YtqI from Bacillus subtilis has both oligoribonuclease and pAp-phosphatase activity

Oligoribonuclease is the only RNase in Escherichia coli that is able to degrade RNA oligonucleotides five residues and shorter in length. Firmicutes including Bacillus subtilis do not have an Oligoribonuclease (Orn) homologous protein and it is not yet understood which proteins accomplish the equivalent function in these organisms. We had previously identified oligoribonucleases Orn from E. coli and its human homolog Sfn in a screen for proteins that are regulated by 3′-phosphoadenosine 5′-phosphate (pAp). Here, we identify YtqI as a potential functional analog of Orn through its interaction with pAp. YtqI degrades RNA oligonucleotides in vitro with preference for 3-mers. In addition, YtqI has pAp-phosphatase activity in vitro. In agreement with these data, YtqI is able to complement both orn and cysQ mutants in E. coli. An ytqI mutant in B. subtilis shows impairment of growth in the absence of cysteine, a phenotype resembling that of a cysQ mutant in E. coli. Phylogenetic distribution of YtqI, Orn and CysQ supports bifunctionality of YtqI.     

Characterization of NrnA homologs from Mycobacterium tuberculosis and Mycoplasma pneumoniae

Processive RNases are unable to degrade efficiently very short oligonucleotides, and they are complemented by specific enzymes, nanoRNases, that assist in this process. We previously identified NrnA (YtqI) from Bacillus subtilis as a bifunctional protein with the ability to degrade nanoRNA (RNA oligos ≤5 nucleotides) and to dephosphorylate 3'-phosphoadenosine 5'-phosphate (pAp) to AMP. While the former activity is analogous to that of oligoribonuclease (Orn) from Escherichia coli, the latter corresponds to CysQ. NrnA homologs are widely present in bacterial and archaeal genomes. They are found preferably in genomes that lack Orn or CysQ homologs. Here, we characterize NrnA homologs from important human pathogens, Mpn140 from Mycoplasma pneumoniae, and Rv2837c from Mycobacterium tuberculosis. Like NrnA, these enzymes degrade nanoRNA and dephosphorylate pAp in vitro. However, they show dissimilar preferences for specific nanoRNA substrate lengths. Whereas NrnA prefers RNA 3-mers with a 10-fold higher specific activity compared to 5-mers, Rv2837c shows a preference for nanoRNA of a different length, namely, 2-mers. Mpn140 degrades Cy5-labeled nanoRNA substrates in vitro with activities varying within one order of magnitude as follows: 5-mer>4-mer>3-mer>2-mer. In agreement with these in vitro activities, both Rv2837c and Mpn140 can complement the lack of their functional counterparts in E. coli: CysQ and Orn. The NrnA homolog from Streptococcus mutans, SMU.1297, was previously shown to hydrolyze pAp and to complement an E. coli cysQ mutant. Here, we show that SMU.1297 can complement an E. coli orn(-) mutant, suggesting that having both pAp-phosphatase and nanoRNase activity is a common feature of NrnA homologs.     

A RelA-SpoT homolog (Cr-RSH) identified in Chlamydomonas reinhardtii generates stringent factor in vivo and localizes to chloroplasts in vitro

A gene encoding a putative guanosine 3′,5′-bispyrophosphate (ppGpp) synthase–degradase, designated Cr-RSH, was identified in the unicellular photosynthetic eukaryote Chlamydomonas reinhardtii. The encoded Cr-RSH protein possesses a putative chloroplast-targeting signal at its NH₂-terminus, and translocation of Cr-RSH into chloroplasts isolated from C.reinhardtii was demonstrated in vitro. The predicted mature region of Cr-RSH exhibits marked similarity to eubacterial members of the RelA–SpoT family of proteins. Expression of an NH₂-terminal portion of Cr-RSH containing the putative ppGpp synthase domain in a relA, spoT double mutant of Escherichia coli complemented the growth deficits of the mutant cells. Chromatographic analysis of ³²P-labeled cellular mononucleotides also revealed that expression of Cr-RSH in the mutant bacterial cells resulted in the synthesis of ppGpp. SpoT, which catalyzes (p)ppGpp degradation, is dispensable in E.coli only if cells also lack RelA, which possesses (p)ppGpp synthase activity. The complementation analysis thus indicated that Cr-RSH possesses both ppGpp synthase and degradase activities. These results represent the first demonstration of ppGpp synthase–degradase activities in a eukaryotic organism, and they suggest that eubacterial stringent control mediated by ppGpp has been conserved during evolution of the chloroplast from a photosynthetic bacterial symbiont.     

Modular construction for function of a ribonucleoprotein enzyme: the catalytic domain of Bacillus subtilis RNase P complexed with B. subtilis RNase P protein

The bacterial RNase P holoenzyme catalyzes the formation of the mature 5′-end of tRNAs and is composed of an RNA and a protein subunit. Among the two folding domains of the RNase P RNA, the catalytic domain (C-domain) contains the active site of this ribozyme. We investigated specific binding of the Bacillus subtilis C-domain with the B.subtilis RNase P protein and examined the catalytic activity of this C-domain–P protein complex. The C-domain forms a specific complex with the P protein with a binding constant of ~0.1 µM. The C-domain–P protein complex and the holoenzyme are equally efficient in cleaving single-stranded RNA (~0.9 min^–1 at pH 7.8) and substrates with a hairpin–loop 3′ to the cleavage site (~40 min^–1). The holoenzyme reaction is much more efficient with a pre-tRNA substrate, binding at least 100-fold better and cleaving 10–500 times more efficiently. These results demonstrate that the RNase P holoenzyme is functionally constructed in three parts. The catalytic domain alone contains the active site, but has little specificity and affinity for most substrates. The specificity and affinity for the substrate is generated by either the specificity domain of RNase P RNA binding to a T stem–loop-like hairpin or RNase P protein binding to a single-stranded RNA. This modular construction may be exploited to obtain RNase P-based ribonucleoprotein complexes with altered substrate specificity.     

Active site constraints in the hydrolysis reaction catalyzed by bacterial RNase P: analysis of precursor tRNAs with a single 3'-S-phosphorothiolate internucleotide linkage

Endonucleolytic processing of precursor tRNAs (ptRNAs) by RNase P yields 3′-OH and 5′-phosphate termini, and at least two metal ions are thought to be essential for catalysis. To determine if the hydrolysis reaction catalyzed by bacterial RNase P (RNAs) involves stabilization of the 3′-oxyanion leaving group by direct coordination to one of the catalytic metal ions, ptRNA substrates with single 3′-S-phosphorothiolate linkages at the RNase P cleavage site were synthesized. With a 3′-S-phosphorothiolate-modified ptRNA carrying a 7 nt 5′-flank, a complete shift of the cleavage site to the next unmodified phosphodiester in the 5′-direction was observed. Cleavage at the modified linkage was not restored in the presence of thiophilic metal ions, such as Mn²⁺ or Cd²⁺. To suppress aberrant cleavage, we also constructed a 3′-S-phosphorothiolate-modified ptRNA with a 1 nt 5′-flank. No detectable cleavage of this substrate was seen in reactions catalyzed by RNase P RNAs from Escherichia coli and Bacillus subtilis, independent of the presence of thiophilic metal ions. Ground state binding of modified ptRNAs was not impaired, suggesting that the 3′-S-phosphorothiolate modification specifically prevents formation of the transition state, possibly by excluding catalytic metal ions from the active site.     

The poly(A) binding protein Hfq protects RNA from RNase E and exoribonucleolytic degradation

The Hfq protein, which shares sequence and structural homology with the Sm and Lsm proteins, binds to various RNAs, primarily recognizing AU-rich single-stranded regions. In this paper, we study the ability of the Escherichia coli Hfq protein to bind to a polyadenylated fragment of rpsO mRNA. Hfq exhibits a high specificity for a 100-nucleotide RNA harboring 18 3′-terminal A-residues. Structural analysis of the adenylated RNA–Hfq complex and gel shift assays revealed the presence of two Hfq binding sites. Hfq binds primarily to the poly(A) tail, and to a lesser extent a U-rich sequence in a single-stranded region located between two hairpin structures. The oligo(A) tail and the interhelical region are sensitive to 3′–5′ exoribonucleases and RNase E hydrolysis, respectively, in vivo. In vitro assays demonstrate that Hfq protects poly(A) tails from exonucleolytic degradation by both PNPase and RNase II. In addition, RNase E processing, which occurred close to the U-rich sequence, is impaired by the presence of Hfq. These data suggest that Hfq modulates the sensitivity of RNA to ribonucleases in the cell.     

Conformational change in the Bacillus subtilis RNase P holoenzyme–pre-tRNA complex enhances substrate affinity and limits cleavage rate

Ribonuclease P (RNase P) is a ribonucleoprotein complex that catalyzes the 5′ maturation of precursor tRNAs. To investigate the mechanism of substrate recognition in this enzyme, we characterize the thermodynamics and kinetics of Bacillus subtilis pre-tRNA^Asp binding to B. subtilis RNase P holoenzyme using fluorescence techniques. Time courses for fluorescein-labeled pre-tRNA binding to RNase P are biphasic in the presence of both Ca(II) and Mg(II), requiring a minimal two-step association mechanism. In the first step, the apparent bimolecular rate constant for pre-tRNA associating with RNase P has a value that is near the diffusion limit and is independent of the length of the pre-tRNA leader. Following formation of the initial enzyme–substrate complex, a unimolecular step enhances the overall affinity of pre-tRNA by eight- to 300-fold as the length of the leader sequence increases from 2 to 5 nucleotides. This increase in affinity is due to a decrease in the reverse rate constant for the conformational change that correlates with the formation of an optimal leader–protein interaction in the RNase P holoenzyme–pre-tRNA complex. Furthermore, the forward rate constant for the conformational change becomes rate limiting for cleavage under single-turnover conditions at high pH, explaining the origin of the observed apparent pK_a in the RNase P-catalyzed cleavage reaction. These data suggest that a conformational change in the RNase P•pre-tRNA complex is coupled to the interactions between the 5′ leader and P protein and aligns essential functional groups at the cleavage active site to enhance efficient cleavage of pre-tRNA.     

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

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

RNase J1 endonuclease activity as a probe of RNA secondary structure

Reliable determination of RNA secondary structure depends on both computer algorithms and experimental probing of nucleotides in single- or double-stranded conformation. Here we describe the exploitation of the endonucleolytic activity of the Bacillus subtilis enzyme RNase J1 as a probe of RNA structure. RNase J1 cleaves in single-stranded regions and, in vitro at least, the enzyme has relatively relaxed nucleotide specificity. We confirmed the feasibility of the approach on an RNA of known structure, B. subtilis tRNA^Thr. We then used RNase J1 to solve the secondary structure of the 5′ end of the hbs mRNA. Finally, we showed that RNase J1 can also be used in footprinting experiments by probing the interaction between the 30S ribosomal subunit and the Shine–Dalgarno element of the hbs mRNA.     

RNase activity of polynucleotide phosphorylase is critical at low temperature in Escherichia coli and is complemented by RNase II

In Escherichia coli, the cold shock response is exerted upon a temperature change from 37°C to 15°C and is characterized by induction of several cold shock proteins, including polynucleotide phosphorylase (PNPase), during acclimation phase. In E. coli, PNPase is essential for growth at low temperatures; however, its exact role in this essential function has not been fully elucidated. PNPase is a 3′-to-5′ exoribonuclease and promotes the processive degradation of RNA. Our screening of an E. coli genomic library for an in vivo counterpart of PNPase that can compensate for its absence at low temperature revealed only one protein, another 3′-to-5′ exonuclease, RNase II. Here we show that the RNase PH domains 1 and 2 of PNPase are important for its cold shock function, suggesting that the RNase activity of PNPase is critical for its essential function at low temperature. We also show that its polymerization activity is dispensable in its cold shock function. Interestingly, the third 3′-to-5′ processing exoribonuclease, RNase R of E. coli, which is cold inducible, cannot complement the cold shock function of PNPase. We further show that this difference is due to the different targets of these enzymes and stabilization of some of the PNPase-sensitive mRNAs, like fis, in the Δpnp cells has consequences, such as accumulation of ribosomal subunits in the Δpnp cells, which may play a role in the cold sensitivity of this strain.     

Oligoribonuclease is a common downstream target of lithium-induced pAp accumulation in Escherichia coli and human cells

We identified Oligoribonuclease (Orn), an essential Escherichia coli protein and the only exonuclease degrading small ribonucleotides (5mer to 2mer) and its human homologue, small fragment nuclease (Sfn), in a screen for proteins that are potentially regulated by 3′-phosphoadenosine 5′-phosphate (pAp). We show that both enzymes are sensitive to micromolar amounts of pAp in vitro. We also demonstrate that Orn can degrade short DNA oligos in addition to its activity on RNA oligos, similar to what was documented for Sfn. pAp was shown to accumulate as a result of inhibition of the pAp-degrading enzyme by lithium, widely used to treat bipolar disorder, thus its regulatory targets are of significant medical interest. CysQ, the E.coli pAp-phosphatase is strongly inhibited by lithium and calcium in vitro and is a main target of lithium toxicity in vivo. Our findings point to remarkable conservation of the connection between sulfur- and RNA metabolism between E.coli and humans.     

Bacillus subtilis RNase J1 endonuclease and 5′ exonuclease activities in the turnover of ΔermC mRNA

RNase J1, a ribonuclease with 5′ exonuclease and endonuclease activities, is an important factor in Bacillus subtilis mRNA decay. A model for RNase J1 endonuclease activity in mRNA turnover has RNase J1 binding to the 5′ end and tracking to a target site downstream, where it makes a decay-initiating cleavage. The upstream fragment from this cleavage is degraded by 3′ exonucleases; the downstream fragment is degraded by RNase J1 5′ exonuclease activity. Previously, ΔermC mRNA was used to show 5′-end dependence of mRNA turnover. Here we used ΔermC mRNA to probe RNase J1-dependent degradation, and the results were consistent with aspects of the model. ΔermC mRNA showed increased stability in a mutant strain that contained a reduced level of RNase J1. In agreement with the tracking concept, insertion of a strong stem–loop structure at +65 resulted in increased stability. Weakening this stem–loop structure resulted in reversion to wild-type stability. RNA fragments containing the 3′ end were detected in a strain with reduced RNase J1 expression, but were undetectable in the wild type. The 5′ ends of these fragments mapped to the upstream side of predicted stem–loop structures, consistent with an impediment to RNase J1 5′ exonuclease processivity. A ΔermC mRNA deletion analysis suggested that decay-initiating endonuclease cleavage could occur at several sites near the 3′ end. However, even in the absence of these sites, stability was further increased in a strain with reduced RNase J1, suggesting alternate pathways for decay that could include exonucleolytic decay from the 5′ end.     

Bacillus subtilis RecN binds and protects 3'-single-stranded DNA extensions in the presence of ATP

Bacillus subtilis RecN appears to be an early detector of breaks in double-stranded DNA. In vivo, RecN forms discrete nucleoid-associated structures and in vitro exhibits Mg²⁺-dependent single-stranded (ss) DNA binding and ssDNA-dependent ATPase activities. In the presence of ATP or ADP, RecN assembles to form large networks with ssDNA molecules (designated complexes CII and CIII) that involve ATP binding and requires a 3′-OH at the end of ssDNA molecule. Addition of dATP–RecA complexes dissociates RecN from these networks, but this is not observed following addition of an ssDNA binding protein. Apparently, ATP modulates the RecN–ssDNA complex for binding to ssDNA extensions and, in vivo, RecN–ATP bound to 3′-ssDNA might sequester ssDNA ends within complexes that protect the ssDNA while the RecA accessory proteins recruit RecA. With the association of RecA to ssDNA, RecN would dissociate from the DNA end facilitating the subsequent steps in DNA repair.