Upstream DNA Research Articles

Characterization of the upstream region that regulates the transcription of the gene for the precursor to EGF-related peptides, exogastrula-inducing peptides, of the sea urchin Anthocidaris crassispina

The EGIP gene for exogastrula-inducing peptides (EGIPs) of the sea urchin Anthocidaris crassispina, which are structurally related to the epidermal growth factor, is activated at the onset of gastrulation in subdomains of the embryonic ectoderm. We showed in our previous study that the spatial and temporal regulation of EGIP is conducted by the upstream region from −372 to +194, and that there is an enhancer element between −372 and −210. In this study, we introduced into sea urchin embryos PCR-amplified DNA containing differently truncated EGIP flanking region that was ligated to the GFP reporter gene, and examined the transient expression of the reporter gene, showing that both the −270/−238 and −249/−210 regions were essential for the enhancer activity. We further showed that there is another activating element between −65 and −21, and that even the region between −65 and +194 is sufficient for ectoderm-specific expression of the EGIP gene. The electrophoretic mobility shift assay showed that the −270/−210 enhancer region and the proximal −61/+30 region include specific binding sites for nuclear proteins of sea urchin embryos. Besides these unique sites, the presence of multiple binding sites for GCF1-like nuclear proteins have been revealed in the upstream DNA.

Recruitment of σ54-RNA Polymerase to the Pu Promoter of Pseudomonas putida through Integration Host Factor-mediated Positioning Switch of α Subunit Carboxyl-terminal Domain on an UP-like Element

The interactions between the sigma54-containing RNA polymerase (sigma54-RNAP) and the region of the Pseudomonas putida Pu promoter spanning from the enhancer to the binding site for the integration host factor (IHF) were analyzed both by DNase I and hydroxyl radical footprinting. A short Pu region centered at position -104 was found to be involved in the interaction with sigma54-RNAP, both in the absence and in the presence of IHF protein. Deletion or scrambling of the -104 region strongly reduced promoter affinity in vitro and promoter activity in vivo, respectively. The reduction in promoter affinity coincided with the loss of IHF-mediated recruitment of the sigma54-RNAP in vitro. The experiments with oriented-alpha sigma54-RNAP derivatives containing bound chemical nuclease revealed interchangeable positioning of only one of the two alpha subunit carboxyl-terminal domains (alphaCTDs) both at the -104 region and in the surroundings of position -78. The addition of IHF resulted in perfect position symmetry of the two alphaCTDs. These results indicate that, in the absence of IHF, the sigma54-RNAP asymmetrically uses only one alphaCTD subunit to establish productive contacts with upstream sequences of the Pu promoter. In the presence of IHF-induced curvature, the closer proximity of the upstream DNA to the body of the sigma54-RNAP can allow the other alphaCTD to be engaged in and thus favor closed complex formation.

An intersubunit contact stimulating transcription initiation by E coli RNA polymerase: interaction of the alpha C-terminal domain and sigma region 4.

The C-terminal domain of the Escherichia coli RNA polymerase (RNAP) alpha subunit (alphaCTD) stimulates transcription initiation by interacting with upstream (UP) element DNA and a variety of transcription activators. Here we identify specific substitutions in region 4.2 of sigma 70 (sigma(70)) and in alphaCTD that decrease transcription initiation from promoters containing some, but not all, UP elements. This decrease in transcription derives from a decrease in the initial equilibrium constant for RNAP binding (K(B)). The open complexes formed by the mutant and wild-type RNAPs differ in DNAse I sensitivity at the junction of the alphaCTD and sigma DNA binding sites, correlating with the differences in transcription. A model of the DNA-alphaCTD-sigma region 4.2 ternary complex, constructed from the previously determined X-ray structures of the Thermus aquaticus sigma region 4.2-DNA complex and the E. coli alphaCTD-DNA complex, indicates that the residues identified by mutation in sigma region 4.2 and in alphaCTD are in very close proximity. Our results strongly suggest that alphaCTD, when bound to an UP element proximal subsite, contacts the RNAP sigma(70) subunit, increasing transcription. Previous data from the literature suggest that this same sigma-alphaCTD interaction also plays a role in transcription factor-mediated activation.

The fission yeast TFIIB-related factor limits RNA polymerase III to a TATA-dependent pathway of TBP recruitment.

The RNA polymerase (pol) III-transcribed (e.g. tRNA and 5S rRNA) genes of traditionally studied organisms rely on gene-internal promoters that precisely position the initiation factor, TFIIIB, on the upstream promoter-less DNA. This is accomplished by the ability of the TFIIIB subunit, TFIIB-related factor (Brf1), to make stable protein-protein interactions with TATA-binding protein (TBP) and place it on the promoter-less upstream DNA. Unlike traditional model organisms, Schizosaccharomyces pombe tRNA and 5S rRNA genes contain upstream TATA promoters that are required to program functional pol III initiation complexes. In this study we demonstrate that S.pombe (Sp)Brf does not form stable interactions with TBP in the absence of DNA using approaches that do reveal stable association of TBP and S.cerevisiae (Sc)Brf1. Gel mobility analyses demonstrate that a TBP-TATA DNA complex can recruit SpBrf to a Pol III promoter. Consistent with this, overproduction of SpBrf in S.pombe increases the expression of a TATA-dependent, but not a TATA-less, suppressor tRNA gene. Since previous whole genome analysis also revealed TATA elements upstream of tRNA genes in Arabidopsis, this pathway may be more widespread than appreciated previously.

Expression of cnf1 by Escherichia coli J96 involves a large upstream DNA region including the hlyCABD operon, and is regulated by the RfaH protein.

Examination of 55 clinical isolates of uropathogenic Escherichia coli producing the CNF1 toxin demonstrated that the cnf1 gene is systematically associated with a hly operon via a highly conserved hlyD-cnf1 intergenic region (igs, 943 bp) as shown in the J96 UPEC strain. We examined if this association could reflect a co-regulation of the production of these toxins. Translation of cnf1 from an immediately upstream promoter has been shown to be controlled by means of an anti-Shine-Dalgarno sequence present in the cnf1 coding sequence [fold-back inhibition (cnf1 fbi)]. The cnf1 fbi was not regulated by elements present in the igs. An RNA covering the full hlyD sequence, the igs and extending on the cnf1 gene, was then detected in the J96 strain. This RNA could be part of a HlyCABD mRNA. Transcription of the haemolysin operon requires RfaH antitermination activity. Inactivation of rfaH in J96 resulted in a 100-fold reduction of the CNF1 content of bacteria. The production of CNF1 from a plasmidic igscnf1 DNA was not sensitive to RfaH, indicating that this factor acted on cnf1 transcription via the hly promoter. This way the cnf1 fbi mechanism might be overcome by transcription of cnf1 from the haemolysin promoter and antitermination by RfaH. This constitutes a novel system of bacterial virulence factors co-regulation.

Visualizing RNA Extrusion and DNA Wrapping in Transcription Elongation Complexes of Bacterial and Eukaryotic RNA Polymerases

Transcription ternary complexes of Escherichia coli RNA polymerase and yeast RNA polymerase III have been analyzed by atomic force microscopy. Using the method of nucleotide omission and different DNA templates, E.coli RNAP has been stalled at position +24, +70 and +379 and RNAP III at position +377 from the starting site. Conformational analysis of E.coli RNAP elongation complexes reveals an average DNA compaction of 22nm and a DNA deformation compatible with ∼180° DNA wrapping against the enzyme. The extent of protein–DNA interaction attributed to wrapping, however, is less than that of corresponding open promoter complexes. DNA wrapping was also observed for RNAP III elongation complexes, which showed a DNA compaction of 30nm. When the RNA polymerases were stalled far from the promoter (+379 and +377), the growing RNA transcript was often visible and it was prevalently seen exiting from the enzyme on the opposite side relative to the smallest angle subtended by the upstream and downstream DNA arms. Surprisingly, we found that many complexes had a second RNAP, not involved in transcription, bound to the growing RNA of a ternary complex. DNA wrapping in the elongation complex suggests a possible mechanism by which the polymerase may overcome the physical barrier to transcription imposed by the nucleosomes.

Human SM22 alpha BAC encompasses regulatory sequences for expression in vascular and visceral smooth muscles at fetal and adult stages.

The SM22 alpha gene has widely been used to study the regulatory mechanisms of smooth muscle cell (SMC) gene expression during cardiovascular development. To determine the regulatory mechanisms for the evolutionarily conserved human SM22 alpha (hSM22 alpha) gene, we demonstrated that 445 bp upstream DNA sequences of hSM22 alpha gene exhibited a high transcriptional activity in arterial SMC, not in venous nor in visceral SMCs during embryogensis. However, this promoter was gradually turned off in adulthood. Inclusion of the first intron in this promoter suppressed the promoter activity in pulmonary trunk arterial SMCs, whereas the expression in other systemic vasculature remained similar to that of the hSM22-445 promoter during the fetal and adult stages. To determine whether additional sequences are required for SM22 alpha expression in all subtypes of SMCs, we examined the expression of a bacterial artificial chromosome containing the hSM22 alpha locus in transgenic mice. The hSM22 alpha transgene showed similar developmental expression patterns as the endogenous mouse SM22 alpha gene, suggesting that this bacterial artificial chromosome contains essential regulatory sequences for its expression in arterial, venous, and visceral tissues during development.

Fluorescence Resonance Energy Transfer (FRET) in Analysis of Transcription-Complex Structure and Function

Publisher Summary This chapter discusses the Fluorescence Resonance Energy Transfer (FRET) to monitor movement of RNA polymerase (RNAP) relative to DNA during transcription and to define three-dimensional structures of transcription complexes in solution. FRET is a physical phenomenon that permits measurement of distances. FRET occurs in a system where a fluorescent probe serves as a donor and a second fluorescent probe serves as an acceptor, where the emission spectrum of the donor overlaps the excitation spectrum of the acceptor. The chapter presents protocols for FRET experiments that permit measurement of distances between positions on upstream DNA and positions within RNAP (“trailing-edge FRET”), distances between positions on downstream DNA and positions within RNAP (“leading-edge FRET”), and distances between positions on RNAP core and positions within σ70 (“core- σ70FRET”). Later the preparation of DNA fragments, sigma σ70, RNAP core, RNAP holoenzyme, and RNA polymerase-promoter open complex (RPo) is discussed. DNA–RNAP FRET permits monitoring of movement of RNAP relative to DNA during promoter escape and elongation and provides information about three-dimensional structures of RPo and RDe. The approach involves two complementary sets of experiments: trailing-edge-FRET experiments, which monitor the distance between a fluorescent probe in RNAP and a fluorescent probe on DNA upstream of RNAP; and leading-edge-FRET experiments, which monitor the distance between a fluorescent probe in RNAP, and a fluorescent probe on DNA downstream of RNAP.

Transcriptional and Translational Regulation of Zebrafish Connexin 55.5 (zf.Cx.55.5) and Connexin 52.6 (zf.Cx52.6)

Zebrafish connexin 55.5 (zf.Cx55.5) and connexin 52.6 (zf.Cx52.6) show highly restricted expression patterns in the nervous system. Both connexins are confined to subsets of neurons in the fish retina. In order to get initial answers to the questions of pattern definition in neuronal subsets, we elucidated molecular mechanisms responsible for their expression. Different upstream DNA fragments were subcloned into a pGL3-basic vector and transiently transfected in HeLa and N2A cells. Luciferase activity showed the presence of two putative promoter elements in zfCx55.5 and a promoter element in zfCx52.6 that showed different promoter activities in HeLa and N2A cells. Moreover, fusion constructs of zfCx55.5 with EGFP revealed the presence of a new isoform with an additional short exon I.

A DNA element recognised by the molybdenum-responsive transcription factor ModE is conserved in Proteobacteria, green sulphur bacteria and Archaea

BackgroundThe transition metal molybdenum is essential for life. Escherichia coli imports this metal into the cell in the form of molybdate ions, which are taken up via an ABC transport system. In E. coli and other Proteobacteria molybdenum metabolism and homeostasis are regulated by the molybdate-responsive transcription factor ModE.ResultsOrthologues of ModE are widespread amongst diverse prokaryotes, but not ubiquitous. We identified probable ModE-binding sites upstream of genes implicated in molybdenum metabolism in green sulphur bacteria and methanogenic Archaea as well as in Proteobacteria. We also present evidence of horizontal transfer of nitrogen fixation genes between green sulphur bacteria and methanogenic Archaea.ConclusionsWhereas most of the archaeal helix-turn-helix-containing transcription factors belong to families that are Archaea-specific, ModE is unusual in that it is found in both Archaea and Bacteria. Moreover, its cognate upstream DNA recognition sequence is also conserved between Archaea and Bacteria, despite the fundamental differences in their core transcription machinery. ModE is the third example of a transcriptional regulator with a binding signal that is conserved in Bacteria and Archaea.

Structural basis for the transition from initiation to elongation transcription in T7 RNA polymerase.

To make messenger RNA transcripts, bacteriophage T7 RNA polymerase (T7 RNAP) undergoes a transition from an initiation phase, which only makes short RNA fragments, to a stable elongation phase. We have determined at 2.1 angstrom resolution the crystal structure of a T7 RNAP elongation complex with 30 base pairs of duplex DNA containing a "transcription bubble" interacting with a 17-nucleotide RNA transcript. The transition from an initiation to an elongation complex is accompanied by a major refolding of the amino-terminal 300 residues. This results in loss of the promoter binding site, facilitating promoter clearance, and creates a tunnel that surrounds the RNA transcript after it peels off a seven-base pair heteroduplex. Formation of the exit tunnel explains the enhanced processivity of the elongation complex. Downstream duplex DNA binds to the fingers domain, and its orientation relative to upstream DNA in the initiation complex implies an unwinding that could facilitate formation of the open promoter complex.

Identification of the Omega4514 regulatory region, a developmental promoter of Myxococcus xanthus that is transcribed in vitro by the major vegetative RNA polymerase.

Omega4514 is the site of a Tn5 lac insertion in the Myxococcus xanthus genome that fuses lacZ expression to a developmentally regulated promoter. DNA upstream of the insertion site was cloned, and the promoter was localized. The promoter resembles vegetative promoters in sequence, and sigma(A) RNA polymerase, the major form of RNA polymerase in growing M. xanthus, initiated transcription from this promoter in vitro. Two complete open reading frames were identified downstream of the promoter and before the Omega4514 insertion. The first gene product (ORF1) has a putative helix-turn-helix DNA-binding motif and shows sequence similarity to transcriptional regulators. ORF2 is most similar to subunit A of glutaconate coenzyme A (CoA) transferase, which is involved in glutamate fermentation. Tn5 lac Omega4514 is inserted in the third codon of ORF3, which is similar to subunit B of glutaconate CoA-transferase. An orf1 disruption mutant exhibited a mild sporulation defect, whereas neither a disruption of orf2 nor insertion Omega4514 in orf3 caused a defect. Based on DNA sequence analysis, the three genes are likely to be cotranscribed with a fourth gene whose product is similar to alcohol dehydrogenases. ORF1 delays and reduces expression of the operon during development, but relief from this negative autoregulation does not fully explain the regulation of the operon, because expression from a small promoter-containing fragment is strongly induced during development of an orf1 mutant. Also, multiple upstream DNA elements are necessary for full developmental expression. These results suggest that transcriptional activation also regulates the operon. Omega4514 is the first example of a developmentally regulated M. xanthus operon that is transcribed by the major vegetative RNA polymerase, and its regulation appears to involve both negative autoregulation by ORF1 and positive regulation by one or more transcriptional activators.

Isolation and analysis of retroviral integration targets by solo long terminal repeat inverse PCR.

Upon retroviral infection, the genomic RNA is reverse transcribed to make proviral DNA, which is then integrated into the host chromosome. Although the viral elements required for successful integration have been extensively characterized, little is known about the host DNA structure constituting preferred targets for proviral integration. In order to elucidate the mechanism for the target selection, comparison of host DNA sequences at proviral integration sites may be useful. To achieve simultaneous analysis of the upstream and downstream host DNA sequences flanking each proviral integration site, a Moloney murine leukemia virus-based retroviral vector was designed so that its integrated provirus could be removed by Cre-loxP homologous recombination, leaving a solo long terminal repeat (LTR). Taking advantage of the solo LTR, inverse PCR was carried out to amplify both the upstream and downstream cellular flanking DNA. The method called solo LTR inverse PCR, or SLIP, proved useful for simultaneously cloning the upstream and downstream flanking sequences of individual proviral integration sites from the polyclonal population of cells harboring provirus at different chromosomal sites. By the SLIP method, nucleotide sequences corresponding to 38 independent proviral integration targets were determined and, interestingly, atypical virus-host DNA junction structures were found in more than 20% of the cases. Characterization of retroviral integration sites using the SLIP method may provide useful insights into the mechanism for proviral integration and its target selection.

E. coli Transcription Repair Coupling Factor (Mfd Protein) Rescues Arrested Complexes by Promoting Forward Translocation

Transcription and DNA repair are coupled in E. coli by the Mfd protein, which dissociates transcription elongation complexes blocked at nonpairing lesions and mediates recruitment of DNA repair proteins. We show that Mfd influences the elongation state of RNA polymerase (RNAP); transcription complexes that have reverse translocated into the backtracked position, a potentially important intermediate in RNA proofreading and repair, are restored to the forward position by the activity of Mfd, and arrested complexes are rescued into productive elongation. Mfd may act through a translocase activity that rewinds upstream DNA, leading either to translocation or to release of RNA polymerase when the enzyme active site cannot continue elongation.

Architectural requirements for optimal activation by tandem CRP molecules at a class I CRP-dependent promoter.

The Escherichia coli cyclic AMP receptor protein (CRP) activates transcription at target promoters by interacting with the C-terminal domain of the RNA polymerase alpha subunit. We have constructed a set of promoters carrying tandem DNA sites for CRP with one site centred at position -61.5 and the other site located at different upstream positions. Optimal CRP-dependent activation of transcription is observed when the upstream DNA site for CRP is located at position -93.5 or at position -103.5. Evidence is presented to suggest that activation by the upstream-bound CRP molecule is due to interaction with the C-terminal domain of the RNA polymerase alpha subunit.

Transcription Termination: Primary Intermediates and Secondary Adducts

In living organisms, stable elongation complexes of RNA polymerase dissociate at specific template positions in a process of transcription termination. It has been suggested that the dissociation is not the immediate cause of termination but is preceded by catalytic inactivation of the elongation complex. In vitro reducing ionic strength can be used to stabilize very unstable and catalytically inactive complex at the point of termination; the previous biochemical characterization of this complex has led to important conclusions regarding termination mechanism. Here we analyze in detail the complexes formed between DNA template, nascent RNA, and Escherichia coli RNA polymerase during transcription through the tR2 terminator of bacteriophage lambda. At low ionic strength, the majority of elongation complexes fall apart upon reaching the terminator. Released RNA and DNA efficiently rebind RNA polymerase (RNAP) and form binary RNAP.RNA and RNAP.DNA complexes, which are indistinguishable from binary complexes obtained by direct mixing of the purified nucleic acids and the enzyme. A small fraction of elongation complexes that reach termination point escapes dissociation because RNA polymerase has backtracked from the terminator to an upstream DNA position. Thus, transcription elongation to a terminator site produces no termination intermediates that withstand dissociation in the time scale appropriate for biochemical studies.

Architectural requirements for optimal activation by tandem CRP molecules at a class I CRP-dependent promoter

The Escherichia coli cyclic AMP receptor protein (CRP) activates transcription at target promoters by interacting with the C-terminal domain of the RNA polymerase α subunit. We have constructed a set of promoters carrying tandem DNA sites for CRP with one site centred at position −61.5 and the other site located at different upstream positions. Optimal CRP-dependent activation of transcription is observed when the upstream DNA site for CRP is located at position −93.5 or at position −103.5. Evidence is presented to suggest that activation by the upstream-bound CRP molecule is due to interaction with the C-terminal domain of the RNA polymerase α subunit.

Identification of two middle promoters upstream DNA ligase gene 30 of bacteriophage T4

Bacteriophage T4 DNA ligase gene 30 lies in the cluster of prereplicative genes located counterclockwise from map units 149 to 121. Based on the early transcription studies this gene has been considered as a typical early gene of bacteriophage T4. In agreement with this assignment, two strong T4 early promoters, P E 30.8 (128.6) and P E 30.7 (128.2), located about 3.1 and 2.7 kb upstream from gene 30 have been revealed by promoter mapping and sequence analysis. In addition, the existence of a putative early promoter just upstream of gene 30 was proposed from the sequence data. However, here we show that the putative early promoter just upstream of gene 30 is, in fact, a T4 middle promoter. Furthermore, we detected one more middle promoter located in the genomic region between early promoter P E 30.7 (128.2) and DNA ligase gene 30 in the coding region of gene 30.3. Both new middle promoters have differences from the consensus MotA box, while their −10 regions match the σ 70 consensus sequence very well. The 5′ ends of MotA-dependent transcripts directed from these promoters, as well as the kinetics of 5′ end accumulation in the cells, have been determined by primer extension analysis. The results of these analyses indicate that both MotA-dependent and MotA-independent promoters control the transcription of T4 DNA ligase gene 30 in vivo. Moreover, we show that the first transcripts for gene 30 are directed from its own middle promoter, P M 30.

Genomic organization of the gene that encodes the precursor to EGF-related peptides, exogastrula-inducing peptides, of the sea urchin Anthocidaris crassispina

Exogastrula-inducing peptides (EGIPs) were identified in embryos of the sea urchin Anthocidaris crassispina as polypeptides with structural similarity to epidermal growth factor (EGF) that severely affect gastrulation of sea urchin embryos to induce exogastrulation. Here we have obtained genomic clones for the EGIP precursor gene ( EGIP) and determined its genomic organization. The EGIP gene spans the length of 9 kb in the genome and is composed of seven exons and six introns. Each of the four EGF motifs in the precursor protein is encoded by a single exon, and all the exon boundaries are in phase 1, suggesting that EGIP have been generated during evolution by duplication of an exon encoding a single ancient EGIP sequence. The 5′-flanking sequence of EGIP from −4372 to +194 revealed the presence of multiple repeat sequences including direct and inverted repeats as well as two clusters of GGGG/CCCC elements. The function of the upstream flanking region of EGIP was examined by introducing the gene constructs into embryos in which different regions from the flanking DNA were placed upstream to the GFP reporter gene. Systematic deletion of the upstream DNA revealed the presence of potent enhancer activity between −372 and −210.

Cyp6a8 of Drosophila melanogaster: gene structure, and sequence and functional analysis of the upstream DNA

In Drosophila, the insecticide resistant 91-R strain is an overproducer and susceptible 91-C and ry 506 strains are the underproducers of CYP6A8 mRNA encoded by a cytochrome P450 gene, Cyp6a8. Low expression of Cyp6a8 in the underproducer strains is due to a downregulatory effect of a putative repressor locus, which is thought to be mutant in the overproducer strain [ Maitra, S. et al., Gene 269 (2000), 147-156]. In the present investigation, organization of Cyp6a8 and promoter activity of its upstream DNA were analyzed. Cyp6a8 has two introns of which intron II is similar to the introns of other insect CYP genes with respect to its length and position. Intron I is only 36 bp long and lacks consensus splice sites. It is also in-frame with the CYP6A8 open reading frame. Therefore, inefficient splicing of intron I may produce two isoforms of CYP6A8. Analysis of Cyp6a8 upstream DNA of the overproducer 91-R strain showed that DNA sequences between −199 and −761 bp are required for the highest constitutive and barbital-induced expression of Cyp6a8. This region has six barbie boxes and binding sites for various transcription factors. Promoter activity of the −11/−761 DNA of the overproducer 91-R strain was found to be 4-fold lower in the genome of underproducer ry 506 strain, which is wild type for the putative repressor gene, than in the genome of F1 hybrids of 91-R and ry 506 strains. These results suggest that –11/-761 Cyp6a8 DNA of the 91-R strain can respond to the active repressor present in the hybrid genome and further support our previous findings that overexpression of Cyp6a8 is a result of mutation of a repressor gene rather than mutation of the cis-regulatory sequences.