Mutually exclusive RNA secondary structures regulate translation initiation of DinQ in Escherichia coli.

Protein translation can be affected by changes in the secondary structure of mRNA. The dinQ gene in Escherichia coli encodes a primary transcript (+1) that is inert to translation. Ribonucleolytic removal of the 44 first nucleotides converts the +1 transcript into a translationally active form, but the mechanism behind this structural change is unknown. Here we present experimental evidence for a mechanism where alternative RNA secondary structures in the two dinQ mRNA variants affect translation initiation by mediating opening or closing of the ribosome binding sequence. This structural switch is determined by alternative interactions of four sequence elements within the dinQ mRNA and also by the agrB antisense RNA. Additionally, the structural conformation of +1 dinQ suggests a locking mechanism comprised of an RNA stem that both stabilizes and prevents translation initiation from the full-length dinQ transcript. BLAST search and multiple sequence alignments define a new family of dinQ-like genes widespread in Enterobacteriaceae with close RNA sequence similarities in their 5' untranslated regions. Thus, it appears that a whole new family of genes is regulated by the same mechanism of alternative secondary RNA structures.

Tiling array study of MNNG treated Escherichia coli reveals a widespread transcriptional response.

The alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) is known to trigger the adaptive response by inducing the ada-regulon - consisting of three DNA repair enzymes Ada, AlkB, AlkA and the enigmatic AidB. We have applied custom designed tiling arrays to study transcriptional changes in Escherichia coli following a MNNG challenge. Along with the expected upregulation of the adaptive response genes (ada, alkA and alkB), we identified a number of differentially expressed transcripts, both novel and annotated. This indicates a wider regulatory response than previously documented. There were 250 differentially-expressed and 2275 similarly-expressed unannotated transcripts. We found novel upregulation of several stress-induced transcripts, including the SOS inducible genes recN and tisAB, indicating a novel role for these genes in alkylation repair. Furthermore, the ada-regulon A and B boxes were found to be insufficient to explain the regulation of the adaptive response genes after MNNG exposure, suggesting that additional regulatory elements must be involved.

Tiling array analysis of UV treated Escherichia coli predicts novel differentially expressed small peptides.

BACKGROUND: Despite comprehensive investigation, the Escherichia coli SOS response system is not yet fully understood. We have applied custom designed whole genome tiling arrays to measure UV invoked transcriptional changes in E. coli. This study provides a more complete insight into the transcriptome and the UV irradiation response of this microorganism. RESULTS: We detected a number of novel differentially expressed transcripts in addition to the expected SOS response genes (such as sulA, recN, uvrA, lexA, umuC and umuD) in the UV treated cells. Several of the differentially expressed transcripts might play important roles in regulation of the cellular response to UV damage. We have predicted 23 novel small peptides from our set of detected non-gene transcripts. Further, three of the predicted peptides were cloned into protein expression vectors to test the biological activity. All three constructs expressed the predicted peptides, in which two of them were highly toxic to the cell. Additionally, a remarkably high overlap with previously in-silico predicted non-coding RNAs (ncRNAs) was detected. Generally we detected a far higher transcriptional activity than the annotation suggests, and these findings correspond with previous transcription mappings from E. coli and other organisms. CONCLUSIONS: Here we demonstrate that the E. coli transcriptome consists of far more transcripts than the present annotation suggests, of which many transcripts seem important to the bacterial stress response. Sequence alignment of promoter regions suggest novel regulatory consensus sequences for some of the upregulated genes. Finally, several of the novel transcripts identified in this study encode putative small peptides, which are biologically active.