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)

In recent studies we have identified PC2 and PC3, members of a family of serine proteases that are related structurally to subtilisin, and have provided evidence that these are involved in the tissue-specific processing of prohormones and neuropeptides. PC2 is expressed at high levels in the islets of Langerhans, where it participates in the processing of proinsulin to insulin (S.P.S. and D.F.S., unpublished data). To evaluate the regulated expression of the human PC2 (hPC2) gene we have analyzed its structure and characterized its promoter. A map of the gene was constructed by using 11 clones isolated from two human genomic DNA libraries. The gene spans greater than 130 kilobase pairs and consists of 12 exons. Comparison with the structure of the gene encoding human furin, another member of this superfamily, revealed a high degree of conservation of exon-intron junctions. The hPC2 gene was localized to chromosome 20, band p11.2. The 5' flanking region of the hPC2 gene is very G+C-rich and contains six potential Sp1 binding sites but no TATA or CAAT box. Expression of chloramphenicol acetyltransferase reporter fusions containing the putative promoter region was observed to occur in beta TC-3 mouse insulinoma cells but not in HepG2 human hepatoma cells, consistent with the known tissue-specific pattern of expression of the hPC2 gene. Analysis of the level of chloramphenicol acetyltransferase activity with several deletion mutants identified the region from -1100 to -539 from the translation start site as essential for hPC2 promoter activity.
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PMID:Identification and analysis of the gene encoding human PC2, a prohormone convertase expressed in neuroendocrine tissues. 159 2

Insulin-producing cells and fibroblasts were fused to produce hybrid lines. In hybrids derived from both hamster and rat insulinoma cells, no insulin mRNA could be detected in any of seven lines examined by Northern (RNA) analysis despite the presence in each line of the insulin genes of both parental cells. Hybrid cells were transfected with recombinant chloramphenicol acetyltransferase plasmids containing defined segments of the rat insulin I gene 5' flank. We observed no transcriptional activity of the intact insulin enhancer or of IEB2, a critical cis-acting element of the insulin enhancer. IEB2 has previously been shown to interact in vitro with IEF1, a DNA-binding activity observed selectively in insulin-producing cells. Hybrid cells showed no detectable IEF1 activity. Furthermore, the insulin enhancer was unable to reduce transcription directed by the Moloney sarcoma virus enhancer in a double-enhancer construct. Thus, extinction of insulin gene expression in the hybrids apparently does not operate through a direct action of repressors on the insulin enhancer; rather, extinction is accompanied by, and may be caused by, reduced DNA-binding activity of the putative transcriptional activator IEF1.
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PMID:Extinction of insulin gene expression in hybrids between beta cells and fibroblasts is accompanied by loss of the putative beta-cell-specific transcription factor IEF1. 199 8

Analogues of cAMP have been reported to increase insulin mRNA levels in normal rat beta-cells and hamster insulinoma cells (HIT). To define the mechanisms by which cAMP modulates insulin gene expression, we first investigated its effects on the transcriptional rate of the insulin gene in HIT cells. Nuclear run-on assays revealed a 4-fold increase in transcription observed as early as 1 h after stimulation. To characterize the cis-acting sequences of the rat insulin I gene promoter and the trans-acting factors mediating the cAMP effect on insulin gene transcription, we constructed DNA plasmids containing various lengths of the rat insulin I gene 5'-flanking region linked to the bacterial reporter gene, chloramphenicol acetyltransferase (CAT). Studies of the transcriptional activity of 5'-deletionally and pointly mutated plasmids after transfection into HIT cells revealed the presence of a cAMP-responsive element (CRE), TGACGTCC, between -177 and -184 relative to the transcriptional start site, whose sequence closely matches the previously defined CREs, present in cAMP-responsive genes. Gel retardation and Southwestern assays identify a protein of molecular weight approximately 43,000, binding specifically to the insulin CRE. We conclude that the rat insulin I gene is regulated by cAMP through a CRE and that the nuclear protein interacting with it might be similar or identical to the previously purified cAMP-responsive protein, CREB.
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PMID:Functional characterization of a cAMP-responsive element of the rat insulin I gene. 215 35

To define the cis-acting elements important for rat insulin II gene expression, we analyzed the effects of 5' deletions and linker-scanning mutations on the expression of a rat insulin II reporter gene in an insulinoma cell line (HIT). The reporter gene contained 448 base pairs of 5'-flanking sequence joined to the bacterial chloramphenicol acetyltransferase gene. Expression of the 5' deletion mutations indicated that the minimal sequence requirement for efficient expression was 218 base pairs of 5'-flanking sequence, and at least three regions downstream from - 218 were important for transcription. A more precise localization of these elements and the cis-acting sequences in the promoter was achieved by analysis of the expression of 18 linker-scanning mutations. In these studies at least four other regions important for expression of the rat insulin II gene were identified. These findings suggest that the sequences important for rat insulin II and rat insulin I expression may differ significantly despite the high degree of sequence similarity in their 5'-flanking regions.
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PMID:Mutagenesis of the rat insulin II 5'-flanking region defines sequences important for expression in HIT cells. 265 5

Gastrin gene expression was observed in two permanent rat insulinoma (RIN) cell lines derived from a rat insulinoma. Gastrin expression was selective; highest expression was seen in a cell line which did not express other islet cell hormones. Gastrin mRNA transcription initiated from the same promoter as antral gastrin mRNA. DNA transfection studies with a gastrin chloramphenicol acetyltransferase chimeric gene showed higher expression in gastrin-expressing RIN cells than non-gastrin-expressing islet cells. This implies that gastrin-expressing RIN cells selectively express a trans-acting transcriptional activator which binds to cis-acting regulatory sequences within the 5'-flanking DNA sequence and first exon of the gastrin gene. The gastrin peptide precursor synthesized in these RIN cell lines is subject to the same repertoire of posttranslational modifications within the cell's secretory apparatus (endoproteolytic cleavage, tyrosine sulfation, and C-terminal amidation) as seen in antral G cells. Gastrin mRNA levels in these RIN cells were selectively increased by increasing the extracellular calcium concentration. Membrane depolarization also stimulated gastrin mRNA levels, probably through activation of voltage-sensitive calcium channels. Thus, these gastrin-expressing RIN cell lines provide permanent cell lines useful in analyzing the cellular regulation of gastrin gene expression.
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PMID:Gastrin gene expression and regulation in rat islet cell lines. 305 95

Three subtypes of alpha 2-adrenergic receptors (alpha 2A, alpha 2B and alpha 2C) have been described that differ in their primary sequence and tissue-specific expression and are encoded by three distinct genes. Previous work has shown that the human alpha 2A-adrenergic receptor gene promoter consists of a TATA-box (TATAAA), palindromic sequence (CCCACGTGGG) and GC-box (GGGGCGG) motif. Sequence analysis of the putative promoter region of the rat alpha 2A-adrenergic receptor gene showed that these promoter regions are conserved in their sequence and relative location. We analysed the transcriptional activity of these regions using RINm5F, a rat insulinoma cell line that expresses the endogenous alpha 2A-adrenergic receptor gene. These results showed that the region from -484 to -92 has a negative effect on transcription, as deletion of this region in alpha 2A-adrenergic receptor gene-chloramphenicol acetyltransferase reporter constructs increased reporter gene activity. This region included the GC-box sequence which is a consensus binding site for the nuclear factor SP1, which is a positive activator of transcription. Gel-mobility-shift assays and supershift assays with an antibody that recognizes SP1 showed binding of the SP1 nuclear factor as well as other nuclear factors to this GC-box region. Additional nuclear factors bind to the downstream palindromic region. We suggest that positive- and negative-acting nuclear factors contribute to the activity of the alpha 2-adrenergic receptor promoter.
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PMID:A negative regulatory element in the promoter region of the rat alpha 2A-adrenergic receptor gene overlaps an SP1 consensus binding site. 748 93

Transcription factor CREB regulates cyclic AMP (cAMP)-dependent gene expression by binding to and activating transcription from cAMP response elements (CREs) in the promoters of target genes. The transcriptional transactivation functions of CREB are activated by its phosphorylation by cAMP-dependent protein kinase A (PKA). In studies of many different phenotypically distinct cells, the CRE of the somatostatin gene promoter is a prototype of a highly cAMP-responsive element regulated by CREB. We now report on a somatostatin-producing rat insulinoma cell line, RIN-1027-B2, in which transcription from the somatostatin gene promoter is paradoxically repressed by CREB. We find that CREB fails to transactivate a CRE-containing somatostatin-chloramphenicol acetyltransferase reporter even when coexpressed with the catalytic subunit of PKA. CAAT box/enhancer-binding protein beta (C/EBP beta) and C/EBP-related activating transcription factor bind to the CRE in the promoter of the somatostatin gene and transactivate transcription. CREB binds competitively with C/EBP beta to the somatostatin CRE in vitro and represses C/EBP beta-induced transcription of the CRE-containing somatostatin-chloramphenicol acetyltransferase reporter. The lack of CREB-mediated transcriptional stimulation is due to the presence of a heat-stable inhibitor of PKA that prevents activation of PKA and subsequent CREB phosphorylation in the nucleus. These findings indicate that dephosphorylated CREB is a negative regulator of C/EBP-activated transcription of the somatostatin gene promoter in RIN-1027-B2 cells.
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PMID:Impaired cyclic AMP-dependent phosphorylation renders CREB a repressor of C/EBP-induced transcription of the somatostatin gene in an insulinoma cell line. 779 50

In pancreatic beta-cells, the high Km glucose transporter GLUT2 catalyzes the first step in glucose-induced insulin secretion by glucose uptake. Expression of the transporter has been reported to be modulated by glucose either at the protein or mRNA levels. In this study we used the differentiated insulinoma cell line INS-1 which expresses high levels of GLUT2 and show that the expression of GLUT2 is regulated by glucose at the transcriptional level. By run-on transcription assays we showed that glucose induced GLUT2 gene transcription 3-4-fold in INS-1 cells which was paralleled by a 1.7-2.3-fold increase in cytoplasmic GLUT2 mRNA levels. To determine whether glucose regulatory sequences were present in the promoter region of GLUT2, we cloned and characterized a 1.4-kilobase region of mouse genomic DNA located 5' of the translation initiation site. By RNase protection assays and primer extension, we determined that multiple transcription initiation sites were present at positions -55, -64, and -115 from the first coding ATG and which were identified in liver, intestine, kidney, and beta-cells mRNAs. Plasmids were constructed with the mouse promoter region linked to the reporter gene chloramphenicol acetyltransferase (CAT), and transiently and stably transfected in the INS-1 cells. Glucose induced a concentration-dependent increase in CAT activity which reached a maximum of 3.6-fold at 20 mM glucose. Similar CAT constructs made of the human GLUT2 promoter region and the CAT gene displayed the same glucose-dependent increase in transcriptional activity when transfected into INS-1 cells. Comparison of the mouse and human promoter regions revealed sequence identity restricted to a few stretches of sequences which suggests that the glucose responsive element(s) may be conserved in these common sequences.
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PMID:Characterization of the murine high Km glucose transporter GLUT2 gene and its transcriptional regulation by glucose in a differentiated insulin-secreting cell line. 792 31

Transfection of chimeric chloramphenicol acetyltransferase plasmids containing various deletions of the human gastric inhibitory polypeptide (GIP) promoter into hamster insulinoma (HIT T15) cells indicated that the region between -180 and +14 is sufficient for basal promoter activity. Two CRE-BP1 binding sites were identified in this promoter region by DNase I footprinting with the bacterially expressed cAMP response element (CRE) binding protein, CRE-BP1. Mutation analyses showed that these two CREs are required for the basal promoter activity, and furthermore that one site, at nucleotide-158, contributed mainly to the cAMP inducibility of the GIP promoter in HIT T15 cells. Interestingly, the GIP promoter activity was repressed by the c-jun proto-oncogene product, possibly through the CREs.
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PMID:Two 3',5'-cyclic-adenosine monophosphate response elements in the promoter region of the human gastric inhibitory polypeptide gene. 842 36

A mini-human insulin gene and four derivatives mutated at several regions potentially involved in the regulation of gene expression were used to generate transgenic mouse lines. The effect of these mutations on the efficiency of gene expression and cell specificity was studied using three approaches: (1) Northern blot analysis using total RNA from pancreas and other organs, (2) radioimmunoassay to detect the human C-peptide in urine samples, and (3) immunocytochemistry of pancreas sections to examine whether expression of the transgene was still specifically expressed in beta-cells. Mutation of the cis-acting elements located between -238 and -206 (GCII and CTII motifs) resulted in a strong decrease of gene expression in the pancreas of transgenic mice, but it did not lead to complete extinction of the transgene expression. This region alone (-255/-202), when linked to the minimal Herpes simplex virus thymidine kinase gene (tk) promoter, failed to activate chloramphenicol acetyltransferase (CAT) gene expression in transfected insulinoma cells, while it was activated by the equivalent region of the rat insulin I gene. On the contrary, mutation of the DNA motifs located between -109 and -75 (GCI and CTI) or between -323 and -297 (CTIII) did not significantly affect the level of the human insulin gene expression in transgenic mice. Replacement of the insulin promoter (-58/+l) by the tk promoter did not alter its level of expression in transgenic mice. In all instances, expression of the different transgenes remained localized in the islet beta-cells. Altogether, these results indicate that the GCII-CTII motif is an important regulatory element for efficient expression of the human insulin gene in vivo, although it alone does not allow gene expression as it would require the association of other elements.
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PMID:Human insulin gene expression in transgenic mice: mutational analysis of the regulatory region. 885 74

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