Single amino acid changes in the predicted RNase H domain of Escherichia coli RNase G lead to complementation of RNase E deletion mutants

The endoribonuclease RNase E of Escherichia coli is an essential enzyme that plays a major role in all aspects of RNA metabolism. In contrast, its paralog, RNase G, seems to have more limited functions. It is involved in the maturation of the 5′ terminus of 16S rRNA, the processing of a few tRNAs, and the initiation of decay of a limited number of mRNAs but is not required for cell viability and cannot substitute for RNase E under normal physiological conditions. Here we show that neither the native nor N-terminal extended form of RNase G can restore the growth defect associated with either the rne-1 or rneΔ1018 alleles even when expressed at very high protein levels. In contrast, two distinct spontaneously derived single amino acid substitutions within the predicted RNase H domain of RNase G, generating the rng-219 and rng-248 alleles, result in complementation of the growth defect associated with various RNase E mutants, suggesting that this region of the two proteins may help distinguish their in vivo biological activities. Analysis of rneΔ1018/rng-219 and rneΔ1018/rng-248 double mutants has provided interesting insights into the distinct roles of RNase E and RNase G in mRNA decay and tRNA processing.     

RNase G of Escherichia coli exhibits only limited functional overlap with its essential homologue,RNase E

RNase G (rng) is an E. coli endoribonuclease that is homologous to the catalytic domain of RNase E (rne), an essential protein that is a major participant in tRNA maturation, mRNA decay, rRNA processing and M1 RNA processing. We demonstrate here that whereas RNase G inefficiently participates in the degradation of mRNAs and the processing of 9S rRNA, it is not involved in either tRNA or M1 RNA processing. This conclusion is supported by the fact that inactivation of RNase G alone does not affect 9S rRNA processing and only leads to minor changes in mRNA half-lives. However, in rng rne double mutants mRNA decay and 9S rRNA processing are more defective than in either single mutant. Conversely, increasing RNase G levels in an rne-1 rng::cat double mutant, proportionally increased the extent of 9S rRNA processing and decreased the half-lives of specific mRNAs. In contrast, variations in the amount of RNase G did not alter tRNA processing under any circumstances. Thus, the failure of RNase G to complement rne mutations, even when overproduced at high levels, apparently results from its inability to substitute for RNase E in the maturation of tRNAs.     

Analysis of mRNA decay and rRNA processing in Escherichia coli multiple mutants carrying a deletion in RNase III.

RNase III is an endonuclease involved in processing both rRNA and certain mRNAs. To help determine whether RNase III (rnc) is required for general mRNA turnover in Escherichia coli, we have created a deletion-insertion mutation (delta rnc-38) in the structural gene. In addition, a series of multiple mutant strains containing deficiencies in RNase II (rnb-500), polynucleotide phosphorylase (pnp-7 or pnp-200), RNase E (rne-1 or rne-3071), and RNase III (delta rnc-38) were constructed. The delta rnc-38 single mutant was viable and led to the accumulation of 30S rRNA precursors, as has been previously observed with the rnc-105 allele (P. Gegenheimer, N. Watson, and D. Apirion, J. Biol. Chem. 252:3064-3073, 1977). In the multiple mutant strains, the presence of the delta rnc-38 allele resulted in the more rapid decay of pulse-labeled RNA but did not suppress conditional lethality, suggesting that the lethality associated with altered mRNA turnover may be due to the stabilization of specific mRNAs. In addition, these results indicate that RNase III is probably not required for general mRNA decay. Of particular interest was the observation that the delta rnc-38 rne-1 double mutant did not accumulate 30S rRNA precursors at 30 degrees C, while the delta rnc-38 rne-3071 double mutant did. Possible explanations of these results are discussed.     

The rne gene is the structural gene for the processing endoribonuclease RNase E of Escherichia coli.

Summary Using T7 RNA polymerase and specific constructs derived from 5S rRNA and RNA I genes, we generated substrates for the RNA processing enzyme RNase E. Using these substrates we have shown that a 3.2 kb DNA fragment that complements the rne-3071 mutation can express RNase E activity. We also found that T7 RNA polymerase terminates within the 5S rRNA gene.     

Analysis of mRNA decay and rRNA processing in Escherichia coli in the absence of RNase E-based degradosome assembly

We demonstrate here that the assembly of the RNase E-based degradosome of Escherichia coli is not required for normal mRNA decay in vivo. In contrast, deletion of the arginine-rich RNA binding site (ARRBS) from the RNase E protein slightly impairs mRNA decay. When both the degradosome scaffold region and the ARRBS are missing, mRNA decay is dramatically slowed, but 9S rRNA processing is almost normal. An extensive RNase E truncation mutation (rnedelta610) had a more pronounced mRNA decay defect at 37 degrees C than the temperature-sensitive rne-1 allele at 44 degrees C. Taken together, these data suggest that the inviability associated with inactivation of RNase E is not related to defects in either mRNA decay or rRNA processing.     

The action of α-amanitin in vivo on the synthesis and maturation of mouse liver ribonucleic acids

α-Amanitin acts in vitro and in vivo as a selective inhibitor of nucleoplasmic RNA polymerases. Treatment of mice with low doses of α-amanitin causes the following changes in the synthesis, maturation and nucleocytoplasmic transfer of liver RNA species. 1. The synthesis of the nuclear precursor of mRNA is strongly inhibited and all electrophoretic components are randomly affected. The labelling of cytoplasmic mRNA is blocked. These effects may be correlated with the rapid and lasting inhibition of nucleoplasmic RNA polymerase. 2. The synthesis and maturation of the nuclear precursor of rRNA is inhibited within 30min. (a) The initial effect is a strong (about 80%) inhibition of the early steps of 45S precursor rRNA maturation. (b) The synthesis of 45S precursor rRNA is also inhibited and the effect increases from about 30% at 30min to more than 70% at 150min. (c) The labelling of nuclear and cytoplasmic 28S and 18S rRNA is almost completely blocked. The labelling of nuclear 5S rRNA is inhibited by about 50%, but that of cytoplasmic 5S rRNA is blocked. (d) The action of α-amanitin on the synthesis of precursor rRNA cannot be correlated with the slight gradual decrease of nucleolar RNA polymerase activity (only 10–20% inhibition at 150min). (e) The inhibition of precursor rRNA maturation and synthesis precedes the ultrastructural lesions of the nucleolus detected by standard electron microscopy. 3. The synthesis of nuclear 4.6S precursor of tRNA is not affected by α-amanitin. However, the labelling of nuclear and cytoplasmic tRNA is decreased by about 50%, which indicates an inhibition of precursor tRNA maturation. The results of this study suggest that the synthesis and maturation of the precursor of rRNA and the maturation of the precursor of tRNA are under the control of nucleoplasmic gene products. The regulator molecules may be either RNA or proteins with exceedingly fast turnover.     

The function of RNase G in Escherichia coli is constrained by its amino and carboxyl termini

RNase G is a homologue of the essential Escherichia coli ribonuclease RNase E. Whereas RNase E plays a key role in the degradation of mRNA and the processing of tRNA and rRNA in E. coli, the biological functions of RNase G appear more limited. We report here that this difference in function is not merely a consequence of the significantly lower cellular concentration of RNase G, but also reflects differences in the intrinsic properties of these ribonucleases, as overproducing wild-type RNase G at a level up to 20 times the usual cellular concentration of RNase E cannot normally compensate for the absence of RNase E in E. coli. Instead, RNase G can sustain significant growth of RNase E-deficient E. coli cells only when it bears an unnatural extension at its amino terminus (e.g. MRKGINM) or carboxyl terminus (e.g. GHHHHHH). These extensions presumably enable RNase G to cleave critically important cellular RNAs whose efficient processing or degradation ordinarily requires RNase E. That extending the amino terminus of RNase G restores growth to E. coli cells lacking RNase E without detectably improving tRNA processing suggests that RNase E is not essential for tRNA production and is required for cell growth because it plays an indispensable role in the maturation or decay of essential E. coli RNAs other than tRNA.     

The gene specifying RNase E (rne) and a gene affecting mRNA stability (ams) are the same gene

A DNA clone complementing the rne-3071 mutation has been expressed and localized in the physical map of Escherichia coli. The DNA fragment from this clone was localized to the region of the E. coli chromosome where the rne-3071 mutation has been mapped. The position of this DNA fragment in the E. coli chromosome, the size of the product directed by this DNA fragment (110,000 Da), the restriction map of this fragment, the fact that the same clone complements the ams mutation, and the observation that the rne-3071 and the ams mutations cause similar patterns of RNA synthesis, show that the rne gene--a gene specifying the processing endonuclease RNase E--and the ams gene--a gene that affects mRNA stability--are identical.     

3′ Untranslated Region-Dependent Degradation of the aceA mRNA,Encoding the Glyoxylate Cycle Enzyme Isocitrate Lyase,by RNase E/G in Corynebacterium glutamicum

We previously reported that the Corynebacterium glutamicum RNase E/G encoded by the rneG gene (NCgl2281) is required for the 5′ maturation of 5S rRNA. In the search for the intracellular target RNAs of RNase E/G other than the 5S rRNA precursor, we detected that the amount of isocitrate lyase, an enzyme of the glyoxylate cycle, increased in rneG knockout mutant cells grown on sodium acetate as the sole carbon source. Rifampin chase experiments showed that the half-life of the aceA mRNA was about 4 times longer in the rneG knockout mutant than in the wild type. Quantitative real-time PCR analysis also confirmed that the level of aceA mRNA was approximately 3-fold higher in the rneG knockout mutant strain than in the wild type. Such differences were not observed in other mRNAs encoding enzymes involved in acetate metabolism. Analysis by 3′ rapid amplification of cDNA ends suggested that RNase E/G cleaves the aceA mRNA at a single-stranded AU-rich region in the 3′ untranslated region (3′-UTR). The lacZ fusion assay showed that the 3′-UTR rendered lacZ mRNA RNase E/G dependent. These findings indicate that RNase E/G is a novel regulator of the glyoxylate cycle in C. glutamicum.     

<Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis> RNase E/G-type endoribonuclease encoded by NCgl2281 is involved in the 5′ maturation of 5S rRNA

Corynebacterium glutamicum has one RNase E/G ortholog and one RNase J ortholog but no RNase Y. We previously reported that the C. glutamicum NCgl2281 gene encoding the RNase E/G ortholog complemented the rng::cat mutation in Escherichia coli but not the rne-1 mutation. In this study, we constructed an NCgl2281 knockout mutant and found that the mutant cells accumulated 5S rRNA precursor molecules. The processing of 16S and 23S rRNA, tRNA, and tmRNA was normal. Primer extension analysis revealed that the RNase E/G ortholog cleaved at the −1 site of the 5′ end of 5S rRNA. However, 3′ maturation was essentially unaffected. These findings showed that C. glutamicum NCgl2281 endoribonuclease is involved in the 5′ maturation of 5S rRNA. This is the first report showing the physiological function of the RNase E/G ortholog in bacteria having one RNase E/G and one RNase J but no RNase Y.     

Roles of the 5'-phosphate sensor domain in RNase E

Viable mutations affecting the 5'-phosphate sensor of RNase E, including R169Q or T170A, become lethal when combined with deletions removing part of the non-catalytic C-terminal domain of RNase E. The phosphate sensor is required for efficient autoregulation of RNase E synthesis as RNase E R169Q is strongly overexpressed with accumulation of proteolytic fragments. In addition, mutation of the phosphate sensor stabilizes the rpsT P1 mRNA as much as sixfold and slows the maturation of 16S rRNA. In contrast, the decay of other model mRNAs and the processing of several tRNA precursors are unaffected by mutations in the phosphate sensor. Our data point to the existence of overlapping mechanisms of substrate recognition by RNase E, which lead to a hierarchy of efficiencies with which its RNA targets are attacked.     

The ams-1 and rne-3071 temperature-sensitive mutations in the ams gene are in close proximity to each other and cause substitutions within a domain that resembles a product of the Escherichia coli mre locus.

Two temperature-sensitive mutations, ams-1 and rne-3071, in the ams (altered mRNA stability) gene have been used extensively to investigate the processing and decay of RNA in Escherichia coli. We have sequenced these temperature-sensitive alleles and found that the mutations are separated by only 6 nucleotides and cause conservative amino acid substitutions next to a possible nucleotide-binding site within the N-terminal domain of the Ams protein. Computer analysis revealed that the region altered by the mutations has extensive sequence similarity to a predicted gene product from the mre (murein pathway cluster e) locus of E. coli, which has been implicated previously in determining bacterial cell shape.     

RNA structure-dependent uncoupling of substrate recognition and cleavage by Escherichia coli ribonuclease III

Members of the ribonuclease III superfamily of double-strand-specific endoribonucleases participate in diverse RNA maturation and decay pathways. Ribonuclease III of the gram-negative bacterium Escherichia coli processes rRNA and mRNA precursors, and its catalytic action can regulate gene expression by controlling mRNA translation and stability. It has been proposed that E.coli RNase III can function in a non-catalytic manner, by binding RNA without cleaving phosphodiesters. However, there has been no direct evidence for this mode of action. We describe here an RNA, derived from the T7 phage R1.1 RNase III substrate, that is resistant to cleavage in vitro by E.coli RNase III but retains comparable binding affinity. R1.1[CL3B] RNA is recognized by RNase III in the same manner as R1.1 RNA, as revealed by the similar inhibitory effects of a specific mutation in both substrates. Structure-probing assays and Mfold analysis indicate that R1.1[CL3B] RNA possesses a bulge– helix–bulge motif in place of the R1.1 asymmetric internal loop. The presence of both bulges is required for uncoupling. The bulge–helix–bulge motif acts as a ‘catalytic’ antideterminant, which is distinct from recognition antideterminants, which inhibit RNase III binding.     

The C nucleotide at the mature 5′ end of the Escherichia coli proline tRNAs is required for the RNase E cleavage specificity at the 3′ terminus as well as functionality

Proline tRNA 3′-maturation in Escherichia coli occurs through a one-step RNase E endonucleolytic cleavage immediately after the CCA determinant. This processing pathway is distinct from the 3′-end maturation of the other tRNAs by avoiding the widespread use of 3′ → 5′ exonucleolytic processing, 3′-polyadenylation and subsequent degradation. Here, we show that the cytosine (C) at the mature 5′-terminus of the proK and proL tRNAs is required for both the RNase E cleavage immediately after the CCA determinant and their functionality. Thus, changing the C nucleotide at the mature 5′-terminus of the proL and proK tRNAs to the more common G nucleotide led to RNase E cleavages 1–4 nucleotides downstream of the CCA determinant. Furthermore, the 5′-modified mutant tRNAs required RNase T and RNase PH for their 3′-maturation and became substrates for polyadenylation and degradation. Strikingly, the aminoacylation of the 5′-modified proline tRNAs was blocked due to the change in the recognition element for prolyl-tRNA-synthetase. An analogous modification of the pheV 5′-mature terminus from G to C nucleotide did not support cell viability. This result provides additional support for the importance of first nucleotide of the mature tRNAs in their processing and functionality.     

Deregulation of poly(A) polymerase I in Escherichia coli inhibits protein synthesis and leads to cell death

Polyadenylation plays important roles in RNA metabolism in both prokaryotes and eukaryotes. Surprisingly, deregulation of polyadenylation by poly(A) polymerase I (PAP I) in Escherichia coli leads to toxicity and cell death. We show here that mature tRNAs, which are normally not substrates for PAP I in wild-type cells, are rapidly polyadenylated as PAP I levels increase, leading to dramatic reductions in the fraction of aminoacylated tRNAs, cessation of protein synthesis and cell death. The toxicity associated with PAP I is exacerbated by the absence of either RNase T and/or RNase PH, the two major 3′ → 5′ exonucleases involved in the final step of tRNA 3′-end maturation, confirming their role in the regulation of tRNA polyadenylation. Furthermore, our data demonstrate that regulation of PAP I is critical not for preventing the decay of mRNAs, but rather for maintaining normal levels of functional tRNAs and protein synthesis in E. coli, a function for polyadenylation that has not been observed previously in any organism.     

Drosophila RNase Z processes mitochondrial and nuclear pre-tRNA 3' ends in vivo

Although correct tRNA 3′ ends are crucial for protein biosynthesis, generation of mature tRNA 3′ ends in eukaryotes is poorly understood and has so far only been investigated in vitro. We report here for the first time that eukaryotic tRNA 3′ end maturation is catalysed by the endonuclease RNase Z in vivo. Silencing of the JhI-1 gene (RNase Z homolog) in vivo with RNAi in Drosophila S2 cultured cells causes accumulation of nuclear and mitochondrial pre-tRNAs, suggesting that JhI-1 encodes both forms of the tRNA 3′ endonuclease RNase Z, and establishing its biological role in endonucleolytic tRNA 3′ end processing. In addition our data show that in vivo 5′ processing of nuclear and mitochondrial pre-tRNAs occurs before 3′ processing.