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)

The translational regulation of ferritin expression currently represents the only well characterized example for eukaryotic translational control by high affinity interactions between a specific cytoplasmic protein, iron regulatory factor [IRF], and an mRNA-binding site, the iron-responsive element [IRE], located in the 5' untranslated region [UTR] of ferritin mRNAs. To elucidate whether IRE/IRF may represent the first physiological example of a more general mechanism for mRNA-specific translational control, high affinity RNA-binding sites for the bacteriophage MS2 coat protein or the spliceosomal protein U1A were introduced into the 5' UTR of capped chloramphenicol acetyltransferase [CAT] transcripts. In the absence of these RNA-binding proteins, CAT mRNA was efficiently translated. Addition of purified MS2 coat protein or U1A caused a specific, dose-dependent repression of CAT biosynthesis in rabbit reticulocyte and wheat germ in vitro translation systems. The translational blockage imposed by the RNA/protein complex was reversible and did not alter the stability of the repressed mRNAs. Translational repression caused by binding of U1A or MS2 proteins to their target mRNAs is shown to be position-dependent in vitro. Thus, mRNA/protein complexes without an a priori role in eukaryotic mRNA translation function as translational effectors with characteristics resembling those of IRE/IRF.
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PMID:Bacteriophage and spliceosomal proteins function as position-dependent cis/trans repressors of mRNA translation in vitro. 145 20

We have isolated non-globin cDNA clones specific for erythroid differentiation from K562 human erythroleukemia cells and have identified those that may regulate globin gene transcription. A cDNA library was constructed from K562 cells induced by hemin for production of embryonic and fetal hemoglobins and screened against cDNA from uninduced K562 cells. Full-length clones specific for induced K562 cells were ligated into a eukaryotic expression vector and transfected into HeLa cells to allow for production of the corresponding coded polypeptide. The ability to increase epsilon- or gamma-globin promoter activity was identified using cotransfection with a second vector containing a globin gene promoter fused to a reporter gene. Six of the induced K562-specific clones exhibited the ability to increase the levels of the reporter genes, bacterial chloramphenicol acetyltransferase and human growth hormone. Sequencing analyses of these clones indicated that five were homologous to ferritin heavy and light chains and one had no homology with known DNA or protein sequences. The ferritin light chain cDNA had the greatest effect on globin gene promoter activation, increasing the gamma-globin promoter activity by 6-8-fold. The activation of the globin gene promoter in the absence of globin gene translation suggests that ferritin (or iron) may have a direct role in globin gene transcription. The subtractive library cloning strategy has enabled us to isolate cDNA clones that activate specific gene promoter without the requirement of direct DNA binding. This approach may allow further identification of the genes encoding proteins that are involved in the control of erythropoiesis.
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PMID:Activation of globin gene expression by cDNAs from induced K562 cells. Evidence for involvement of ferritin in globin gene expression. 184 May 94

The iron-responsive regulation of ferritin mRNA translation is mediated by the specific interaction of the ferritin repressor protein (FRP) with the iron-responsive element (IRE), a highly conserved 28-nucleotide sequence located in the 5' untranslated region of ferritin mRNAs. The IRE alone is necessary and sufficient to confer repression of translation by FRP upon a heterologous message, chloramphenicol acetyltransferase, in an in vitro translation system. The activity of FRP is sensitive to iron in vivo. Cytoplasmic extracts of rabbit kidney cells show reduction of FRP activity when grown in the presence of iron, as detected by RNA band shift assay. Using a nitrocellulose filter binding assay to examine the interaction of FRP with the IRE in more detail, we find that purified FRP has a single high-affinity binding site for the IRE with a Kd of 20-50 pM. Hemin pretreatment decreases the total amount of FRP which can bind to the IRE. This effect is dependent on hemin concentration. Interestingly, the FRP which remains active at a given hemin concentration binds to the IRE with the same high affinity as untreated FRP. A variety of hemin concentrations were examined for their effect on preformed FRP/IRE complexes. All hemin concentrations tested resulted in rapid complex breakdown. The final amount of complex breakdown corresponds to the concentration of hemin present in the reaction. The effect of hemin on FRP activity suggests that a specific hemin binding site exists on FRP.
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PMID:Characteristics of the interaction of the ferritin repressor protein with the iron-responsive element. 185 87

Ferritin, a cytoplasmic protein critical in iron metabolism, displays iron-dependent regulation of its biosynthetic rate with no corresponding changes in mRNA levels. An iron-responsive element (IRE) has been identified in the 5'-untranslated region (UTR) of the human ferritin heavy chain mRNA which, when placed in the 5'-UTR of heterologous reporter genes, confers iron-dependent translational regulation to the hybrid mRNAs. However, whereas the biosynthetic rate of ferritin in response to changes in iron status exhibits a 30-80-fold range, the apparent ranges observed for reporter gene constructs utilizing chloramphenicol acetyltransferase assays or human growth hormone radioimmunoassays have been much less. A deletion and reconstitution study was undertaken to address the possibility that regions of the ferritin gene and mRNA other than the IRE may be necessary for the production of the full range of iron regulation. Data are presented that demonstrate that the IRE alone is capable of conferring iron-dependent translational regulation of biosynthesis to downstream encoded proteins that is both qualitatively and quantitatively similar to that observed with expression of ferritin itself. Thus, the complete range of iron-dependent translational regulation conferred by the IRE occurs independently of the presence of the ferritin promoter, other regions of the ferritin 5'-UTR, the ferritin coding region, and the ferritin 3'-UTR. Additionally, experiments addressing the translatability in vivo of various ferritin construct mRNAs support the theory that the IRE functions as the binding site for a translational repressor.
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PMID:The iron-responsive element is the single element responsible for iron-dependent translational regulation of ferritin biosynthesis. Evidence for function as the binding site for a translational repressor. 319 10

Ferritin plays a key role in determining the intracellular fate of iron and is highly regulated by the iron status of the cell. We have identified a cis-acting element in the transcribed but nontranslated 5' leader sequence of human ferritin heavy-chain mRNA. In transiently transfected murine fibroblasts, the presence of a 157-nucleotide region of the 5' leader sequence was found to be necessary for iron-dependent regulation of ferritin biosynthesis. Further, this 5' leader region is sufficient to transfer iron-mediated translational control to the expression of a heterologous gene product, chloramphenicol acetyltransferase.
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PMID:A cis-acting element is necessary and sufficient for translational regulation of human ferritin expression in response to iron. 347 5

In previous studies, we showed that acute administration of iron to intact rats or to rat hepatoma cells in culture induces synthesis of the iron-storage protein ferritin by activating translation of inactive cytoplasmic ferritin mRNAs for both the heavy (H) and the light (L) subunits. In the course of activation, these ferritin mRNAs are recruited onto polysomes. To elucidate the structural features of these mRNAs involved in the translational response to iron, a chimera was constructed from the 5' and 3' untranslated regions (UTRs) of ferritin L subunit mRNA fused to the reading frame of the mRNA of bacterial chloramphenicol acetyltransferase (CAT). This chimera and deletion constructs derived from it were introduced into a rat hepatoma cell line by retrovirus-mediated gene transfer. The complete chimera showed increased CAT activity in response to iron enrichment of the medium, whereas deletion of the first 67 nucleotides of the 5' UTR, which contain a highly conserved sequence, caused loss of regulation by iron. Whereas cis-acting sequences located in the 5' flanking regions of many genes have been repeatedly implicated in modulating their transcriptional expression, we report here a specific regulatory translational sequence found within the 5' UTR of a eukaryotic mRNA.
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PMID:Iron regulates ferritin mRNA translation through a segment of its 5' untranslated region. 347 2

In this paper, we examine the mechanisms that regulate the expression of the heavy (H) ferritin subunit in the colon carcinoma Caco-2 cell line allowed to differentiate spontaneously in vitro. The differentiation process of these cells in continuous culture is accompanied by an accumulation of the mRNA coding for the apoferritin H chain. The analysis of Caco-2 subclones stably transfected with an H-chain promoter-chloramphenicol acetyltransferase (CAT) construct revealed that the mRNA increase is paralleled by an enhanced transcription of the H gene, driven by the -100 to +4 region of the H promoter. The H gene transcriptional activation seems to be a specific feature of differentiated Caco-2 cells, since the activity of other promoters did not change upon differentiation. The -100 to +4 region of the H promoter binds a transcription factor called Bbf (B-box binding factor); electrophoretic-mobility-shift-assay analyses showed that the retarded complex due to Bbf-H promoter interaction is significantly increased in the differentiated cells. We propose that the activation of H-ferritin gene expression may be associated with the establishment of a differentiated phenotype in Caco-2 cells, and that the H-ferritin gene transcriptional up-regulation is accompanied by a modification in the activity of the transcription factor Bbf.
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PMID:Transcriptional activation of the H-ferritin gene in differentiated Caco-2 cells parallels a change in the activity of the nuclear factor Bbf. 748 31

The mechanisms that regulate the expression of ferritin, the iron storage protein, have been investigated in Friend erythroleukemia cells (FLCs) induced to differentiate by several chemical compounds. In differentiating FLCs, administration of hemin increases the steady-state level of ferritin mRNA about 15-fold and the ferritin content about 20- to 25-fold. Conversely, iron salts have only mild stimulatory effects on these parameters and iron chelators only slightly inhibited the stimulatory effect of hemin. Transient transfection experiments with a construct in which the human ferritin H-chain promoter drives the expression of the indicator chloramphenicol acetyltransferase (CAT) gene show that the increase in mRNA content is mainly due to enhanced transcription. In addition to transcriptional effects, translational regulation resulting in the further increase in ferritin synthesis is shown by CAT assays from cells transiently transfected with a construct containing the coding region for the indicator CAT mRNA under the translational control of the mRNA ferritin iron-responsive element. We conclude that, in FLCs induced to differentiate, hemin acts synergistically with the differentiation inducers, increasing ferritin expression. Both transcriptional and translational mechanisms are responsible for this synergistic effect, which appears to be characteristic of differentiated erythroid cells because it is not observed in other cell types (ie, fibroblastic cell lines).
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PMID:Regulation of ferritin H-chain expression in differentiating Friend leukemia cells. 763 66

Ferritin, the major intracellular iron storage protein of eucaryotic cells, is regulated during inflammation and malignancy. We previously reported that transcription of the H subunit of ferritin (ferritin H) is negatively regulated by the adenovirus E1A oncogene in mouse NIH 3T3 fibroblasts (Y. Tsuji, E. Kwak, T. Saika, S. V. Torti, and F. M. Torti, J. Biol. Chem. 268:7270-7275, 1993). To elucidate the mechanism of transcriptional repression of the ferritin H gene by E1A, a series of deletions in the 5' flanking region of the mouse ferritin H gene were constructed, fused to the chloramphenicol acetyltransferase (CAT) gene, and transiently cotransfected into NIH 3T3 cells with an E1A expression plasmid. The results indicate that the E1A-responsive region is located approximately 4.1 kb 5' to the transcription initiation site of the ferritin H gene. Further analyses revealed that a 37-bp region, termed FER-1, is the target of E1A-mediated repression. This region also serves as an enhancer, augmenting ferritin H transcription independently of position and orientation. FER-1 was dissected into two component elements, i.e., a 22-bp dyad symmetry element and a 7-bp AP1-like sequence. Insertion of these DNA sequences into a ferritin H-CAT chimeric gene lacking an E1A-responsive region indicated that (i) the 22-bp dyad symmetry sequence by itself has no enhancer activity, (ii) the AP1-like sequence has moderate enhancer activity which is repressed by E1A, and (iii) the combination of the dyad symmetry element and the AP1-like sequence is required for maximal enhancer activity and repression by E1A. Gel retardation assays and cotransfection experiments with c-fos and c-jun expression vectors suggested that members of the Fos and Jun families bind to the AP1-like element of FER-1 and contribute to its regulation. In addition, gel retardation assays showed that E1A reduces the ability of nuclear proteins to bind to the AP1-like sequence without affecting the levels of nuclear factors that recognize the 22-bp dyad symmetry element. Taken together, these results demonstrate that FER-1 serves as both an enhancer of ferritin H transcription and a target for E1A-mediated repression.
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PMID:FER-1, an enhancer of the ferritin H gene and a target of E1A-mediated transcriptional repression. 765 32

Ascorbate is an important cofactor in many cellular metabolic reactions and is intimately linked to iron homeostasis. Continuously cultured cells are ascorbate deficient due to the lability of the vitamin in solution and to the fact that daily supplementation of media with ascorbate is unusual. We found that ascorbate repletion alone did not alter ferritin synthesis. However, ascorbate-replete human hepatoma cells, Hep3B and HepG2, as well as K562 human leukemia cells achieved a substantially higher cellular ferritin content in response to a challenge with iron than did their ascorbate-deficient counterparts grown under standard culture conditions. Most of the elevation in ferritin content was due to an increase in de novo ferritin synthesis of greater than 50-fold, as shown by in vivo labeling with [35S]methionine and immunoprecipitation. RNA-blot analysis showed only minor changes in steady state levels of ferritin mRNA, suggesting that ascorbate enhances iron-induced ferritin synthesis primarily by post-transcriptional events. Transient gene expression experiments using chloramphenicol acetyltransferase reporter gene constructs showed that the ascorbate effect on ferritin translation is not mediated through the stem-loop near the translational start site that transduces ferritin synthesis in response to cytokines. The data suggest that ascorbate possibly modifies the action of the iron-responsive element on ferritin translation, although more precise structure-function studies are needed to clarify this issue. These data demonstrate a novel role of ascorbate as a signaling molecule in post-transcriptional gene regulation. The mechanism by which ascorbate modulates cellular iron metabolism is complex and requires additional detailed investigation.
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PMID:Ascorbic acid enhances iron-induced ferritin translation in human leukemia and hepatoma cells. 785 59

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