E. coli promoter spacer regions contain nonrandom sequences which correlate to spacer length

Identification of cis-acting elements upstream of regR gene in streptococcus pneumoniae

The identification and characterization of functional cis-acting elements is of fundamental importance for comprehending the regulatory mechanisms of gene transcription and bacterial pathogenesis. The transcription factor RegR has been demonstrated to control both competence and virulence in Streptococcus pneumoniae. Despite the clear contribution of RegR to these pathways, the mechanisms underlying its transcriptional regulation remain poorly understood. In this study, we conducted mutational analysis, gene dissection and luciferase activity assays to characterize the cis-elements situated upstream of the regR gene. Our findings revealed that a 311 bp 3'-terminal DNA sequence of the spd0300 gene represents a central region of the upstream cis-acting element of regR. Further investigations identified two structurally similar enhancer-like sequences within this region which feature prominently in the regulation of regR transcription. Furthermore, employing DNA pull-down assays allowed us to enrich the trans-acting factors with the potential to interact with these cis-acting elements. Notably, we found that the competence regulator ComE was implicated in the regulation of regR transcription, a finding which was corroborated by electrophoretic mobility shift assays (EMSA) and quantitative real-time PCR analyses (qRT-PCR). Taken together, our data thus provide fresh insight into the transcriptional regulation of regR.

The Context-Dependent Influence of Promoter Sequence Motifs on Transcription Initiation Kinetics and Regulation

The fitness of an individual bacterial cell is highly dependent upon the temporal tuning of gene expression levels when subjected to different environmental cues. Kinetic regulation of transcription initiation is a key step in modulating the levels of transcribed genes to promote bacterial survival. The initiation phase encompasses the binding of RNA polymerase (RNAP) to promoter DNA and a series of coupled protein-DNA conformational changes prior to entry into processive elongation. The time required to complete the initiation phase can vary by orders of magnitude and is ultimately dictated by the DNA sequence of the promoter. In this review, we aim to provide the required background to understand how promoter sequence motifs may affect initiation kinetics during promoter recognition and binding, subsequent conformational changes which lead to DNA opening around the transcription start site, and promoter escape. By calculating the steady-state flux of RNA production as a function of these effects, we illustrate that the presence/absence of a consensus promoter motif cannot be used in isolation to make conclusions regarding promoter strength. Instead, the entire series of linked, sequence-dependent structural transitions must be considered holistically. Finally, we describe how individual transcription factors take advantage of the broad distribution of sequence-dependent basal kinetics to either increase or decrease RNA flux.

Interaction of Escherichia coli RNA polymerase with artificial promoters, containing nonnucleotide spacers

To study the functional role of the spacer region between two consensus -10 and -35 elements of promoters, recognized by E. coli RNA polymerase, the model promoter-like DNA duplexes containing nonnucleotide inserts (mimicking 17-mer spacer) either in one or both strands, were constructed. The modified duplexes can form the heparin-resistant binary complexes with RNA polymerase. The DNA duplex with nonnucleotide insert in the template strand can specifically direct the synthesis of mRNA in the in vitro run-off transcription assays.

Promoter spacer DNA plays an active role in integrating the functional consequences of RNA polymerase contacts with -10 and -35 promoter elements

Bacterial RNA polymerase (RNAP) interacts with conserved -10 and -35 promoter elements to recognize the promoter and to form an open complex in which DNA duplex around transcription start site melts. Using model DNA constructs (fork junction DNA) that mimic DNA structure found in the open complex we observed that the consequences of mutations in -10 promoter element for RNAP binding exhibited a striking dependence on the presence or absence of a functional -35 promoter element. A role of spacer DNA (a non-conserved DNA sequence connecting -10 and -35 promoter elements) in this phenomenon was probed with a series of fork junction DNA constructs containing perturbations to the spacer DNA. In the absence of a physical connection between the -10 and -35 DNA elements, or when -10 and -35 DNA elements were connected by a long flexible non-DNA linker, the dependence of RNAP interactions with -10 element on the strength of -35 element was lost. When these DNA elements were linked by a rigid DNA duplex or by a DNA duplex containing a short single-stranded gap, the coupling between the -10 and -35 binding activities was observed. These results indicated that promoter spacer DNA played an active role in integrating the functional consequences of RNA polymerase contacts with -10 and -35 promoter element. This role likely involves physical deformation of the spacer occurring in parallel with promoter melting as shown by Fluorescence Resonance Energy Transfer (FRET) experiments with the probes incorporated into spacer DNA.

Nature of the promoter activated by C.PvuII, an unusual regulatory protein conserved among restriction-modification systems

A widely distributed family of small regulators, called C proteins, controls a subset of restriction-modification systems. The C proteins studied to date activate transcription of their own genes and that of downstream endonuclease genes; this arrangement appears to delay endonuclease expression relative to that of the protective methyltransferase when the genes enter a new cell. C proteins bind to conserved sequences called C boxes. In the PvuII system, the C boxes have been reported to extend from -23 to +3 relative to the transcription start for the gene for the C protein, an unexpected starting position relative to a bound activator. This study suggests that transcript initiation within the C boxes represents initial, C-independent transcription of pvuIICR. The major C protein-dependent transcript appears to be a leaderless mRNA starting farther downstream, at the initiation codon for the pvuIIC gene. This conclusion is based on nuclease S1 transcript mapping and the effects of a series of nested deletions in the promoter region. Furthermore, replacing the region upstream of the pvuIIC initiation codon with a library of random oligonucleotides, followed by selection for C-dependent transcription, yielded clones having sequences that resemble -10 promoter hexamers. The -35 hexamer of this promoter would lie within the C boxes. However, the spacing between C boxes/-35 and the apparent -10 hexamer can be varied by +/-4 bp with little effect. This suggests that, like some other activator-dependent promoters, PpvuIICR may not require a -35 hexamer. Features of this transcription activation system suggest explanations for its broad host range.

Flexible elements in the structure of promoter DNA as probed by cationic surfactant binding

A susceptibility of promoter DNA for adaptive conformational transitions has been studied using a cationic surfactant dodecyltrimethylammonium bromide (C(12)TAB) as a model DNA-binding ligand. DNAse 1 and KMnO(4) were utilized as structure-specific reagents. Both reagents revealed ligand-induced perturbations in the double helix of promoters T7A1 and T7D. These conformational transitions appeared to be strongly associated with pyrimidine-purine steps, which have non-random distribution within RNA polymerase contact region of the promoter DNA and are present in the binding sites for a majority of transcription regulation proteins. Potential flexibility of these elements creates therefore a specific media for transcription complex formation. Molecular mechanism of DNA interaction with C(12)TAB is discussed.

A plasmid vector for isolation of strong promoters in Escherichia coli

In order to isolate very strong promoters from bacteria and bacteriophage a plasmid named pProm was constructed. It possesses an origin (ORI) for replication in Gram-negative bacteria, an ORI for replication in Gram-positive bacteria, a promoterless ampicillin resistance gene with a multiple cloning site (MCS) in the position formerly occupied by the ampicillin promoter, a tetracycline resistance gene for selection in Gram-negative bacteria and a chloramphenicol resistance gene for selection in Gram-positive bacteria. Insertion in the MCS of DNA fragments of Staphylococcus aureus bacteriophages resulted in isolation of several clones very resistant to ampicillin. The DNA fragments inserted in these recombinant plasmids were sequenced and all of them contained putative promoter motifs. Direct measurement of the penicillinase activity indicated that one of the isolated promoters could be included within a group of the stronger known prokaryotic promoters. According to these results pProm is a powerful tool to perform studies on promoter strength and for industrial applications.

Non-canonical sequence elements in the promoter structure. Cluster analysis of promoters recognized by Escherichia coli RNA polymerase

Nucleotide sequences of 441 promoters recognized by Escherichia coli RNA polymerase were subjected to a site-specific cluster analysis based on the hierarchical method of classification. Five regions permitting promoter subgrouping were identified. They are located at -54 +/- 4, -44 +/- 3, -35 +/- 3 (-35 element), -29 +/- 2 and -11 +/-4 (-10 element). Promoters were independently subgrouped on the basis of their sequence homology in each of these regions and typical sequence elements were determined. The putative functional significance of the revealed elements is discussed on the basis of available biochemical data. Those promoters that have a high degree of homology with the revealed sequence elements were selected as representatives of corresponding promoter groups and the presence of other sequence motifs in their structure was examined. Both positive and negative correlations in the presence of particular sequence motifs were observed; however, the degree of these interdependencies was not high in all cases, probably indicating that different combinations of the signal elements may create a promoter. The list of promoter sequences with the presence of different sequence elements is available on request by Email: ozoline@venus.iteb. serpukhov.su.

Structure of open promoter complexes with Escherichia coli RNA polymerase as revealed by the DNase I footprinting technique: compilation analysis

Footprinting data for 33 open promoter complexes with Escherichia coli RNA polymerase, as well as 17 ternary complexes with different regulators, have been compiled using a computer program FUTPR. The typical and individual properties of their structural organization are analyzed. Promoters are subgrouped according to the extent of the polymerase contact area. A set of alternative sequence elements that could be responsible for RNA polymerase attachment in different promoter groups is suggested on the basis of their sequence homology near the hyperreactive sites. The model of alternative pathways used for promoter activation is discussed.

DNA sequences at and between the GC and TATA boxes: potential DNA looping and spatial juxtapositioning of the protein factors

Regulation of gene expression in eukaryotes involves a complex assembly of DNA recognition sequence elements and their respective protein factors. The upstream promoter/enhancer sequences are position and orientation independent. Despite their variable distances from the TATA box and transcription start site, interaction between the protein activators and TATA general transcription factors takes place, enabling induced levels of transcription initiation. Here the intervening sequences between the GC and TATA boxes are examined as functions of their lengths. Regardless of the substantial differences in the spacer sizes, similar mono and dinucleotide distributions are noted. Purine-purine base pair steps, except for AA, are more frequent at and near the GC box in the 5' ends of the loops than in their 3' ends. Pyrimidine-pyrimidine base pair steps, except for TT behave similarly. AT and TA (as well as AA and TT) are more frequent in the 3' ends of the loops near the TATA. Examination of these distributions, as well as of the sequences composing the GC and TATA boxes indicates that the DNA in the upstream part of the loop is more rigid, whereas the downstream regions are far more flexible. The flexibility of the general TATA region may afford correct spatial juxtapositioning of the proteins with respect to each other, enabling interactions between the activators and the general transcription factors.

The eukaryotic CCAAT and TATA boxes, DNA spacer flexibility and looping

Regulation of RNA transcription in eukaryotic polymerase II promoters involves a complex assembly of protein factors. Some of the factors bind to their cognate DNA-sequence elements while others mediate between the DNA bound ones. In order to enable protein-protein interaction, their spatial positioning with respect to each other is critical. Here two DNA-sequence-elements are investigated, the CCAAT and the TATA boxes and their spacers. Whereas the position of the TATA is fixed at about -30, that of the CCAAT can vary substantially from -50 to -200. Despite the variable loop sizes, the CTF (CCAAT-binding) protein interacts--either directly or indirectly via a co-activator--with the general basal TATA-binding transcription factors. Sequence analysis of the spacers, as a function of their sizes, reveals that in the upstream regions of the spacers RR and YY are abundant. In the downstream, 3' region of the spacers RY and YR are very frequent. The DNA sequence elements and their intervening spacers are analyzed in terms of their geometry, anisotropic flexibility and local superhelical density. Our results indicate that the CCAAT and its vicinity is rigid, whereas the TATA and its surroundings is flexible. It is the large flexibility of this region in twist and in roll which allows DNA looping. General mechanistic implications for pol II promoters are discussed.

Identification of the promoter region of the ribosome-releasing factor cistron (frr)

Previous studies of the structure and expression of the ribosome-releasing factor (RRF) cistron (frr) have suggested that an efficient promoter region is located in the RRF cistron. We report here on the nucleotide sequence and in vivo function of the RRF promoter. The transcriptional start site was determined by primer extension to be 58 bp upstream of the translational initiation codon of frr. The location of the RRF promoter region was confirmed by means of (i) deletion analysis of the 5' proximal sequences of frr fused to the chloramphenicol acetyltransferase reporter gene, (ii) analysis of RRF produced in vivo from the deletion derivatives of frr cloned into pUC19, and (iii) gel retardation analysis with Escherichia coli RNA polymerase. The -35 and -10 regions were TTacCc and TATAcT, respectively. The strength of the RRF promoter was similar to that of the lac promoter, as determined by in vivo expression of chloramphenicol acetyltransferase activity. However, the RRF promoter was not affected by the intracellular cyclic AMP level despite the presence of a cyclic AMP receptor protein binding site downstream of the RRF promoter.

Regulation of expression of the Escherichia coli K-12 mtr gene by TyrR protein and Trp repressor

The Escherichia coli K-12 mtr gene, which encodes a tryptophan-specific permease, was cloned, and its nucleotide sequence was determined. The precise location of the mtr gene at 69 min on the E. coli chromosome was determined. The mtr gene product was identified as a 414-amino-acid residue protein with a calculated molecular weight of 44,332. The protein is very hydrophobic, consistent with its presumed location spanning the cytoplasmic membrane. The initiation sites of transcription and translation were identified. Construction of an mtr-lacZ transcriptional fusion facilitated investigation of the molecular basis of mtr regulation. The TyrR protein in association with phenylalanine or tyrosine is responsible for the activation of mtr expression, whereas the Trp repressor in conjunction with tryptophan serves to repress expression of this gene. Site-directed mutagenesis confirmed that sequences in the mtr regulatory region homologous to TyrR protein and to Trp repressor-binding sites were involved in the activation and repression of mtr expression, respectively. Sequences homologous to sigma 70- and sigma 54-dependent promoters were identified upstream of the transcription start point of mtr. It was determined that transcription of mtr occurs only via a sigma 70-dependent promoter.

Training back-propagation neural networks to define and detect DNA-binding sites

A three layered back-propagation neural network was trained to recognize E. coli promoters of the 17 base spacing class. To this end, the network was presented with 39 promoter sequences and derivatives of those sequences as positive inputs; 60% A + T random sequences and sequences containing 2 promoter-down point mutations were used as negative inputs. The entire promoter sequence of 58 bases, approximately -50 to +8, was entered as input. The network was asked to associate an output of 1.0 with promoter sequence input and 0.0 with non-promoter input. Generally, after 100,000 input cycles, the network was virtually perfect in classifying the training set. A trained network was about 80% effective in recognizing 'new' promoters which were not in the training set, with a false positive rate below 0.1%. Network searches on pBR322 and on the lambda genome were also performed. Overall the results were somewhat better than the best rule-based procedures. The trained network can be analyzed both for its choice of base and relative weighting, positive and negative, at each position of the sequence. This method, which requires only appropriate input/output training pairs, can be used to define and search for any DNA regulatory sequence for which there are sufficient exemplars.