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

Stochastic nature and physiological implications of 5'-NAD RNA cap in bacteria

RNA 5'-modification with NAD+/NADH (oxidized/reduced nicotinamide adenine dinucleotide) has been found in bacteria, eukaryotes and viruses. 5'-NAD is incorporated into RNA by RNA polymerases (RNAPs) during the initiation of synthesis. It is unknown (i) which factors and physiological conditions permit substantial NAD incorporation into RNA in vivo and (ii) how 5'-NAD impacts gene expression and the fate of RNA in bacteria. Here we show in Escherichia coli that RNA NADylation is stimulated by low cellular concentration of the competing substrate ATP, and by weakening ATP contacts with RNAP active site. Additionally, RNA NADylation may be influenced by DNA supercoiling. RNA NADylation does not interfere with posttranscriptional RNA processing by major ribonuclease RNase E. It does not impact the base-pairing between RNAI, the repressor of plasmid replication, and its antisense target, RNAII. Leaderless NADylated model mRNA cI-lacZ is recognized by the 70S ribosome and is translated with the same efficiency as triphosphorylated cI-lacZ mRNA. Translation exposes the 5'-NAD of this mRNA to de-capping by NudC enzyme. We suggest that NADylated mRNAs are rapidly degraded, consistent with their low abundance in published datasets. Furthermore, we observed that ppGpp inhibits NudC de-capping activity, contributing to the growth phase-dependency of NADylated RNA levels.

Hfq-Antisense RNA I Binding Regulates RNase E-Dependent RNA Stability and ColE1 Plasmid Copy Number

The mechanisms and consequences of gene regulation by Hfq on trans-encoded small RNAs (sRNAs) have been well studied and documented. Recent employment of Genomic SELEX to search for Hfq-binding motifs has indicated that Hfq might frequently regulate gene expression controlled by cis-antisense RNAs. Here, we use the classic ColE1 plasmid antisense RNA-based regulation model (i.e., RNA I) to study the role of Hfq in controlling antisense regulatory functions. We show that Hfq exhibits a high binding affinity for RNA I and that binding limits RNase E cleavage, thereby stabilizing RNA I and reducing the plasmid copy number. Full-length RNA I displays a binding affinity for Hfq in the sub-micromolar range. In vivo overexpression of Hfq prolongs RNA I stability and reduces the ColE1 plasmid copy number, whereas deletion of hfq reduces RNA I stability and increases the plasmid copy number. RNA I predominantly binds to the proximal face of Hfq and exhibits competitive ability against a chromosome-borne proximal face-bound sRNA (DsrA) for Hfq binding. Through its strong promoter and high gene dosage features, plasmid-encoded antisense RNA I results in high RNA I expression, so it may antagonize the effects of trans-encoded RNAs in controlling target gene expression.

The role of the 5' sensing function of ribonuclease E in cyanobacteria

RNA degradation is critical for synchronising gene expression with changing conditions in prokaryotic and eukaryotic organisms. In bacteria, the preference of the central ribonucleases RNase E, RNase J and RNase Y for 5'-monophosphorylated RNAs is considered important for RNA degradation. For RNase E, the underlying mechanism is termed 5' sensing, contrasting to the alternative 'direct entry' mode, which is independent of monophosphorylated 5' ends. Cyanobacteria, such as Synechocystis sp. PCC 6803 (Synechocystis), encode RNase E and RNase J homologues. Here, we constructed a Synechocystis strain lacking the 5' sensing function of RNase E and mapped on a transcriptome-wide level 283 5'-sensing-dependent cleavage sites. These included so far unknown targets such as mRNAs encoding proteins related to energy metabolism and carbon fixation. The 5' sensing function of cyanobacterial RNase E is important for the maturation of rRNA and several tRNAs, including tRNAGluUUC. This tRNA activates glutamate for tetrapyrrole biosynthesis in plant chloroplasts and in most prokaryotes. Furthermore, we found that increased RNase activities lead to a higher copy number of the major Synechocystis plasmids pSYSA and pSYSM. These results provide a first step towards understanding the importance of the different target mechanisms of RNase E outside Escherichia coli.

mRNA Degradation Rates Are Coupled to Metabolic Status in Mycobacterium smegmatis

The logistics of tuberculosis therapy are difficult, requiring multiple drugs for many months. Mycobacterium tuberculosis survives in part by entering nongrowing states in which it is metabolically less active and thus less susceptible to antibiotics. Basic knowledge on how M. tuberculosis survives during these low-metabolism states is incomplete, and we hypothesize that optimized energy resource management is important. Here, we report that slowed mRNA turnover is a common feature of mycobacteria under energy stress but is not dependent on the mechanisms that have generally been postulated in the literature. Finally, we found that mRNA stability and growth status can be decoupled by a drug that causes growth arrest but increases metabolic activity, indicating that mRNA stability responds to metabolic status rather than to growth rate per se. Our findings suggest a need to reorient studies of global mRNA stabilization to identify novel mechanisms that are presumably responsible.

The success of Mycobacterium tuberculosis as a human pathogen is due in part to its ability to survive stress conditions, such as hypoxia or nutrient deprivation, by entering nongrowing states. In these low-metabolism states, M. tuberculosis can tolerate antibiotics and develop genetically encoded antibiotic resistance, making its metabolic adaptation to stress crucial for survival. Numerous bacteria, including M. tuberculosis, have been shown to reduce their rates of mRNA degradation under growth limitation and stress. While the existence of this response appears to be conserved across species, the underlying bacterial mRNA stabilization mechanisms remain unknown. To better understand the biology of nongrowing mycobacteria, we sought to identify the mechanistic basis of mRNA stabilization in the nonpathogenic model Mycobacterium smegmatis. We found that mRNA half-life was responsive to energy stress, with carbon starvation and hypoxia causing global mRNA stabilization. This global stabilization was rapidly reversed when hypoxia-adapted cultures were reexposed to oxygen, even in the absence of new transcription. The stringent response and RNase levels did not explain mRNA stabilization, nor did transcript abundance. This led us to hypothesize that metabolic changes during growth cessation impact the activities of degradation proteins, increasing mRNA stability. Indeed, bedaquiline and isoniazid, two drugs with opposing effects on cellular energy status, had opposite effects on mRNA half-lives in growth-arrested cells. Taken together, our results indicate that mRNA stability in mycobacteria is not directly regulated by growth status but rather is dependent on the status of energy metabolism.

Directed evolution of Escherichia coli with lower-than-natural plasmid mutation rates

Unwanted evolution of designed DNA sequences limits metabolic and genome engineering efforts. Engineered functions that are burdensome to host cells and slow their replication are rapidly inactivated by mutations, and unplanned mutations with unpredictable effects often accumulate alongside designed changes in large-scale genome editing projects. We developed a directed evolution strategy, Periodic Reselection for Evolutionarily Reliable Variants (PResERV), to discover mutations that prolong the function of a burdensome DNA sequence in an engineered organism. Here, we used PResERV to isolate Escherichia coli cells that replicate ColE1-type plasmids with higher fidelity. We found mutations in DNA polymerase I and in RNase E that reduce plasmid mutation rates by 6- to 30-fold. The PResERV method implicitly selects to maintain the growth rate of host cells, and high plasmid copy numbers and gene expression levels are maintained in some of the evolved E. coli strains, indicating that it is possible to improve the genetic stability of cellular chassis without encountering trade-offs in other desirable performance characteristics. Utilizing these new antimutator E. coli and applying PResERV to other organisms in the future promises to prevent evolutionary failures and unpredictability to provide a more stable genetic foundation for synthetic biology.

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.

NAD captureSeq indicates NAD as a bacterial cap for a subset of regulatory RNAs

A distinctive feature of prokaryotic gene expression is the absence of 5'-capped RNA. In eukaryotes, 5',5'-triphosphate-linked 7-methylguanosine protects messenger RNA from degradation and modulates maturation, localization and translation. Recently, the cofactor nicotinamide adenine dinucleotide (NAD) was reported as a covalent modification of bacterial RNA. Given the central role of NAD in redox biochemistry, posttranslational protein modification and signalling, its attachment to RNA indicates that there are unknown functions of RNA in these processes and undiscovered pathways in RNA metabolism and regulation. The unknown identity of NAD-modified RNAs has so far precluded functional analyses. Here we identify NAD-linked RNAs from bacteria by chemo-enzymatic capture and next-generation sequencing (NAD captureSeq). Among those identified, specific regulatory small RNAs (sRNAs) and sRNA-like 5'-terminal fragments of certain mRNAs are particularly abundant. Analogous to a eukaryotic cap, 5'-NAD modification is shown in vitro to stabilize RNA against 5'-processing by the RNA-pyrophosphohydrolase RppH and against endonucleolytic cleavage by ribonuclease (RNase) E. The nudix phosphohydrolase NudC decaps NAD-RNA and thereby triggers RNase-E-mediated RNA decay, while being inactive against triphosphate-RNA. In vivo, ∼13% of the abundant sRNA RNAI is NAD-capped in the presence, and ∼26% in the absence, of functional NudC. To our knowledge, this is the first description of a cap-like structure and a decapping machinery in bacteria.

Post-transcriptional control of gene expression: bacterial mRNA degradation

Many biological processes cannot be fully understood without detailed knowledge of RNA metabolism. The continuous breakdown and resynthesis of prokaryotic mRNA permit rapid production of new kinds of proteins. In this way, mRNA levels can regulate protein synthesis and cellular growth. Analysing mRNA degradation in prokaryotes has been particularly difficult because most mRNA undergo rapid exponential decay. Prokaryotic mRNAs differ in their susceptibility to degradation by endonucleases and exonucleases, possibly because of variation in their sequencing and structure. In spite of numerous studies, details of mRNA degradation are still largely unknown. This review highlights those aspects of mRNA metabolism which seem most influential in the regulation of gene expression.

Two pathways for RNase E action in Escherichia coli in vivo and bypass of its essentiality in mutants defective for Rho-dependent transcription termination

The endonuclease RNase E of Escherichia coli is essential for viability, but deletion of its C-terminal half (CTH) is not lethal. RNase E preferentially acts on 5'-monophosphorylated RNA whose generation from primary transcripts is catalysed by RppH, but ΔRppH strains are viable. Here we show that the RNase E-ΔCTH ΔRppH combination is lethal, and that the lethality is suppressed by rho or nusG mutations impairing Rho-dependent transcription termination. Lethality was correlated with defects in bulk mRNA decay and tRNA processing, which were reversed by the rho suppressor. Lethality suppression was dependent on RNase H1 or the helicase UvsW of phage T4, both of which act to remove RNA-DNA hybrids (R-loops). The rho and nusG mutations also rescued inviability of a double alteration R169Q (that abolishes 5'-sensing) with ΔCTH in RNase E, as also that of conditional RNase E deficiency. We suggest that the ΔCTH alteration leads to loss of a second 5'-end-independent pathway of RNase E action. We further propose that an increased abundance of R-loops in the rho and nusG mutants, although ordinarily inimical to growth, contributes to rescue the lethality associated with loss of the two RNase E cleavage pathways by providing an alternative means of RNA degradation.

Rapid cleavage of RNA by RNase E in the absence of 5' monophosphate stimulation

The best characterized pathway for the initiation of mRNA degradation in Escherichia coli involves the removal of the 5'-terminal pyrophosphate to generate a monophosphate group that stimulates endonucleolytic cleavage by RNase E. We show here however, using well-characterized oligonucleotide substrates and mRNA transcripts, that RNase E can cleave certain RNAs rapidly without requiring a 5'-monophosphorylated end. Moreover, the minimum substrate requirement for this mode of cleavage, which can be categorized as 'direct' or 'internal' entry, appears to be multiple single-stranded segments in a conformational context that allows their simultaneous interaction with RNase E. While previous work has alluded to the existence of a 5' end-independent mechanism of mRNA degradation, the relative simplicity of the requirements identified here for direct entry suggests that it could represent a major means by which mRNA degradation is initiated in E. coli and other organisms that contain homologues of RNase E. Our results have implications for the interplay of translation and mRNA degradation and models of gene regulation by small non-coding RNAs.

The sequence of sites recognised by a member of the RNase E/G family can control the maximal rate of cleavage, while a 5'-monophosphorylated end appears to function cooperatively in mediating RNA binding

Members of the RNase E/G family are multimeric, 5'-end-sensing, single-strand-specific endoribonucleases that are found in chloroplasts as well as bacteria, and have central roles in RNA processing and degradation. A well-studied member of this family is Escherichia coli RNase G. Recently, we have shown that the interaction of this enzyme with a 5'-monophosphorylated end can enhance substrate binding in vitro and the decay of mRNA in vivo. We show here that a single-stranded site despite not being sufficient for rapid cleavage makes a substantial contribution to the binding of RNase G. Moreover, we find that the sequence of a site bound by RNase G can moderate the maximal rate by at least an order of magnitude. This supports a model for the RNase E/G family in which a single-stranded segment(s) can cooperate in the binding of enzyme that subsequently cleaves preferentially at another site. We also provide evidence that in order to promote cleavage a 5'-monophosphorylated end needs to be linked physically to a single-stranded site, indicating that it functions cooperatively. Our results are discussed in terms of recent X-ray crystal structures and models for the initiation of bacterial mRNA degradation.

Getting to the end of RNA: structural analysis of protein recognition of 5' and 3' termini

The specific recognition by proteins of the 5' and 3' ends of RNA molecules is an important facet of many cellular processes, including RNA maturation, regulation of translation initiation and control of gene expression by degradation and RNA interference. The aim of this review is to survey recent structural analyses of protein binding domains that specifically bind to the extreme 5' or 3' termini of RNA. For reasons of space and because their interactions are also governed by catalytic considerations, we have excluded enzymes that modify the 5' and 3' extremities of RNA. It is clear that there is enormous structural diversity among the proteins that have evolved to bind to the ends of RNA molecules. Moreover, they commonly exhibit conformational flexibility that appears to be important for binding and regulation of the interaction. This flexibility has sometimes complicated the interpretation of structural results and presents significant challenges for future investigations.

Endonucleolytic initiation of mRNA decay in Escherichia coli

Instability is a fundamental property of mRNA that is necessary for the regulation of gene expression. In E. coli, the turnover of mRNA involves multiple, redundant pathways involving 3'-exoribonucleases, endoribonucleases, and a variety of other enzymes that modify RNA covalently or affect its conformation. Endoribonucleases are thought to initiate or accelerate the process of mRNA degradation. A major endoribonuclease in this process is RNase E, which is a key component of the degradative machinery amongst the Proteobacteria. RNase E is the central element in a multienzyme complex known as the RNA degradosome. Structural and functional data are converging on models for the mechanism of activation and regulation of RNase E and its paralog, RNase G. Here, we discuss current models for mRNA degradation in E. coli and we present current thinking on the structure and function of RNase E based on recent crystal structures of its catalytic core.

Post-transcriptional processing of the LEE4 operon in enterohaemorrhagic Escherichia coli

Enterohaemorrhagic Escherichia coli (EHEC) employs a type III secretion system (T3SS) to export translocator and effector proteins required for mucosal colonization. The T3SS is encoded in a pathogenicity island called the locus of enterocyte effacement (LEE) that is organized in five major operons, LEE1 to LEE5. LEE4 encodes a regulator of secretion (SepL), translocators (EspA, D and B), two chaperones (CesD2 and L0017), a T3SS component (EscF) and an effector protein (EspF). It was originally proposed that the esp transcript is transcribed from a promoter located at the end of sepL but other authors suggested that this transcript is the result of a post-transcriptional processing event. In this study, we established that the espADB mRNA is generated by post-transcriptional processing at the end of the sepL coding sequence. RNase E is the endonuclease involved in the cleavage, but the interaction of this enzyme with other proteins through its C-terminal half is dispensable. A putative transcription termination event in the cesD2 coding region would generate the 3' end of the transcript. Similar to what has been described for other processed transcripts, the cleavage of LEE4 seems a mechanism to differentially regulate SepL and Esp protein production.

Identifying and characterizing substrates of the RNase E/G family of enzymes

The study of RNA decay and processing in Escherichia coli has revealed a central role for RNase E, an endonuclease that is essential for cell viability. This enzyme is required for the normal rapid decay of many transcripts and is involved in the processing of precursors of 16S and 5S ribosomal RNA, transfer RNA, the transfer-messenger RNA, and the RNA component of RNase P. Although there is reasonable knowledge of the repertoire of transcripts cleaved by RNase E in E. coli, a detailed understanding of the molecular recognition events that control the cleavage of RNA by this key enzyme is only starting to emerge. Here we describe methods for identifying sites of endonucleolytic cleavage and determining whether they depend on functional RNase E. This is illustrated with the pyrG eno bicistronic transcript, which is cleaved in the intergenic region primarily by an RNase E-dependent activity and not as previously thought by RNase III. We also describe the use of oligoribonucleotide and in vitro-transcribed substrates to investigate cis-acting factors such as 5'-monophosphorylation, which can significantly enhance the rate of cleavage but is insufficient to ensure processivity. Most of the approaches that we describe can be applied to the study of homologs of E. coli RNase E, which have been found in approximately half of the eubacteria that have been sequenced.

Dark-induced mRNA instability involves RNase E/G-type endoribonuclease cleavage at the AU-box and SD sequences in cyanobacteria

Light-responsive gene expression is crucial to photosynthesizing organisms. Here, we studied functions of cis-elements (AU-box and SD sequences) and a trans-acting factor (ribonuclease, RNase) in light-responsive expression in cyanobacteria. The results indicated that AU-rich nucleotides with an AU-box, UAAAUAAA, just upstream from an SD confer instability on the mRNA under darkness. An RNase E/G homologue, Slr1129, of the cyanobacterium Synechocystis sp. strain PCC 6803 was purified and confirmed capable of endoribonucleolytic cleavage at the AU- (or AG)-rich sequences in vitro. The cleavage depends on the primary target sequence and secondary structure of the mRNA. Complementation tests using Escherichia coli rne/rng mutants showed that Slr1129 fulfilled the functions of both the RNase E and RNase G. An analysis of systematic mutations in the AU-box and SD sequences showed that the cis-elements also affect significantly mRNA stability in light-responsive genes. These results strongly suggested that dark-induced mRNA instability involves RNase E/G-type cleavage at the AU-box and SD sequences in cyanobacteria. The mechanical impact and a possible common mechanism with RNases for light-responsive gene expression are discussed.

Tolerance of the Rieske-type [2Fe-2S] cluster in recombinant ferredoxin BphA3 from Pseudomonas sp. KKS102 to histidine ligand mutations

BphA3 from Pseudomonas sp. KKS102 is a Rieske-type [2Fe-2S] ferredoxin that transfers electrons from an NADH-dependent oxidoreductase, BphA4, to a biphenyl dioxygenase complex. A high-level expression and purification system for the recombinant BphA3 in Escherichia coli was constructed. Two histidine ligands of the Rieske-type cluster in BphA3, were each replaced with serine, cysteine, asparagine and tyrosine. The single mutants, in which either His44 or His65 was replaced with a cysteine residue (CH and HC mutants respectively), and the double mutant, in which both histidine residues were replaced with cysteine residue (CC mutant), accumulated to high levels in the E. coli cells, while the other single mutants did not. The purified WT (wild-type) protein showed characteristic near-UV and visible absorption and CD spectra of Rieske-type clusters. The X-ray absorption spectra were suggestive of the existence of [2Fe-2S] clusters, with one histidine and three cysteine ligands in the CH and HC mutants, and an [2Fe-2S] cluster with four cysteine ligands in the CC mutant. The BphA4-dependent cytochrome c reductase activities of the mutants were less than 0.3% of that of the WT protein. The redox potential of the WT protein determined by cyclic voltammetry was -180+/-5 mV compared with the standard hydrogen electrode, and that of the CH mutant was approx. 175 mV lower. The changes in the near-UV and visible absorption spectra of the mutants showed that the reduced iron-sulphur clusters in the mutants were unstable. His44 and His65 in BphA3 can be replaced with cysteine residues, but are required for the stabilization of the reduced form of the cluster.

“Zn-Link”: A Metal-Sharing Interface that Organizes the Quaternary Structure and Catalytic Site of the Endoribonuclease, RNase E†

Ribonuclease E is an essential hydrolytic endonuclease in Escherichia coli, and it plays a central role in maintaining the balance and composition of the messenger RNA population. The enzyme is also required for rRNA and tRNA processing. We have shown earlier that the highly conserved catalytic domain of E. coli RNase E is a homotetramer [Callaghan, A. J. et al. (2003) Biochemistry 42, 13848-13855]. Here, we report that this quaternary organization requires zinc. Two protomers share a single zinc ion, and quantitative analysis indicates that each protein contributes two cysteine thiols toward the coordination of the metal. The candidate cysteines are part of a motif that is conserved in the RNase E protein family, and mutation of these residues causes the partial loss of zinc, the complete disruption of the tetramer into dimers, and effective catalytic inactivation. However, these mutations do not affect RNA binding. The tetramer can be artificially maintained by disulfide bond formation, which fully displaces the zinc but largely preserves the catalytic activity. Thus, catalytic activity does not require zinc directly but does require the quaternary structure, for which the metal is essential. We propose that the RNase E tetramer has two nonequivalent subunit interfaces, one of which is mediated by a single, tetrathiol-zinc complex, which we refer to as a "Zn-link" motif. One or both interfaces organize the active site, which is distinct from the primary site of RNA binding.

Catalytic activation of multimeric RNase E and RNase G by 5'-monophosphorylated RNA

RNase E is an endonuclease that plays a central role in RNA processing and degradation in Escherichia coli. Like its E. coli homolog RNase G, RNase E shows a marked preference for cleaving RNAs that bear a monophosphate, rather than a triphosphate or hydroxyl, at the 5' end. To investigate the mechanism by which 5'-terminal phosphorylation can influence distant cleavage events, we have developed fluorogenic RNA substrates that allow the activity of RNase E and RNase G to be quantified much more accurately and easily than before. Kinetic analysis of the cleavage of these substrates by RNase E and RNase G has revealed that 5' monophosphorylation accelerates the reaction not by improving substrate binding, but rather by enhancing the catalytic potency of these ribonucleases. Furthermore, the presence of a 5' monophosphate can increase the specificity of cleavage site selection within an RNA. Although monomeric forms of RNase E and RNase G can cut RNA, the ability of these enzymes to discriminate between RNA substrates on the basis of their 5' phosphorylation state requires the formation of protein multimers. Among the molecular mechanisms that could account for these properties are those in which 5'-end binding by one enzyme subunit induces a protein structural change that accelerates RNA cleavage by another subunit.

Quaternary Structure and Catalytic Activity of the Escherichia coli Ribonuclease E Amino-Terminal Catalytic Domain

RNase E is an essential endoribonuclease that plays a central role in the processing and degradation of RNA in Escherichia coli and other bacteria. Most endoribonucleases have been shown to act distributively; however, Feng et al. [(2002) Proc. Natl. Acad. Sci. U.S.A. 99, 14746-14751] have recently found that RNase E acts via a scanning mechanism. A structural explanation for the processivity of RNase E is provided here, with our finding that the conserved catalytic domain of E. coli RNase E forms a homotetramer. Nondissociating nanoflow-electrospray mass spectrometry suggests that the tetramer binds up to four molecules of a specific substrate RNA analogue. The tetrameric assembly of the N-terminal domain of RNase E is consistent with crystallographic analyses, which indicate that the tetramer possesses approximate D(2) dihedral symmetry. Using X-ray solution scattering data and symmetry restraints, a solution shape is calculated for the tetramer. This shape, together with limited proteolysis data, suggests that the S1-RNA binding domains of RNase E lie on the periphery of the tetramer. These observations have implications for the structure and function of the RNase E/RNase G ribonuclease family and for the assembly of the E. coli RNA degradosome, in which RNase E is the central component.

A Streptomyces coelicolor functional orthologue of Escherichia coli RNase E shows shuffling of catalytic and PNPase-binding domains

Previous work has detected an RNase E-like endoribonucleolytic activity in cell extracts obtained from Streptomyces. Here, we identify a Streptomyces coelicolor gene, rns, encoding a 140 kDa protein (RNase ES) that shows endoribonucleolytic cleavage specificity characteristic of RNase E, confers viability on and allows propagation of Escherichia coli cells lacking RNase E and accomplishes RNase E-like regulation of plasmid copy number in E. coli. However, notwithstanding its complementation of rne-deleted E. coli, RNase ES did not accurately process 9S rRNA from E. coli. Additionally, whereas RNase E is normally required for E. coli survival, rns is not an essential gene in S. coelicolor. Deletion analysis mapped the catalytic domain of RNase ES near its centre and showed that regions located near the RNase ES termini interact with an S. coelicolor homologue of polynucleotide phosphorylase (PNPase) - a major component of E. coli RNase E-based degradosomes. The interacting arginine- and proline-rich segments resemble the C-terminally located degradosome scaffold region of E. coli RNase E. Our results indicate that RNase ES is a structurally shuffled RNase E homologue showing evolutionary conservation of functional RNase E-like enzymatic activity, and suggest the existence of degradosome-like complexes in Gram-positive bacteria.

Two distinct regions on the surface of an RNA-binding domain are crucial for RNase E function

Despite its importance for RNA processing and degradation in Escherichia coli, little is known about the structure of RNase E or its mechanism of action. We have modelled the three-dimensional structure of an essential amino-terminal domain of RNase E on the basis of its sequence homology to the S1 family of RNA-binding domains. Each of the five surface-exposed aromatic residues and most of the 14 basic residues of this RNase E domain were replaced with alanine to determine their importance for RNase E function. All the surface residues essential for cell growth and feedback regulation of RNase E synthesis mapped to one end of the domain. In vitro assays indicate that these essential residues fall into two functionally distinct groups that form discrete clusters on opposite faces of the S1 domain. One group, comprising Phe-57, Phe-67 and Lys-112 [corrected], is of general importance for the ribonuclease activity of RNase E, whereas the other group, comprising Lys-37 and Tyr-60, is entirely dispensable for catalytic activity in vitro. The side-chains of two residues previously identified as sites of temperature-sensitive mutations lie buried directly beneath the surface region defined by Phe-57, Phe-67 and Lys-112 [corrected], which probably enhances RNase E activity by making a crucial contribution to the binding of substrate RNAs. In contrast to the S1 domain, an arginine-rich RNA-binding domain in the carboxyl half of RNase E appears to have a more peripheral role in RNase E function, as it is not required for feedback regulation, cell growth or ribonuclease activity.

Escherichia coli poly(A)-binding proteins that interact with components of degradosomes or impede RNA decay mediated by polynucleotide phosphorylase and RNase E

The multifunctional ribonuclease RNase E and the 3'-exonuclease polynucleotide phosphorylase (PNPase) are major components of an Escherichia coli ribonucleolytic "machine" that has been termed the RNA degradosome. Previous work has shown that poly(A) additions to the 3' ends of RNA substrates affect RNA degradation by both of these enzymes. To better understand the mechanism(s) by which poly(A) tails can modulate ribonuclease action, we used selective binding in 1 m salt to identify E. coli proteins that interact at high affinity with poly(A) tracts. We report here that CspE, a member of a family of RNA-binding "cold shock" proteins, and S1, an essential component of the 30 S ribosomal subunit, are poly(A)-binding proteins that interact functionally and physically, respectively, with degradosome ribonucleases. We show that purified CspE impedes poly(A)-mediated 3' to 5' exonucleolytic decay by PNPase by interfering with its digestion through the poly(A) tail and also inhibits both internal cleavage and poly(A) tail removal by RNase E. The ribosomal protein S1, which is known to interact with sequences at the 5' ends of mRNA molecules during the initiation of translation, can bind to both RNase E and PNPase, but in contrast to CspE, did not affect the ribonucleolytic actions of these enzymes. Our findings raise the prospect that E. coli proteins that bind to poly(A) tails may link the functions of degradosomes and ribosomes.

Cleavage of poly(A) tails on the 3'-end of RNA by ribonuclease E of Escherichia coli

RNase E initiates the decay of Escherichia coli RNAs by cutting them internally near their 5'-end and is a component of the RNA degradosome complex, which also contains the 3'-exonuclease PNPASE: Recently, RNase E has been shown to be able to remove poly(A) tails by what has been described as an exonucleolytic process that can be blocked by the presence of a phosphate group on the 3'-end of the RNA. We show here, however, that poly(A) tail removal by RNase E is in fact an endonucleolytic process that is regulated by the phosphorylation status at the 5'- but not the 3'-end of RNA. The rate of poly(A) tail removal by RNase E was found to be 30-fold greater when the 5'-terminus of RNA substrates was converted from a triphosphate to monophosphate group. This finding prompted us to re-analyse the contributions of the ribonucleolytic activities within the degradosome to 3' attack since previous studies had only used substrates that had a triphosphate group on their 5'-end. Our results indicate that RNase E associated with the degradosome may contribute to the removal of poly(A) tails from 5'-monophosphorylated RNAs, but this is only likely to be significant should their attack by PNPase be blocked.

Enhanced cleavage of RNA mediated by an interaction between substrates and the arginine-rich domain of E. coli ribonuclease E

Endonucleolytic cutting by the essential Escherichia coli ribonuclease RNaseE has a central role in both the processing and decay of RNA. Previously, it has been shown that an oligoribonucleotide corresponding in sequence to the single-stranded region at the 5' end of RNAI, the antisense regulator of ColE1-type plasmid replication, is efficiently cut by RNaseE. Combined with the knowledge that alteration of the structure of stem-loops within complex RNaseE substrates can either increase or decrease the rate of cleavage, this result has led to the notion that stem-loops do not serve as essential recognition motifs for RNaseE, but can affect the rate of cleavage indirectly by, for example, determining the single-strandedness of the site or its accessibility. We report here, however, that not all oligoribonucleotides corresponding to RNaseE-cleaved segments of complex substrates are sufficient to direct efficient RNaseE cleavage. We provide evidence using 9 S RNA, a precursor of 5 S rRNA, that binding of structured regions by the arginine-rich RNA- binding domain (ARRBD) of RNaseE can be required for efficient cleavage. Binding by the ARRBD appears to counteract the inhibitory effects of sub-optimal cleavage site sequence and overall substrate conformation. Furthermore, combined with the results from recent analyses of E. coli mutants in which the ARRBD of RNase E is deleted, our findings suggest that substrate binding by RNaseE is essential for the normal rapid decay of E. coli mRNA. The simplest interpretation of our results is that the ARRBD recruits RNaseE to structured RNAs, thereby increasing the localised concentration of the N-terminal catalytic domain, which in turn leads to an increase in the rate of cleavage.

Messenger RNA stability and its role in control of gene expression in bacteria and phages

The stability of mRNA in prokaryotes depends on multiple factors and it has not yet been possible to describe the process of mRNA degradation in terms of a unique pathway. However, important advances have been made in the past 10 years with the characterization of the cis-acting RNA elements and the trans-acting cellular proteins that control mRNA decay. The trans-acting proteins are mainly four nucleases, two endo- (RNase E and RNase III) and two exonucleases (PNPase and RNase II), and poly(A) polymerase. RNase E and PNPase are found in a multienzyme complex called the degradosome. In addition to the host nucleases, phage T4 encodes a specific endonuclease called RegB. The cis-acting elements that protect mRNA from degradation are stable stem-loops at the 5' end of the transcript and terminators or REP sequences at their 3' end. The rate-limiting step in mRNA decay is usually an initial endonucleolytic cleavage that often occurs at the 5' extremity. This initial step is followed by directional 3' to 5' degradation by the two exonucleases. Several examples, reviewed here, indicate that mRNA degradation is an important step at which gene expression can be controlled. This regulation can be either global, as in the case of growth rate-dependent control, or specific, in response to changes in the environmental conditions.

Absence of RNASE III alters the pathway by which RNAI, the antisense inhibitor of ColE1 replication, decays

RNAI is a short RNA, 108 nt in length, which regulates the replication of the plasmid ColE1. RNAI turns over rapidly, enabling plasmid replication rate to respond quickly to changes in plasmid copy number. Because RNAI is produced in abundance, is easily extracted and turns over quickly, it has been used as a model for mRNA in studying RNA decay pathways. The enzymes polynucleotide phosphorylase, poly(A) polymerase and RNase E have been demonstrated to have roles in both messenger and RNAI decay; it is reported here that these enzymes can work independently of one another to facilitate RNAI decay. The roles in RNAI decay of two further enzymes which facilitate mRNA decay, the exonuclease RNase II and the endonuclease RNase III, are also examined. RNase II does not appear to accelerate RNAI decay but it is found that, in the absence of RNase III, polyadenylated RNAI, unprocessed by RNase E, accumulates. It is also shown that RNase III can cut RNAI near nt 82 or 98 in vitro. An RNAI fragment corresponding to the longer of these can be found in extracts of an mc+ pcnB strain (which produces RNase III) but not of an rnc pcnB strain, suggesting that RNAI may be a substrate for RNase III in vivo. A possible pathway for the early steps in RNAI decay which incorporates this information is suggested.

RNase E is required for the maturation of ssrA RNA and normal ssrA RNA peptide-tagging activity

During recent studies of ribonucleolytic "degradosome" complexes of Escherichia coli, we found that degradosomes contain certain RNAs as well as RNase E and other protein components. One of these RNAs is ssrA (for small stable RNA) RNA (also known as tm RNA or 10Sa RNA), which functions as both a tRNA and mRNA to tag the C-terminal ends of truncated proteins with a short peptide and target them for degradation. Here, we show that mature 363-nt ssrA RNA is generated by RNase E cleavage at the CCA-3' terminus of a 457-nt ssrA RNA precursor and that interference with this cleavage in vivo leads to accumulation of the precursor and blockage of SsrA-mediated proteolysis. These results demonstrate that RNase E is required to produce mature ssrA RNA and for normal ssrA RNA peptide-tagging activity. Our findings indicate that RNase E, an enzyme already known to have a central role in RNA processing and decay in E. coli, also has the previously unsuspected ability to affect protein degradation through its role in maturation of the 3' end of ssrA RNA.

The genes encoding formamidopyrimidine and MutY DNA glycosylases in Escherichia coli are transcribed as part of complex operons

Escherichia coli formamidopyrimidine (Fpg) DNA glycosylase and MutY DNA glycosylase are base excision repair proteins that work together to protect cells from the mutagenic effects of the commonly oxidized guanine product 7,8-dihydro-8-oxoguanine. The genes encoding these proteins, fpg and mutY, are both cotranscribed as part of complex operons. fpg is the terminal gene in an operon with the gene order radC, rpmB, rpmG, and fpg. This operon has transcription initiation sites upstream of radC, in the radC coding region, and immediately upstream of fpg. There is a strong attenuator in the rpmG-fpg intergenic region and three transcription termination sites downstream of fpg. There is an additional site, in the radC-rpmB intergenic region, that corresponds either to a transcription initiation site or to an RNase E or RNase III cleavage site. mutY is the first gene in an operon with the gene order mutY, yggX, mltC, and nupG. This operon has transcription initiation sites upstream of mutY, in the mutY coding region, and immediately upstream of nupG. There also appear to be attenuators in the yggX-mltC and mltC-nupG intergenic regions. The order of genes in these operons has been conserved or partially conserved only in other closely related gram-negative bacteria, although it is not known whether the genes are cotranscribed in these other organisms.

Escherichia coli cafA gene encodes a novel RNase, designated as RNase G, involved in processing of the 5' end of 16S rRNA

We found that the Escherichia coli cafA::cat mutant accumulated a precursor of 16S rRNA. This precursor migrated to the same position with 16.3S precursor found in the BUMMER strain that is known to be deficient in the 5' end processing of 16S rRNA. Accumulation of 16. 3S rRNA in the BUMMER mutant was complemented by introduction of a plasmid carrying the cafA gene. The mutant type cafA gene cloned from the BUMMER strain had a 11-bp deletion in its coding region. A small amount of the mature 16S rRNA was still formed in the cafA::cat mutant. This residual activity was found to be due to RNase E encoded by the rne/ams gene by rifampicin-chase experiments of the cafA::cat ams1 double mutant. These results indicated that the cafA gene encodes a novel RNase responsible for processing of the 5' end of 16S rRNA.

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.

Degradation of FinP antisense RNA from F-like plasmids: the RNA-binding protein, FinO, protects FinP from ribonuclease E

Transfer of F-like plasmids is regulated by the FinOP system, which controls the expression of traJ, a positive regulator of the transfer operon. F FinP is a 79 base antisense RNA, composed of two stem-loops, complementary to the 5' untranslated leader of traJ mRNA. Binding of FinP to the traJ leader sequesters the traJ ribosome binding site, preventing its translation and repressing plasmid transfer. The FinO protein binds stem-loop II of FinP and traJ mRNA and promotes duplex formation in vitro. FinO stabilizes FinP, increasing its effective concentration in vivo. To determine how FinO protects FinP from decay, the degradation of FinP was examined in a series of ribonuclease-deficient strains. Using Northern blot analysis, full-length FinP was found to be stabilized sevenfold in an RNase E-deficient strain. The major site of RNase E cleavage was mapped on synthetic FinP, to the single-stranded region between stem-loops I and II. A secondary site near the 5' end ( approximately 10 bases) was also observed. A GST-FinO fusion protein protected FinP from RNase E cleavage at both sites in vitro. Two duplexes between FinP and traJ mRNA were detected in an RNase III-deficient strain. The larger duplex resulted from extension of the FinP transcript at its 3' end, suggesting readthrough at the terminator that corresponds to FinP stem-loop II. A point mutant of finP (finP305; C30U) that is unable to repress traJ in the presence of FinO was also characterized. The pattern of RNase E digestion of finP305 RNA differed from FinP, and GST-FinO did not protect finP305 RNA from cleavage in vitro. The half-life of finP305 RNA decreased more than tenfold in vivo, such that the steady-state levels of finP305 RNA, in the presence of FinO, were insufficient to significantly reduce the level of traJ mRNA available for translation, allowing derepressed levels of transfer.

Transcript analysis of the pcbABC genes encoding the antenna apoproteins in the photosynthetic prokaryote, Prochlorothrix hollandica

The tightly linked pcbABC genes encode the chlorophyll a/b-binding apoproteins in the oxygenic photosynthetic prokaryote Prochlorothrix hollandica. Northern blotting experiments employing gene-specific DNA probes have identified a complex pattern of transcription from the pcb region. A large 4.4-kb transcript detected in cultures maintained in high light, low light and in darkness results from the cotranscription of all three genes, whereas pcbAB, pcbBC and individual pcbA, B, and C mRNAs are similarly detected in all light regimes. The half lives of the RNAs vary from 15 min for the pcbABC transcript, to over 60 min for the pcbA and pcbC mRNAs. The lack of identifiable promoter sequences other than the region upstream from pcbA, plus the enhanced stability of the individual single gene transcripts, suggest that the smaller RNA species arise from processing of larger transcripts. Transcription and mRNA turnover occurs largely independent of light intensity, in contrast to what is seen in most other phototrophs, in which light influences the accumulation of antenna apoprotein gene mRNAs.

Escherichia coli mrsC is an allele of hflB, encoding a membrane-associated ATPase and protease that is required for mRNA decay

The mrsC gene of Escherichia coli is required for mRNA turnover and cell growth, and strains containing the temperature-sensitive mrsC505 allele have longer half-lives than wild-type controls for total pulse-labeled and individual mRNAs (L. L. Granger et al., J. Bacteriol. 180:1920-1928, 1998). The cloned mrsC gene contains a long open reading frame beginning at an initiator UUG codon, confirmed by N-terminal amino acid sequencing, encoding a 70,996-Da protein with a consensus ATP-binding domain. mrsC is identical to the independently identified ftsH gene except for three additional amino acids at the N terminus (T. Tomoyasu et al., J. Bacteriol. 175:1344-1351, 1993). The purified protein had a Km of 28 microM for ATP and a Vmax of 21.2 nmol/microg/min. An amino-terminal glutathione S-transferase-MrsC fusion protein retained ATPase activity but was not biologically active. A glutamic acid replacement of the highly conserved lysine within the ATP-binding motif (mrsC201) abolished the complementation of the mrsC505 mutation, confirming that the ATPase activity is required for MrsC function in vivo. In addition, the mrsC505 allele conferred a temperature-sensitive HflB phenotype, while the hflB29 mutation promoted mRNA stability at both 30 and 44 degrees C, suggesting that the inviability associated with the mrsC505 allele is not related to the defect in mRNA decay. The data presented provide the first direct evidence for the involvement of a membrane-bound protein in mRNA decay in E. coli.

RNA components of Escherichia coli degradosome: evidence for rRNA decay

Recently, we found that a multicomponent ribonucleolytic degradosome complex formed around RNase E, a key mRNA-degrading and 9S RNA-processing enzyme, contains RNA in addition to its protein components. Herein we show that the RNA found in the degradosome consists primarily of rRNA fragments that have a range of distinctive sizes. We further show that rRNA degradation is carried out in the degradosome by RNase E cleavage of A+U-rich single-stranded regions of mature 16S and 23S rRNAs. The 5S rRNA, which is known to be generated by RNase E processing of the 9S precursor, was also identified in the degradosome, but tRNAs, which are not cleaved by RNase E in vitro, were absent. Our results, which provide evidence that decay of mature rRNAs occurs in growing Escherichia coli cells in the RNA degradosome, implicate RNase E in degradosome-mediated decay.

An rne-1 pnp-7 double mutation suppresses the temperature-sensitive defect of lacZ gene expression in a divE mutant

A divE mutant, which has a temperature-sensitive mutation in the tRNA1Ser gene, exhibits differential loss of the synthesis of certain proteins, such as beta-galactosidase and succinate dehydrogenase, at nonpermissive temperatures. In Escherichia coli, the UCA codon is recognized only by tRNA1Ser. Several genes containing UCA codons are normally expressed after a temperature shift to 42 degrees C in the divE mutant. Therefore, it is unlikely that the defect in protein synthesis at 42 degrees C is simply caused by a defect in the decoding function of the mutant tRNA1Ser. In this study, we sought to determine the cause of the defect in lacZ gene expression in the divE mutant. It has also been shown that the defect in lacZ gene expression is accompanied by a decrease in the amount of lacZ mRNA. To examine whether inactivation of mRNA degradation pathways restores the defect in lacZ gene expression, we constructed divE mutants containing rne-1, rnb-500, and pnp-7 mutations in various combinations. We found that the defect was almost completely restored by introducing an rne-1 pnp-7 double mutation into the divE mutant. Northern hybridization analysis showed that the rne-1 mutation stabilized lacZ mRNA, whereas the pnp-7 mutation stabilized mutant tRNA1Ser, at 44 degrees C. We present a mechanism that may explain these results.

Antisense RNA-regulated programmed cell death

Eubacterial plasmids and chromosomes encode multiple killer genes belonging to the hok gene family. The plasmid-encoded killer genes mediate plasmid stabilization by killing plasmid-free cells. This review describes the genetics, molecular biology, and evolution of the hok gene family. The complicated antisense RNA-regulated control-loop that regulates posttranscriptional and postsegregational activation of killer mRNA translation in plasmid-free cells is described in detail. Nucleotide covariations in the mRNAs reveal metastable stem-loop structures that are formed at the mRNA 5' ends in the nascent transcripts. The metastable structures prevent translation and antisense RNA binding during transcription. Coupled nucleotide covariations provide evidence for a phylogenetically conserved mRNA folding pathway that involves sequential dynamic RNA rearrangements. Our analyses have elucidated an intricate mechanism by which translation of an antisense RNA-regulated mRNA can be conditionally activated. The complex phylogenetic relationships of the plasmid- and chromosome-encoded systems are also presented and discussed.

Poly(A)- and poly(U)-specific RNA 3' tail shortening by E. coli ribonuclease E

Ribonuclease (RNase) E is an extensively studied enzyme from Escherichia coli whose site-specific endoribonuclease activity on single-stranded RNA has a central role in the processing of ribosomal RNA, the degradation of messenger RNA and the control of replication of ColE1-type plasmids. Here we report a previously undetected activity of RNase E: the ability to shorten 3' poly(A)- and poly(U)-homopolymer tails on RNA molecules. This activity, which leaves a 6-nucleotide adenylate or a 1-nucleotide uridylate remnant on primary transcripts, resides in the amino-terminal region of RNase E and does not require other protein cofactors. Addition of a 3'-terminal phosphate group prevents both removal of the poly(A) tail and endonucleolytic cleavage within primary transcripts, but has no effect on the cleavage of transcripts with tails that have already been truncated. The ability of RNase E to shorten poly(A) tails, together with the effect of tail length on endonucleolytic cleavage within primary transcripts, suggests a mechanism by which RNase E may exercise overall control over RNA decay.

ARD-1 cDNA from human cells encodes a site-specific single-strand endoribonuclease that functionally resembles Escherichia coli RNase E

The human ARD-1 (activator of RNA decay) cDNA sequence can rescue mutations in the Escherichia coli rne gene, which specifies the essential endoribonuclease RNase E, resulting in RNase E-like cleavages in vivo in rne-defective bacteria and in vitro in extracts isolated from these cells (Wang, M., and Cohen, S. N. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 10591-10595). Recent studies indicate that the 13.3-kDa protein encoded by ARD-1 cDNA is almost identical to the carboxyl-terminal end of the bovine protein NIPP-1, a nuclear inhibitor of protein phosphatase 1; separate transcripts formed by alternative splicing are proposed to encode the discrete ARD-1 and combined ARD-1/NIPP-1 products (Van Eynde, A., Wera, S., Beullens, M. , Torrekens, S., Van Leuven, F., Stalmans, W., and Bollens, M. (1995) J. Biol. Chem. 270, 28068-28074). Here we show that affinity column-purified protein encoded by human ARD-1 cDNA in E. coli is a site-specific Mg2+-dependent endoribonuclease that binds in vitro to RNase E substrates, cleaves RNA at the same sites as RNase E, and, like RNase E, generates 5' phosphate termini at sites of cleavage. Our results indicate that the ARD-1 peptide can function as a ribonucleolytic analog of E. coli RNase E as well as a domain of the protein phosphatase inhibitor, NIPP-1.

RNase E: still a wonderfully mysterious enzyme

Ribonuclease E (RNase E), which is encoded by an essential Escherichia coli gene known variously as rne, ams, and hmp, was discovered initially as an rRNA-processing enzyme but it is now known to have a general role in RNA decay. Multiple functions, including the ability to cleave RNA endonucleolytically in AU-rich single-strand regions, RNA-binding capabilities, and the ability to interact with polynucleotide phosphorylase and other proteins implicated in the processing and degradation of RNA, are encoded by its 1,061 amino acid residues. The presence of homologues and functional analogues of the rne gene in a variety of prokaryotic and eukaryotic species suggests that its functions have been highly conserved during evolution. While much has been learned in recent years about the structure and functions of RNase E, there is continuing mystery about possible additional activities and molecular interactions of this enzyme.

RNase E polypeptides lacking a carboxyl-terminal half suppress a mukB mutation in Escherichia coli

We have isolated suppressor mutants that suppress temperature-sensitive colony formation and anucleate cell production of a mukB mutation. A linkage group (smbB) of the suppressor mutations is located in the rne/ams/hmp gene encoding the processing endoribonuclease RNase E. All of the rne (smbB) mutants code for truncated RNase E polypeptides lacking a carboxyl-terminal half. The amount of MukB protein was higher in these rne mutants than that in the rne+ strain. These rne mutants grew nearly normally in the mukB+ genetic background. The copy number of plasmid pBR322 in these rne mutants was lower than that in the rne+ isogenic strain. The results suggest that these rne mutations increase the half-lives of mukB mRNA and RNAI of pBR322, the antisense RNA regulating ColE1-type plasmid replication. We have demonstrated that the wild-type RNase E protein bound to polynucleotide phosphorylase (PNPase) but a truncated RNase E polypeptide lacking the C-terminal half did not. We conclude that the C-terminal half of RNase E is not essential for viability but plays an important role for binding with PNPase. RNase E and PNPase of the multiprotein complex presumably cooperate for effective processing and turnover of specific substrates, such as mRNAs and other RNAs in vivo.

RNase E cleaves at multiple sites in bubble regions of RNA I stem loops yielding products that dissociate differentially from the enzyme

Earlier work has shown that RNase E cleaves RNAI, the antisense repressor of replication of ColE1-type plasmids, producing pRNAI-5, whose further decay is mediated by the poly(A)-dependent activity of polynucleotide phosphorylase and other 3' to 5' exonucleases. Using a poly(A) polymerase-deficient strain to impede exonucleolytic decay, we show that RNAI is additionally cleaved by RNase E at multiple sites, generating a series of decay intermediates that are differentially retained by the RNA binding domain (RBD) of RNase E. Primer extension analysis of RNAI decay intermediates and RNase T1 mapping of the cleavage products of RNAI generated in vitro by affinity-purified RNase E showed that RNase E can cleave internucleotide bonds in the bubble regions of duplex RNA segments and in single-stranded regions. Chemical in situ probing of a complex formed between RNAI and the RBD indicates that binding to the RBD destabilizes RNAI secondary structure. Our results suggest a model in which a series of sequential RNase E-mediated cleavages occurring at multiple sites of RNAI, some of which may be made more accessible to RNase E by the destabilizing effects of its RBD, generate RNA fragments that are further degraded by poly(A)-dependent 3' to 5' exonucleases.

A DEAD-box RNA helicase in the Escherichia coli RNA degradosome

The Escherichia coli RNA degradosome is a multi-enzyme complex that contains the exoribonuclease polynucleotide phosphorylase (PNPase) and the endoribonuclease RNase E. Both enzymes are important in RNA processing and messenger RNA degradation. Here we report that enolase and RhlB are two other major components of the degradosome. Enolase is a glycolytic enzyme with an unknown role in RNA metabolism. RhlB is a member of the DEAD-box family of ATP-dependent RNA helicases, which are found in both prokaryotes and eukaryotes. We show that the degradosome has an ATP-dependent activity that aids the degradation of structured RNA by PNPase. Incubation of the degradosome with affinity-purified antibody against RhlB inhibited the ATP-stimulated RNA degradation. These results suggest that RhlB acts by unwinding RNA structures that impede the processive activity of PNPase. RhlB is thus an important enzyme in mRNA turnover.

Mutations affecting mRNA processing and fimbrial biogenesis in the Escherichia coli pap operon

The Escherichia coli pap genetic determinant includes 11 genes and encodes expression of Pap pili on the bacterial surface. An RNase E-dependent mRNA-processing event in the intercistronic papB-papA region results in the accumulation of a papA-gene-specific mRNA in considerable excess of the primary papB-papA mRNA transcription product. We have introduced mutations in the intercistronic region and studied the effect in vivo of these mutations on the processing event, PapA protein expression, and the biogenesis of fimbriae on the bacterial surface. Our studies establish that mRNA processing is an important event in the mechanism resulting in differential gene expression of the major pap operon. The deletion of sequences corresponding to the major cleavage site abolished processing, reduced expression of PapA protein, and resulted in "crew-cut" bacteria with short fimbrial structures on the bacterial surface. Only a limited part of the intercistronic region appeared to be required as the recognized target for the processing to occur. Upstream sequences to a position within 10 nucleotides of the major RNase E-dependent cleavage site could be deleted without any detectable effect on papB-papA mRNA processing, PapA protein expression, or fimbria formation. Substitution mutations of specific bases at the cleavage site by site-directed mutagenesis showed that there were alternative positions at which cleavage could be enhanced, and tests with an in vitro processing assay showed that such cleavages were also RNase E dependent. Our findings are discussed in relation to other fimbrial operons and other known targets of the RNase E endoribonuclease.