Abstract
Stress-induced DNA duplex destabilization (SIDD) analysis exploits the known structural and energetic properties of DNA to predict sites that are susceptible to strand separation under negative superhelical stress. When this approach was used to calculate the SIDD profile of the entire Escherichia coli K12 genome, it was found that strongly destabilized sites occur preferentially in intergenic regions that are either known or inferred to contain promoters, but rarely occur in coding regions. Here, we investigate whether the genes grouped in different functional categories have characteristic SIDD properties in their upstream flanks. We report that strong SIDD sites in the E. coli K12 genome are statistically significantly overrepresented in the upstream regions of genes encoding transcriptional regulators. In particular, the upstream regions of genes that directly respond to physiological and environmental stimuli are more destabilized than are those regions of genes that are not involved in these responses. Moreover, if a pathway is controlled by a transcriptional regulator whose gene has a destabilized 5′ flank, then the genes (operons) in that pathway also usually contain strongly destabilized SIDD sites in their 5′ flanks. We observe this statistically significant association of SIDD sites with upstream regions of genes functioning in transcription in 38 of 43 genomes of free-living bacteria, but in only four of 18 genomes of endosymbionts or obligate parasitic bacteria. These results suggest that strong SIDD sites 5′ to participating genes may be involved in transcriptional responses to environmental changes, which are known to transiently alter superhelicity. We propose that these SIDD sites are active and necessary participants in superhelically mediated regulatory mechanisms governing changes in the global pattern of gene expression in prokaryotes in response to physiological or environmental changes.
Highlights
Genomic DNA encodes proteins and RNAs, and plays active roles in mechanisms regulating many biological processes, primarily through interactions with proteins and other molecules
We report that the destabilized sites we find in the Escherichia coli K12 genome are statistically significantly overrepresented in the upstream regions of genes encoding proteins that regulate transcription
The regions upstream of genes that directly respond to physiological and environmental stimuli are more destabilized than are those regions of genes that are not involved in these responses. These results suggest that strong Stress-induced DNA duplex destabilization (SIDD) sites upstream of participating genes may be involved in transcriptional responses to environmental changes
Summary
Genomic DNA encodes proteins and RNAs, and plays active roles in mechanisms regulating many biological processes, primarily through interactions with proteins and other molecules. Strictly lexical analysis of genomic DNA sequences has been a focus of contemporary biology, it is becoming increasingly clear that the physical, chemical, and structural properties of the DNA molecule can play key roles in the onset or progression of many regulatory events. Some of these attributes are not directly related to sequence in any simple way. If strand opening at a regulatory site is the rate-limiting step in initiating a process, this superhelical destabilization can have a major effect on the frequency with which that process occurs In this way, changes in the in vivo level of superhelicity could strongly affect specific regulatory events
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