structure and was independent of whether that codon specified lysine or tyrosine. These observations support a model for chloramphenicol induction of cat-86 in which the antibiotic stalls ribosome transit in the regulatory leader. Stalling of ribosomes in the leader can therefore lead to destabilization of the RNA stem-loop structure.
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PMID:Drug-free induction of a chloramphenicol acetyltransferase gene in Bacillus subtilis by stalling ribosomes in a regulatory leader. 311 38

The plasmid gene cat-86 specifies chloramphenicol-inducible chloramphenicol acetyltransferase in Bacillus subtilis. Induction by the antibiotic is primarily due to activation of the translation of cat-86-encoded mRNA. It has been suggested that the inducer stalls ribosomes at a discrete location in the leader region of cat-86 mRNA, which causes the destabilization of a downstream RNA secondary structure that normally sequesters the cat-86 ribosome binding site. It is the destabilization of this RNA secondary structure that permits translation of the cat-86 coding sequence. In the present report, we show that ribosomes that were stalled in the cat-86 leader by starvation of host cells for the amino acid specified by leader codon 6 induced gene expression to a level above that detected when cells were starved for the amino acids specified by leader codons 7 and 8. Starvation for amino acids specified by leader codons 3, 4, or 5 failed to activate cat-86 expression. These results indicate that the stalled ribosome that is most active in cat-86 induction has its aminoacyl site occupied by leader codon 6. To determine if chloramphenicol also stalled ribosomes in the cat-86 regulatory leader such that the aminoacyl site was occupied by codon 6, we separately changed leader codons 3, 4, 5, and 6 to the translation termination (ochre) codon TAA. Each of the mutated genes was tested for its ability to be induced by chloramphenicol. The results show that replacement of leader codons 3, 4, or 5 by the ochre codon blocked induction, whereas replacement of leader codon 6 by the ochre codon permitted induction. Collectively, these observations lead to the conclusion that cat-86 induction requires ribosome stalling in leader mRNA, and they identify leader codon 6 as the codon most likely to be occupied by the aminoacyl site of a stalled ribosome that is active in the induction.
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PMID:Chloramphenicol induction of cat-86 requires ribosome stalling at a specific site in the leader. 312 23

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