Mycobacterial transcriptional signals: requirements for recognition by RNA polymerase and optimal transcriptional activity

Majority of the promoter elements of mycobacteria do not function well in other eubacterial systems and analysis of their sequences has established the presence of only single conserved sequence located at the -10 position. Additional sequences for the appropriate functioning of these promoters have been proposed but not characterized, probably due to the absence of sufficient number of strong mycobacterial promoters. In the current study, we have isolated functional promoter-like sequences of mycobacteria from the pool of random DNA sequences. Based on the promoter activity in Mycobacterium smegmatis and score assigned by neural network promoter prediction program, we selected one of these promoter sequences, namely A37 for characterization in order to understand the structure of housekeeping promoters of mycobacteria. A37-RNAP complexes were subjected to DNase I footprinting and subsequent mutagenesis. Our results demonstrate that in addition to -10 sequences, DNA sequence at -35 site can also influence the activity of mycobacterial promoters by modulating the promoter recognition by RNA polymerase and subsequent formation of open complex. We also provide evidence that despite exhibiting similarities in -10 and -35 sequences, promoter regions of mycobacteria and Escherichia coli differ from each other due to differences in their requirement of spacer sequences between the two positions.     

Up-promoter mutations in the lpp gene of Escherichia coli.

The promoter of the gene for the major outer membrane lipoprotein, the most abundant protein in Escherichia coli, is considered to be one of the strongest promoters in E. coli. The nucleotide sequences of the -10 and the -35 regions of the lpp promoter were altered in a step-wise manner to conform to their respective consensus sequences by synthetic oligonucleotide-directed site-specific mutagenesis. The mutated promoters were then fused to the lacZ gene to measure promoter activity. The beta-galactosidase activity increased approximately 1.9 and 2.4 fold when the -10 region (AATACT) was altered to TATACT(P1) and TATAAT (consensus sequence; P2), respectively. Similarly, it increased approximately 1.2 and 4.2 fold, when the -35 region (TTCTCA) was altered to TTCACA(R1) and TTGACA (consensus sequence; R2), respectively. When the mutations at the -10 and -35 regions were combined, the overall improvement of the promoter activity for R2-P1 was 4.0 fold over that of the wild-type promoter, while it was only 2.5 fold for R2-P2. These results indicate that substantial improvement of the promoter activity can be achieved by changing either of the two key regions to their respective consensus sequences. However, the complete conformity to consensus sequences at both regions does not necessarily result in the highest activity. With use of the improved lpp promoter in an expression cloning vehicle pIN-III-ompA, staphylococcal nuclease A was produced at a level of approximately 47% of the total cellular protein.     

Mutational analysis of the lac regulatory region: second-site changes that activate mutant promoters.

Second-site mutations that restored activity to severe lacP1 down-promoter mutants were isolated. This was accomplished by using a bacteriophage f1 vector containing a fusion of the mutant E. coli lac promoters with the structural gene for chloramphenicol acetyltransferase (CAT), so that a system was provided for selecting phage revertants (or pseudorevertants) that conferred resistance of phage-infected cells to chloramphenicol. Among the second-site changes that relieved defects in mutant lac promoters, the only one that restored lacP1 activity was a T----G substitution at position -14, a weakly conserved site in E. coli promoters. Three other sequence changes, G----A at -2, A----T at +1, and C----A at +10, activated nascent promoters in the lac regulatory region. The nascent promoters conformed to the consensus rule, that activity is gained by sequence changes toward homology with consensus sequences at the -35 and -10 regions of the promoter. However, the relative activities of some promoters cannot be explained solely by consideration of their conserved sequence elements.     

The structural basis of the high in vivo strength of the rRNA P2 promoter of Escherichia coli

Ribosomal RNA promoters of Escherichia coli are probably the strongest promoters in vivo and they can be used on plasmid vectors to express protein-coding sequences at a high rate. In fact, the P2 promoter of the rrnB gene is stronger (in vivo) than the tac promoter, which has a perfect consensus sequence. Conversion of the rrnB P2 promoter sequence to consensus significantly increases in vivo promoter strength. The removal of four nucleotides downstream of the -10 region also increases the strength of this promoter. On the other hand, shifting of the A + T-rich region upstream of this promoter by an 11-bp insertion drastically decreases in vivo activity. It is concluded that the two functionally important hexanucleotide sequences, -35 and -10, are necessary but not sufficient factors for the optimalization of in vivo promoter strength.