Purification and properties of ribonuclease E, an RNA-processing enzyme from Escherichia coli

In Vivo Cleavage Map Illuminates the Central Role of RNase E in Coding and Non-coding RNA Pathways

Understanding RNA processing and turnover requires knowledge of cleavages by major endoribonucleases within a living cell. We have employed TIER-seq (transiently inactivating an endoribonuclease followed by RNA-seq) to profile cleavage products of the essential endoribonuclease RNase E in Salmonella enterica. A dominating cleavage signature is the location of a uridine two nucleotides downstream in a single-stranded segment, which we rationalize structurally as a key recognition determinant that may favor RNase E catalysis. Our results suggest a prominent biogenesis pathway for bacterial regulatory small RNAs whereby RNase E acts together with the RNA chaperone Hfq to liberate stable 3' fragments from various precursor RNAs. Recapitulating this process in vitro, Hfq guides RNase E cleavage of a representative small-RNA precursor for interaction with a mRNA target. In vivo, the processing is required for target regulation. Our findings reveal a general maturation mechanism for a major class of post-transcriptional regulators.

Degradation of mRNA in Escherichia coli: an old problem with some new twists

Metabolic instability is a hallmark property of mRNAs in most if not all organisms and plays an essential role in facilitating rapid responses to regulatory cues. This article provides a critical examination of recent progress in the enzymology of mRNA decay in Escherichia coli, focusing on six major enzymes: RNase III, RNase E, polynucleotide phosphorylase, RNase II, poly(A) polymerase(s), and RNA helicase(s). The first major advance in our thinking about mechanisms of RNA decay has been catalyzed by the possibility that mRNA decay is orchestrated by a multicomponent mRNA-protein complex (the "degradosome"). The ramifications of this discovery are discussed and developed into mRNA decay models that integrate the properties of the ribonucleases and their associated proteins, the role of RNA structure in determining the susceptibility of an RNA to decay, and some of the known kinetic features of mRNA decay. These models propose that mRNA decay is a vectorial process initiated primarily at or near the 5' terminus of susceptible mRNAs and propagated by successive endonucleolytic cleavages catalyzed by RNase E in the degradosome. It seems likely that the degradosome can be tethered to its substrate, either physically or kinetically through a preference for monphosphorylated RNAs, accounting for the usual "all or none" nature of mRNA decay. A second recent advance in our thinking about mRNA decay is the rediscovery of polyadenylated mRNA in bacteria. Models are provided to account for the role of polyadenylation in facilitating the 3' exonucleolytic degradation of structured RNAs. Finally, we have reviewed the documented properties of several well-studied paradigms for mRNA decay in E. coli. We interpret the published data in light of our models and the properties of the degradosome. It seems likely that the study of mRNA decay is about to enter a phase in which research will focus on the structural basis for recognition of cleavage sites, on catalytic mechanisms, and on regulation of mRNA decay.

Proteins associated with RNase E in a multicomponent ribonucleolytic complex

The Escherichia coli endoribonuclease RNase E is essential for RNA processing and degradation. Earlier work provided evidence that RNase E exists intracellularly as part of a multicomponent complex and that one of the components of this complex is a 3'-to-5' exoribonuclease, polynucleotide phosphorylase (EC 2.7.7.8). To isolate and identify other components of the RNase E complex, FLAG-epitope-tagged RNase E (FLAG-Rne) fusion protein was purified on a monoclonal antibody-conjugated agarose column. The FLAG-Rne fusion protein, eluted by competition with the synthetic FLAG peptide, was found to be associated with other proteins. N-terminal sequencing of these proteins revealed the presence in the RNase E complex not only of polynucleotide phosphorylase but also of DnaK, RNA helicase, and enolase (EC 4.2.1.11). Another protein associated only with epitope-tagged temperature-sensitive (Rne-3071) mutant RNase E but not with the wild-type enzyme is GroEL. The FLAG-Rne complex has RNase E activity in vivo and in vitro. The relative amount of proteins associated with wild-type and Rne-3071 expressed at an elevated temperature differed.

Translation through an uncDC mRNA secondary structure governs the level of uncC expression in Escherichia coli

Escherichia coli expresses the beta and epsilon subunits of F1F0-ATP synthase at relative levels consistent with the 3:1 (beta/epsilon) stoichiometry in the holoenzyme. The mechanism of translational control of expression of the uncC gene (epsilon subunit) relative to the immediately 5' uncD gene (beta subunit) was examined. Previous expression studies and a computer analysis suggested the presence of an RNA secondary structure including the 3' end of uncD, the uncDC intergenic region, and the uncC Shine-Dalgarno sequence (S. D. Dunn and H. G. Dallmann, J. Bacteriol. 172:2782-2784, 1990). Analysis of in vitro-transcribed RNA by cleavage with RNases T1, V1, and CL3 and by chemical modification with dimethyl sulfate and diethyl pyrocarbonate confirmed a predicted structure. Introduction of premature uncD stop codons inserted 5' of the secondary structure strongly reduced epsilon expression, whereas stop codons inserted at positions within the secondary structure showed smaller effects, indicating that translational control of epsilon synthesis involves partial coupling to beta synthesis. Possible mechanisms by which the RNA secondary structure and the unfolding of this structure by translation of uncD may govern the level of uncC expression are discussed.

The rne gene and ribonuclease E

The cloned rne+ gene complements temperature sensitive RNase E mutations and directs the synthesis of a polypeptide. In vitro the RNA transcribed from the rne gene directs the synthesis of a number of polypeptides, one of which is identical in size to the in vivo product of the rne gene. A rabbit reticulocyte cell free extract programmed with this RNA produced RNase E activity. Thus, it is evident that the rne gene is the structural gene for RNase E. However, the in vivo product of the cloned RNase E gene is more thermolabile than the chromosomal gene product. When cells containing the rne plasmid were treated with chloramphenicol, the pre-existing RNase E became less heat labile with time. This leads to the suggestion that in the cell RNase E undergoes post-translational modification(s).

Functional interaction of heat shock protein GroEL with an RNase E-like activity in Escherichia coli

The highly specific endoribonuclease activities of RNase E (which processes ribosomal 9S RNA into p5S RNA) and RNase K (which initiates decay of the ompA mRNA) are inferred to play a central role in RNA processing and mRNA decay in Escherichia coli. In vivo both activities are affected by a conditional mutation of the ams/rne gene that seems to be complemented at nonpermissive temperatures by a fragment of the groEL gene. Analysis of the relationship between the two nucleases and the heat shock protein revealed that GroEL interacts functionally with an RNase E-like activity but not with an RNase K activity, a groEL mutation affected 9S RNA processing but not ompA mRNA cleavage, RNase E activity could be precipitated with an antibody against GroEL, and a highly purified GroEL preparation contained RNase E activity but not RNase K activity. When purifying RNase E activity, we obtained a preparation containing two major proteins of 60 and 17 kDa. The size and the N-terminal sequence identified the 60-kDa protein as GroEL.

Control of RNase E-mediated RNA degradation by 5'-terminal base pairing in E. coli

Despite the variety of messenger RNA half-lives in bacteria (0.5-30 min in Escherichia coli) and their importance in controlling gene expression, their molecular basis remains obscure. The lifetime of an entire mRNA molecule can be determined by features near its 5' end, but no 5' exoribonuclease has been identified in any prokaryotic organism. A mutation that inactivates E. coli RNase E also increases the average lifetime of bulk E. coli mRNA and of many individual messages, suggesting that cleavage by this endonuclease may be the rate-determining step in the degradation of most mRNAs in E. coli. We have investigated the substrate preference of RNase E in E. coli by using variants of RNA I, a small untranslated RNA whose swift degradation in vivo is initiated by RNase E cleavage at an internal site. We report here that RNase E has an unprecedented substrate specificity for an endoribonuclease, as it preferentially cleaves RNAs that have several unpaired nucleotides at the 5' end. The sensitivity of RNase E to 5'-terminal base pairing may explain how determinants near the 5' end can control rates of mRNA decay in bacteria.

The rate of processing and degradation of antisense RNAI regulates the replication of ColE1-type plasmids in vivo

We show that the rate of degradation of RNAI, an anti-sense repressor of the replication primer RNAII, is a key element of control in the replication of ColE1-type plasmids in vivo. Cleavage of RNAI by RNAase E, a ribosomal RNA-processing enzyme encoded or controlled by the rne (also known as ams) locus, relieves repression by endonucleolytically converting RNAI to a very rapidly decaying product, pRNAI-5. A 5' triphosphate-terminated homolog of pRNAI-5 is degraded slowly and consequently inhibits replication. Nucleotide substitutions within the RNAase E cleavage sequence alter RNAI half-life and plasmid copy number, changing also the incompatibility phenotype. RNAI variants lacking the sequence cleaved by RNAase E are eliminated by growth rate-dependent degradation, resulting in growth-responsive control of plasmid replication and copy number.

Genetic studies of cleavage-initiated mRNA decay and processing of ribosomal 9S RNA show that the Escherichia coli ams and rne loci are the same

We show in the present paper that the cleavages initiating decay of the ompA mRNA are suppressed both in the Escherichia coli ams(ts) strain (originally defined by a prolonged bulk mRNA half-life) and in the me(ts) strain (originally defined by aberrant 9S RNA processing). The temperature-sensitive defects of both these strains are complemented by a recombinant lambda phage containing a genomic segment that carries the putative ams locus. A 5.8 kb fragment from this genomic DNA segment was cloned into a low-copy plasmid and used to transform the ams(ts) and rne(ts) strains. This resulted in growth at the non-permissive temperature and a reoccurrence of the cleavages initiating decay of the ompA mRNA. Deletion analyses of this 5.8 kb fragment indicated that the putative ams open reading frame could complement both the Ams(ts) and the Rne(ts) phenotype with regard to the ompA cleavages. In addition we showed that the ams(ts) strain suppresses 9S RNA processing to 5S RNA to the same extent as the rne(ts) strain, and that the rne(ts0 strain has a prolonged bulk mRNA half-life, as was reported for the ams(ts) strain. Therefore we suggest that ams and rne reflect the same gene locus; one which is involved both in mRNA decay and RNA processing. We discuss how this gene locus may related to the previously characterized endoribonucleolytic activities of RNase E and RNase K.

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.

Sequencing and expression of the rne gene of Escherichia coli

RNase E is a major endonucleolytic RNA processing enzyme in Escherichia coli. We have sequenced a 3.2 kb EcoRI-BamHI fragment encoding the rne gene, and identified its reading frame. Upstream from the gene, there are appropriate consensus sequences for a putative promoter and a ribosome binding site. We have translated this gene using a T7 RNA polymerase/promoter system. We determined 25 amino acids from the N-terminal of the translated product and they are in full agreement with the DNA sequence. The translated product of the rne gene migrates in SDS containing polyacrylamide gels as a 110,000 Da polypeptide, but the open reading frame found in the sequenced DNA indicates a much smaller protein. The entity that migrates as a 110,000 Da contains RNA, which could account, at least partially, for the migration of the rne gene product in SDS containing polyacrylamide gels.

Processing enzyme ribonuclease E specifically cleaves RNA I. An inhibitor of primer formation in plasmid DNA synthesis

When the RNA processing enzyme RNAase E is inactivated in an Escherichia coli strain carrying derivatives of the colicin E1 plasmid, a small RNA, about 100 nucleotides long, accumulates. Structural analysis of this RNA showed that it is RNA I, the RNA that inhibits plasmid DNA synthesis. RNA I is a specific substrate for RNAase E and the cleavage takes place between the fifth and sixth nucleotides from the 5' end of the molecule. This is only the second natural RNA substrate that has been found, so far, for the RNA processing enzyme ribonuclease E, the other being a precursor for 5 S ribosomal RNA. It is remarkable that nine nucleotides around the cleavage sites are identical in both substrates: (Formula: see text). Therefore, we suggest that at least part of the interaction between RNAase E and its substrate is controlled by these nine nucleotides.

Molecular cloning of the gene for the RNA-processing enzyme RNase III of Escherichia coli

A ColE1 plasmid from the Clarke and Carbon collection [Clarke, L. & Carbon, J. (1976) Cell 9, 91-99] that contains a 14.4-kilobase Escherichia coli DNA insert complements the rnc-105 mutation, which destroys the activity of the RNA-processing enzyme RNase III. This insert and smaller restriction endonuclease fragments derived from it were cloned into the plasmid pBR329. A number of these recombinant plasmids complemented the rnc-105 mutation in a recA genetic background. The smallest cloned fragment that compensated for the rnc-105 mutation was 1.3 kilobase in size. This fragment led to the synthesis of two polypeptides. One of these polypeptides was 25,300 daltons and corresponded in size to the subunit of RNase III. Fragments cloned in opposite orientations led to synthesis of RNase III, indicating that the cloned fragments contained an endogenous promoter. Extracts of an rnc+ E. coli strain containing an rnc+ plasmid had at least 10 times more RNase III activity than did an analogous strain containing the pBR329 plasmid.

Synthesis and processing of 5 S rRNA from an rrnB minigene in a plasmid

A recombinant plasmid containing the promoters, terminators and only the intact 5 S rRNA gene of rrnB is expressed efficiently in Escherichia coli cells. In strains containing a thermolabile RNAase E (rne) full-length transcripts of the rrnB region from the plasmid and a partially processed intermediate product accumulate at non-permissive temperatures. Upon addition of chloramphenicol two additional plasmid-specific RNA molecules appear. They are shorter than the full-length transcripts. These species contain the 3'-end region of the full-length transcripts. Even though the 5' ends of these RNAs were most likely produced by degradative enzymes these 5' ends are not ragged. All these plasmid-specific RNAs are specific substrates for the two endonucleolytic RNA processing enzymes, RNAase E and RNAase III.