Distinct 18S rRNA precursors are targets of the exosome complex, the exoribonuclease RRP6L2 and the terminal nucleotidyltransferase TRL in Arabidopsis thaliana.

The biosynthesis of ribosomal RNA and its incorporation into functional ribosomes is an essential and intricate process that includes production of mature ribosomal RNA from large precursors. Here, we analyse the contribution of the plant exosome and its co-factors to processing and degradation of 18S pre-RNAs in Arabidopsis thaliana. Our data show that, unlike in yeast and humans, an RRP6 homologue, the nucleolar exoribonuclease RRP6L2, and the exosome complex, together with RRP44, function in two distinct steps of pre-18S rRNA processing or degradation in Arabidopsis. In addition, we identify TRL (TRF4/5-like) as the terminal nucleotidyltransferase that is mainly responsible for oligoadenylation of rRNA precursors in Arabidopsis. We show that TRL is required for efficient elimination of the excised 5' external transcribed spacer and of 18S maturation intermediates that escaped 5' processing. Our data also suggest involvement of additional nucleotidyltransferases, including terminal uridylyltransferase(s), in modifying rRNA processing intermediates in plants.

Polyadenylation-assisted RNA degradation processes in plants.

Polyadenylation is a multifunctional post-transcriptional modification that is best known for stabilizing eukaryotic mRNAs and promoting their translation. However, the primordial role of polyadenylation is to target RNAs for degradation by 3' to 5' exoribonucleases. Polyadenylation-assisted RNA degradation contributes to post-transcriptional control in the three genetic compartments of a plant cell: the nucleus, the chloroplast and the mitochondrion. Here, we review the current knowledge of this RNA degradation pathway in these compartments, highlighting recent results that emphasize the crucial role of polyadenylation-assisted RNA degradation in plant genome expression. We also discuss other possible roles of polyadenylation and its sister process polyuridylation.

Coping with cryptic and defective transcripts in plant mitochondria.

Plant mitochondria are particularly prone to the production of both defective and cryptic transcripts as a result of the complex organisation and mode of expression of their genome. Cryptic transcripts are generated from intergenic regions due to a relaxed control of transcription. Certain intergenic regions are transcribed at higher rates than genuine genes and therefore, cryptic transcripts are abundantly produced in plant mitochondria. In addition, primary transcripts from genuine genes must go through complex post-transcriptional processes such as C to U editing and cis or trans splicing of group II introns. These post-transcriptional processes are rather inefficient and as a result, defective transcripts are constantly produced in plant mitochondria. In this review, we will describe the nature of cryptic and defective transcripts as well as their fate in plant mitochondria. Although RNA surveillance is crucial to establishing the final transcriptome by degrading cryptic transcripts, plant mitochondria are able to tolerate a surprising high level of defective transcripts.

Degradation of a polyadenylated rRNA maturation by-product involves one of the three RRP6-like proteins in Arabidopsis thaliana.

Yeast Rrp6p and its human counterpart, PM/Scl100, are exosome-associated proteins involved in the degradation of aberrant transcripts and processing of precursors to stable RNAs, such as the 5.8S rRNA, snRNAs, and snoRNAs. The activity of yeast Rrp6p is stimulated by the polyadenylation of its RNA substrates. We identified three RRP6-like proteins in Arabidopsis thaliana: AtRRP6L3 is restricted to the cytoplasm, whereas AtRRP6L1 and -2 have different intranuclear localizations. Both nuclear RRP6L proteins are functional, since AtRRP6L1 complements the temperature-sensitive phenotype of a yeast rrp6Delta strain and mutation of AtRRP6L2 leads to accumulation of an rRNA maturation by-product. This by-product corresponds to the excised 5' part of the 18S-5.8S-25S rRNA precursor and accumulates as a polyadenylated transcript, suggesting that RRP6L2 is involved in poly(A)-mediated RNA degradation in plant nuclei. Interestingly, the rRNA maturation by-product is a substrate of AtRRP6L2 but not of AtRRP6L1. This result and the distinctive subcellular distribution of AtRRP6L1 to -3 indicate a specialization of RRP6-like proteins in Arabidopsis.

Arabidopsis GCP2 and GCP3 are part of a soluble gamma-tubulin complex and have nuclear envelope targeting domains.

In higher plants, microtubules (MTs) are assembled in distinctive arrays in the absence of a defined organizing center. Three MT nucleation sites have been described: the nuclear surface, the cell cortex and cortical MT branch points. The Arabidopsis thaliana (At) genome contains putative orthologues encoding all the components of characterized mammalian nucleation complexes: gamma-tubulin and gamma-tubulin complex proteins GCP2 to GCP6. We have cloned the cDNA encoding AtGCP2, and show that gamma-tubulin, AtGCP2 and AtGCP3 are part of the same tandem affinity-purified complex and are present in a large membrane-associated complex. In addition, small soluble gamma-tubulin complexes of the size expected for a gamma-tubulin core complex are recruited to isolated nuclei. Using immunogold labelling, AtGCP3 is localized to both the nuclear envelope (NE) and the plasma membrane. To identify domains that could play a role in targeting complexes to these nucleation sites, truncated AtGCP2- and AtGCP3-green fluorescent protein fusion proteins were expressed in BY-2 cells. Several domains from AtGCP2 and AtGCP3 are capable of targeting fusions to the NE. We propose that regulated recruitment of soluble gamma-tubulin-containing complexes is responsible for nucleation at dispersed sites in plant cells and contributes to the formation and organization of the various MT arrays.

The plant-specific ssDNA binding protein OSB1 is involved in the stoichiometric transmission of mitochondrial DNA in Arabidopsis.

Plant mitochondrial genomes exist in a natural state of heteroplasmy, in which substoichiometric levels of alternative mitochondrial DNA (mtDNA) molecules coexist with the main genome. These subgenomes either replicate autonomously or are created by infrequent recombination events. We found that Arabidopsis thaliana OSB1 (for Organellar Single-stranded DNA Binding protein1) is required for correct stoichiometric mtDNA transmission. OSB1 is part of a family of plant-specific DNA binding proteins that are characterized by a novel motif that is required for single-stranded DNA binding. The OSB1 protein is targeted to mitochondria, and promoter-beta-glucuronidase fusion showed that the gene is expressed in budding lateral roots, mature pollen, and the embryo sac of unfertilized ovules. OSB1 T-DNA insertion mutants accumulate mtDNA homologous recombination products and develop phenotypes of leaf variegation and distortion. The mtDNA rearrangements occur in two steps: first, homozygous mutants accumulate subgenomic levels of homologous recombination products; second, in subsequent generations, one of the recombination products becomes predominant. After the second step, the process is no longer reversible by backcrossing. Thus, OSB1 participates in controlling the stoichiometry of alternative mtDNA forms generated by recombination. This regulation could take place in gametophytic tissues to ensure the transmission of a functional mitochondrial genome.

The plant Spc98p homologue colocalizes with gamma-tubulin at microtubule nucleation sites and is required for microtubule nucleation.

The molecular basis of microtubule nucleation is still not known in higher plant cells. This process is better understood in yeast and animals cells. In the yeast spindle pole body and the centrosome in animal cells, gamma-tubulin small complexes and gamma-tubulin ring complexes, respectively, nucleate all microtubules. In addition to gamma-tubulin, Spc98p or its homologues plays an essential role. We report here the characterization of rice and Arabidopsis homologues of SPC98. Spc98p colocalizes with gamma-tubulin at the nuclear surface where microtubules are nucleated on isolated tobacco nuclei and in living cells. AtSpc98p-GFP also localizes at the cell cortex. Spc98p is not associated with gamma-tubulin along microtubules. These data suggest that multiple microtubule-nucleating sites are active in plant cells. Microtubule nucleation involving Spc98p-containing gamma-tubulin complexes could then be conserved among all eukaryotes, despite differences in structure and spatial distribution of microtubule organizing centers.