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)

Genomic clones containing 1.7 kilobases of the 5'-flanking region of the rat TSH receptor (TSHR) plus coding sequence from the ATG initiation codon [1 basepair (bp)] to the start of the first intron (170 bp) have been isolated and characterized. RNAase protection, primer extension, and cDNA sequences cloned by the anchored polymerase chain reaction identified multiple transcriptional start sites, the major ones clustered between -89 to -68 bp. This portion of the 5'-flanking region has neither a TATA nor a CCAAT box, is GC rich but has no GC box motif, and has features of promoters seen in "housekeeping" genes. Chimeras containing 1.7 kilobases (-1707 to -2 bp) of the 5'-flanking region, or deletions thereof, and the bacterial chloramphenicol acetyltransferase (CAT) gene expressed significant CAT activity when transfected into rat thyroid cell lines, FRTL-5 and FRT, but not BRL rat liver or HeLa cells. TSH decreased CAT activity in the FRTL-5 thyroid cells that had been stably transfected with the TSHR-CAT chimeric constructs. Negative regulation of promoter activity by TSH was duplicated by 10 microM forskolin in FRT thyroid cells, which express no TSHR mRNA. Deletion analyses indicated that a "minimal" region, exhibiting promoter activity, tissue specificity, and negative regulation by TSH, is located between -195 and -39 bp; this region is highly conserved in rat and human TSHR genes. Differential digestion of genomic DNA by MspI and HpaII revealed that the TSHR promoter is methylated in FRT, but not FRTL-5, cells; methylation of the promoter may be associated with loss of endogenous TSHR gene expression in FRT cells.
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PMID:Characterization of the 5'-flanking region of the rat thyrotropin receptor gene. 131 4

The "minimal" promoter region of the TSH receptor gene, -195 to -39 basepairs (bp), exhibits basal promoter activity, thyroid specificity, and negative regulation by TSH via its cAMP signal. In FRT thyroid cells and by comparison to pTRCAT5'-199, 5'-deletion mutants of chloramphenicol acetyltransferase (CAT) constructs from -199 to -150 bp of the minimal promoter decrease basal CAT activity by 50%, whereas continued deletion to -146 bp increases activity more than 4-fold. Continued deletion to -131 bp results in basal activity less than that of the -199 bp construct. An octameric cAMP response element (CRE)-like sequence, TGAGGTCA, is within -146 to -131 bp and starts at -139 bp. Its mutation to a consensus CRE (TGACGTCA) or AP1 (TGAGTCA) site or mutation of several residues flanking its 3'-terminus can improve promoter activity as much as 8-fold compared to pTRCAT5'-199. A nonpalindromic mutation to CGAGGACA decreases basal promoter activity to the level of the 199-bp minimal promoter. The CRE-like sequence between -139 and -132 bp is a constitutive enhancer of promoter activity in FRT thyroid cells, since, ligated to a simian virus-40-promoter-driven CAT gene, it increases CAT activity in the absence of forskolin in proportion to copy number and independent of direction or position. It can, however, function as a cAMP-responsive CRE, as evidenced by the fact that forskolin increases the activity of the same simian virus-40-promoter-driven CAT gene constructs in Buffalo rat liver (BRL) cells. DNAase-I footprinting shows that the CRE region is protected by a purified binding region peptide of the CRE-binding protein, activating transcription factor-2, and recombinant AP1 (human c-jun) as well as by BRL, FRT, and FRTL-5 rat thyroid cell nuclear extracts. Gel mobility shift analyses show that multiple CRE-binding proteins in the BRL, FRT, and FRTL-5 cell nuclear extracts form complexes with the CRE-like site, that one of these is CRE-binding protein, and that all form complexes with mutant sequences of the CRE-like site in a manner that exactly parallels their effects on constitutive enhancer function in FRT thyroid cells. We show, therefore, that the CRE-like site in the minimal TSH receptor promoter functions as a constitutive enhancer of promoter activity in FRT thyroid cells yet is a cAMP-responsive CRE.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Role of the cyclic adenosine 3',5'-monophosphate response element in efficient expression of the rat thyrotropin receptor promoter. 133 54

The thyroid follicular cell requires elevated levels of cAMP for normal growth and optimal expression of the differentiated phenotype. The recent discovery of cAMP-regulated enhancer binding (CREB) proteins prompted us to analyze the possible role of these transcription factors in controlling thyroid cell growth and differentiated phenotype using the FRTL5 thyroid cell line as a model system. FRTL5 cells were stably transfected with an expression vector containing either the gene for wild type CREB (WTCREB) or a dominant negative mutant form of CREB, termed KCREB, which dimerizes with and inactivates endogenous CREB. Transfected clones were found to express the transfected KCREB and WTCREB mRNAs at higher levels than the endogenous CREB mRNA. Transient expression of a somatostatin-chloramphenicol acetyltransferase fusion gene in these clones demonstrated a 60% reduction of cAMP-regulated enhancer-dependent transcriptional activity in the KCREB transfected clones and wild type levels of activity in the WTCREB transfected clones. Parameters of growth (DNA synthesis and growth rate) and differentiation (iodide uptake and thyroglobulin mRNA levels) were then analyzed in the transfected clones. Transfection of WTCREB had no effect on any of the parameters examined in comparison to untransfected cells, presumably because CREB is already constitutively expressed at maximal levels in normal FRTL5 cells. However, cells expressing KCREB showed an 18-40% reduction in TSH-stimulated thymidine incorporation, a 31% increase in the length of the cell cycle, and a 4-fold reduction in TSH-stimulated iodide uptake in comparison with wild type cells or cells tranfected with wild type CREB.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:3',5'-cyclic adenosine monophosphate-regulated enhancer binding (CREB) activity is required for normal growth and differentiated phenotype in the FRTL5 thyroid follicular cell line. 133 55

Transcription of the thyroglobulin (TG) gene is stimulated by TSH via cAMP. We have characterized the sequence elements responsible for the hormone-dependent expression of TG gene in rat thyroid FRTL-5 cells using internal deletion and linker-scanning mutants of the minimal TG promoter (-170 basepairs) fused with the bacterial chloramphenicol acetyltransferase reporter gene. The TG gene is regulated by at least two regions located between -165 and -140 bp (TG-III) and between -95 and -65 bp (TG-I) from the transcription initiation site. The intervening region can be deleted without significant effect on the promoter activity. Either of the two regions alone does not promote hormone-dependent transcription. A DNase footprinting assay showed that TG-I and TG-III are the principal protein-binding sites and that the proteins interacting with these two regions are induced by TSH or cAMP. These results suggest that the hormone-dependent expression of TG gene may be achieved by cooperative interaction of the proteins bound to TG-I and TG-III.
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PMID:The deoxyribonucleic acid regions involved in the hormonal regulation of thyroglobulin gene expression. 184 93

Transcription of the thyroglobulin (TG) gene in rat thyroid FRTL-5 cells is stimulated by two hormones, TSH and insulin-like growth factor-I (IGF-I). The effect of TSH is mimicked by cAMP. Promoter regions of the rat TG gene responsible for hormonal action as well as the nuclear regulatory proteins that interact with these regions were characterized. Minimal promoter that responds to both hormones has been found to be up to -171 basepairs from the transcription initiation site. In DNase-I footprinting analysis, nuclear extracts from cells treated with either of these hormones protected the same two major regions within the minimal promoter. Mutations in these two regions abolished basal, TSH-stimulated, as well as IGF-I-stimulated expression of the fused reporter gene chloramphenicol acetyltransferase. DNA mobility shift assay revealed that cAMP and IGF-I induce binding of similar nuclear proteins to these promoter regions. These results suggest that rat TG gene transcription is regulated by the convergent action of two distinct signaling pathways, possibly involving similar DNA-binding nuclear proteins and regulatory sequences of the TG gene promoter.
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PMID:Similar nuclear factors mediate stimulation of rat thyroglobulin gene transcription by thyrotropin and insulin-like growth factor-I. 196 92

Our previous studies demonstrated TRH stimulation of TSH beta gene transcription in rat pituitary cell cultures and in transient expression assays, with the TRH-sensitive region located between -1.3 kilobases and -204 basepairs (bp) relative to the major transcriptional start site. Using nuclear runoff and transient expression assays, we have analyzed the interactions among TRH, the phorbol ester 12-myristate 13-acetate (PMA), and the adenylate cyclase activator forskolin on TSH beta gene transcription. In cultured pituitary cells, TSH beta gene transcription was stimulated by 2 h of 10(-9) M TRH (2- to 4-fold), 100 nM PMA (2- to 6-fold), or 2 microM forskolin (1.5- to 2.5-fold) treatment, with additive interactions among all three effectors. Chimeric plasmids containing various 5'-flanking portions of the TSH beta gene and both transcriptional start sites, fused to the chloramphenicol acetyltransferase (CAT) gene, were transfected into the clonal pituitary GH3 cell line to delineate DNA sequences conferring this regulation. Transfected TSH beta CAT constructs containing TSH beta gene sequences from -2100/+27I150, -1295/+27I150, and -520/+27I150 expressed CAT enzyme activity which was stimulated by 24 h of TRH (2- to 3-fold), PMA (3- to 6-fold), or forskolin (1.5- to 3-fold) treatment, similar to observations in normal pituitary cells. In addition, a CAT expression vector construct containing only upstream TSH beta gene sequences from -703 to -85 bp, fused to the heterologous thymidine kinase promoter (tkCAT), exhibited similarly stimulated transcription in a transfection assay in response to TRH, PMA, and forskolin.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Interactions of thyrotropin-releasing hormone, phorbol ester, and forskolin-sensitive regions of the rat thyrotropin-beta gene. 217 92

In order to investigate the molecular mechanism(s) by which TRH regulates the biosynthesis of TSH, we are studying the effects of TRH on the expression of the TSH subunit genes (alpha and TSH beta). To study the structure-function relation of TRH stimulation of the activity of the single rat TSH beta gene, chimaeric plasmids were constructed. The 5'-flanking region of the rat TSH beta gene including exon 1 (5'-untranslated region) was inserted into a promoterless, modified pBR, chloramphenicol acetyltransferase (CAT) expression vector. After transfection, specific TSH beta promoter activity was evident in both TRH-responsive pituitary-derived GH3 and primary pituitary cell cultures. To determine potential regulation of TSH beta promoter-directed activity in these cells by TRH, cells were incubated with media containing TRH (10(-7) to 10(-11) M) for 1 to 48 h. TRH stimulated a 1.5- to 3-fold increase in TSH beta promoter activity. Concomitant with an increase in CAT activity was an anticipated increase in PRL synthesis in the GH3 cells in response to TRH. The TRH effect on the TSH beta gene was specific; no increase in CAT activity was detected for TKCAT (thymidine kinase of herpes simplex virus promoter), pBRCAT (no promoter), or TSH beta CAT (3'-5'-orientation). Similar results were obtained using primary pituitary cell cultures. Deletion mutation analysis indicated that TRH sensitivity was detected in a 1.1 kilobase, but not in a 0.38 kilobase TSH beta gene fragment suggesting that the TRH responsive element(s) resides at least in part within the 700 base pairs of the 5'-flanking sequence.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Thyrotropin-releasing hormone stimulates the activity of the rat thyrotropin beta-subunit gene promoter transfected into pituitary cells. 249 52

Thyroid hormones suppress the synthesis of TSH in part by decreasing the rate of alpha and TSH beta gene transcription. Cis-acting DNA sequences present in the rat TSH beta subunit gene that are induced in transcriptional regulation by thyroid hormone have been identified by deletion-mutation and transient expression studies. Plasmid expression vectors were constructed including 2900, 900, 204, 77, 17 base pairs (bp) of 5'-flanking sequence and exon (5'-untranslated sequence, transcriptional start sites) fused to the coding region of the bacterial chloramphenicol acetyltransferase (CAT) gene. The transfected chimaeric plasmids demonstrated expression (with TSH beta DNA sequences in the 5'- to -3'-but not 3'- to -5'-orientation) in both a clonal pituitary cell line, GH3, and primary pituitary cell cultures, both of which are responsive to thyroid hormones. T3 (10(-11) M to 10(-7) M) treatment of transfected cells produced a dose-dependent decrease in CAT expression with a maximal 70% decrease at 10(-8) M. While a decrease in the basal level of expression was noted with progressive removal of both 5'-flanking and intronic sequences adjacent to exon 1, the fold-decrease in response to T3 was equivalent even in the 57 bp construct. In contrast, T3 had no effect on CAT expression directed by the promoter of the herpes simplex virus thymidine kinase gene. Thus, the rat TSH beta gene 5'-flanking region can direct heterologous gene expression in GH3 cells and contains sequences which have properties of a putative cis-active T3 responsive regulatory element(s).2+he
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PMID:Thyroid hormones regulate rat thyrotropin beta gene promoter activity expressed in GH3 cells. 254 80

We are interested in the mechanisms by which endocrine and developmental factors regulate TSH synthesis at both pre-translational and post-translational levels. Thyroid hormone profoundly decreases transcription of the TSH-beta gene, while TRH and agents modifying cyclic AMP increase transcription. To elucidate the molecular mechanisms underlying these effects, human embryonal kidney cells were transfected with constructs of the human TSH-beta gene fused to the chloramphenicol acetyltransferase gene. The first exon of human TSH-beta, contains an element that increases basal expression and mediates T3-induced gene repression, probably through a direct interaction with c-erbA beta. This transcriptional repression by T3 appears aberrant in thyrotropic tumors. In contrast, TRH and agents modifying cyclic AMP mediate increased transcription of TSH-beta through interacting with upstream regulatory elements. Thyroid hormone, TRH and developmental factors also regulate the branching pattern and relative sialylation of TSH carbohydrate chains, which may affect TSH action in vitro and in vivo. Certain thyrotropic tumors produce TSH with more complex carbohydrate branching patterns, which may increase its biologic activity.
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PMID:Pre-translational and post-translational regulation of TSH synthesis in normal and neoplastic thyrotrophs. 269 12

Thyroid hormone regulation of the human thyrotropin beta-subunit gene (TSH beta) was examined in a human embryonal cell line (293). Transient expression studies were performed with chimeric plasmids containing the reporter gene, chloramphenicol acetyltransferase. Sequences in the first exon between +9 and +37 base pairs (bp) enhanced gene expression from the human TSH beta promoter in the absence of thyroid hormone as well as mediated a concentration-dependent triiodothyronine (L-T3) decrease in gene expression. Thyroid hormone inhibition of expression was also conferred to the herpes simplex virus thymidine kinase promoter by inserting +3 to +37 bp of the human TSH beta gene downstream from the start of transcription. Primer extension analysis of RNA from transfected cell cultures revealed accurate transcription initiation in only those constructs which contained sequences between +9 and +37 bp. Moreover, RNA analysis confirmed that L-T3 inhibition of chloramphenicol acetyltransferase activity from chimeric pTSH beta CAT constructs occurred at a pretranslational level. In addition, a nuclear thyroid hormone receptor, c-erbA-beta, bound to this region in an avidin-biotin DNA binding assay. These data suggest that L-T3, bound to its receptor, may inhibit human TSH beta expression by interfering with an element that functions to enhance gene expression.
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PMID:Thyroid hormone inhibition of human thyrotropin beta-subunit gene expression is mediated by a cis-acting element located in the first exon. 276 33


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