Domain analysis of the chloroplast polynucleotide phosphorylase reveals discrete functions in RNA degradation,polyadenylation, and sequence homology with exosome proteins

The molecular mechanism of mRNA degradation in the chloroplast consists of sequential events, including endonucleolytic cleavage, the addition of poly(A)-rich sequences to the endonucleolytic cleavage products, and exonucleolytic degradation. In spinach chloroplasts, the latter two steps of polyadenylation and exonucleolytic degradation are performed by the same phosphorolytic and processive enzyme, polynucleotide phosphorylase (PNPase). An analysis of its amino acid sequence shows that the protein is composed of two core domains related to RNase PH, two RNA binding domains (KH and S1), and an alpha-helical domain. The amino acid sequence and domain structure is largely conserved between bacteria and organelles. To define the molecular mechanism that controls the two opposite activities of this protein in the chloroplast, the ribonuclease, polymerase, and RNA binding properties of each domain were analyzed. The first core domain, which was predicted to be inactive in the bacterial enzymes, was active in RNA degradation but not in polymerization. Surprisingly, the second core domain was found to be active in degrading polyadenylated RNA only, suggesting that nonpolyadenylated molecules can be degraded only if tails are added, apparently by the same protein. The poly(A) high-binding-affinity site was localized to the S1 domain. The complete spinach chloroplast PNPase, as well as versions containing the core domains, complemented the cold sensitivity of an Escherichia coli PNPase-less mutant. Phylogenetic analyses of the two core domains showed that the two domains separated very early, resulting in the evolution of the bacterial and organelle PNPases and the exosome proteins found in eukaryotes and some archaea.     

RNA polyadenylation and degradation in cyanobacteria are similar to the chloroplast but different from Escherichia coli

The mechanism of RNA degradation in Escherichia coli involves endonucleolytic cleavage, polyadenylation of the cleavage product by poly(A) polymerase, and exonucleolytic degradation by the exoribonucleases, polynucleotide phosphorylase (PNPase) and RNase II. The poly(A) tails are homogenous, containing only adenosines in most of the growth conditions. In the chloroplast, however, the same enzyme, PNPase, polyadenylates and degrades the RNA molecule; there is no equivalent for the E. coli poly(A) polymerase enzyme. Because cyanobacteria is a prokaryote believed to be related to the evolutionary ancestor of the chloroplast, we asked whether the molecular mechanism of RNA polyadenylation in the Synechocystis PCC6803 cyanobacteria is similar to that in E. coli or the chloroplast. We found that RNA polyadenylation in Synechocystis is similar to that in the chloroplast but different from E. coli. No poly(A) polymerase enzyme exists, and polyadenylation is performed by PNPase, resulting in heterogeneous poly(A)-rich tails. These heterogeneous tails were found in the amino acid coding region, the 5' and 3' untranslated regions of mRNAs, as well as in rRNA and the single intron located at the tRNA(fmet). Furthermore, unlike E. coli, the inactivation of PNPase or RNase II genes caused lethality. Together, our results show that the RNA polyadenylation and degradation mechanisms in cyanobacteria and chloroplast are very similar to each other but different from E. coli.     

Sok antisense RNA from plasmid R1 is functionally inactivated by RNase E and polyadenylated by poly(A) polymerase I

The hok/sok system of plasmid R1, which mediates plasmid stabilization by the killing of plasmid-free cells, codes for two RNA species, Sok antisense RNA and hok mRNA. Sok RNA, which is unstable, inhibits translation of the stable hok mRNA. The 64 nt Sok RNA folds into a single stem-loop domain with an 11 nt unstructured 5' domain. The initial recognition reaction between Sok RNA and hok mRNA takes place between the 5' domain and the complementary region in hok mRNA. In this communication we examine the metabolism of Sok antisense RNA. We find that RNase E cleaves the RNA 6 nt from its 5' end and that this cleavage initiates Sok RNA decay. The RNase E cleavage occurs in the part of Sok RNA that is responsible for the initial recognition of the target loop in hok mRNA and thus leads to functional inactivation of the antisense. The major RNase E cleavage product (denoted pSok_-6) is rapidly degraded by polynucleotide phosphorylase (PNPase). Thus, the RNase E cleavage tags pSok₋₆ for further rapid degradation by PNPase from its 3' end. We also show that Sok RNA is polyadenylated by poly(A) polymerase I (PAP I), and that the poly(A)-tailing is prerequisite for the rapid 3'-exonucleolytic degradation by PNPase.     

Novel role for RNase PH in the degradation of structured RNA

Escherichia coli contains multiple 3' to 5' RNases, of which two, RNase PH and polynucleotide phosphorylase (PNPase), use inorganic phosphate as a nucleophile to catalyze RNA cleavage. It is known that an absence of these two enzymes causes growth defects, but the basis for these defects has remained undefined. To further an understanding of the function of these enzymes, the degradation pattern of different cellular RNAs was analyzed. It was observed that an absence of both enzymes results in the appearance of novel mRNA degradation fragments. Such fragments were also observed in strains containing mutations in RNase R and PNPase, enzymes whose collective absence is known to cause an accumulation of structured RNA fragments. Additional experiments indicated that the growth defects of strains containing RNase R and PNPase mutations were exacerbated upon RNase PH removal. Taken together, these observations suggested that RNase PH could play a role in structured RNA degradation. Biochemical experiments with RNase PH demonstrated that this enzyme digests through RNA duplexes of moderate stability. In addition, mapping and sequence analysis of an mRNA degradation fragment that accumulates in the absence of the phosphorolytic enzymes revealed the presence of an extended stem-loop motif at the 3' end. Overall, these results indicate that RNase PH plays a novel role in the degradation of structured RNAs and provides a potential explanation for the growth defects caused by an absence of the phosphorolytic RNases.     

Polynucleotide Phosphorylase Functions as Both an Exonuclease and a Poly(A) Polymerase in Spinach Chloroplasts

The molecular mechanism of mRNA degradation in the chloroplast consists of sequential events including endonucleolytic cleavage, the addition of poly(A)-rich sequences to the endonucleolytic cleavage products, and exonucleolytic degradation by polynucleotide phosphorylase (PNPase). In Escherichia coli, polyadenylation is performed mainly by poly(A)-polymerase (PAP) I or by PNPase in its absence. While trying to purify the chloroplast PAP by following in vitro polyadenylation activity, it was found to copurify with PNPase and indeed could not be separated from it. Purified PNPase was able to polyadenylate RNA molecules with an activity similar to that of lysed chloroplasts. Both activities use ADP much more effectively than ATP and are inhibited by stem-loop structures. The activity of PNPase was directed to RNA degradation or polymerization by manipulating physiologically relevant concentrations of P(i) and ADP. As expected of a phosphorylase, P(i) enhanced degradation, whereas ADP inhibited degradation and enhanced polymerization. In addition, searching the complete Arabidopsis genome revealed several putative PAPs, none of which were preceded by a typical chloroplast transit peptide. These results suggest that there is no enzyme similar to E. coli PAP I in spinach chloroplasts and that polyadenylation and exonucleolytic degradation of RNA in spinach chloroplasts are performed by one enzyme, PNPase.     

The role of the S1 domain in exoribonucleolytic activity: substrate specificity and multimerization

RNase II is a 3'-5' exoribonuclease that processively hydrolyzes single-stranded RNA generating 5' mononucleotides. This enzyme contains a catalytic core that is surrounded by three RNA-binding domains. At its C terminus, there is a typical S1 domain that has been shown to be critical for RNA binding. The S1 domain is also present in the other major 3'-5' exoribonucleases from Escherichia coli: RNase R and polynucleotide phosphorylase (PNPase). In this report, we examined the involvement of the S1 domain in the different abilities of these three enzymes to overcome RNA secondary structures during degradation. Hybrid proteins were constructed by replacing the S1 domain of RNase II for the S1 from RNase R and PNPase, and their exonucleolytic activity and RNA-binding ability were examined. The results revealed that both the S1 domains of RNase R and PNPase are able to partially reverse the drop of RNA-binding ability and exonucleolytic activity resulting from removal of the S1 domain of RNase II. Moreover, the S1 domains investigated are not equivalent. Furthermore, we demonstrate that S1 is neither responsible for the ability to overcome secondary structures during RNA degradation, nor is it related to the size of the final product generated by each enzyme. In addition, we show that the S1 domain from PNPase is able to induce the trimerization of the RNaseII-PNP hybrid protein, indicating that this domain can have a role in the biogenesis of multimers.     

Degradation of ribosomal RNA during starvation: comparison to quality control during steady-state growth and a role for RNase PH

Ribosomal RNAs are generally stable in growing Escherichia coli cells. However, their degradation increases dramatically under conditions that lead to slow cell growth. In addition, incomplete RNA molecules and molecules with defects in processing, folding, or assembly are also eliminated in growing cells in a process termed quality control. Here, we show that there are significant differences between the pathways of ribosomal RNA degradation during glucose starvation and quality control during steady-state growth. In both processes, endonucleolytic cleavage of rRNA in ribosome subunits is an early step, resulting in accumulation of large rRNA fragments when the processive exoribonucleases, RNase II, RNase R, and PNPase are absent. For 23S rRNA, cleavage is in the region of helix 71, but the exact position can differ in the two degradative processes. For 16S rRNA, degradation during starvation begins with shortening of its 3' end in a reaction catalyzed by RNase PH. In the absence of this RNase, there is no 3' end trimming of 16S rRNA and no accumulation of rRNA fragments, and total RNA degradation is greatly reduced. In contrast, the degradation pattern in quality control remains unchanged when RNase PH is absent. During starvation, the exoribonucleases RNase II and RNase R are important for fragment removal, whereas for quality control, RNase R and PNPase are more important. These data highlight the similarities and differences between rRNA degradation during starvation and quality control during steady-state growth and describe a role for RNase PH in the starvation degradative pathway.     

The RNA degradosome and poly(A) polymerase of Escherichia coli are required in vivo for the degradation of small mRNA decay intermediates containing REP-stabilizers

In Escherichia coli, REP-stabilizers are structural elements in polycistronic messages that protect 5'-proximal cistrons from 3'-->5' exonucleolytic degradation. The stabilization of a protected cistron can be an important determinant in the level of gene expression. Our results suggest that RNase E, an endoribonuclease, initiates the degradation of REP-stabilized mRNA. However, subsequent degradation of mRNA fragments containing a REP-stabilizer poses a special challenge to the mRNA degradation machinery. Two enzymes, the DEAD-box RNA helicase, RhlB and poly(A) polymerase (PAP) are required to facilitate the degradation of REP-stabilizers by polynucleotide phosphorylase (PNPase). This is the first in vivo evidence that these enzymes are required for the degradation of REP-stabilizers. Furthermore, our results show that REP degradation by RhlB and PNPase requires their association with RNase E as components of the RNA degradosome, thus providing the first in vivo evidence that this ribonucleolytic multienzyme complex is involved in the degradation of structured mRNA fragments.     

Genetic analysis of polynucleotide phosphorylase structure and functions

Polynucleotide phosphorylase (PNPase) is a phosphate-dependent 3' to 5' exonuclease widely diffused among bacteria and eukaryotes. The enzyme, a homotrimer, can also be found associated with the endonuclease RNase E and other proteins in a heteromultimeric complex, the RNA degradosome. PNPase negatively controls its own gene (pnp) expression by destabilizing pnp mRNA. A current model of autoregulation maintains that PNPase and a short duplex at the 5'-end of pnp mRNA are the only determinants of mRNA stability. During the cold acclimation phase autoregulation is transiently relieved and cellular pnp mRNA abundance increases significantly. Although PNPase has been extensively studied and widely employed in molecular biology for about 50 years, several aspects of structure-function relationships of such a complex protein are still elusive. In this work, we performed a systematic PCR mutagenesis of discrete pnp regions and screened the mutants for diverse phenotypic traits affected by PNPase. Overall our results support previous proposals that both first and second core domains are involved in the catalysis of the phosphorolytic reaction, and that both phosphorolytic activity and RNA binding are required for autogenous regulation and growth in the cold, and give new insights on PNPase structure-function relationships by implicating the alpha-helical domain in PNPase enzymatic activity.     

Running rings around RNA: a superfamily of phosphate-dependent RNases.

The exosome of Saccharomyces cerevisiae and the degradosome of Escherichia coli are multienzyme complexes involved in the degradation of mRNA. Both contain enzymes that are similar to the phosphate-dependent exoribonuclease RNase PH. These enzymes are phosphorylases that degrade RNA from the 3'-end. A recent X-ray crystallographic study of the polynucleotide phosphorylase (PNPase) from Streptomyces antibioticus reveals, for the first time, the atomic structure of a member of the RNase PH superfamily. Here, information from the structure of PNPase is used to address two related issues. First, the structure supports the idea that PNPase, which is a trimer of multidomain subunits, arose by duplication of a gene encoding an RNase PH-like enzyme. Second, the structure might explain how RNase PH-like enzymes associate into oligomeric rings that degrade RNA in a processive reaction.     

Different specificities of ribonuclease II and polynucleotide phosphorylase in 3'mRNA decay.

We review recent evidence on the in vivo and in vitro mRNA degradation properties of 2 3'-exonucleases, ribonuclease II and polynucleotide phosphorylase. Although secondary structures in the RNA can act as protective barriers against 3' exonucleolytic degradation, it appears that this effect depends on the stability of these structures. The fact that RNase II is more sensitive to RNA secondary structure than PNPase, could account for some differences observed in messenger degradation by the 2 enzymes in vivo. Terminator stem-loop structures are often very stable and 3' exonucleolytic degradation proceeds only after they have been eliminated by an endonucleolytic cleavage. Other secondary structures preceding terminator stem-loop seem to contribute to mRNA stability against exonucleolytic decay.     

Different specificities of ribonuclease II and polynucleotide phosphorylase in 3'mRNA decay

We review recent evidence on the in vivo and in vitro mRNA degradation properties of 2 3'-exonucleases, ribonuclease II and polynucleotide phosphorylase. Although secondary structures in the RNA can act as protective barriers against 3' exonucleolytic degradation, it appears that this effect depends on the stability of these structures. The fact that RNase II is more sensitive to RNA secondary structure than PNPase, could account for some differences observed in messenger degradation by the 2 enzymes in vivo. Terminator stem-loop structures are often very stable and 3' exonucleolytic degradation proceeds only after they have been eliminated by an endonucleolytic cleavage. Other secondary structures preceding terminator stem-loop seem to contribute to mRNA stability against exonucleolytic decay.     

Defining the domains of human polynucleotide phosphorylase (hPNPaseOLD-35) mediating cellular senescence

To fully comprehend cellular senescence, identification of relevant genes involved in this process is mandatory. Human polynucleotide phosphorylase (hPNPase(OLD-35)), an evolutionarily conserved 3', 5' exoribonuclease mediating mRNA degradation, was first identified as a predominantly mitochondrial protein overexpressed during terminal differentiation and senescence. Overexpression of hPNPase(OLD-35) in human melanoma cells and melanocytes induces distinctive changes associated with senescence, potentially mediated by direct degradation of c-myc mRNA by this enzyme. hPNPase(OLD-35) contains two RNase PH (RPH) domains, one PNPase domain, and two RNA binding domains. Using deletion mutation analysis in combination with biochemical and molecular analyses we now demonstrate that the presence of either one of the two RPH domains conferred similar functional activity as the full-length protein, whereas a deletion mutant containing only the RNA binding domains was devoid of activity. Moreover, either one of the two RPH domains induced the morphological, biochemical, and gene expression changes associated with senescence, including degradation of c-myc mRNA. Subcellular distribution confirmed hPNPase(OLD-35) to be localized both in mitochondria and the cytoplasm. The present study elucidates how a predominantly mitochondrial protein, via its localization in both mitochondria and cytoplasm, is able to target a specific cytoplasmic mRNA, c-myc, for degradation and through this process induce cellular senescence.     

Crystal structure of the phosphorolytic exoribonuclease RNase PH from Bacillus subtilis and implications for its quaternary structure and tRNA binding

RNase PH is a member of the family of phosphorolytic 3' --> 5' exoribonucleases that also includes polynucleotide phosphorylase (PNPase). RNase PH is involved in the maturation of tRNA precursors and especially important for removal of nucleotide residues near the CCA acceptor end of the mature tRNAs. Wild-type and triple mutant R68Q-R73Q-R76Q RNase PH from Bacillus subtilis have been crystallized and the structures determined by X-ray diffraction to medium resolution. Wild-type and triple mutant RNase PH crystallize as a hexamer and dimer, respectively. The structures contain a rare left-handed beta alpha beta-motif in the N-terminal portion of the protein. This motif has also been identified in other enzymes involved in RNA metabolism. The RNase PH structure and active site can, despite low sequence similarity, be overlayed with the N-terminal core of the structure and active site of Streptomyces antibioticus PNPase. The surface of the RNase PH dimer fit the shape of a tRNA molecule.     

Characterization of Staphylococcus epidermidis Polynucleotide phosphorylase and its interactions with ribonucleases RNase J1 and RNase J2

Polynucleotide phosphorylase catalyzes both 3′-5′ exoribonuclease and polyadenylation reactions. The crystal structure of Staphylococcus epidermidis PNPase revealed a bound phosphate in the PH2 domain of each protomer coordinated by three adjacent serine residues. Mutational analysis suggests that phosphate coordination by these serine residues is essential to maintain the catalytic center in an active conformation. We note that PNPase forms a complex with RNase J1 and RNase J2 without substantially altering either exo-ribonuclease or polyadenylation activity of this enzyme. This decoupling of catalytic activity from protein-protein interactions suggests that association of these endo- or exo-ribonucleases with PNPase could be more relevant for cellular localization or concerted targeting of structured RNA for recycling.