Identification of close contacts between the sigma N (sigma 54) protein and promoter DNA in closed promoter complexes.

The complexes forming between the alternative sigma factor protein sigma N (sigma 54), its holoenzyme and promoter DNA were analysed using the hydroxyl radical probe and by photochemical footprinting of bromouridine-substituted DNA. Close contacts between the promoter, sigma N and its holoenzyme appear to be restricted predominantly to one face of the DNA helix, extending from -31 to -5. They all appear attributable to sigma N and no extra close contacts from the core RNA polymerase subunits in the holoenzyme-promoter DNA complex were detected. We suggest that the apparent absence of close core RNA polymerase contacts in the region of the promoter DNA to be melted during open complex formation is important for maintaining the closed complex. Results of the hydroxyl radical footprinting imply that sigma N makes multiple DNA backbone contacts across and beyond the -12, -24 consensus promoter elements, and the photochemical footprints indicate that consensus thymidine residues contribute important major groove contacts to sigma N. Formation of the open complex is shown to involve a major structural transition in the DNA contacted by sigma N, establishing a direct role for sigma N in formation of the activated promoter complex.     

The DNA sequence at the T7 C promoter.

Restriction fragments of T7 DNA which selectively bind E. coli RNA polymerase have been identified. These include fragments located close to the beginning of gene 1 where according to Minkley and Pribnow (1973) there is a promoter called C. The smallest fragment from this region which binds RNA polymerase has been sequenced. It contains a promoter-like sequence, at an appropriate distance from the sequence TACA which Minkley and Pribnow suggested should lie at the initiation site of C. RNA synthesised in vitro from these fragments has been sequenced. The RNA sequence corresponds to the sequence to the right of the C promoter. The C promoter differs significantly from the A1 A2 and A3 promoters in sequence. Its structure and position suggest it plays a role in T7 infection.     

Interaction of Escherichia coli RNA-polymerase with DNA-duplexes containing repetitive sequences

Nitrocellulose filter binding technique has been used to study the binding of E. coli RNA polymerase to synthetic DNA duplexes (100-200 base pairs), containing the repeating fragments of promoters. It has been shown, that the duplex, containing the repeats of "ideal". Pribnow box forms heparin resistant complexes with enzyme, the stability of which is comparable with that of lacUV5 promoter complexes (the half life is approximately 200 min). The synthetic polynucleotide with repeating trp-promoter-operator sequence less stable complexes with RNA polymerase, the half life of which being 30 min.     

A study of unwinding of DNA and shielding of the DNA grooves by RNA polymerase by using methylation with dimethylsulphate.

The dimethylsulphate method has been used to study the complexes of RNA polymerase (Escherichia coli) with DNA of T7 phage, poly[d(A--T)] and fragments of calf thymus DNA protected against DNase digestion by RNA polymerase. The binding of RNA polymerase to DNA significantly increases the formation of 1-methyl-adenine produced by methylation of the single-stranded DNA region, diminishes by about 10% the formation of 3-methyl-adenine by methylation within the minor groove and does not affect the formation of 7-methyl-guanine by methylation within the major DNA groove. The presence of nascent RNA decreases the formation of 1-methyl-adenine in DNA of the complex by about 30%. The initiation of RNA synthesis or RNA synthesis itself does not influence the methylation of the major groove but shielding of the minor groove increases by about twice as much. These results suggest that RNA polymerase, upon binding, breaks Watson-Crick base-pairing in a DNA region of about 15-base-pairs long, that nascent RNA forms a duplex with DNA of about 10-base-pairs long; and that the enzyme weakly interacts with DNA along its grooves and preferentially makes contacts with the minor groove.     

Specific contacts between the bacteriophage T3, T7, and SP6 RNA polymerases and their promoters

The specificity and structural simplicity of the bacteriophage T3, T7, and SP6 RNA polymerases make these enzymes particularly well suited for studies of polymerase-promoter interactions. To understand the initial recognition process between the enzyme and its promoters, DNA fragments that carry phage promoters were chemically modified by three different methods: base methylation, phosphate ethylation, and base removal. The positions at which these modifications prevented or enhanced binding by the RNA polymerases were then determined. The results indicate that specific contacts within the major groove of the promoter between positions-5 and -12 are important for phage polymerase binding. Removal of individual bases from either strand of the initiation region (-5 to +3) resulted in enhanced binding of the polymerase, suggesting that disruption of the helix in this region may play a role in stabilization of the polymerase-promoter complexes.     

Structural basis of DNA recognition by the alternative sigma-factor, sigma54

The sigma subunit of bacterial RNA polymerase (RNAP) regulates gene expression by directing RNAP to specific promoters. Unlike sigma(70)-type proteins, the alternative sigma factor, sigma(54), requires interaction with an ATPase to open DNA. We present the solution structure of the C-terminal domain of sigma(54) bound to the -24 promoter element, in which the conserved RpoN box motif inserts into the major groove of the DNA. This structure elucidates the basis for sequence specific recognition of the -24 element, orients sigma(54) on the promoter, and suggests how the C-terminal domain of sigma(54) interacts with RNAP.     

Nucleotide sequence of the three major early promoters of bacteriophage T7.

I have determined the nucleotide sequences of the three major early promoters of bacteriophage T7 (A1, A2, A3). The sequences confirm the two main homologies found between other known promoters for E. coli RNA polymerase (nucleoside triphosphate:RNA nucleotidyl transferase, E.C. 2. 7. 7. 6). In particular, all three T7 promoters show a very good match with the -35 region homology; the A2 and A3 promoters share a 17 basepair sequence in this region. On the other hand, the match with the Pribnow Box homology is much less pronounced and different for each T7 promoter.     

A temperature dependent transition in the Pribnow box of the trp promoter

Proton NMR spectra of the trp operator-promoter (sequence CGTACTAGTT.AACTAGTACG) show selective changes in chemical shift and relaxation rates over the range of temperature 0-45 degrees C for the non-exchangeable protons of A11 and A12 only. These bases are in the centre of the Pribnow box. The changes imply that at least three conformational states become significantly populated in this range of temperature, and probably involve a change in the propellor twists of A11 and A12 for one transition, and changes in the helical twist and local pitch for the other. As (1) mutations in the Pribnow box that destroy the TAA sequence impair promoter activity, and (2) the abortive initiation assay for RNA polymerase shows a transition near 20 degrees C, we propose that the observed conformational transitions in the trp promoter are an essential feature of good promoters.     

Periodicity in contacts of RNA-polymerase with promotors]

Periodicities in the position of E.coli RNA polymerase promoter contacts on several promoters (lacUV5, T7 A3, tetR, lambda cin, lambda c17, RNA1, and trp S.t.) were found by means of Fourier analysis. The comparison of the Fourier spectrum of core RNA polymerase contacts on the lacUV5 promoter and that of holoenzyme revealed a more prominent 7-periodicity in the Fourier spectrum of holoenzyme contacts. 6-, 7-, and 8-periodicities were found in the primary structure of the majority of E.coli promoters. It is shown that RNA polymerase recognizes specific periodic patterns in the promoter structure.