Formation Of Specific DNA-protein Complexes Research Articles

A Protein in the Yeast Saccharomyces cerevisiae Presents DNA Binding Homology to the p53 Checkpoint Protein and Tumor Suppressor.

Saccharomyces cerevisiae does not contain a p53 homolog. Utilizing this yeast as an in vivo test tube model, our aim was to investigate if a yeast protein would show p53 DNA binding homology. Electrophoretic mobility shift analyses revealed the formation of specific DNA-protein complexes consisting of S. cerevisiae nuclear protein(s) and oligonucleotides containing p53 DNA binding sites. A S. cerevisiae p53 binding site factor (Scp53BSF) bound to a p53 synthetic DNA-consensus sequence (SCS) and a p53 binding-site sequence from the MDM2 oncogene. The complexes were of comparable size. Like mammalian p53, the affinity of Scp53BSF for the SCS oligonucleotide was higher than for the MDM2 oligonucleotide. Binding of Scp53BSF to the SCS and MDM2 oligonucleotides was strongly competed by unlabeled oligonucleotides containing mammalian p53 sites, but very little by a mutated site oligonucleotide. Importantly, Scp53BSF-DNA binding activity was significantly induced in extracts from cells with DNA damage. This resulted in dose-dependent coordinated activation of transcription when using p53-binding site reporter constructs. An ancient p53-like DNA binding protein may have been found, and activation of DNA-associated factors to p53 response elements may have functions not yet determined.

Slow troponin C gene expression in chicken heart and liver is regulated by similar enhancers

Two isoforms of troponin C (TnC) are encoded by distinct single copy genes. Expression of fast TnC is restricted to the skeletal muscle, whereas the slow isoform is expressed in both skeletal and cardiac muscle. Chicken slow TnC (cTnC) gene is also expressed in some non-muscle tissues like the liver and the brain. Expression of cTnC gene is regulated by two distinct enhancers in cardiac and skeletal muscles. The cardiac specific enhancer is located in the immediate 5′ flanking region (bp −124 to −79) of the murine cTnC gene whereas the skeletal enhancer is located within the first intron (bp 997 to 1141). In the present study we have examined how cTnC gene expression is regulated in the chicken liver. Transient transfection of liver cells with cTnC-CAT reporter constructs containing various regions of the murine cTnC gene showed that its expression in chicken liver is regulated by the cardiac specific enhancer. Furthermore, electrophoretic mobility shift assays using synthetic oligonucleotides corresponding to both CEF-1 and CEF-2 regions of the murine cardiac enhancer revealed formation of specific DNA-protein complexes. Ultraviolet light induced covalent linking of nuclear proteins to CEF-1 and CEF-2 oligomers were used to examine the nature of the cardiac enhancer binding polypeptides; one polypeptide of 48 kDa appeared to bind to both CEF-1 and CEF-2 sequences.

Platelet-derived growth factor A-chain gene transcription is mediated by positive and negative regulatory regions in the promoter.

Platelet-derived growth factor (PDGF) is a disulphide-linked heterodimer of two polypeptide chains, the A and B chains, which are encoded by genes on separate chromosomes. The A-chain gene is transcribed in a number of transformed and non-transformed cell lines and is inducible by a wide variety of growth factors, cytokines and other mitogenic agonists. To localize DNA elements that mediate basal transcription in the promoter regulatory region of the A-chain gene, we have employed 5'-endpoint deletion mutagenesis and transient expression analysis in the renal epithelial cell line BSC-1 (African green monkey). Studies conducted in this cell line, which expresses high concentrations of PDGF A-chain mRNA, reveal a positive regulatory element (PRE) in a GC-rich stretch of the A-chain promoter between -82 and -40, relative to the transcription start site. Two discrete regions of the promoter were identified as negative regulatory elements (NREs), located between -1029 and -880 (NRE1) and between -1800 and -1029 (NRE2). The -1800 to -812 region, which contains both NREs, functions as a potent NRE when relocated in either orientation adjacent to the herpes simplex virus thymidine kinase promoter, reducing transcription activity by 60% in the positive orientation and 85% in the negative orientation. Comparison of BSC-1 cells and Saos-2 cells (human osteogenic sarcoma), which do not express significant quantities of PDGF A-chain mRNA or protein, indicates that basal transcription of the gene is determined by enhancer activity mediated by the GC-rich region rather than through de-repression of the upstream NREs. Electrophoretic gel mobility shift assays reveal a complex pattern of nuclear protein binding to the GC-rich PRE (-73 to -46). Competition studies conducted with mutant oligonucleotides that alternately disrupt consensus binding sites for Sp-1 or Egr-1 demonstrate a requirement for the presence of an Sp1-like core sequence (GGCGGG) but not Egr-1/Krox-24 [GCG(G/T)-GGGCG] for the formation of specific DNA-protein complexes. Our observations suggest that basal transcription of the A-chain gene in renal epithelial cells is achieved through active enhancement, mediated by a GC-rich PRE and nuclear proteins that bind to Sp-1-like consensus DNA sequences.

Differentiation-Specific Transcriptional Regulation of the Hepatitis B Virus Nucleocapsid Gene in Human Hepatoma Cell Lines

Transcription from the hepatitis B virus (HBV) nucleocapsid promoter is regulated in a cell-type-specific manner and can be modulated by the HBV enhancer 1 element. Mutagenesis analysis of the nucleocapsid promoter demonstrated that the two Sp1-binding sites (CpB and CpC) in the minimal promoter were the major determinants of transcriptional activity in the dedifferentiated hepatoma cell line, HepG2.1, and the human cervical carcinoma cell line, HeLa S3. In contrast, binding sites for transcription factors located immediately upstream (CpE) and downstream (CpF) of the two Sp1-binding sites were shown to be important determinants of nucleocapsid promoter activity in the differentiated hepatoma cell lines, Huh7 and HepG2. The role of these elements in the regulation of the nucleocapsid promoter activity correlated with the formation of specific DNA-protein complexes between Huh7 and HepG2 nuclear extracts and the CpE and CpF region sequences. Characterization of the influence of the nucleocapsid promoter mutations in the presence or absence of the enhancer 1 demonstrated that modification of individual transcription factor binding sites does not prevent enhancer-mediated activation of transcription from the nucleocapsid promoter. These results indicate that differentiated-hepatoma-specific transcription factors plus the Sp1 transcription factor interacting with the nucleocapsid promoter and the enhancer 1 regulatory region contribute to the level of transcription from this HBV promoter.

Functional characterization of the INO2 gene of Saccharomyces cerevisiae. A positive regulator of phospholipid biosynthesis.

The INO2 locus encodes a novel product showing structural similarity to the basic helix-loop-helix (b-HLH) family of regulatory proteins (Nikoloff, D.M., McGraw, P., and Henry, S.A. (1992) Nucleic Acids Res. 20, 3253). The ino2 mutants exhibit pleiotropic defects in phospholipid metabolism including inability to derepress the biosynthetic enzyme inositol-1-phosphate synthase. Localization of mutations in ino2 strains has demonstrated that the b-HLH domain is required for biological activity and is sensitive to perturbation, thereby establishing a correlation between the structure and function of Ino2p. Defects in the b-HLH domain of Ino2p resulted in reduced DNA binding activity. In addition, the absence of a specific DNA-protein complex correlated with a reduction or loss of INO1 transcription. Studies using Ino2p-specific antibody revealed that Ino2p participates in the formation of specific DNA-protein complexes. Ino2p-dependent binding activity overlapped with a region of the INO1 promoter that contains two potential HLH consensus binding sites. Furthermore, Ino2p showed single base pair discrimination in a putative binding site, establishing a relationship between Ino2p and its target binding site.

BOX DNA: a novel regulatory element related to embryonal carcinoma cell differentiation.

BOX DNA was previously isolated from the DNA sequence inserted in the enhancer B domain of mutant polyomavirus (fPyF9) DNA. We also reported that BOX DNA functioned negatively on DNA replication and transcription of another polyomavirus mutant (PyhrN2) in F9-28 cells, a subclone of mouse F9 embryonal carcinoma (EC) cells expressing the polyomavirus large T antigen. In this study, we demonstrate that BOX DNA enhances transcription from the thymidine kinase (TK) promoter in various EC cells. One or three copies of BOX DNA, linked to the bacterial chloramphenicol acetyltransferase gene under the control of the herpes simplex virus TK promoter, activated promoter activity in F9, P19, and ECA2 cells. Band shift assays using BOX DNA as a probe revealed that specific binding proteins were present in all EC cells examined; the patterns of BOX DNA-protein complexes were the same among them. A mutation introduced within BOX DNA abolished enhancer activity as well as the formation of specific DNA-protein complexes. In non-EC cells, including L and BALB/3T3 cells, the enhancer activity of BOX DNA on the TK promoter was not observed, although binding proteins specific to the sequence exist. In band shift assays, the patterns of the DNA-protein complexes of either L or BALB/3T3 cells were different from those of EC cells. Furthermore, the enhancer activity of BOX DNA decreased upon differentiation induction in all EC cells examined, of different origins and distinct differentiation ability. In parallel with the loss of enhancer activity, the binding proteins specific for BOX DNA decreased in these cells. Moreover, we cloned a genomic DNA of F9, termed BOXF1, containing BOX DNA sequence approximately 400 bp upstream from the RNA start site of the gene. BOXF1, containing a TATA-like motif and the binding elements for Sp1 and Oct in addition to BOX DNA, possessed promoter activity deduced by a BOXF1-chloramphenicol acetyltransferase construct. Deletion analyses of the construct revealed that the transcription of BOXF1 gene is regulated by BOX DNA, preferentially in undifferentiated EC cells versus differentiated cells. Hence, BOX DNA is probably a novel transcriptional element related to EC cell differentiation.

BOX DNA: a novel regulatory element related to embryonal carcinoma cell differentiation.

BOX DNA was previously isolated from the DNA sequence inserted in the enhancer B domain of mutant polyomavirus (fPyF9) DNA. We also reported that BOX DNA functioned negatively on DNA replication and transcription of another polyomavirus mutant (PyhrN2) in F9-28 cells, a subclone of mouse F9 embryonal carcinoma (EC) cells expressing the polyomavirus large T antigen. In this study, we demonstrate that BOX DNA enhances transcription from the thymidine kinase (TK) promoter in various EC cells. One or three copies of BOX DNA, linked to the bacterial chloramphenicol acetyltransferase gene under the control of the herpes simplex virus TK promoter, activated promoter activity in F9, P19, and ECA2 cells. Band shift assays using BOX DNA as a probe revealed that specific binding proteins were present in all EC cells examined; the patterns of BOX DNA-protein complexes were the same among them. A mutation introduced within BOX DNA abolished enhancer activity as well as the formation of specific DNA-protein complexes. In non-EC cells, including L and BALB/3T3 cells, the enhancer activity of BOX DNA on the TK promoter was not observed, although binding proteins specific to the sequence exist. In band shift assays, the patterns of the DNA-protein complexes of either L or BALB/3T3 cells were different from those of EC cells. Furthermore, the enhancer activity of BOX DNA decreased upon differentiation induction in all EC cells examined, of different origins and distinct differentiation ability. In parallel with the loss of enhancer activity, the binding proteins specific for BOX DNA decreased in these cells. Moreover, we cloned a genomic DNA of F9, termed BOXF1, containing BOX DNA sequence approximately 400 bp upstream from the RNA start site of the gene. BOXF1, containing a TATA-like motif and the binding elements for Sp1 and Oct in addition to BOX DNA, possessed promoter activity deduced by a BOXF1-chloramphenicol acetyltransferase construct. Deletion analyses of the construct revealed that the transcription of BOXF1 gene is regulated by BOX DNA, preferentially in undifferentiated EC cells versus differentiated cells. Hence, BOX DNA is probably a novel transcriptional element related to EC cell differentiation.

Transcriptional regulation of the human IgE receptor (Fc epsilon RII/CD23) by EBV. Identification of EBV-responsive regulatory elements in intron 1.

EBV infection of B cells induces the B cell activation Ag, CD23 (Fc epsilon RII). CD23 remains constitutively expressed at high levels in all EBV-immortalized B cells and likely plays an important role in the initiation and maintenance of immortalization by EBV. By utilizing an EBV-negative Burkitt's lymphoma line (BJAB) and EBV-positive sublines derived from it by in vitro infection, we have examined the molecular mechanisms involved in the regulation of CD23 by EBV. By nuclear runoff analysis, we have found that induction of CD23 is mediated by transcriptional activation that occurs in the presence of the transformation-competent B958 virus but not in the presence of the nontransforming P3HR-1 strain of EBV. To identify EBV-responsive transcriptional regulatory elements of CD23, we have performed reporter gene assays using plasmids containing fragments of the CD23 gene derived from its 5' terminus and adjacent flanking region transfected into EBV-positive and -negative BJAB lines. We have identified a 534-bp fragment of the gene which enhances transcription from a heterologous promoter (SV40) and reporter gene (chloramphenicol acetyltransferase) only in the presence of transformation-competent strains of EBV. Deletion of 144 bp of intron 1 from the 3' end of this fragment results in loss of EBV-responsive enhancer activity. The finding of an EBV-responsive enhancer element of CD23 is supported by mobility shift assays that demonstrated the formation of specific DNA-protein complexes between nuclear protein from transforming EBV-positive cells and the 144-bp intron sequence. These studies suggest that the transcriptional activation of CD23 by transforming strains of EBV involves regulatory elements that are located within the first intron of the gene.

A DNA sequence upstream of the puf operon of Rhodobacter capsulatus is involved in its oxygen-dependent regulation and functions as a protein binding site

The transcription of the polycistronic puf operon which encodes pigment binding proteins of the reaction center and light-harvesting complex I of Rhodobacter capsulatus is regulated by the oxygen tension in the culture. A DNA sequence upstream of the puf transcriptional start was identified as a protein binding site. A DNA fragment carrying this DNA sequence participated in the formation of two DNA-protein complexes. The relative amounts of the two complexes were dependent on the oxygen tension in cultures from which the cytosolic fraction used for the in vitro binding studies was isolated. A single base pair transition within the protein binding site affected the oxygen-dependent expression of puf in vivo and the formation of DNA-protein complexes in vitro. The data suggest that the formation of specific DNA-protein complexes is involved in the oxygen-dependent regulation of the puf promoter. A DNA fragment containing the promoter region of the puc operon that encodes proteins of the light-harvesting complex II acted as a competitor for the formation of the DNA-protein complexes with the puf-specific fragment, indicating coregulation of the two operons.

Regulation of a human neurotropic virus promoter, JCVE: identification of a novel activator domain located upstream from the 98 bp enhancer promoter region

Transcription of the human neurotropic virus promoter, JCVE, and its regulation in glial cells are controlled by the 98 bp tandem repeats positioned between the viral early and late genes. Here, we show that a region, designated domain-D, located upstream from the 98 bp repeats functions as a transcriptional activator and increases JCVE promoter activity. Using the reporter SV40E promoter fused to the bacterial chloramphenicol acetyltransferase (CAT) gene, we demonstrate that domain-D stimulates the basal SV40E promoter activity in glial and to a lesser degree in HeLa cells. Results from gel mobility-shift assays indicate that domain-D interacts with proteins derived from glial and HeLa extracts and results in the formation of specific DNA-protein complexes. Through UV cross-linking assays, we demonstrate that these complexes have similar electrophoretic mobilities which comigrate with the 43-50 Kd proteins derived from glial and HeLa cells. These findings, together with our previous observations, imply that the JCVE control region is composed of multiple common and specific activator domains that may account for the increased expression of the promoter in glial cells. The possible role of the D-binding protein in transcription of the JCVE promoter is discussed.

A novel method for transfection and expression of reconstituted DNA-protein complexes in eukaryotic cells.

Transfection of foreign DNA into eukaryotic cells has become an important tool in molecular biology. Based on the results of previous studies of the core structure of human adenoviruses, we have developed a novel transfection method. The procedure involves the in vitro reconstitution of foreign DNA-of viral or other origins-with the major core protein VII of adenovirus type 2 (Ad2) or protamine from salmon sperm. Both proteins are rich in basic amino acids and appear to share structural features. The DNA-protein complexes are added directly to the medium of eukaryotic cells. The in vitro formation of specific DNA-protein complexes can be assessed by gel electrophoretic analyses. Bovine serum albumin does not enter into specific complexes with DNA. Transfection of DNA-protein VII or DNA-protamine complexes results in their rapid transport into the cell nuclei. About 2-4 hr after transfection, up to 40% of the DNA added to cell cultures in complexes can be found in the nucleus, as compared with less than 10% of the DNA when other transfection methods are applied or when naked DNA is added to cell cultures. DNAs transfected by the new method into mammalian or insect cells retain their characteristic restriction patterns at least 48 hr after transfection and are expressed efficiently. Supercoiled circular plasmid DNAs are converted to open circular or linear DNA. Expression has been measured both for transiently expressed genes (chloramphenicol acetyltransferase gene, Ad2 DNA in human HeLa cells) and for genes that have been integrated into the host genome and are expressed permanently, such as the gene for neomycin phosphotransferase in hamster BHK21 cells.(ABSTRACT TRUNCATED AT 250 WORDS)