Mutational analysis of Escherichia coli σ28 and its target promoters reveals recognition of a composite −10 region, comprised of an 'extended −10' motif and a core −10 element

σ²⁸ controls the expression of flagella-related genes and is the most widely distributed alternative σ factor, present in motile Gram-positive and Gram-negative bacteria. The distinguishing feature of σ²⁸ promoters is a long −10 region (GCCGATAA). Despite the fact that the upstream GC is highly conserved, previous studies have not indicated a functional role for this motif. Here we examine the functional relevance of the GCCG motif and determine which residues in σ²⁸ participate in its recognition. We find that the GCCG motif is a functionally important composite element. The upstream GC constitutes an extended −10 motif and is recognized by R91, a residue in Domain 3 of σ²⁸. The downstream CG is the upstream edge of −10 region of the promoter; two residues in Region 2.4, D81 and R84, participate in its recognition. Consistent with their role in base-specific recognition of the promoter, R91, D81 and D84 are universally conserved in σ²⁸ orthologues. σ²⁸ is the second Group 3 σ shown to use an extended −10 region in promoter recognition, raising the possibility that other Group 3 σs will do so as well.     

Identification and characterization of novel low-temperature-inducible promoters of Escherichia coli.

Escherichia coli promoters that are more active at low temperature (15 to 20 degrees C) than at 37 degrees C were identified by using the transposon Tn5-lac to generate promoter fusions expressing beta-galactosidase (beta-Gal). Tn5-lac insertions that resulted in low-temperature-regulated beta-Gal expression were isolated by selecting kanamycin-resistant mutants capable of growth on lactose minimal medium at 15 degrees C but which grew poorly at 37 degrees C on this medium. Seven independent mutants were selected for further studies. In one such strain, designated WQ11, a temperature shift from 37 degrees C to either 20 or 15 degrees C resulted in a 15- to 24-fold induction of beta-Gal expression. Extended growth at 20 or 15 degrees C resulted in 36- to 42-fold-higher beta-Gal expression over that of cells grown at 37 degrees C. Treatment of WQ11 with streptomycin, reported to induce a response similar to heat shock, failed to induce beta-Gal expression. In contrast, treatment with either chloramphenicol or tetracycline, which mimics a cold shock response, resulted in a fourfold induction of beta-Gal expression in strain WQ11. Hfr genetic mapping studies complemented by physical mapping indicated that in at least three mutants (WQ3, WQ6, and WQ11), Tn5-lac insertions mapped at unique sites where no known cold shock genes have been reported. The Tn5-lac insertions of these mutants mapped to 81, 12, and 34 min on the E. coli chromosome, respectively. The cold-inducible promoters from two of the mutants (WQ3 and WQ11) were cloned and sequenced, and their temperature regulation was examined. Comparison of the nucleotide sequences of these two promoters with the regulatory elements of other known cold shock genes identified the sequence CCAAT as a putative conserved motif.     

Thiol-sensitive promoters of Escherichia coli.

Mu dX(lac) insertion mutants of Escherichia coli CSH50 in which the expression of the lacZ gene was sensitive to the presence of exogenous 1-thioglycerol or dithiothreitol were isolated. Both stimulatory and inhibitory mutants were found. The existence of several thiol-sensitive promoters suggests that exogenous thiols may provoke global stress responses in E. coli.     

DNA sequence elements located immediately upstream of the -10 hexamer in Escherichia coli promoters: a systematic study

We have made a systematic study of how the activity of an Escherichia coli promoter is affected by the base sequence immediately upstream of the –10 hexamer. Starting with an activator-independent promoter, with a 17 bp spacing between the –10 and –35 hexamer elements, we constructed derivatives with all possible combinations of bases at positions –15 and –14. Promoter activity is greatest when the ‘non-template’ strand carries T and G at positions –15 and –14, respectively. Promoter activity can be further enhanced by a second T and G at positions –17 and –16, respectively, immediately upstream of the first ‘TG motif’. Our results show that the base sequence of the DNA segment upstream of the –10 hexamer can make a significant contribution to promoter strength. Using published collections of characterised E.coli promoters, we have studied the frequency of occurrence of ‘TG motifs’ upstream of the promoters’ –10 elements. We conclude that correctly placed ‘TG motifs’ are found at over 20% of E.coli promoters.     

Substitutions in the Escherichia coli RNA polymerase sigma70 factor that affect recognition of extended -10 elements at promoters

Previous work has shown that the base sequence of the DNA segment immediately upstream of the -10 hexamer at bacterial promoters (the extended -10 element) can make a significant contribution to promoter strength. Guided by recently published structural information, we used alanine scanning and suppression mutagenesis of Region 2.4 and Region 3.0 of the Escherichia coli RNA polymerase sigma(70) subunit to identify amino acid sidechains that play a role in recognition of this element. Our study shows that changes in these regions of the sigma(70) subunit can affect the recognition of different extended -10 element sequences.     

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.     

Dissection of recognition determinants of Escherichia coli σ32 suggests a composite −10 region with an 'extended −10' motif and a core −10 element

σ³² controls expression of heat shock genes in Escherichia coli and is widely distributed in proteobacteria. The distinguishing feature of σ³² promoters is a long −10 region (CCCCATNT) whose tetra-C motif is important for promoter activity. Using alanine-scanning mutagenesis of σ³² and in vivo and in vitro assays, we identified promoter recognition determinants of this motif. The most downstream C (−13) is part of the −10 motif; our work confirms and extends recognition determinants of −13C. Most importantly, our work suggests that the two upstream Cs (−16, −15) constitute an 'extended −10' recognition motif that is recognized by K130, a residue universally conserved in β- and γ-proteobacteria. This residue is located in the α-helix of σDomain 3 that mediates recognition of the extended −10 promoter motif in other σs. K130 is not conserved in α- and δ-/ε-proteobacteria and we found that σ³² from the α-proteobacterium Caulobacter crescentus does not need the extended −10 motif for high promoter activity. This result supports the idea that K130 mediates extended −10 recognition. σ³² is the first Group 3 σ shown to use the 'extended −10' recognition motif.