Design of cAMP-CRP-activated promoters in Escherichia coli.

We have studied the deoP2 promoter of Escherichia coli to define features that are required for optimal activation by the complex of adenosine 3',5' monophosphate (cAMP) and the cAMP receptor protein (CRP). Systematic mutagenesis of deoP2 shows that the distance between the CRP site and the -10 hexamer is the crucial factor in determining whether the promoter is activated by cAMP-CRP. Based on these observations, we propose that cAMP-CRP-activated promoters can be created by correctly aligning a CRP target and a -10 hexamer. This idea has been successfully tested by converting both a CRP-independent promoter and a sequence resembling the consensus -10 hexamer to strongly cAMP-CRP-activated promoters.

The CytR repressor antagonizes cyclic AMP-cyclic AMP receptor protein activation of the deoCp2 promoter of Escherichia coli K-12.

We have investigated the regulation of the Escherichia coli deoCp2 promoter by the CytR repressor and the cyclic AMP (cAMP) receptor protein (CRP) complexed to cAMP. Promoter regions controlled by these two proteins characteristically contain tandem cAMP-CRP binding sites. Here we show that (i) CytR selectively regulated cAMP-CRP-dependent initiations, although transcription started from the same site in deoCp2 in the absence or presence of cAMP-CRP; (ii) deletion of the uppermost cAMP-CRP target (CRP-2) resulted in loss of CytR regulation, but had only a minor effect on positive control by the cAMP-CRP complex; (iii) introduction of point mutations in either CRP target resulted in loss of CytR regulation; and (iv) regulation by CytR of deletion mutants lacking CRP-2 could be specifically reestablished by increasing the intracellular concentration of CytR. These findings indicate that both CRP targets are required for efficient CytR repression of deoCp2. Models for the action of CytR are discussed in light of these findings.

Tandem DNA-bound cAMP-CRP complexes are required for transcriptional repression of the deoP2 promoter by the CytR repressor in Escherichia coli.

We have studied the deoP2 promoter in Escherichia coli to define features important for its interaction with the CytR repressor. As is characteristic for CytR-regulated promoters, deoP2 encodes tandem binding sites for the activating complex cAMP-CRP. One of these sites, CRP-1, overlaps the -35 region, and is sufficient for activation; the second site, CRP-2, centred around -93, is indispensable for repression. Here we demonstrate, by means of in vivo titration, that CytR interaction with deoP2 depends not only on CRP-2, but also on CRP-1 and the length and possibly the sequence separating these two sites. Also, point mutations in either CRP site reduce or abolish CytR titration; however, no co-operativity is observed in the interaction of CytR with the two CRP binding sites. Furthermore, the reduction in CytR titration parallels the reduction in binding of cAMP-CRP to the mutated CRP sites in vitro. These observations are not easily explained by current models for the action of prokaryotic repressors; instead we favour a model in which the interaction of CytR with deoP2 depends on the presence of tandem DNA-bound cAMP-CRP complexes.

Characterization of the binding sites of protein L11 and the L10.(L12)4 pentameric complex in the GTPase domain of 23 S ribosomal RNA from Escherichia coli.

Ribonuclease and chemical probes were used to investigate the binding sites of ribosomal protein L11 and the pentameric complex L10.(L12)4 on Escherichia coli 23 S RNA. Protein complexes were formed with an RNA fragment constituting most of domains I and II or with 23 S RNA and they were investigated by an end-labelling method and a reverse transcriptase procedure, respectively. The results demonstrate that the two protein moieties bind at adjacent sites within a small RNA region. The L11 binding region overlaps with those of the modified peptide antibiotics thiostrepton and micrococcin and is constrained structurally by a three-helix junction while the L10.(L12)4 site is centred on an adjacent internal loop. The secondary structure of the whole region was determined in detail by the phylogenetic sequence comparison method, and the results for the L11 binding region, together with the experimental data, were used in a computer graphics approach to build a partial RNA tertiary structural model. The model provides insight into the topography of the L11 binding site. It also provides a structural rationale for the mutually co-operative binding of protein L11 with the antibiotics thiostrepton and micrococcin, and with the L10.(L12)4 protein complex.

Tandem DNA-bound cAMP-CRP complexes are required for transcriptional repression of the deoP2 promoter by the CytR repressor in Escherichia coli.

We have studied the deoP2 promoter in Escherichia coli to define features important for its interaction with the CytR repressor. As is characteristic for CytR-regulated promoters, deoP2 encodes tandem binding sites for the activating complex cAMP-CRP. One of these sites, CRP-1, overlaps the - 35 region, and is sufficient for activation; the second site, CRP-2, centred around-93, is indispensable for repression. Here we demonstrate, by means of in vivo titration, that CytR interaction with deoP2 depends not only on CRP-2, but also on CRP-1 and the length and possibly the sequence separating these two sites. Also, point mutations in either CRP site reduce or abolish CytR titration; however, no co-operativity is observed in the interaction of CytR with the two CRP binding sites. Furthermore, the reduction in CytR titration parallels the reduction in binding of cAMP-CRP to the mutated CRP sites in vitro. These observations are not easily explained by current models for the action of prokaryotic repressors; instead we favour a model in which the interaction of CytR with deoP2 depends on the presence of tandem DNA-bound cAMP-CRP complexes.

Does unpaired adenosine-66 from helix II of Escherichia coli 5S RNA bind to protein L18?

Adenosine-66 is unpaired within helix II of Escherichia coli 5S RNA and lies in the binding site of ribosomal protein L18. It has been proposed as a recognition site for protein L18. We have investigated further the structural importance of this nucleotide by deleting it. The 5S RNA gene of the rrnB operon of E. coli was subjected to primer-directed mutagenesis. To produce the deletion it was necessary to use simultaneously the mutagenic dodecamer dCGGCGCACGGCG and the universal M13 primer dCCCAGTCACGACGTT, and to employ forced annealing conditions. The mutated gene was expressed in an overproducing plasmid derived from pKK3535. Binding studies with protein L18 revealed that the protein bound much more weakly to the mutated 5S RNA. We consider the most likely explanation of this result is that L18 interacts with adenosine-66, and we present a tentative model for an interaction between the unpaired adenosine and the adjacent guanosine-67 of the RNA and glutamine-19 of the protein L18.