Determinants in the rpsT mRNAs recognized by the 5′‐sensor domain of RNase E

RNase E plays a central role in processing virtually all classes of cellular RNA in many bacterial species. A characteristic feature of RNase E and its paralogue RNase G, as well as several other unrelated ribonucleases, is their preference for 5′‐monophosphorylated substrates. The basis for this property has been explored in vitro. At limiting substrate, cleavage of the rpsT mRNA by RNase E (residues 1–529) is inefficient, requiring excess enzyme. The rpsT mRNA is cleaved sequentially in a 5′ to 3′ direction, with the initial cleavage(s) at positions 116/117 or 190/191 being largely driven by direct entry, independent of the 5′‐terminus or the 5′‐sensor domain of RNase E. Generation of the 147 nt 3′‐limit product requires sequential cleavages that generate 5′‐monophosphorylated termini on intermediates, and the 5′‐sensor domain of RNase E. These requirements can be bypassed with limiting enzyme by deleting a stem‐loop structure adjacent to the site of the major, most distal cleavage. Alternatively, this specific cleavage can be activated substantially by a 5′‐phosphorylated oligonucleotide annealed 5′ to the cleavage site. This finding suggests that monophosphorylated small RNAs may destabilize their mRNA targets by recruiting the 5‐sensor domain of RNase E ‘in trans’.     

The ribosome binding site of a mini‐ORF protects a T3SS mRNA from degradation by RNase E

Enterohaemorrhagic Escherichia coli harbours a pathogenicity island encoding a type 3 secretion system used to translocate effector proteins into the cytosol of intestinal epithelial cells and subvert their function. The structural proteins of the translocon are encoded in a major espADB mRNA processed from a precursor. The translocon mRNA should be highly susceptible to RNase E cleavage because of its AU‐rich leader region and monophosphorylated 5′‐terminus, yet it manages to avoid rapid degradation. Here, we report that the espADB leader region contains a strong Shine–Dalgarno element (SD2) and a translatable mini‐ORF of six codons. Disruption of SD2 so as to weaken ribosome binding significantly reduces the concentration and stability of esp mRNA, whereas codon substitutions that impair translation of the mini‐ORF have no such effect. These findings suggest that occupancy of SD2 by ribosomes, but not mini‐ORF translation, helps to protect espADB mRNA from degradation, likely by hindering RNase E access to the AU‐rich leader region.     

A small RNA activates CFA synthase by isoform‐specific mRNA stabilization

Small RNAs use a diversity of well‐characterized mechanisms to repress mRNAs, but how they activate gene expression at the mRNA level remains not well understood. The predominant activation mechanism of Hfq‐associated small RNAs has been translational control whereby base pairing with the target prevents the formation of an intrinsic inhibitory structure in the mRNA and promotes translation initiation. Here, we report a translation‐independent mechanism whereby the small RNA RydC selectively activates the longer of two isoforms of cfa mRNA (encoding cyclopropane fatty acid synthase) in Salmonella enterica. Target activation is achieved through seed pairing of the pseudoknot‐exposed, conserved 5′ end of RydC to an upstream region of the cfa mRNA. The seed pairing stabilizes the messenger, likely by interfering directly with RNase E‐mediated decay in the 5′ untranslated region. Intriguingly, this mechanism is generic such that the activation is equally achieved by seed pairing of unrelated small RNAs, suggesting that this mechanism may be utilized in the design of RNA‐controlled synthetic circuits. Physiologically, RydC is the first small RNA known to regulate membrane stability.     

Distinct Requirements for 5′-Monophosphate-assisted RNA Cleavage by Escherichia coli RNase E and RNase G

RNase E and RNase G are homologous endonucleases that play important roles in RNA processing and decay in Escherichia coli and related bacterial species. Rapid mRNA degradation is facilitated by the preference of both enzymes for decay intermediates whose 5′ end is monophosphorylated. In this report we identify key characteristics of RNA that influence the rate of 5′-monophosphate-assisted cleavage by these two ribonucleases. In vitro, both require at least two and prefer three or more unpaired 5′-terminal nucleotides for such cleavage; however, RNase G is impeded more than RNase E when fewer than four unpaired nucleotides are present at the 5′ end. Each can tolerate any unpaired nucleotide (A, G, C, or U) at either of the first two positions, with only modest biases. The optimal spacing between the 5′ end and the scissile phosphate appears to be eight nucleotides for RNase E but only six for RNase G. 5′-Monophosphate-assisted cleavage also occurs, albeit more slowly, when that spacing is greater or at most one nucleotide shorter than the optimum, but there is no simple inverse relationship between increased spacing and the rate of cleavage. These properties are also manifested during 5′-end-dependent mRNA degradation in E. coli.     

Bacillus subtilis ribonucleases J1 and J2 form a complex with altered enzyme behaviour

Ribonucleases J1 and J2 are recently discovered enzymes with dual 5′‐to‐3′ exoribonucleolytic/endoribonucleolytic activity that plays a key role in the maturation and degradation of Bacillus subtilis RNAs. RNase J1 is essential, while its paralogue RNase J2 is not. Up to now, it had generally been assumed that the two enzymes functioned independently. Here we present evidence that RNases J1 and J2 form a complex that is likely to be the predominant form of these enzymes in wild‐type cells. While both RNase J1 and the RNase J1/J2 complex have robust 5′‐to‐3′ exoribonuclease activity in vitro, RNase J2 has at least two orders of magnitude weaker exonuclease activity, providing a possible explanation for why RNase J1 is essential. The association of the two proteins also has an effect on the endoribonucleolytic properties of RNases J1 and J2. While the individual enzymes have similar endonucleolytic cleavage activities and specificities, as a complex they behave synergistically to alter cleavage site preference and to increase cleavage efficiency at specific sites. These observations dramatically change our perception of how these ribonucleases function and provide an interesting example of enzyme subfunctionalization after gene duplication.     

RNase HI stimulates the activity of RnlA toxin in Escherichia coli

A type II toxin–antitoxin system in Escherichia coli, rnlA‐rnlB, functions as an anti‐phage mechanism. RnlA is a toxin with an endoribonuclease activity and the cognate RnlB inhibits RnlA toxicity in E. coli cells. After bacteriophage T4 infection, RnlA is activated by the disappearance of RnlB, resulting in the rapid degradation of T4 mRNAs and consequently no T4 propagation, when T4 dmd is defective: Dmd is an antitoxin against RnlA for promoting own propagation. Previous studies suggested that the activation of RnlA after T4 infection was regulated by multiple components. Here, we provide the evidence that RNase HI is an essential factor for activation of RnlA. The dmd mutant phage could grow on ΔrnhA (encoding RNase HI) cells, in which RnlA‐mediated mRNA cleavage activity was defective. RNase HI bound to RnlA in vivo and enhanced the RNA cleavage activity of RnlA in vitro. In addition, ectopic expression of RnlA in ΔrnlAB ΔrnhA cells has less effect on cell toxicity and RnlA‐mediated mRNA degradation than in ΔrnlAB cells. This is the first example of a direct factor for activation of a toxin.     

The effects of RNA degradation enzymes on antisense RNAI controlling ColE2 plasmid copy number

Replication of the ColE2 plasmid requires a plasmid-coded initiator protein (Rep). Rep expression is controlled by antisense RNA (RNAI), which prevents the Rep mRNA translation. In this paper, we examined the effects of RNA degradation enzymes on the degradation pathways of RNAI of the ColE2 plasmid. In the DeltapcnB strain lacking the poly(A) polymerase I (PAP I) the RNAI degradation intermediate (RNAI(*)) accumulates much more than that in the wt strain. RNAI(*) is produced by the RNase E cleavage. RNase II and PNPase are involved in further degradation of RNAI(*) and PAP I is necessary for efficient degradation. The degradation process of ColE2 RNAI is similar to those of R1 CopA RNA and ColE1 RNAI, although the nucleotide sequences and fine secondary structures of these three RNAs are different. ColE2 RNAI is cleaved at multiple positions in the 5' end region by RNase E. The degradation pathway of ColE2 RNAI shown here is quite different from that of the ColE2 Rep mRNA which we have previously reported. In the DeltapcnB strain used for RNA analysis the copy number of the ColE2 plasmid decreases to about a half as compared with that in the isogenic wt strain.