Characterization of regulatory elements on the promoter region of human ATP-citrate lyase.
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ATP-citrate lyase (ACL), an enzyme catalyzing the first step in biosynthesis of fatty acids, is induced during the lipogenesis and cholesterologenesis. We demonstrate that the region -213 to -128 of human ACL promoter is responsible for conferring glucose-mediated transcription. This region in the ACL promoter contains Sp1 binding sites determined by DNase I foot-printing assay. Gel retardation assay using oligonucleotides from -179 to -141 and -140 to -110 showed two specific DNA-protein complexes postulated to be formed by transcription factor Sp1. Competition gel shift and supershift assays have confirmed that these DNA-protein complexes were the result of induced Sp1 as well as another Sp1-related proteins. Western blot analysis also demonstrated that transcription factor Sp1 was slightly increased in the nuclear proteins extracted from Alexander cells following supplementation of glucose. In addition, expression of 110 kDa protein reacting with antibody against Sp3 was dramatically increased by glucose supplementation, while isoforms of Sp3, about 80 kDa in size was decreased in its amounts. Our results suggest that changes in the expression of Sp1 family proteins play an important role in activation of the ACL promoter by glucose. (+info)
Analysis of DNase-I-hypersensitive sites at the 3' end of the cystic fibrosis transmembrane conductance regulator gene (CFTR).
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The cystic fibrosis transmembrane conductance regulator gene (CFTR) exhibits a complex pattern of expression that shows temporal and spatial regulation, although the control mechanisms are not fully known. We have mapped DNase-I-hypersensitive sites (DHSs) flanking the CFTR gene with the aim of identifying potential regulatory elements. We previously characterized DHSs at -79.5 and -20.9 kb with respect to the CFTR translational start site and a regulatory element in the first intron of the gene at 185+10 kb. We have now mapped five DHSs lying 3' to the CFTR gene at 4574+5.4, +6.8, +7.0, +7.4 and +15.6 kb that show some degree of tissue specificity. The DHSs are seen in chromatin extracted from human primary epithelial cells and cell lines; the presence of the +15.6 kb site is tissue-specific in transgenic mice carrying a human CFTR yeast artificial chromosome. Further analysis of the 4574+15.6 kb DHS implicates the involvement of CCAAT-enhancer-binding protein (C/EBP), cAMP-response-element-binding protein (CREB)/activating transcription factor (ATF) and activator protein 1 (AP-1) family transcription factors at this regulatory element. (+info)
DNA ligase III is recruited to DNA strand breaks by a zinc finger motif homologous to that of poly(ADP-ribose) polymerase. Identification of two functionally distinct DNA binding regions within DNA ligase III.
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Mammalian DNA ligases are composed of a conserved catalytic domain flanked by unrelated sequences. At the C-terminal end of the catalytic domain, there is a 16-amino acid sequence, known as the conserved peptide, whose role in the ligation reaction is unknown. Here we show that conserved positively charged residues at the C-terminal end of this motif are required for enzyme-AMP formation. These residues probably interact with the triphosphate tail of ATP, positioning it for nucleophilic attack by the active site lysine. Amino acid residues within the sequence RFPR, which is invariant in the conserved peptide of mammalian DNA ligases, play critical roles in the subsequent nucleotidyl transfer reaction that produces the DNA-adenylate intermediate. DNA binding by the N-terminal zinc finger of DNA ligase III, which is homologous with the two zinc fingers of poly(ADP-ribose) polymerase, is not required for DNA ligase activity in vitro or in vivo. However, this zinc finger enables DNA ligase III to interact with and ligate nicked DNA at physiological salt concentrations. We suggest that in vivo the DNA ligase III zinc finger may displace poly(ADP-ribose) polymerase from DNA strand breaks, allowing repair to occur. (+info)
Flexible zinc finger requirement for binding of the transcriptional activator staf to U6 small nuclear RNA and tRNA(Sec) promoters.
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The transactivator Staf, which contains seven zinc finger motifs, exerts its effect on gene expression by binding to specific targets in small nuclear RNA (snRNA) and snRNA-type gene promoters. In this work, binding site selection allowed us to identify the 21-base pair ATTACCCATAATGCATYGCGG sequence as the high affinity consensus binding site for Staf. It shows a high sequence divergence with Staf-responsive elements in the Xenopus selenocysteine tRNA (tRNA(Sec)) and human U6 snRNA promoters. By using a combination of approaches, we analyzed the interaction of wild-type and truncated Staf zinc finger domains with the consensus, Xenopus tRNA(Sec), and human U6 sites. Two main conclusions emerged from our data. First, the data clearly indicate that zinc finger 7 does not establish base-specific contacts in Staf-DNA complexes. The second conclusion concerns zinc finger 1, which is required for the binding to the Xenopus tRNA(Sec) site but is dispensable in the case of the human U6 site. Taking into account the sequence differences in the two sites, these findings demonstrate that Staf utilizes zinc finger 1 in a rather flexible manner, illustrating how a protein can interact with DNAs containing targets of different sequences. (+info)
An upstream element containing an ETS binding site is crucial for transcription of the human presenilin-1 gene.
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Deletion mapping of the human presenilin-1 (PS1) promoter delineated the most active fragment from -118 to +178 in relation to the transcription start site mapped in this study, in both human neuroblastoma SK-N-SH and hepatoma HepG2 cells. 5' deletions revealed that a crucial element controlling over 90% of the promoter activity in these cell lines is located between -22 and -6. A mutation altering only two nucleotides of the ETS consensus sequence present at -12 (GGAA to TTAA) has a similar effect. Electrophoretic mobility shift assays showed that a set of specific complexes between nuclear factors and the PS1 promoter are eliminated by this point mutation, as well as by competition with an ETS consensus oligonucleotide. Competition experiments in DNase I footprinting correlated with electrophoretic mobility shift assays and showed that only one of several footprints over the PS1 promoter is eliminated by competition with an ETS consensus oligonucleotide. It extends from -14 to -6 and surrounds the ETS motif present at -12. Thus, a crucial ETS element is present at -12 and binds a protein(s) recognizing specifically the ETS consensus motif. At least one such complex is eliminated by preincubating the nuclear extract with an antibody with broad cross-reactivity with Ets-1 and Ets-2 proteins, thus confirming that an ETS transcription factor(s) recognizes the -12 motif. Several Sp1 binding motifs at positions -70, -55, and +20 surround this ETS element. Competition DNase I footprinting showed that Sp1-like nuclear factors recognize specifically these sites in both cell lines. Furthermore, a combination of 5' and 3' deletions indicated the presence of positive promoter elements between -96 and -35 as well as between +6 and +42. Thus, transfection and footprinting assays correlate to suggest that Sp1 transcription factor(s) bind at several sites upstream and downstream from the initiation site and activate the transcription of the PS1 promoter. Sequences downstream from the transcription initiation site also contain major control elements. 3' deletions from +178 to +107 decreased promoter activity by 80%. However, further deletion to +42 increased promoter activity by 3-4-fold. Collectively, these data indicate that sequences upstream and downstream from the transcription start site each control over 80% of the promoter activity. Hence, this suggests that protein-protein interactions between factors recognizing downstream and upstream sequences are involved. (+info)
Carp liver actin: isolation, polymerization and interaction with deoxyribonuclease I (DNase I).
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The aim of this study was to isolate and to characterize actin from the carp liver cytosol and to examine its ability to polymerize and interact with bovine pancreatic DNase I. Carp liver actin was isolated by ion-exchange chromatography, followed by gel filtration and a polymerization/depolymerization cycle or by affinity chromatography using DNase I immobilized to agarose. The purified carp liver actin was a cytoplasmic beta-actin isoform as verified by immunoblotting using isotype specific antibodies. Its isoelectric point (pI) was slightly higher than the pI of rabbit skeletal muscle alpha-actin. Polymerization of purified carp liver actin by 2 mM MgCl(2) or CaCl(2) was only obtained after addition of phalloidin or in the presence of 1 M potassium phosphate. Carp liver actin interacted with DNase I leading to the formation of a stable complex with concomitant inhibition of the DNA degrading activity of DNase I and its ability to polymerize. The estimated binding constant (K(b)) of carp liver actin to DNase I was calculated to be 1.85x10(8) M(-1) which is about 5-fold lower than the affinity of rabbit skeletal muscle alpha-actin to DNase I. (+info)
In vivo analysis of DNase I hypersensitive sites in the human CFTR gene.
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BACKGROUND: The cystic fibrosis transmembrane conductance regulator gene (CFTR) shows a complex pattern of expression. The regulatory elements conferring tissue-specific and temporal regulation are thought to lie mainly outside the promoter region. Previously, we identified DNase I hypersensitive sites (DHS) that may contain regulatory elements associated with the CFTR gene at -79.5 and at -20.5 kb with respect to the ATG and at 10 kb into the first intron. MATERIALS AND METHODS: In order to evaluate these regulatory elements in vivo we examined these DHS in a human CFTR gene that was introduced on a yeast artificial chromosome (YAC) into transgenic mice. The 310 kb human CFTR YAC was shown to restore the pheno-type of CF-null mice and so is likely to contain most of the regulatory elements required for tissue-specific expression of CFTR. RESULTS: We found that the YAC does not include the -79.5 kb region. The DHS at -20.5 kb is present in the chromatin of most tissues of the transgenic mice, supporting its non-tissue-specific nature. The DHS in the first intron is present in a more restricted set of tissues in the mice, although its presence does not show complete concordance with CFTR expression. The intron I DHS may be important for the higher levels of expression found in human pancreatic ducts and in lung submucosal glands. CONCLUSION: These data support the in vivo importance of these regulatory elements. (+info)
An origin of bidirectional DNA replication is located within a CpG island at the 3" end of the chicken lysozyme gene.
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We previously identified a broad initiation zone of DNA replication at the chicken lysozyme gene locus. However, the existence of a highly preferred origin of bidirectional replication (OBR), often found in initiation zones, remained elusive. In order to re-examine this issue we used a competitive PCR assay to determine the abundance of closely spaced genomic segments in a 1 kb size fraction of nascent DNA. A sharp peak of nascent strand abundance occurred at the 3" end of the gene, where initiation events were 17 times more frequent than upstream of the gene. This primary initiation site, active in lysozyme expressing myelomonocytic HD11 cells and non-expressing hepatic DU249 cells, was found to reside within an unusually located CpG island. While most CpG islands are found at the 5" end of genes, the lysozyme gene island extends from the 3" end of the second intron and includes approximately 1.2 kb of 3" flanking DNA. As diagnosed by methylation-sensitive restriction enzymes, the island is largely non-methylated in HD11 cells, DU249 cells and inactive chicken erythrocytes. Furthermore, a DNase I hypersensitive site (HS) that is composed of two subsites separated by approximately 100 bp, was localised very close to the segment with the highest initiation activity. Our results suggest that the non-methylated CpG island and the HS provide an accessible chromatin structure for the lysozyme gene origin of replication. (+info)