A DNA structural atlas for Escherichia coli.

We have performed a computational analysis of DNA structural features in 18 fully sequenced prokaryotic genomes using models for DNA curvature, DNA flexibility, and DNA stability. The structural values that are computed for the Escherichia coli chromosome are significantly different from (and generally more extreme than) that expected from the nucleotide composition. To aid this analysis, we have constructed tools that plot structural measures for all positions in a long DNA sequence (e.g. an entire chromosome) in the form of color-coded wheels (http://www.cbs.dtu. dk/services/GenomeAtlas/). We find that these "structural atlases" are useful for the discovery of interesting features that may then be investigated in more depth using statistical methods. From investigation of the E. coli structural atlas, we discovered a genome-wide trend, where an extended region encompassing the terminus displays a high of level curvature, a low level of flexibility, and a low degree of helix stability. The same situation is found in the distantly related Gram-positive bacterium Bacillus subtilis, suggesting that the phenomenon is biologically relevant. Based on a search for long DNA segments where all the independent structural measures agree, we have found a set of 20 regions with identical and very extreme structural properties. Due to their strong inherent curvature, we suggest that these may function as topological domain boundaries by efficiently organizing plectonemically supercoiled DNA. Interestingly, we find that in practically all the investigated eubacterial and archaeal genomes, there is a trend for promoter DNA being more curved, less flexible, and less stable than DNA in coding regions and in intergenic DNA without promoters. This trend is present regardless of the absolute levels of the structural parameters, and we suggest that this may be related to the requirement for helix unwinding during initiation of transcription, or perhaps to the previously observed location of promoters at the apex of plectonemically supercoiled DNA. We have also analyzed the structural similarities between groups of genes by clustering all RNA and protein-encoding genes in E. coli, based on the average structural parameters. We find that most ribosomal genes (protein-encoding as well as rRNA genes) cluster together, and we suggest that DNA structure may play a role in the transcription of these highly expressed genes.

Pedersen AG ，Jensen LJ ，Brunak S ，Staerfeldt HH ，Ussery DW ... -  《JOURNAL OF MOLECULAR BIOLOGY》

Curved DNA in promoter sequences.

Gabrielian AE ，Landsman D ，Bolshoy A 《-》

The G+C-rich discriminator region of the tyrT promoter antagonises the formation of stable preinitiation complexes.

RNA polymerase forms a highly stable preinitiation complex at many prokaryotic promoters in the absence of ribonucleotides. These are often characterised by the longevity of the DNA strand-separated (open) complex in the presence of heparin. In contrast, such complexes are notoriously unstable at the promoters for rRNA and tRNA under similar conditions. The high G+C content within the DNA-melting region of these promoters has been implicated in this seemingly anomalous behaviour. Here, we used rapid-pulse UV laser photo-footprinting to monitor the transient structural intermediates formed at the Escherichia coli tyrT promoter. Promoter derivatives with A+T for G/C base substitutions within the G+C-rich discriminator region (-7 to -1) augmented the stability of complexes on both linear fragments and supercoiled plasmid DNA. Analysis of the lifetime of the preinitiation complexes as a function of the discriminator sequence reveals a direct relationship between the A+T content of the DNA-melting region and the stability of the ensuing complex. Our results are consistent with the premise that a G/C block to DNA-untwisting and/or DNA-melting operates to prevent the formation of the stable isomers that are implicated in most other transcription initiation pathways.

Pemberton IK ，Muskhelishvili G ，Travers AA ，Buckle M ... -  《JOURNAL OF MOLECULAR BIOLOGY》

The effect of the DNA conformation on the rate of NtrC activated transcription of Escherichia coli RNA polymerase.sigma(54) holoenzyme.

The transcription activator protein NtrC (nitrogen regulatory protein C) can catalyze the transition of Escherichia coli RNA polymerase complexed with the sigma 54 factor (RNAP.sigma(54)) from the closed complex (RNAP.sigma(54) bound at the promoter) to the open complex (melting of the promoter DNA). This process involves phosphorylation of NtrC (NtrC-P), assembly of an octameric NtrC-P complex at the enhancer sequence, interaction of this complex with promoter-bound RNAP.sigma(54) via DNA looping, and hydrolysis of ATP. We have used this system to study the influence of the DNA conformation on the transcription activation rate in single-round transcription experiments with superhelical plasmids as well as linearized templates. Most of the templates had an intrinsically curved DNA sequence between the enhancer and the promoter and differed with respect to the location of the curvature and the distance between the two DNA sites. The following results were obtained: (i) a ten- to 60-fold higher activation rate was observed with the superhelical templates as compared to the linearized conformation; (ii) the presence of an intrinsically curved DNA sequence increased the activation rate of linear templates about five times; (iii) no systematic effect for the presence and/or location of the inserted curved sequence was observed for the superhelical templates. However, the transcription activation rate varied up to a factor of 10 between some of the constructs. (iv) Differences in the distance between enhancer and promoter had little effect for the superhelical templates studied. The results were compared with theoretical calculations for the dependence of the contact probability between enhancer and promoter expressed as the molar local concentration j(M). A correlation of j(M) with the transcription activation rate was observed for values of 10(-8) M<j(M)<10(-6) M and a kinetic model for NtrC-P-catalyzed open complex formation was developed.

Schulz A ，Langowski J ，Rippe K 《JOURNAL OF MOLECULAR BIOLOGY》

Effect of DNA structural flexibility on promoter strength--molecular dynamics studies of E. coli promoter sequences.

Thiyagarajan S ，Rajan SS ，Gautham N 《BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS》