Deregulation of poly(A) polymerase I in Escherichia coli inhibits protein synthesis and leads to cell death

Polyadenylation plays important roles in RNA metabolism in both prokaryotes and eukaryotes. Surprisingly, deregulation of polyadenylation by poly(A) polymerase I (PAP I) in Escherichia coli leads to toxicity and cell death. We show here that mature tRNAs, which are normally not substrates for PAP I in wild-type cells, are rapidly polyadenylated as PAP I levels increase, leading to dramatic reductions in the fraction of aminoacylated tRNAs, cessation of protein synthesis and cell death. The toxicity associated with PAP I is exacerbated by the absence of either RNase T and/or RNase PH, the two major 3′ → 5′ exonucleases involved in the final step of tRNA 3′-end maturation, confirming their role in the regulation of tRNA polyadenylation. Furthermore, our data demonstrate that regulation of PAP I is critical not for preventing the decay of mRNAs, but rather for maintaining normal levels of functional tRNAs and protein synthesis in E. coli, a function for polyadenylation that has not been observed previously in any organism.     

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.     

RapA, Escherichia coli RNA polymerase SWI/SNF subunit-dependent polyadenylation of RNA

In this work, we describe RapA-dependent polyadenylation of model RNA substrates and endogenous, RNA polymerase-associated nucleic acid fragments. We demonstrate that the Escherichia coli RNA polymerase obtained through the classic purification procedure carries endogenous RNA oligonucleotides, which, in the presence of ATP, are polyriboadenylated in a RapA-dependent manner by an accessory poly(rA) polymerase. RNA polymerase isolated from poly(A) polymerase- (PAP-) and polynucleotide phosphorylase- (PNP-) deficient E. coli strain lacks accessory (rA)(n)-synthetic activity. Experiments with reconstituted RNA polymerase-PAP and RNA polymerase-PNP mixtures suggest that RapA enables the polyadenylation by PAP of RNA polymerase-associated RNA. Mutations disrupting RapA's ATP-hydrolytic function disrupt RapA-dependent polyadenylation, and the rapA(-)E. coli strain displays a measurable reduction in RNA polyadenylation. RapA-dependent polyadenylation can also be modulated by mutations in the section of RapA's SWI/SNF domain linked to interaction with single-stranded nucleic acid. We have developed enzymatic assays in which model, synthetic RNAs are polyriboadenylated in a RapA-dependent manner. Taken together, our results are consistent with RapA acting as an RNA polymerase-associated, ATP-dependent RNA translocase. Our work further links RapA to RNA remodeling and provides new mechanistic insights into the functional interaction between RNA polymerase and RapA.     

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.     

Roles of polyadenylation and nucleolytic cleavage in the filamentous phage mRNA processing and decay pathways in Escherichia coli.

To define basic features of mRNA processing and decay in Escherichia coli, we have examined a set of mRNAs encoded by the filamentous phage f1 that have structures typical of bacterial mRNAs. They bear a stable hairpin stem-loop on the 3' end left from rho-independent termination and are known to undergo processing by RNase E. A small percentage of the f1 mRNAs were found to bear poly(A) tails that were attached to heterogeneous positions near the common 3' end. In a poly(A) polymerase-deficient host, the later-appearing processed mRNAs were stabilized, and a novel small RNA accumulated. This approximately 125-nt RNA proved to arise via RNase E cleavage from the 3'-terminal region of the mRNAs bearing the terminator. Normally ribosomes translating gene VIII appear to protect this cleavage site from RNase E, so that release of the fragment from the mRNAs occurs very slowly. The data presented define additional steps in the f1 mRNA processing and decay pathways and clarify how features of the pathways are used in establishing and maintaining the persistent filamentous phage infection. Although the primary mode of decay is endonucleolytic cleavage generating a characteristic 5' --> 3' wave of products, polyadenylation is involved in part in degradation of the processed mRNAs and is required for turnover of the 125-nt mRNA fragment. The results place polyadenylation at a later rather than an initiating step of decay. They also provide a clear illustration of how stably structured RNA 3' ends act as barriers to 3' --> 5' exonucleolytic mRNA decay.