Substitution of RNA-polymerase sigma-subunits and transcription regulation

Recent data on regulation of gene activity in bacteria by substitution of RNA polymerase sigma subunits are reviewed. The htpR gene which controls the switch-on of the Escherichia coli heat-shock protein synthesis codes for sigma 32 subunit. sigma 32-containing RNA polymerase transcribes the heat-shock genes in vitro from specific promoters of no use for RNA polymerase containing the major sigma 70 subunit. Several minor sigma subunits have been found in Bacillus subtilis vegetative cells, in addition to the major sigma 55 subunit, differing in the specificity of promoter recognition. Many B. subtilis genes are controlled by tandemly located promoters recognized by RNA polymerases carrying different sigma subunits. sigma 29 subunit is encoded by spoIIG gene and is probably involved in the regulation of sporulation. Specific sigma subunits for transcribing "middle" or "late" genes are encoded by a number of phages.     

Genome-wide bioinformatic prediction and experimental evaluation of potential RNA thermometers

Only recently, the fundamental role of regulatory RNAs in prokaryotes and eukaryotes has been appreciated. We developed a pipeline from bioinformatic prediction to experimental validation of new RNA thermometers. Known RNA thermometers are located in the 5′-untranslated region of certain heat shock or virulence genes and control translation by temperature-dependent base pairing of the ribosome binding site. We established the searchable database RNA-SURIBA (Structures of Untranslated Regions In BActeria). A structure-based search pattern reliably recognizes known RNA thermometers and predicts related structures upstream of annotated genes in complete genome sequences. The known ROSE₁ (Repression Of heat Shock gene Expression) thermometer and several other functional ROSE-like elements were correctly predicted. For further investigation, we chose a new candidate upstream of the phage shock gene D (pspD) in the pspABCDE operon of E. coli. We established a new reporter gene system that measures translational control at heat shock temperatures and we demonstrated that the upstream region of pspD does not confer temperature control to the phage shock gene. However, translational efficiency was modulated by a point mutation stabilizing the predicted hairpin. Testing other candidates by this structure prediction and validation process will lead to new insights into the requirements for biologically active RNA thermometers. The database is available on . Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Development of RNA polymerase-promoter contacts during open complex formation.

We have charted the movements of E sigma 32 RNA polymerase at the heat-shock promoter PgroE throughout open complex formation, using hydroxyl radical footprinting. In combination with methylation protection and DNase I experiments, these data suggest the following model for open complex formation. E sigma 32 initially anchors itself in the upstream region of the promoter forming the first closed complex, RPC1; in this complex the enzyme makes backbone contacts in the -35 region of the promoter that are maintained throughout open complex formation. An isomerization follows resulting in a second closed complex, RPC2; in this complex the enzyme makes base-specific and backbone contacts in the -10 region that are almost identical to those found in the open complex. Thus, at the groE promoter, upstream contacts are established in RPC1 and downstream contacts in RPC2. A similar pattern of backbone contacts was obtained for E sigma 32 bound in the open complex at two additional heat-shock promoters, suggesting that the overall topology of holoenzyme in the open complex is similar regardless of sequence variations in the promoter.     

RNAthermsw: Direct Temperature Simulations for Predicting the Location of RNA Thermometers

The mechanism of RNA thermometers is a subject of growing interest. Also known as RNA thermosensors, these temperature-sensitive segments of the mRNA regulate gene expression by changing their secondary structure in response to temperature fluctuations. The detection of RNA thermometers in various genes of interest is valuable as it could lead to the discovery of new thermometers participating in fundamental processes such as preferential translation during heat-shock. RNAthermsw is a user-friendly webserver for predicting the location of RNA thermometers using direct temperature simulations. It operates by analyzing dotted figures generated as a result of a moving window that performs successive energy minimization folding predictions. Inputs include the RNA sequence, window size, and desired temperature change. RNAthermsw can be freely accessed at http://www.cs.bgu.ac.il/~rnathemsw/RNAthemsw/ (with the slash sign at the end). The website contains a help page with explanations regarding the exact usage.     

Characterization of heat-shock response of the marine bacterium Vibrio harveyi

We have investigated heat-shock response in a marine bacterium Vibrio harveyi. We have found that 39 C was the highest tempature at which V. harveyi was able to grow steadily. A shift from 30° C to 39° C caused increased synthesis of at least 10 proteins, as judged by SDS-PAGE, with molecular masses of 90, 70, 58, 41, 31, 27, 22, 15, 14.5 and 14kDa. The 70, 58, 41 and 14.5 kDa proteins were immunologically homologous to DnaK, GroEL, DnaJ and GroES heat-shock proteins of Escherichia coli, respectively. V. harveyi GroES protein had a lower molecular mass (14.5 kDa) than E. coli GroES, migrating in SDS-PAGE as 15 kDa protein. We showed that a protein of ～43 kDa, immunologically reactive with antiserum against E. coli sigma 32 subunit (σ³²) of RNA polymerase, was induced by heat-shock and co-purified with V. harveyi RNA polymerase. These results suggest that the 43 kDa protein is a heat-shock sigma protein of V. harveyi. Preparation containing the V. harveyi sigma 32 homologue, supplemented with core RNA polymerase of E. coli, was able to transcribe heat-shock promoters of E. coli in vitro.     

Bacterial RNA thermometers: molecular zippers and switches

Bacteria use complex strategies to coordinate temperature-dependent gene expression. Many genes encoding heat shock proteins and virulence factors are regulated by temperature-sensing RNA sequences, known as RNA thermometers (RNATs), in their mRNAs. For these genes, the 5' untranslated region of the mRNA folds into a structure that blocks ribosome access at low temperatures. Increasing the temperature gradually shifts the equilibrium between the closed and open conformations towards the open structure in a zipper-like manner, thereby increasing the efficiency of translation initiation. Here, we review the known molecular principles of RNAT action and the hierarchical RNAT cascade in Escherichia coli. We also discuss RNA-based thermosensors located upstream of cold shock and other genes, translation of which preferentially occurs at low temperatures and which thus operate through a different, more switch-like mechanism. Finally, we consider the potential biotechnological applications of natural and synthetic RNATs.     

In vitro effect of the Escherichia coli heat shock regulatory protein on expression of heat shock genes.

In Escherichia coli, the ability to elicit a heat shock response depends on the htpR gene product. Previous work has shown that the HtpR protein serves as a sigma factor (sigma 32) for RNA polymerase that specifically recognizes heat shock promoters (A.D. Grossman, J.W. Erickson, and C.A. Gross Cell 38:383-390, 1984). In the present study we showed that sigma 32 synthesized in vitro could stimulate the expression of heat shock genes. The in vitro-synthesized sigma 32 was found to be associated with RNA polymerase. In vivo-synthesized sigma 32 was also associated with RNA polymerase, and this polymerase (E sigma 32) could be isolated free of the standard polymerase (E sigma 70). E sigma 32 was more active than E sigma 70 with heat shock genes; however, non-heat-shock genes were not transcribed by E sigma 32. The in vitro expression of the htpR gene required E sigma 70 but did not require E sigma 32.