In plant mitochondria, transcription proceeds well beyond the region that will become mature 3 extremities of mRNAs, and the mechanisms of 3 maturation are largely unknown. Here, we show the involvement of two exoribonucleases, AtmtPNPase and AtmtRNaseII, in the 3 processing of atp9 mRNAs in Arabidopsis thaliana mitochondria. Down-regulation of AtmtPNPase results in the accumulation of pretranscripts of several times the size of mature atp9 mRNAs, indicating that 3 processing of these transcripts is performed mainly exonucleolytically by AtmtPNPase. This enzyme is however not sufficient to completely process atp9 mRNAs, because with down-regulation of another mitochondrial exoribonuclease, AtmtRNaseII, about half of atp9 transcripts exhibit short 3 nucleotide extensions compared with mature mRNAs. These short extensions can be efficiently removed by AtmtRNaseII in vitro. Taken together, these results show that 3 processing of atp9 mRNAs in Arabidopsis mitochondria is, at least, a twostep phenomenon. First, AtmtPNPase is involved in removing 3 extensions that may reach several kilobases. Second, AtmtRNaseII degrades short nucleotidic extensions to generate the mature 3 -ends.Functional RNAs are generated through a series of complex post-transcriptional processes. The nature of these processes can vary depending on the organism or cellular compartment considered and may include maturation of 5Ј and 3Ј termini, splicing of introns, capping, editing, base modifications, or addition of nongenomically-encoded nucleotides such as polyadenylation. Processing of mRNAs is well documented for bacterial and eukaryotic nuclear mRNAs (1, 2). Our knowledge of maturation of plastid transcripts is also extensive for both Chlamydomonas and higher plants (3). However, mRNA maturation processes in plant mitochondria are far less well characterized. Two lines of evidence suggest that processing of 3Ј extremities occurs for any RNA in plant mitochondria. First, run-on experiments have demonstrated that transcription proceeds beyond the region that corresponds to mature 3Ј-ends of mRNAs and rRNAs (4). Second, it has been shown using an in vitro transcription system that inverted repeats that terminate some mitochondrial mRNAs are not recognized as transcription termination signals (5). These inverted repeats seem to be essential as processing signals in vitro (5) and in vivo (6, 7). However, the ribonucleases involved in 3Ј mRNA maturation processes remain to be identified in plant mitochondria.Escherichia coli represents one of the model organisms for which the function, mechanism, and regulation of ribonucleases (RNases) are intensively studied (for example, see Refs. 1, 8, and 9). Among the eight characterized exoribonucleases in E. coli, polynucleotide phosphorylase (PNPase) 1 and RNaseII are the main exoribonucleases involved in degrading mRNAs in a 3Ј to 5Ј direction but participate also in processing events. PNPase-like proteins are also present in human mitochondria (10) and in chloroplasts. In the latter, it is involved both ...
Plant mitochondria contain three rRNA genes, rrn26, rrn18 and rrn5, the latter two being co-transcribed. We have recently identified a polynucleotide phosphorylase-like protein (AtmtPNPase) in Arabidopsis mitochondria. Plants downregulated for AtmtPNPase expression (PNP-plants) accumulate 18S rRNA species polyadenylated at internal sites, indicating that AtmtPNPase is involved in 18S rRNA degradation. In addition, AtmtPNPase is required to degrade the leader sequence of 18S rRNA, a maturation by-product excised by an endonucleolytic cut 5' to the 18S rRNA. PNP-plants also accumulate 18S rRNA precursors correctly processed at their 5' end but containing the intergenic sequence (ITS) between the 18S and 5S rRNA. Interestingly, these precursors may be polyadenylated. Taken together, these results suggest that AtmtPNPase initiates the degradation of the ITS from 18S precursors following polyadenylation. To test this, we overexpressed in planta a second mitochondrial exoribonuclease, AtmtRNaseII, that degrades efficiently unstructured RNA including poly(A) tails. This resulted also in the detection of 18S rRNA precursors showing that AtmtRNaseII is not able to degrade the ITS but can impede the action of AtmtPNPase in initiating the degradation of the ITS. These results show that AtmtPNPase is essential for several aspects of 18S rRNA metabolism in Arabidopsis mitochondria.
Recently, we and others have reported that mRNAs may be polyadenylated in plant mitochondria, and that polyadenylation accelerates the degradation rate of mRNAs. To further characterize the molecular mechanisms involved in plant mitochondrial mRNA degradation, we have analyzed the polyadenylation and degradation processes of potato atp9 mRNAs. The overall majority of polyadenylation sites of potato atp9 mRNAs is located at or in the vicinity of their mature 3-extremities. We show that a 3-to 5-exoribonuclease activity is responsible for the preferential degradation of polyadenylated mRNAs as compared with non-polyadenylated mRNAs, and that 20 -30 adenosine residues constitute the optimal poly(A) tail size for inducing degradation of RNA substrates in vitro. The addition of as few as seven non-adenosine nucleotides 3 to the poly(A) tail is sufficient to almost completely inhibit the in vitro degradation of the RNA substrate. Interestingly, the exoribonuclease activity proceeds unimpeded by stable secondary structures present in RNA substrates. From these results, we propose that in plant mitochondria, poly(A) tails added at the 3 ends of mRNAs promote an efficient 3-to 5-degradation process.The control of mRNA stability constitutes an important aspect of the regulation of gene expression in all organisms. Polyadenylation of mRNAs is involved in the control of mRNA stability, however, with two significantly different roles depending on the organism or subcellular compartment concerned. Polyadenylation is required for stabilizing virtually all nuclear-encoded mRNAs in all eukaryotes. In contrast, polyadenylation targets mRNAs for degradation in eubacteria (1, 2), chloroplasts (3-6), plant mitochondria (7-9), and trypanosome mitochondria (10). In eubacteria and chloroplasts, degradation of mRNAs is initiated by endonucleolytic cleavages. The resulting fragments are then degraded by 3Ј-to 5Ј-exonuclease activities (1, 5). In both systems, polyadenylation targets endonucleolytic cleavage products for rapid degradation. In chloroplasts, structured mature 3Ј ends are poor substrates for polyadenylation as compared with the internal RNA fragments generated by endonuclease(s) (5, 6).In plant mitochondria, molecular mechanisms involved in mRNA stability or degradation are still poorly understood (11). For instance, no proteins involved in these processes have been formally identified, although several candidate genes have now been identified since the completion of the nuclear genome sequence of Arabidopsis thaliana. Stable secondary structures can be predicted at the 3Ј-extremities of some but not all plant mitochondrial mRNAs (12). When present, these structures appear to be involved in stabilizing the transcripts (13-15) and in the correct processing of 3Ј-extremities rather than being signals for transcription termination (15). Mature 3Ј termini of plant mitochondria mRNAs are generated by 3Ј-processing of longer pre-mRNA molecules (15), and stable mature mRNAs are not constitutively polyadenylated at their 3Ј-extremit...
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