RNA polymerase mutants defective in the initiation of transcription-coupled DNA repair.

The bacterial Mfd protein is a transcription-repair coupling factor that performs two key functions during transcription-coupled DNA repair. The first is to remove RNA polymerase (RNAP) complexes that have been stalled by a DNA lesion from the site of damage, and the second is to mediate the recruitment of DNA repair proteins. Mfd also displaces transcription complexes that have been stalled by protein roadblocks, and catalyses the reactivation of transcription complexes that have become 'backtracked'. We have identified amino acid substitutions in the beta subunit of Escherichia coli RNAP that disrupt a direct interaction between Mfd and RNAP. These substitutions prevent Mfd displacing stalled RNAP from DNA in vivo and in vitro. They define a highly conserved surface-exposed patch on the beta1 domain of RNAP that is required by Mfd for the initial step of transcription-coupled repair, the enhancement of roadblock repression and the reactivation of backtracked transcription complexes.

A DNA translocation motif in the bacterial transcription--repair coupling factor, Mfd.

The bacterial transcription-repair coupling factor, Mfd, is a superfamily II helicase that releases transcription elongation complexes stalled by DNA damage or other obstacles. Transcription complex displacement is an ATP-dependent reaction that is thought to involve DNA translocation without the strand separation associated with classical helicase activity. We have identified single amino acid substitutions within Mfd that disrupt the ability of Mfd to displace RNA polymerase but do not prevent ATP hydrolysis or binding to DNA. These substitutions, or deletion of the C-terminal 209 residues of Mfd, abrogate the ability of Mfd to increase the efficiency of roadblock repression in vivo. The substitutions fall in a region of Mfd that is homologous to the 'TRG' motif of RecG, a protein that catalyses ATP-dependent translocation of Holliday junctions. Our results define a translocation motif in Mfd and suggest that Mfd and RecG couple ATP hydrolysis to translocation of DNA in a similar manner.

UP element-dependent transcription at the Escherichia coli rrnB P1 promoter: positional requirements and role of the RNA polymerase alpha subunit linker.

The UP element stimulates transcription from the rrnB P1 promoter through a direct interaction with the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). We investigated the effect on transcription from rrnB P1 of varying both the location of the UP element and the length of the alpha subunit interdomain linker, separately and in combination. Displacement of the UP element by a single turn of the DNA helix resulted in a large decrease in transcription from rrnB P1, while displacement by half a turn or two turns totally abolished UP element-dependent transcription. Deletions of six or more amino acids from within the alpha subunit linker resulted in a decrease in UP element-dependent stimulation, which correlated with decreased binding of alphaCTD to the UP element. Increasing the alpha linker length was less deleterious to RNA polymerase function at rrnB P1 but did not compensate for the decrease in activation that resulted from displacing the UP element. Our results suggest that the location of the UP element at rrnB P1 is crucial to its function and that the natural length of the alpha subunit linker is optimal for utilisation of the UP element at this promoter.

Analysis of interactions between Activating Region 1 of Escherichia coli FNR protein and the C-terminal domain of the RNA polymerase alpha subunit: use of alanine scanning and suppression genetics.

Activating Region 1 of Escherichia coli FNR protein is proposed to interact directly with the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD) during transcription activation at FNR-regulated promoters. Using an alphaCTD alanine scan mutant library, we have identified the residues of alphaCTD that are important for FNR-dependent transcription activation. Residues Asp-305, Gly-315, Arg-317, Leu-318 and Asp-319 are proposed to be the key residues in the contact site on alphaCTD for Activating Region 1 of FNR. In previous work, it had been shown that Activating Region 1 of FNR is a large surface-exposed patch and that the two crucial amino acid residues are Thr-118 and Ser-187. In this work, we have constructed Arg-118 FNR and Arg-187 FNR and shown that both FNR derivatives are defective in transcription activation. However, the activity of FNR carrying Arg-118 can be partially restored by substitutions of Lys-304 in alphaCTD. Similarly, the activity of FNR carrying Arg-187 can be partially restored by substitutions of Arg-317 or Leu-318 in alphaCTD. The specificity of the restoration suggests that, during transcription activation by FNR, the side-chain of residue 118 in Activating Region 1 of FNR is located close to Lys-304 and Asp-305 in alphaCTD. Similarly, the side-chain of residue 187 in Activating Region 1 of FNR is located close to Arg-317 and Leu-318 in alphaCTD. These results can be used to model the interface between Activating Region 1 of FNR and its contact target in alphaCTD, and permit comparison of this interface with the interface between Activating Region 1 of the related transcription activator, CRP and alphaCTD.

The Escherichia coli RNA polymerase alpha subunit linker: length requirements for transcription activation at CRP-dependent promoters.

The C-terminal domain of the Escherichia coli RNA polymerase alpha subunit (alphaCTD) plays a key role in transcription initiation at many activator-dependent promoters. This domain is connected to the N-terminal domain by an unstructured linker, which is proposed to confer a high degree of mobility on alphaCTD. To investigate the role of this linker in transcription activation we tested the effect of altering the linker length on promoters dependent on the cyclic AMP receptor protein (CRP). Short deletions within the alpha linker decrease CRP-dependent transcription at a Class I promoter while increasing the activity of a Class II promoter. Linker extension impairs CRP-dependent transcription from both promoters, with short extensions exerting a more marked effect on the Class II promoter. Activation at both classes of promoter was shown to remain dependent upon activating region 1 of CRP. These results show that the response to CRP of RNA polymerase containing linker-modified alpha subunits is class specific. These observations have important implications for the architecture of transcription initiation complexes at CRP-dependent promoters.

Interactions between the Escherichia coli cAMP receptor protein and the C-terminal domain of the alpha subunit of RNA polymerase at class I promoters.

The Escherichia coli cAMP receptor protein (CRP) is a factor that activates transcription at over 100 target promoters. At Class I CRP-dependent promoters, CRP binds immediately upstream of RNA polymerase and activates transcription by making direct contacts with the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD). Since alphaCTD is also known to interact with DNA sequence elements (known as UP elements), we have constructed a series of semi-synthetic Class I CRP-dependent promoters, carrying both a consensus DNA-binding site for CRP and a UP element at different positions. We previously showed that, at these promoters, the CRP-alphaCTD interaction and the CRP-UP element interaction contribute independently and additively to transcription initiation. In this study, we show that the two halves of the UP element can function independently, and that, in the presence of the UP element, the best location for the DNA site for CRP is position -69.5. This suggests that, at Class I CRP-dependent promoters where the DNA site for CRP is located at position -61.5, the two alphaCTDs of RNA polymerase are not optimally positioned. Two experiments to test this hypothesis are presented.

Transcription activation at Class II CRP-dependent promoters: identification of determinants in the C-terminal domain of the RNA polymerase alpha subunit.

Many transcription factors, including the Escherichia coli cyclic AMP receptor protein (CRP), act by making direct contacts with RNA polymerase. At Class II CRP-dependent promoters, CRP activates transcription by making two such contacts: (i) an interaction with the RNA polymerase alpha subunit C-terminal domain (alphaCTD) that facilitates initial binding of RNA polymerase to promoter DNA; and (ii) an interaction with the RNA polymerase alpha subunit N-terminal domain that facilitates subsequent promoter opening. We have used random mutagenesis and alanine scanning to identify determinants within alphaCTD for transcription activation at a Class II CRP-dependent promoter. Our results indicate that Class II CRP-dependent transcription requires the side chains of residues 265, 271, 285-288 and 317. Residues 285-288 and 317 comprise a discrete 20x10 A surface on alphaCTD, and substitutions within this determinant reduce or eliminate cooperative interactions between alpha subunits and CRP, but do not affect DNA binding by alpha subunits. We propose that, in the ternary complex of RNA polymerase, CRP and a Class II CRP-dependent promoter, this determinant in alphaCTD interacts directly with CRP, and is distinct from and on the opposite face to the proposed determinant for alphaCTD-CRP interaction in Class I CRP-dependent transcription.

Spacing requirements for interactions between the C-terminal domain of the alpha subunit of Escherichia coli RNA polymerase and the cAMP receptor protein.

During transcription initiation at bacterial promoters, the C-terminal domain of the RNA polymerase alpha subunit (alphaCTD) can interact with DNA-sequence elements (known as UP elements) and with activator proteins. We have constructed a series of semi-synthetic promoters carrying both an UP element and a consensus DNA-binding site for the Escherichia coli cAMP receptor protein (CRP; a factor that activates transcription by making direct contacts with alphaCTD). At these promoters, the UP element was located at a variety of distances upstream of the CRP-binding site, which was fixed at position -41.5 bp upstream of the transcript start. At some positions, the UP element caused enhanced promoter activity whereas, at other positions, it had very little effect. In no case was the CRP-dependence of the promoter relieved. DNase I and hydroxyl-radical footprinting were used to study ternary RNA polymerase-CRP-promoter complexes formed at two of the most active of these promoters, and co-operativity between the binding of CRP and purified alpha subunits was studied. The footprints show that alphaCTD binds to the UP element as it is displaced upstream but that this displacement does not prevent alphaCTD from being contacted by CRP. Models to account for this are discussed.

Transcription activation at class I FNR-dependent promoters: identification of the activating surface of FNR and the corresponding contact site in the C-terminal domain of the RNA polymerase alpha subunit.

A library of random mutations in the Escherichia coli fnr gene has been screened to identify positive control mutants of FNR that are defective in transcription activation at Class I promoters. Single amino acid substitutions at D43, R72, S73, T118, M120, F181, F186, S187 and F191 identify a surface of FNR that is essential for activation which, presumably, makes contact with the C-terminal domain of the RNA polymerase alpha subunit. This surface is larger than the corresponding activating surface of the related transcription activator, CRP. To identify the contact surface in the C-terminal domain of the RNA polymerase alpha subunit, a library of mutations in the rpoA gene was screened for alpha mutants that interfered with transcription activation at Class I FNR-dependent promoters. Activation was reduced by deletions of the alpha C-terminal domain, by substitutions known to affect DNA binding by alpha, by substitutions at E261 and by substitutions at L300, E302, D305, A308, G315 and R317 that appear to identify contact surfaces of alpha that are likely to make contact with FNR at Class I promoters. Again, this surface differs from the surface used by CRP at Class I CRP-dependent promoters.

Transcription activation at class II CRP-dependent promoters: the role of different activating regions.

Transcription activation by the Escherichia coli cyclic AMP receptor protein (CRP) at Class II promoters is dependent on direct interactions between two surface-exposed activating regions (AR1 and AR2) and two contact sites in RNA polymerase. The effects on transcription activation of disrupting either AR1 or AR2 have been measured at different Class II promoters. AR2 but not AR1 is essential for activation at all the Class II promoters that were tested. The effects of single positive control substitutions in AR1 and AR2 vary from one promoter to another: the effects of the different substitutions are contingent on the -35 hexamer sequence. Abortive initiation assays have been used to quantify the effects of positive control substitutions in each activating region on the kinetics of transcription initiation at the Class II CRP- dependent promoter pmelRcon. At this promoter, the HL159 substitution in AR1 results in a defect in the initial binding of RNA polymerase whilst the KE101 substitution in AR2 reduces the rate of isomerization from the closed to the open complex.

Transcription activation at Escherichia coli promoters dependent on the cyclic AMP receptor protein: effects of binding sequences for the RNA polymerase alpha-subunit.

Transcription activation at two semi-synthetic Escherichia coli promoters, CC(-41.5) and CC(-72.5), is dependent on the cyclic AMP receptor protein (CRP) that binds to sites centred 41.5 and 72.5 bp upstream from the respective transcription startpoints. An UP-element that can bind the C-terminal domain of the RNA polymerase (RNAP) alpha-subunit was cloned upstream of the DNA site for CRP at CC(-41.5) and downstream of the DNA site for CRP at CC(-72.5). In both cases CRP-dependent promoter activity was increased by the UP-element, but CRP-independent activity was not increased. DNase I footprinting was exploited to investigate the juxtaposition of bound CRP and RNAP alpha-subunits. In both cases, CRP and RNAP alpha-subunits occupy their cognate binding sites in ternary CRP-RNAP promoter complexes. RNAP alpha-subunits can occupy the UP-element in the absence of CRP, but this is not sufficient for open complex formation. The positive effects of binding RNAP alpha-subunits upstream of the DNA site for CRP at -41.5 are suppressed if the UP-element is incorrectly positioned.