Novel one-step mechanism for tRNA 3'-end maturation by the exoribonuclease RNase R of Mycoplasma genitalium

Mycoplasma genitalium is expected to metabolize RNA using unique pathways because its minimal genome encodes very few ribonucleases. In this work, we report that the only exoribonuclease identified in M. genitalium, RNase R, is able to remove tRNA 3'-trailers and generate mature 3'-ends. Several sequence and structural features of a tRNA precursor determine its precise processing at the 3'-end by RNase R in a purified system. The aminoacyl-acceptor stem plays a major role in stopping RNase R digestion at the mature 3'-end. Disruption of the stem causes partial or complete degradation of the pre-tRNA by RNase R, whereas extension of the stem results in the formation of a product terminating downstream at the new mature 3'-end. In addition, the 3'-terminal CCA sequence and the discriminator residue influence the ability of RNase R to stop at the mature 3'-end. RNase R-mediated generation of the mature 3'-end prefers a sequence of RCCN at the 3' terminus of tRNA. Variations of this sequence may cause RNase R to trim further and remove terminal CA residues from the mature 3'-end. Therefore, M. genitalium RNase R can precisely remove the 3'-trailer of a tRNA precursor by recognizing features in the terminal domains of tRNA, a process requiring multiple RNases in most bacteria.     

Ribonuclease II preserves chloroplast RNA homeostasis by increasing mRNA decay rates,and cooperates with polynucleotide phosphorylase in 3′ end maturation

Ribonuclease R (RNR1) and polynucleotide phosphorylase (cpPNPase) are the two known 3′→5′ exoribonucleases in Arabidopsis chloroplasts, and are involved in several aspects of rRNA and mRNA metabolism. In this work, we show that mutants lacking both RNR1 and cpPNPase exhibit embryo lethality, akin to the non‐viability of the analogous double mutant in Escherichia coli. We were successful, however, in combining an rnr1 null mutation with weak pnp mutant alleles, and show that the resulting chlorotic plants display a global reduction in RNA abundance. Such a counterintuitive outcome following the loss of RNA degradation activity suggests a major importance of RNA maturation as a determinant of RNA stability. Detailed analysis of the double mutant demonstrates that the enzymes catalyze a two‐step maturation of mRNA 3′ ends, with RNR1 polishing 3′ termini created by cpPNPase. The bulky quaternary structure of cpPNPase compared with RNR1 could explain this activity split between the two enzymes. In contrast to the double mutants, the rnr1 single mutant overaccumulates most mRNA species when compared with the wild type. The excess mRNAs in rnr1 are often present in non‐polysomal fractions, and half‐life measurements demonstrate a substantial increase in the stability of most mRNA species tested. Together, our data reveal the cooperative activity of two 3′→5′ exoribonucleases in chloroplast mRNA 3′ end maturation, and support the hypothesis that RNR1 plays a significant role in the destabilization of mRNAs unprotected by ribosomes.     

Ribonuclease A suggests how proteins self-chaperone against amyloid fiber formation

Genomic analyses have identified segments with high fiber-forming propensity in many proteins not known to form amyloid. Proteins are often protected from entering the amyloid state by molecular chaperones that permit them to fold in isolation from identical molecules; but, how do proteins self-chaperone their folding in the absence of chaperones? Here, we explore this question with the stable protein ribonuclease A (RNase A). We previously identified fiber-forming segments of amyloid-related proteins and demonstrated that insertion of these segments into the C-terminal hinge loop of nonfiber-forming RNase A can convert RNase A into the amyloid state through three-dimensional domain-swapping, where the inserted fiber-forming segments interact to create a steric zipper spine. In this study, we convert RNase A into amyloid-like fibers by increasing the loop length and hence conformational freedom of an endogenous fiber-forming segment, SSTSAASS, in the N-terminal hinge loop. This is accomplished by sandwiching SSTSAASS between inserted Gly residues. With these inserts, SSTSAASS is now able to form the steric zipper spine, allowing RNase A to form amyloid-like fibers. We show that these fibers contain RNase A molecules retaining their enzymatic activity and therefore native-like structure. Thus, RNase A appears to prevent fiber formation by limiting the conformational freedom of this fiber-forming segment from entering a steric zipper. Our observations suggest that proteins have evolved to self-chaperone by using similar protective mechanisms.     

Transient interactions of a slow-folding protein with the Hsp70 chaperone machinery

Most known proteins have at least one local Hsp70 chaperone binding site. Does this mean that all proteins interact with Hsp70 as they fold? This study makes an initial step to address the above question by examining the interaction of the E.coli Hsp70 chaperone (known as DnaK) and its co-chaperones DnaJ and GrpE with a slow-folding E.coli substrate, RNase H^D. Importantly, this protein is a nonobligatory client, and it is able to fold in vitro even in the absence of chaperones. We employ stopped-flow mixing, chromatography, and activity assays to analyze the kinetic perturbations induced by DnaK/DnaJ/GrpE (K/J/E) on the folding of RNase H^D. We find that K/J/E slows down RNase H^D''s apparent folding, consistent with the presence of transient chaperone-substrate interactions. However, kinetic retardation is moderate for this slow-folding client and it is expected to be even smaller for faster-folding substrates. Given that the interaction of folding-competent substrates such as RNase H^D with the K/J/E chaperones is relatively short-lived, it does not significantly interfere with the timely production of folded biologically active substrate. The above mode of action is important because it preserves K/J/E bioavailability, enabling this chaperone system to act primarily by assisting the folding of other misfolded and (or) aggregation-prone cellular proteins that are unable to fold independently. When refolding is carried out in the presence of K/J and absence of the nucleotide exchange factor GrpE, some of the substrate population becomes trapped as a chaperone-bound partially unfolded state.     

Involvement of Ser94 in RNase HIII from Chlamydophila pneumoniae in the recognition of a single ribonucleotide misincorporated into double-stranded DNA

We recently provided the first report that RNase HIII can cleave a DNA-rN₁-DNA/DNA substrate (rN₁, one ribonucleotide) in vitro. In the present study, mutagenesis analyses and molecular dynamics (MD) simulations were performed on RNase HIII from Chlamydophila pneumoniae AR39 (CpRNase HIII). Our results elucidate the mechanism of ribonucleotide recognition employed by CpRNase HIII, indicating that the G95/K96/G97 motif of CpRNase HIII represents the main surface interacting with single ribonucleotides, in a manner similar to that of the GR(K)G motif of RNase HIIs. However, CpRNase HIII lacks the specific tyrosine required for RNase HII to recognize single ribonucleotides in double-stranded DNA (dsDNA). Interestingly, MD shows that Ser94 of CpRNase HIII forms a stable hydrogen bond with the deoxyribonucleotide at the (5')RNA–DNA(3') junction, moving this nucleotide away from the chimeric ribonucleotide. This movement appears to deform the nucleic acid backbone at the RNA–DNA junction and allows the ribonucleotide to interact with the GKG motif. Based on the inferences drawn from MD simulations, biochemical results indicated that Ser94 was necessary for catalytic activity on the DNA-rN₁-DNA/DNA substrate; mutant S94V could bind this substrate but exhibited no cleavage. Mismatches opposite the single ribonucleotide misincorporated in dsDNA inhibited cleavage by CpRNase HIII to varying degrees but did not interfere with CpRNase/substrate binding. Further MD results implied that mismatches impair the interaction between Ser94 and the deoxyribonucleotide at the RNA–DNA junction. Consequently, recognition of the misincorporated ribonucleotide was disturbed. Our results may help elucidate the distinct substrate-recognition properties of different RNase Hs.     

Immunosuppression induced by expression of a viral RNase enhances susceptibility of Plutella xylostella to microbial pesticides

Abstract Polydnaviruses are a group of insect DNA viruses and are characterized in their segmented genome that is located in the chromosome(s) of host wasps. A polydnavirus, Cotesia plutellae bracovirus (CpBV), encodes a viral ribonuclease (RNase) T2 in a specific segment #3 (CpBV‐S3). This study tested its effect on gene expression associated with host immune responses in the diamondback moth, Plutella xylostella. Micro‐injection of CpBV‐S3 into nonparasitized larvae induced expression of its two encoded genes, CpBV‐ORF301 (=CpBV‐RNase T2) and CpBV‐ORF302. In response to a bacterial challenge, four antimicrobial peptide genes (hemolin, gloverin, cecropin and lysozyme) and six phenoloxidase (PO)–associated genes (proPO‐activating proteinase, PO, serine proteinase homolog and serpins 1–3) were up‐regulated in their expressions. However, the transient expression of CpBV‐S3 suppressed the expressions of cecropin, PO and serpin 1. Double‐stranded RNA specific to the viral RNase T2 could specifically knockdown the viral gene expression and restored the three gene expressions suppressed in the larvae injected with CpBV‐S3. The inhibitory activity of the viral RNase T2 on the target genes was further proven by the suppression of PO activation in response to bacterial challenge in the larvae injected with CpBV‐S3. This immunosuppression by the expression of the viral RNase T2 resulted in significant increase of pathogen susceptibility of P. xylostella against Bacillus thuringiensis or baculovirus infection.     

Structure of an archaeal homolog of the human protein complex Rpp21-Rpp29 that is a key core component for the assembly of active ribonuclease P

Ribonuclease P (RNase P) is a ribonucleoprotein complex involved in the processing of the 5′-leader sequence of precursor tRNA. Human RNase P protein subunits Rpp21 and Rpp29, which bind to each other, with catalytic RNA (H1 RNA) are sufficient for activating endonucleolytic cleavage of precursor tRNA. Here we have determined the crystal structure of the complex between the Pyrococcus horikoshii RNase P proteins PhoRpp21 and PhoRpp29, the archaeal homologs of Rpp21 and Rpp29, respectively. PhoRpp21 and PhoRpp29 form a heterodimeric structure where the two N-terminal helices (α1 and α2) in PhoRpp21 predominantly interact with the N-terminal extended structure, the β-strand (β2), and the C-terminal helix (α3) in PhoRpp29. The interface is dominated by hydrogen bonds and several salt bridges, rather than hydrophobic interactions. The electrostatic potential on the surface of the heterodimer shows a positively charged cluster on one face, suggesting a possible RNA-binding surface of the PhoRpp21-PhoRpp29 complex. The present structure, along with the result of a mutational analysis, suggests that heterodimerization between PhoRpp21 and PhoRpp29 plays an important role in the function of P. horikoshii RNase P.