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The structure and properties of ternary complexes of RNA polymerase are of central importance in understanding the mechanisms of transcriptional elongation and termination, and the regulation of these primary steps in gene expression. However, there has been no systematic study of the structure and properties of such complexes along a single transcription unit. Recently, we have described the isolation of a collection of halted ternary complexes of Escherichia coli RNA polymerase bearing transcripts from 11 to 35 nucleotides in length along two different transcription units (accompanying paper). Here, we report structural studies of these complexes using DNase I footprinting. Surprisingly, nearly all of the different ternary complexes have distinctly different footprints along the two DNA strands, and the position of the footprint relative to the 3' end of the transcript also varies for most complexes. Halted complexes bearing transcripts of comparable size do not have identical footprints; hence, DNA sequence as well as transcript length plays a role in determining the size and position of the footprint. These differences in structure are consistent with our earlier findings that ternary complexes can differ considerably in stability and gel mobility. The downstream boundary of the RNA polymerase in ternary complexes does not move forward regularly as successive nucleotide residues are added to the RNA chain. In contrast, the upstream boundary moves forward more or less in concert with the movement of the 3' terminus of the transcript. These factors lead to a general compression of the overall footprint as transcription proceeds, together with a steady movement of the 3' terminus of the RNA toward the downstream boundary of the polymerase. Ultimately, after the length of the RNA transcript has increased from eight to ten nucleotides, the downstream boundary of the complex is found to move downstream along the DNA, suggesting a translocation event. We suggest that RNA chain elongation, like RNA chain initiation, may involve a saltatory process in which net translocation of the complex along the DNA occurs only after addition of a number of ribonucleotides to the RNA chain.
J Mol Biol 1992 May 20
PMID:Structural analysis of ternary complexes of Escherichia coli RNA polymerase. Deoxyribonuclease I footprinting of defined complexes. 159 19

Mutations (base changes) were introduced into the four DnaA binding sites (DnaA boxes) of the Escherichia coli replication origin, oriC. Mutations in a single DnaA box did not impair the ability of these origins to replicate in vivo and in vitro. A combination of mutations in two DnaA boxes, R1 and R4, resulted in slower growth of the oriC plasmid-bearing host cells. DnaA protein interaction with mutant and wild-type DnaA boxes was analyzed by DNase I footprinting. Binding of DnaA protein to a mutated DnaA box R1 was not affected by a mutation in DnaA box R4 and vice versa. Mutations in DnaA boxes R1 and R4 did not modify the ability of the DnaA protein to bind to other DnaA boxes in oriC.
Mol Gen Genet 1992 May
PMID:Mutations in the DnaA binding sites of the replication origin of Escherichia coli. 160 77

The D,L-nicotine catabolism of the Gram-positive soil bacterium Arthrobacter oxidans is linked to the presence within the cells of the 160 kb catabolic plasmid pAO1. pAO1-cured cells lost the catabolic enzymes and reintroduction of pAO1 by electroporation into cured cells reestablished the nic+ phenotype. DNA band shift assays with extracts from cured and pAO1+ cells suggested that pAO1 encodes the regulatory protein NicR1. Footprint analysis revealed that two homologous palindromes (IR1 and IR2), present in the 5'-regulatory region of the 6-HDNO gene, were protected from DNase I digestion. Binding of NicR1 to the palindromes is symmetrical, co-operative, and stronger to IR1 containing the 6-HDNO gene promoter than to IR2. Site-directed mutagenesis revealed that steric constraints and sequence requirements for NicR1-binding are located exclusively in the palindromic sequences. Deletions and insertions in the interpalindromic region and in the 6-HDNO promoter -10 sequence had no effect on the binding characteristics of NicR1 to the 6-HDNO regulatory region. Acting as a repressor, NicR1 prevents binding of the E. coli RNA-polymerase to the consensus sigma 70 promoter in vitro. However, the interaction of NicR1 with the 6-HDNO promoter region in extracts of nicotine-induced cells from various growth stages did not differ from that observed with extracts of nicotine-uninduced cells.
Mol Microbiol 1992 Jul
PMID:Interaction of the regulatory protein NicR1 with the promoter region of the pAO1-encoded 6-hydroxy-D-nicotine oxidase gene of Arthrobacter oxidans. 163 Mar 18

We show that the DNA-binding domain of the Drosophila melanogaster regulatory protein Tramtrack consists of a 66 amino acid sequence containing two zinc-finger motifs and a short sequence N-terminal to the first finger motif. This short N-terminal sequence is essential for DNA binding and we suggest it is involved in maintaining the three-dimensional structure of the first finger domain, as has been seen in the nuclear magnetic resonance structure of one of the zinc-finger domains of the yeast transcription factor SW15. The characterization of the DNA-binding activity of this 66 residue peptide (delta 911zf) shows that it binds in a sequence-specific manner, as a monomer, to a natural target site with an apparent KD approximately 4 x 10(-7) M. The shortest delta 911zf binding site, which retains full affinity, consists of an 11 base-pair sequence with a one nucleotide overhang at each 5' end. DNase I, hydroxyl radical and methylation protection footprinting studies show that, in common with other zinc-finger proteins, delta 911zf binds in the major groove of DNA. The data presented are consistent with the zinc-fingers of Tramtrack contacting both strands of the DNA, and thus the binding differs in detail to that observed in the crystal structure of the three zinc-fingers of Zif268 complexed to their target DNA.
J Mol Biol 1992 Jul 20
PMID:Sequence-specific DNA binding by a two zinc-finger peptide from the Drosophila melanogaster Tramtrack protein. 164 Apr 55

The 12 genes which in E. coli K-12 constitute the arginine regulon are organized in nine transcriptional units all of which contain in their 5' non-coding region two 18 bp partially conserved imperfect palindromes (ARG boxes) which are the target sites for binding of the repressor, a hexameric protein. In vitro binding experiments with purified repressor (a gift from W. K. Maas) were performed on the operator sites of four genes, argA, argD, argF, argG, and of two operons, carAb and the bipolar argECBH cluster. A compilation of results obtained by DNase I and hydroxyl radical footprinting clearly indicates that in each case the repressor binds symmetrically to four helical turns covering adjacent pairs of boxes separated by 3 bp, but to one face of the DNA only. Methylation protection experiments bring to light major base contacts with four highly conserved G residues symmetrically distributed in four consecutive major grooves. Symmetrical contacts in the minor groove with A residues have also been identified. Stoichiometry experiments suggest that a single hexameric repressor molecule binds to a pair of adjacent ARG boxes. Although the wild-type operator consists of a pair of adjacent ARG boxes separated by 3 bp (except argR where there are only 2 bp), repressor can bind to a single box but with a greatly reduced affinity. Therefore, adjacent boxes behave co-operatively with respect to the Arg repressor binding, in the sense that the presence of one box largely stimulates the binding of the properly located second box. The optimal distance separating two boxes is 3 bp, but one bp more or less does not abolish this stimulation effect. However, it is completely abolished by the introduction of two or more additional bp unless a full helical turn is introduced. Large variations in the in vivo repression response between individual arginine genes or a wild-type gene and cognate Oc type mutants are not reflected by similar differences in the in vitro binding results where only small differences are observed. The significance of this lack of correlation is discussed.
J Mol Biol 1992 Jul 20
PMID:Arginine regulon of Escherichia coli K-12. A study of repressor-operator interactions and of in vitro binding affinities versus in vivo repression. 164 Apr 56

In the arginine regulon of Escherichia coli K12 each of the eight operator sites consists of two 18-base-pair-long palindromic sequences called ARG boxes. In the operator sites for the structural genes of the regulon the two ARG boxes are separated by three base-pairs, in the regulatory gene argR they are separated by two base-pairs. The hexameric arginine repressor, the product of argR, binds to the two ARG boxes in an operator in the presence of L-arginine. From the results of various kinds of in vitro footprinting experiments with the ARG boxes of argF and argR (DNase I protection, hydroxyl radical, ethylation and methylation interference, methylation protection) it can be concluded that: (1) the repressor binds simultaneously to two adjacent ARG boxes; (2) that it binds on one face of the double helix; and (3) that it forms contacts with the major and minor grooves of each ARG box, but not with the central three base-pairs. The repressor can bind also to a single ARG box, but its affinity is about 100-fold lower than for two ARG boxes. From gel retardation experiments with 3H-labeled repressor and 32P-labeled argF operator DNA, it is concluded that the retarded DNA-protein complex contains no more than one repressor molecule per operator site and that most likely one hexamer binds to two ARG boxes. The bound repressor was shown to induce bending of argF operator DNA. The bending angle calculated from the results of gel retardation experiments is about 70 degrees and the bending center was located within the region encompassing the ARG boxes. The main features that distinguish the arginine repressor from other repressors studied in E. coli are its hexameric nature and the simultaneous binding of one hexameric molecule to two palindromic ARG boxes that are close to each other.
J Mol Biol 1992 Jul 20
PMID:Binding of the arginine repressor of Escherichia coli K12 to its operator sites. 164 Apr 57

There is a 36 bp tract of extreme homopurine/homopyrimidine (PuPy) asymmetry in the maize Adh1 gene promoter (from -44 to -79) that is S1-hypersensitive in plasmids under supercoil tension. Oligodeoxynucleotides corresponding to the PuPy tract were designed to examine the secondary structure of the region and address the possible role of the tract in gene regulation. On the basis of oligodeoxynucleotide band-shift and DNase I footprinting analyses, it was concluded that the homopyrimidine oligodeoxynucleotide can form a triple helix with the duplex PuPy tract in vitro. Transient assays in protoplasts, suspension cells, and seedling roots show that the homopyrimidine oligodeoxynucleotide is also capable of repressing Adh1-GUS gene expression during co-transformation, presumably by the formation of a triple helix with the PuPy tract in vivo. The complementary homopurine oligodeoxynucleotide would not form a triple helix in vitro, nor would it repress Adh1-GUS in vivo. We propose that triple helix formation is a potential regulatory phenomenon in vivo, and that an intraregion triple helix could occur within the Adh1 promoter via the formation of H-DNA.
Plant Mol Biol 1992 Aug
PMID:Site-specific oligodeoxynucleotide binding to maize Adh1 gene promoter represses Adh1-GUS gene expression in vivo. 164 78

A region upstream from the Escherichia coli rrnB P1 promoter, the upstream activator region (UAR), increases the activity of the promoter in vivo and the rate of association with RNA polymerase (E sigma 70) in vitro in the presence of the two initiating nucleotides. We have used four types of chemical and enzymatic footprinting probes to determine whether rrnB P1-E sigma 70 complexes formed in the presence of the initiating nucleotides (RPinit) differ from typical open complexes (RPo) formed in the absence of the initiating nucleotides and to examine the structural differences between rrnB P1 complexes containing the UAR and those lacking the UAR. We find that the rrnB P1-RPinit complex closely resembles open complexes formed at other E sigma 70 promoters, indicating that the formation of the first phosphodiester bond does not result in a major rearrangement of the promoter-RNA polymerase complex. An unusual potassium permanganate modification at position -18 in both RPo and RPinit indicates the possible presence of a subtle difference in the -10, -35 spacer structure compared to some other E. coli promoters. We show that the E sigma 70-rrnB P1 complex formed with the promoter containing the UAR has DNase I and hydroxyl radical cleavage patterns in the -50 region different from those observed with the same promoter lacking the UAR. These results are interpreted to indicate that E sigma 70 may interact with a region further upstream from that contacted by RNA polymerase bound at most other promoters and/or that unusual structural properties of this region are induced by bound E sigma 70.
J Mol Biol 1991 Aug 05
PMID:Factor-independent activation of Escherichia coli rRNA transcription. II. characterization of complexes of rrnB P1 promoters containing or lacking the upstream activator region with Escherichia coli RNA polymerase. 165 94

We have charted the movements of E sigma 32 RNA polymerase at the heat-shock promoter PgroE throughout open complex formation, using hydroxyl radical footprinting. In combination with methylation protection and DNase I experiments, these data suggest the following model for open complex formation. E sigma 32 initially anchors itself in the upstream region of the promoter forming the first closed complex, RPC1; in this complex the enzyme makes backbone contacts in the -35 region of the promoter that are maintained throughout open complex formation. An isomerization follows resulting in a second closed complex, RPC2; in this complex the enzyme makes base-specific and backbone contacts in the -10 region that are almost identical to those found in the open complex. Thus, at the groE promoter, upstream contacts are established in RPC1 and downstream contacts in RPC2. A similar pattern of backbone contacts was obtained for E sigma 32 bound in the open complex at two additional heat-shock promoters, suggesting that the overall topology of holoenzyme in the open complex is similar regardless of sequence variations in the promoter.
J Mol Biol 1991 Aug 05
PMID:Development of RNA polymerase-promoter contacts during open complex formation. 165 95

Dioxin stimulates transcription from the cytochrome P-450IA1 promoter by interaction with the intracellular dioxin receptor. Upon binding of ligand, the receptor is converted to a form which specifically interacts in vitro with two dioxin-responsive positive control elements located in close proximity to each other about 1 kb upstream of the rat cytochrome P-450IA1 gene transcription start point. In rat liver, the cytochrome P-450IA1 gene is marked at the chromatin level by two DNase I-hypersensitive sites that map to the location of the response elements and exist prior to induction of transcription by the dioxin receptor ligand beta-naphthoflavone. In addition, a DNase I-hypersensitive site is detected near the transcription initiation site and is altered in nuclease sensitivity by induction. The presence of the constitutive DNase I-hypersensitive sites at the dioxin response elements correlates with the presence of a constitutive, labile factor which specifically recognizes these elements in vitro. This factor appears to be distinct from the dioxin receptor, which is observed only in nuclear extract from treated cells. In conclusion, these data suggest that a certain protein-DNA architecture may be maintained at the response elements at different stages of gene expression.
Mol Cell Biol 1991 Sep
PMID:Liver cells contain constitutive DNase I-hypersensitive sites at the xenobiotic response elements 1 and 2 (XRE1 and -2) of the rat cytochrome P-450IA1 gene and a constitutive, nuclear XRE-binding factor that is distinct from the dioxin receptor. 165 54


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