Gene/Protein Disease Symptom Drug Enzyme Compound
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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)

Localized mutagenesis and selection for streptomycin resistance were utilized to isolate a chloramphenicol resistance mutation in Escherichia coli K-12 linked to the strA (rpsL) locus. Bacteriophage P1 transduction verified the map position of the new resistance mutation at 72 min, placing it within a dense cluster of ribosomal protein genes. The map position differs from that of known cmlA and cmlB mutations, which map at 18 and 21 min, respectively. Ribosomes prepared from chloramphenicol-resistant and -sensitive isogenic transductants were analyzed in vitro for activity in formation of N-formylmethionyl-puromycin, polyphenylalanine, and polylysine in the presence of inhibitory concentrations of chloramphenicol. Comparisons were also made of 14C-chloramphenicol binding to 70S ribosomes and of the two-dimensional polyacrylamide gel electrophoresis pattern of ribosomal proteins from each strain. There was no detectable difference between ribosomes from sensitive and resistant strains as measured by these assays. Enzymatic modification by chloramphenicol acetyltransferase is not responsible for the observed phenotype.
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PMID:Chloramphenicol resistance mutation in Escherichia coli which maps in the major ribosomal protein gene cluster. 37 48

The sequences required for the maximal expression of the mouse L32 ribosomal protein gene and the binding of nuclear factors to L32 promoter elements were analyzed in mouse myoblasts, fibers, and L cells. Various L32 r-protein promoter sequences were linked to the chloramphenicol acetyltransferase gene (CAT), and the expression of the chimeric genes was measured transiently or after their incorporation into the genome. The sequence requirements for maximal expression of the L32 gene are very similar among the various cells and include the previously identified L32 core promoter from approximately -150 to +75. Only the promoter regions between -45 and +11 displays significant cell type specific differences. Relative to the maximal activity in each cell type, the expression of the L32-CAT gene containing the -45 to +11 region is greater in L cells than in myoblasts or fibers. This difference is correlated with the increased activity of an L cell nuclear factor(s) that binds to this fragment. In addition, our results show that deletion of sequences between -981 and -141 causes a 50-70% reduction of the expression of the L32-CAT gene in myoblasts, fibers and L cells. The transcription of all the L32-CAT genes examined decrease after myoblasts differentiate into fibers in a manner similar to the endogenous L32 gene, but we were unable to distinguish between sequences involved in controlling the expression of the L32 gene during myoblast differentiation and those sequences required for maximal promoter activity. However, gel mobility shift assays showed differences in the binding of myoblast and fiber factors to the four promoter fragments examined. The possible role of these factor binding differences in controlling L32 transcription is discussed.
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PMID:Comparison of the mouse L32 ribosomal protein promoter elements in mouse myoblasts, fibers, and L cells. 142 83

During Xenopus development, the synthesis of ribosomal proteins is regulated at the translational level. To identify the region of the ribosomal protein mRNAs responsible for their typical translational behavior, we constructed a fused gene in which the upstream sequences (promoter) and the 5' untranslated sequence (first exon) of the gene coding for Xenopus ribosomal protein S19 were joined to the coding portion of the procaryotic chloramphenicol acetyltransferase (CAT) gene deleted of its own 5' untranslated region. This fused gene was introduced in vivo by microinjection into Xenopus fertilized eggs, and its activity was monitored during embryogenesis. By analyzing the pattern of appearance of CAT activity and the distribution of the S19-CAT mRNA between polysomes and messenger ribonucleoproteins, it was concluded that the 35-nucleotide-long 5' untranslated region of the S19 mRNA is able to confer to the fused S19-CAT mRNA the translational behavior typical of ribosomal proteins during Xenopus embryo development.
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PMID:The 5' untranslated region of mRNA for ribosomal protein S19 is involved in its translational regulation during Xenopus development. 230 60

The DNA sequences required for expression of the ribosomal protein gene rpL32 were identified by transient-expression assays of chimeric rpL32-chloramphenicol acetyltransferase genes. These studies showed that maximal rpL32 expression requires sequences in a 150- to 200-base-pair region spanning the transcriptional start site. Three discrete regions of importance were identified: one between positions -79 and -69 and two others located downstream of the transcriptional start site. Progressive 5' or 3' deletions caused stepwise decreases in expression, which suggested a complex interplay of redundant or compensatory elements. Gel mobility shift assays were used to identify trans-acting nuclear factors which bind to segments of the rpL32 promoter that are known to be important for transcription. Evidence for several distinct nuclear factors is presented. The binding sites for these factors were localized to the following regions: -79 to -69, -36 to -19, -19 to +11, +11 to +46 in exon I, and within the first 31 base pairs of intron 1. One of these factors may bind to multiple sites within the promoter region. Interestingly, the factor that binds to a sequence motif in the first exon also binds to similar motifs in a comparable region of the c-myc gene.
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PMID:Localization of transcriptional regulatory elements and nuclear factor binding sites in mouse ribosomal protein gene rpL32. 254 59

Transcription of rat liver ribosomal RNA is induced by glucocorticoids. In order to determine whether the expression of ribosomal protein genes is coordinately regulated, we measured the effect of dexamethasone on their transcription. Administration of this hormone to adrenalectomized rats led, within 1 h, to a 2.2-fold enhancement of transcription of liver ribosomal protein genes. To define the dexamethasone-responsive element, we isolated and tested mouse L32 gene sequences for the ability to confer glucocorticoid induction to the bacterial chloramphenicol acetyltransferase (CAT) gene in L cells. An 80 base pair region of the L32 gene, between nucleotide position -69 and +11, with respect to the start site of transcription, was sufficient for induction of the CAT gene by dexamethasone. Despite these stimulating effects, we have failed to detect elevation in the abundance of the ribosomal protein mRNAs both in rat liver and in mouse L cells. Possible interpretations for this seemingly ineffectual process are discussed.
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PMID:Glucocorticoids induce transcription of ribosomal protein genes in rat liver. 279 63

The nucleotide sequence of the operon encoding maize chloroplast ribosomal protein genes S7 and S12 and the promoter activity of a chimeric construct of the -10/-35 sequence of this operon (attached to a promoterless chloramphenicol acetyltransferase gene) have been determined. This operon occurs in the chloroplast genome divided in two parts: part A contains exon 1 of rpS12 (encoding the N-terminal 38 amino acid residues), whereas part B has the following structure: promoter-rpS12 (exon 2 + intron + exon 3)-spacer-rpS7-terminator. Part A is located at the approximate coordinate position 41000, whereas two copies of part B are located at two distant locations in the genome at coordinate positions 18700 and 120200. This unusual organization of the S12 operon in maize (a monocot plant) is similar to that reported in a dicot and a lower plant. The deduced amino acid sequence of maize chloroplast S7 shows 43, 38, 71, and 85% and of S12 shows 66, 72, 91 and 90% sequence identity to the corresponding sequences of Escherichia coli, Euglena gracilis, Marchantia polymorpha, and Nicotiana tabacum, respectively. The promoter upstream of rpS12 (part B) is transcriptionally active in E. coli.
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PMID:Nucleotide sequence, promoter analysis, and linkage mapping of the unusually organized operon encoding ribosomal proteins S7 and S12 in maize chloroplast. 282 17

We succeeded in identifying a promoter element within 200 base pairs upstream a transcriptional unit comprising only a 23S rRNA, 5S rRNA and a tRNA(gly) gene in Thermus thermophilus HB8 [1, 2]. This element shows a high degree of homology to the -35 and -10 consensus sequences for promoters described for Escherichia coli [3, 4]. The promoter activity was measured by the induction of the synthesis of functional chloramphenicol acetyltransferase in Escherichia coli. A region located at the transcriptional start, rich in guanosines and cytidines, is very similar in sequence to the one believed to be under stringent control in stable RNA and ribosomal protein genes of Escherichia coli [5]. Employing nuclease S1 protection we were able to determine the in vivo start of transcription, which was identical with the in vitro start using Escherichia coli RNA-polymerase. Furthermore we identified sequences in the region following the origin of transcription, which are homologous to sections in Escherichia coli rrn promoter-leader regions responsible for antitermination. Our finding of a promoter immediately preceding a 23S/5S rRNA operon proves a transcriptional decoupling of the 16S rRNA genes, a situation so far unprecedented among prokaryotes.
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PMID:An unusual rRNA operon constellation: in Thermus thermophilus HB8 the 23S/5S rRNA operon is a separate entity from the 16S rRNA operon. 312 27

A spontaneously occurring, noninducible, chloramphenicol-resistant mutant of Bacillus subtilis 168 has a mutation (cam-2) which maps in the ribosomal protein region of the chromosome near dal. Its presence does not confer dependence on chloramphenicol. Ribosomes of the cam-2 strain remained sensitive to chloramphenicol in in vitro protein synthesis. No chloramphenicol acetyltransferase activity could be detected.
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PMID:New chloramphenicol resistance locus in Bacillus subtilis. 642 68

A family of 16 genes encoding the mouse ribosomal protein S24 was identified, and four members from this family were cloned. A single expressed intron-containing S24 gene (termed mrpS24) and one pseudogene (mrpS24p) were completely sequenced and characterized. The mrpS24 gene has seven exons and six introns spanning over 5.1 x 10(3) nucleotides (nt). The cap site of S24 was mapped to a G residue four nt upstream of a polypyrimidine tract and 15 nt downstream of a TATA-like (TATGA) element. The 5' region (-325 to +33) of the mrpS24 gene has a functional promoter that was able to express the fused chloramphenicol acetyltransferase (CAT) reporter gene. Two different forms of mouse S24 cDNA clones were previously isolated. Sequence analysis showed that one of these cDNA clones (termed S24a) lacks the entire exon V sequence (18 nt), and the deduced amino acid sequence is missing a C-terminal lysine residue encoded by the other cDNA (S24b). The pseudogene mrpS24p is flanked by an 11-bp direct repeat, and its sequence is almost identical to the S24 cDNA sequence, but it lacks two mini-exons, V and VI (20 nt), as in the cases of the human and rat S24 cDNAs. RT-PCR experiments demonstrated the existence of a third form (S24c) that similarly lacks both of the mini-exons, and suggested that different species of S24 mRNA might arise from alternative splicing of the mini-exons V and VI. Northern blot analysis showed that S24 expression is down- and up-regulated during adipocyte differentiation and in cellular transformation, respectively. RNase protection assays and RT-PCR experiments suggested that these cell-specific changes of S24 mRNA levels are mainly due to fluctuations in S24c mRNA level. Our results provide the first indication that a ribosomal protein gene is regulated by alternative usage of two mini-exons in a cell-specific manner.
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PMID:Molecular characterization of the mouse ribosomal protein S24 multigene family: a uniquely expressed intron-containing gene with cell-specific expression of three alternatively spliced mRNAs. 812 13

The rpL34 gene, which encodes a cytoplasmic ribosomal protein with a high homology to the rat 60S r-protein L34, was isolated from a genomic library of tobacco (Nicotiana tabacum L. cv. Xanthi-nc). A 1500 bp upstream promoter fragment was fused to the chloramphenicol acetyltransferase (CAT) reporter gene or beta-glucuronidase (GUS) reporter gene and transferred into tobacco plants by the Agrobhacterium-mediated leaf disk transformation method. Analysis of CAT activity in leaf tissues showed that mechanical wounding increased the rpL34 promoter activity about 5 times as compared to untreated controls and that the promoter activity was further enhanced by plant growth regulators, 2,4-dichlorophenoxyacetic acid and benzyladenine. Histochemical GUS staining patterns of the transgenic plants showed that the rpL34 promoter activity is high in actively growing tissues, including various meristems, floral organs, and developing fruits. A series of 5' deletion analyses of the rpL34 promoter indicated that a 50 bp region located between -179 and -129 is essential for wound, auxin and cytokinin responses. Deletion of this region reduced the promoter activity to an undetectable level. Insertion of the 50 nucleotide sequence into a minimal promoter restored the promoter activity and the promoter strength was proportional to the copy number of the upstream sequence. The role of TATA and CAAT box regions was studied by a series of 3' deletion analyses. A 3' deletion up to -28 did not significantly affect the promoter strength. However deletion of the promoter up to 70 bp, which deleted the TATA box region, significantly reduced promoter activity. Further deletion of the promoter up to - 104. eliminating the CAAT box region, abolished the promoter activity. These results suggest that the TATA box and CAAT box regions are also important for the rpL34 promoter activity in addition to the 50 bp upstream region.
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PMID:Promoter elements controlling developmental and environmental regulation of a tobacco ribosomal protein gene L34. 900 4


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