Temperature-dependent stability and translation of Escherichia coli ompA mRNA

Promoting health and survival through lowered body temperature

Core body temperature (Tb) is a long-established determinant of longevity across species. In this Perspective, we first summarize evidence demonstrating that reducing Tb increases lifespan and that lowered Tb contributes to the antiaging effects of calorie restriction. Next, we discuss recent data that diverge from prior hypotheses on the mechanisms by which Tb affects longevity, suggesting these are limited neither to the thermodynamics of nonenzymatic chemical reactions, nor reduced formation of mitochondrial reactive oxygen species nor lowered metabolic rate. Instead, recent findings in invertebrates show that cold promotes longevity via specific pathways including nutrient sensing and proteostasis, as well as modulating the thermodynamics of proteins and nucleic acids by changing their structure and function, for example, affecting temperature-sensitive ion channels, long-lived temperature-sensitive dauer mutations, base-pair stability and stem-loop RNA structures. Temperature affects the epigenetic signature and inflammation, and lowering Tb can also induce RNA-binding cold shock proteins, activate cold-sensitive kinases and differential splicing to potentially reshape the cellular environment. Finally, we reflect on important future work and the translational potential of temperature management and temperature mimetics.

Characterization of Escherichia coli chaperonin GroEL as a ribonuclease

Chaperonins are evolutionarily conserved proteins that facilitate polypeptide assemblies. The most extensively studied chaperonin is GroEL, which plays a crucial role in Escherichia coli. In addition to its chaperone activity, the RNA cleavage activity of GroEL has also been proposed. However, direct evidence of GroEL as a ribonuclease (RNase) and its physiological significance has not been fully elucidated. Here, we characterized the role of GroEL in E. coli as an RNase distinct from RNase E/G activity using in vivo reporter assays, in vitro cleavage assays with varying reaction times, divalent ions, and 5' phosphorylation status. GroEL bound to single-stranded RNA at nanomolar concentrations. Functional analysis of GroEL chaperonin-defective mutants and segments identified specific regions, and the chaperone active status of GroEL is not a necessary factor for RNase activity. Additionally, RNase activity of GroEL was attenuated by co-overexpression with GroES. Finally, we characterized potential transcripts regulated by GroEL and the conserved RNase activity of GroEL in Shigella flexneri. Our findings indicate that GroEL is a novel post-transcriptional regulator in bacteria.

Regulation of OmpA Translation and Shigella dysenteriae Virulence by an RNA Thermometer

RNA thermometers are cis-acting riboregulators that mediate the posttranscriptional regulation of gene expression in response to environmental temperature. Such regulation is conferred by temperature-responsive structural changes within the RNA thermometer that directly result in differential ribosomal binding to the regulated transcript. The significance of RNA thermometers in controlling bacterial physiology and pathogenesis is becoming increasingly clear. This study combines in silico, molecular genetics, and biochemical analyses to characterize both the structure and function of a newly identified RNA thermometer within the ompA transcript of Shigella dysenteriae First identified by in silico structural predictions, genetic analyses have demonstrated that the ompA RNA thermometer is a functional riboregulator sufficient to confer posttranscriptional temperature-dependent regulation, with optimal expression observed at the host-associated temperature of 37°C. Structural studies and ribosomal binding analyses have revealed both increased exposure of the ribosomal binding site and increased ribosomal binding to the ompA transcript at permissive temperatures. The introduction of site-specific mutations predicted to alter the temperature responsiveness of the ompA RNA thermometer has predictable consequences for both the structure and function of the regulatory element. Finally, in vitro tissue culture-based analyses implicate the ompA RNA thermometer as a bona fide S. dysenteriae virulence factor in this bacterial pathogen. Given that ompA is highly conserved among Gram-negative pathogens, these studies not only provide insight into the significance of riboregulation in controlling Shigella virulence, but they also have the potential to facilitate further understanding of the physiology and/or pathogenesis of a wide range of bacterial species.

The stability of an mRNA is influenced by its concentration: a potential physical mechanism to regulate gene expression

Changing mRNA stability is a major post-transcriptional way of controlling gene expression, particularly in newly encountered conditions. As the concentration of mRNA is the result of an equilibrium between transcription and degradation, it is generally assumed that at constant transcription, any change in mRNA concentration is the consequence of mRNA stabilization or destabilization. However, the literature reports many cases of opposite variations in mRNA concentration and stability in bacteria. Here, we analyzed the causal link between the concentration and stability of mRNA in two phylogenetically distant bacteria Escherichia coli and Lactococcus lactis. Using reporter mRNAs, we showed that modifying the stability of an mRNA had unpredictable effects, either higher or lower, on its concentration, whereas increasing its concentration systematically reduced stability. This inverse relationship between the concentration and stability of mRNA was generalized to native genes at the genome scale in both bacteria. Higher mRNA turnover in the case of higher concentrations appears to be a simple physical mechanism to regulate gene expression in the bacterial kingdom. The consequences for bacterial adaptation of this control of the stability of an mRNA by its concentration are discussed.

The 4E-BP growth pathway regulates the effect of ambient temperature on Drosophila metabolism and lifespan

Changes in body temperature can profoundly affect survival. The dramatic longevity-enhancing effect of cold has long been known in organisms ranging from invertebrates to mammals, yet the underlying mechanisms have only recently begun to be uncovered. In the nematode Caenorhabditis elegans, this process is regulated by a thermosensitive membrane TRP channel and the DAF-16/FOXO transcription factor, but in more complex organisms the underpinnings of cold-induced longevity remain largely mysterious. We report that, in Drosophila melanogaster, variation in ambient temperature triggers metabolic changes in protein translation, mitochondrial protein synthesis, and posttranslational regulation of the translation repressor, 4E-BP (eukaryotic translation initiation factor 4E-binding protein). We show that 4E-BP determines Drosophila lifespan in the context of temperature changes, revealing a genetic mechanism for cold-induced longevity in this model organism. Our results suggest that the 4E-BP pathway, chiefly thought of as a nutrient sensor, may represent a master metabolic switch responding to diverse environmental factors.

Domain swapping between homologous bacterial small RNAs dissects processing and Hfq binding determinants and uncovers an aptamer for conditional RNase E cleavage

In E. coli, small RNA GlmZ activates the glmS mRNA by base-pairing in an Hfq dependent manner. When not required, GlmZ is bound by adaptor protein RapZ and recruited to RNase E, which cleaves GlmZ in its base-pairing sequence. Small RNA GlmY counteracts cleavage of GlmZ by sequestration of RapZ. Although both sRNAs are highly homologous, only GlmZ specifically binds Hfq and undergoes cleavage by RNase E. We used domain swapping to identify the responsible modules. Two elements, the 3' terminal oligo(U) stretch and the base-pairing region enable GlmZ to interact with Hfq. Accordingly, Hfq inhibits cleavage of GlmZ, directing it to base-pairing. Intriguingly, the central stem loop of GlmZ is decisive for cleavage, whereas the sequence comprising the actual cleavage site is dispensable. Assisted by RapZ, RNase E cleaves any RNA fused to the 3' end of this module. These results suggest a novel mode for RNase E recognition, in which one of the required handholds in the substrate is replaced by an RNA binding protein. This device can generate RNAs of interest in their 5' monophosphorylated form on demand. As these species are rapidly degraded, this tool allows to regulate gene expression post-transcriptionally by modulation of RapZ levels.

Streptomyces coelicolor sRNA scr5239 inhibits agarase expression by direct base pairing to the dagA coding region

Transcriptional regulation of primary and secondary metabolism is well-studied in Streptomyces coelicolor, a model organism for antibiotic production and cell differentiation. In contrast, little is known about post-transcriptional regulation and the potential functions of small non-coding RNAs (sRNAs) in this Gram-positive, GC-rich soil bacterium. Here, we report the identification and characterization of scr5239, an sRNA highly conserved in the genus Streptomyces. The sRNA is 159 nt long, composed of five stem-loops, and encoded in the intergenic region between SCO5238 and SCO5239. scr5239 expression is constitutive under several stress and growth conditions but dependent on the nitrogen supply. scr5239 decreases the production of the antibiotic actinorhodin, and represses expression of the extracellular agarase dagA at the post-transcriptional level by direct base pairing to the coding region 33 nt downstream of the ribosome-binding site.

A 5' leader sequence regulates expression of methanosarcinal CO dehydrogenase/acetyl coenzyme A synthase

In vivo expression of CO dehydrogenase/acetyl coenzyme A synthase in Methanosarcina spp. is coordinately regulated in response to substrate by at least two mechanisms: differential transcription initiation and early elongation termination near the 3' end of a 371-bp leader sequence. This is the first report of regulation of transcription elongation in the Archaea.

Poly(A)-assisted RNA decay and modulators of RNA stability

In Escherichia coli, RNA degradation is orchestrated by the degradosome with the assistance of complementary pathways and regulatory cofactors described in this chapter. They control the stability of each transcript and regulate the expression of many genes involved in environmental adaptation. The poly(A)-dependent degradation machinery has diverse functions such as the degradation of decay intermediates generated by endoribonucleases, the control of the stability of regulatory non coding RNAs (ncRNAs) and the quality control of stable RNA. The metabolism of poly(A) and mechanism of poly(A)-assisted degradation are beginning to be understood. Regulatory factors, exemplified by RraA and RraB, control the decay rates of subsets of transcripts by binding to RNase E, in contrast to regulatory ncRNAs which, assisted by Hfq, target RNase E to specific transcripts. Destabilization is often consecutive to the translational inactivation of mRNA. However, there are examples where RNA degradation is the primary regulatory step.

OmpA is an adhesion factor of Aeromonas veronii, an optimistic pathogen that habituates in carp intestinal tract

AIMS

In the present study, we focused on one of the Aeromonas veronii isolates that exhibited marked adhesion onto carp intestine and studied its membrane-associated proteins for their possible involvement in mucosal adhesion.

METHODS AND RESULTS

We isolated a strain of Aer. veronii (CWP11) that exhibited a high degree of temperature-dependent adhesion activity onto carp intestinal tract and studied its adhesion factor. A proteomic analysis of the membrane-associated fraction showed the presence of multiple proteins that were specifically expressed in CWP11 cells cultured at 25 degrees C. Of these, a 30 kDa protein was identified to be OmpA by a mass fingerprint analysis. Cloning and nucleotide sequencing of the ompA region of CWP11 revealed the presence of two tandem ompA homologues (ompAI-ompAII). Escherichia coli that expressed either OmpAI or OmpAII exhibited marked adhesion onto carp intestinal surface. Disruption of ompAI by a homologous recombination technique resulted in marked reduction of the adhesion activity in CWP11.

CONCLUSION

The OmpA homologue plays an important role in the adhesion of the Aer. veronii strain onto the surface of intestinal tract.

SIGNIFICANCE AND IMPACT OF THE STUDY

We successfully identified an OmpA homologue to be an adhesion factor of Aer. veronii, an optimistic pathogen that habituates in carp intestinal tract.

Posttranscriptional regulation of cspE in Escherichia coli: involvement of the short 5'-untranslated region

Escherichia coli K-12 contains nine paralogs of CspA, namely CspA-CspI. In spite of considerable sequence similarity among these genes, the individual members of this family show significant differences in their expression regulation. Among these nine members, cspA, B, G and I have been reported to be cold-induced. The unusually long 5'-untranslated region (5'-UTR) of these four and other cold-induced genes has often been associated with their inducibility. Sequence analysis of the cspE upstream region revealed two promoter-like motifs having high scores. We identified the promoter site and established that cspE has a much shorter 5'-UTR compared to other cold-induced genes. Our results showed that cspE is induced to about threefold at both the transcript and the protein level in response to cold-shock. Its transcript half-life increases significantly upon cold-shock. Furthermore, we demonstrated that RNase E, a key endonuclease responsible for mRNA degradation in E. coli, regulates cspE transcript stability, possibly through the assembly of a degradosome. In silico analysis of the cspE 5'-UTR revealed alternative secondary structures at 37 and 15 degrees C. A point mutation that was predicted to relax the secondary structure of the 5'-UTR at 15 degrees C showed considerable reduction in transcript stability, indicating that alternative transcript secondary structures might be the cause of the differential stability.

Quaternary structure and biochemical properties of mycobacterial RNase E/G

The RNase E/G family of endoribonucleases plays the central role in numerous post-transcriptional mechanisms in Escherichia coli and, presumably, in other bacteria, including human pathogens. To learn more about specific properties of RNase E/G homologues from pathogenic Gram-positive bacteria, a polypeptide comprising the catalytic domain of Mycobacterium tuberculosis RNase E/G (MycRne) was purified and characterized in vitro. In the present study, we show that affinity-purified MycRne has a propensity to form dimers and tetramers in solution and possesses an endoribonucleolytic activity, which is dependent on the 5'-phosphorylation status of RNA. Our data also indicate that the cleavage specificities of the M. tuberculosis RNase E/G homologue and its E. coli counterpart are only moderately overlapping, and reveal a number of sequence determinants within MycRne cleavage sites that differentially affect the efficiency of cleavage. Finally, we demonstrate that, similar to E. coli RNase E, MycRne is able to cleave in an intercistronic region of the putative 9S precursor of 5S rRNA, thus suggesting a common function for RNase E/G homologues in rRNA processing.

Characterization of compatible solute transporter multiplicity in Corynebacterium glutamicum

The soil bacterium Corynebacterium glutamicum is efficiently protected against hyperosmotic stress by a high redundancy of uptake systems and biosynthesis pathways for compatible solutes. We have previously identified and analyzed four osmoregulated uptake systems for betaine, ectoine, and proline. Because of overlapping substrate specificities, it is not possible to quantify their individual contribution to the stress response in wild-type cells. Using a set of strains in which only one uptake system for compatible solutes is present, we investigated the expression regulation at their transcriptional and translational level. The carrier ectP was found to be regulated at the level of transcription, but the already high maximal uptake capacity of approx. 30 nmol/(min mg cell dry mass, cdm) was not further elevated if the medium osmolality was severely increased, indicating that the amount of EctP is not changed. Thus, EctP may represent the rescue system for C. glutamicum. The betP, lcoP, and proP genes were induced upon hyperosmotic conditions, resulting in a 3-10-fold increase of their transport activity. These systems are thus used to fine-tune the uptake capacity for compatible solutes to the actual demands of the cell. ProP represents the most strongly regulated compatible solute uptake system in C. glutamicum.

Translation initiation and the fate of bacterial mRNAs

Studies in pro- and eukaryotes have revealed that translation can determine the stability of a given messenger RNA. In bacteria, intrinsic mRNA signals can confer efficient ribosome binding, whereas translational feedback inhibition or environmental cues can interfere with this process. Such regulatory mechanisms are often controlled by RNA-binding proteins, small noncoding RNAs and structural rearrangements within the 5' untranslated region. Here, we review molecular events occurring in the 5' untranslated region of primarily Escherichia coli mRNAs with regard to their effects on mRNA stability.

Both RNase E and RNase III control the stability of sodB mRNA upon translational inhibition by the small regulatory RNA RyhB

Previous work has demonstrated that iron-dependent variations in the steady-state concentration and translatability of sodB mRNA are modulated by the small regulatory RNA RyhB, the RNA chaperone Hfq and RNase E. In agreement with the proposed role of RNase E, we found that the decay of sodB mRNA is retarded upon inactivation of RNase E in vivo, and that the enzyme cleaves within the sodB 5′-untranslated region (5′-UTR) in vitro, thereby removing the 5′ stem–loop structure that facilitates Hfq and ribosome binding. Moreover, RNase E cleavage can also occur at a cryptic site that becomes available upon sodB 5′-UTR/RyhB base pairing. We show that while playing an important role in facilitating the interaction of RyhB with sodB mRNA, Hfq is not tightly retained by the RyhB–sodB mRNA complex and can be released from it through interaction with other RNAs added in trans. Unlike turnover of sodB mRNA, RyhB decay in vivo is mainly dependent on RNase III, and its cleavage by RNase III in vitro is facilitated upon base pairing with the sodB 5′-UTR. These data are discussed in terms of a model, which accounts for the observed roles of RNase E and RNase III in sodB mRNA turnover.

Characterization of Aquifex aeolicus RNase E/G

The RNase E/G homologue from the thermophilic eubacterium Aquifex aeolicus has been overexpressed in Escherichia coli, purified, and characterized in vitro. We show that A. aeolicus RNase E/G has a temperature-dependent, endoribonucleolytic activity. The enzyme site-specifically cleaves oligonucleotides and structured RNAs at locations that are partly overlapping or completely different when compared to the positions of E. coli RNase E and RNase G cleavage sites. The efficiency of cleavage by A. aeolicus RNase E/G is dependent on the 5'-phosphorylation status of RNA suggesting differential susceptibility of primary transcripts and their degradative intermediates to the nuclease activity of this enzyme in vivo. Similar to E. coli RNase E, A. aeolicus RNase E/G is able to selectively cleave internucleotide bonds in the 3'-5' direction, and to cut in intercistronic regions of putative tRNA precursors, thus suggesting a common function for RNase E/G homologues in eubacteria.