Stable native RIP9 complexes associate with C‐to‐U RNA editing activity,PPRs, RIPs,OZ1, ORRM1 and ISE2

The mitochondrial and chloroplast mRNAs of the majority of land plants are modified through cytidine to uridine (C‐to‐U) RNA editing. Previously, forward and reverse genetic screens demonstrated a requirement for pentatricopeptide repeat (PPR) proteins for RNA editing. Moreover, chloroplast editing factors OZ1, RIP2, RIP9 and ORRM1 were identified in co‐immunoprecipitation (co‐IP) experiments, albeit the minimal complex sufficient for editing activity was never deduced. The current study focuses on isolated, intact complexes that are capable of editing distinct sites. Peak editing activity for four sites was discovered in size‐exclusion chromatography (SEC) fractions ≥ 670 kDa, while fractions estimated to be approximately 413 kDa exhibited the greatest ability to convert a substrate containing the editing site rps14 C80. RNA content peaked in the ≥ 670 kDa fraction. Treatment of active chloroplast extracts with RNase A abolished the relationship of editing activity with high‐MW fractions, suggesting a structural RNA component in native complexes. By immunoblotting, RIP9, OTP86, OZ1 and ORRM1 were shown to be present in active gel filtration fractions, though OZ1 and ORRM1 were mainly found in low‐MW inactive fractions. Active editing factor complexes were affinity‐purified using anti‐RIP9 antibodies, and orthologs to putative Arabidopsis thaliana RNA editing factor PPR proteins, RIP2, RIP9, RIP1, OZ1, ORRM1 and ISE2 were identified via mass spectrometry. Western blots from co‐IP studies revealed the mutual association of OTP86 and OZ1 with native RIP9 complexes. Thus, RIP9 complexes were discovered to be highly associated with C‐to‐U RNA editing activity and other editing factors indicative of their critical role in vascular plant editosomes.     

The RanBP2 zinc finger domains of chloroplast RNA editing factor OZ1 are required for protein–protein interactions and conversion of C to U

In the chloroplast, organelle zinc finger 1 (OZ1) is a RanBP2-type zinc finger (Znf) protein required for many RNA editing events, a process by which specific cytosines are enzymatically converted to uracils as a correction mechanism for missense mutations in the organelle genomes. RNA editing is carried out by a large multi-protein complex called the ‘editosome’ that contains members of the pentatricopeptide repeat (PPR) protein family, the RNA editing factor interacting protein (also known as MORF) family and the organelle RNA-recognition motif (ORRM) family, in addition to OZ1. OZ1 is an 82-kDa protein with distinct domains, including a pair of Znf domains and a unique C-terminal region. To elucidate the functions of these domains, we have generated truncations of OZ1 for use in protein–protein interaction assays that identified the C-terminal region of OZ1, as well as the Znf domains as the primary interactors with PPR proteins, which are factors required for site-specificity and enzymatic editing. Expression of these OZ1 truncations in vivo showed that the Znf domains were required to restore chloroplast RNA editing in oz1 knockout plants. Mutation of key structural residues in the Znf domains showed that they are necessary for editing and required for interaction with ORRM1, a general editing factor with an RNA-binding domain. These functional characterizations of the Znfs and novel C-terminal domain contribute to our understanding of the model for the chloroplast plant editosome.     

Pentatricopeptide repeat proteins constrain genome evolution in chloroplasts

Higher plants encode hundreds of pentatricopeptide repeat proteins (PPRs) that are involved in several types of RNA processing reactions. Most PPR genes are predicted to be targeted to chloroplasts or mitochondria, and many are known to affect organellar gene expression. In some cases, RNA binding has been directly demonstrated, and the sequences of the cis-elements are known. In this work, we demonstrate that RNA cis-elements recognized by PPRs are constrained in chloroplast genome evolution. Cis-elements for two PPR genes and several RNA editing sites were analyzed for sequence changes by pairwise nucleotide substitution frequency, pairwise indel frequency, and maximum likelihood (ML) phylogenetic distances. All three of these analyses demonstrated that sequences within the cis-element are highly conserved compared with surrounding sequences. In addition, we have compared sequences around chloroplast editing sites and homologous sequences in species that lack an editing site due to the presence of a genomic T. Cis-elements for RNA editing sites are highly conserved in angiosperms; by contrast, comparable sequences around a genomically encoded T exhibit higher rates of nucleotide substitution, higher frequencies of indels, and greater ML distances. The loss in requirement for editing to create the ndhD start codon has resulted in the conversion of the PPR gene responsible for editing that site to a pseudogene. We show that organellar dependence on nuclear-encoded PPR proteins for gene expression has constrained the evolution of cis-elements that are required at the level of RNA processing. Thus, the expansion of the PPR gene family in plants has had a dramatic effect on the evolution of plant organelle genomes.     

PPR蛋白影响植物生长发育的研究进展

植物生长发育是一个极其复杂的生理生化过程,受内外因素共同作用。PPR蛋白是核基因编码的具有重复PPR基序的蛋白,分布广泛,在高等植物中数量巨大。PPR蛋白的靶标一般是线粒体和叶绿体中转录的RNA前体,多数可与MORF互作,参与线粒体和叶绿体基因的RNA编辑。PPR蛋白缺失的突变体植株多数呈现异常表型,影响植物的正常生长发育。本文就近年来发现的PPR蛋白结构、分布,与RNA编辑的关系,及其对植物生长发育的影响进行了综述。     

Cytidine Deaminase Motifs within the DYW Domain of Two Pentatricopeptide Repeat-containing Proteins Are Required for Site-specific Chloroplast RNA Editing

In angiosperm organelles, cytidines are converted to uridines by a deamination reaction in the process termed RNA editing. The C targets of editing are recognized by members of the pentatricopeptide repeat (PPR) protein family. Although other members of the editosome have begun to be identified, the enzyme that catalyzes the C-U conversion is still unknown. The DYW motif at the C terminus of many PPR editing factors contains residues conserved with known cytidine deaminase active sites; however, some PPR editing factors lack a DYW motif. Furthermore, in many PPR-DYW editing factors, the truncation of the DYW motif does not affect editing efficiency, so the role of the DYW motif in RNA editing is unclear. Here, a chloroplast PPR-DYW editing factor, quintuple editing factor 1 (QED1), was shown to affect five different plastid editing sites, the greatest number of chloroplast C targets known to be affected by a single PPR protein. Loss of editing at the five sites resulted in stunted growth and accumulation of apparent photodamage. Adding a C-terminal protein tag to QED1 was found to severely inhibit editing function. QED1 and RARE1, another plastid PPR-DYW editing factor, were discovered to require their DYW motifs for efficient editing. To identify specific residues critical for editing, conserved deaminase residues in each PPR protein were mutagenized. The mutant PPR proteins, when expressed in qed1 or rare1 mutant protoplasts, could not complement the editing defect. Therefore, the DYW motif, and specifically, the deaminase residues, of QED1 and RARE1 are required for editing efficiency.     

Identification of a pentatricopeptide repeat RNA editing factor in Physcomitrella patens chloroplasts

The moss Physcomitrella patens has two RNA editing sites in the chloroplasts. Here we identified a novel DYW-subclass pentatricopeptide repeat (PPR) protein, PpPPR_45, as a chloroplast RNA editing factor in P. patens. Knockdown of the PpPPR_45 gene reduced the extent of RNA editing at the chloroplast rps14-C2 site, whereas over-expression of PpPPR_45 increased the levels of RNA editing at both the rps14-C2 site and its neighboring C site. This indicates that the expression level of PpPPR_45 affects the extent of RNA editing at the two neighboring sites.     

PPR蛋白参与RNA编辑机制的研究进展

RNA编辑是一种发生在转录后核苷酸特异位点的加工修饰现象,包括核苷酸的插入、删除和改变.高等植物中RNA编辑主要发生在线粒体与叶绿体中,具有重要的生物学功能,其机制仍在探索中.而PPR蛋白作为RNA编辑的反式作用因子,成为近几年来分子生物学的研究热点.该文就PPR蛋白、RNA编辑及PPR蛋白参与RNA编辑的机制等进行了综述.     

A Protein-Protein Interaction Map of Trypanosome ��20S Editosomes

Mitochondrial mRNA editing in trypanosomatid parasites involves several multiprotein assemblies, including three very similar complexes that contain the key enzymatic editing activities and sediment at ∼20S on glycerol gradients. These ∼20S editosomes have a common set of 12 proteins, including enzymes for uridylyl (U) removal and addition, 2 RNA ligases, 2 proteins with RNase III-like domains, and 6 proteins with predicted oligonucleotide binding (OB) folds. In addition, each of the 3 distinct ∼20S editosomes contains a different RNase III-type endonuclease, 1 of 3 related proteins and, in one case, an additional exonuclease. Here we present a protein-protein interaction map that was obtained through a combination of yeast two-hybrid analysis and subcomplex reconstitution with recombinant protein. This map interlinks ten of the proteins and in several cases localizes the protein region mediating the interaction, which often includes the predicted OB-fold domain. The results indicate that the OB-fold proteins form an extensive protein-protein interaction network that connects the two trimeric subcomplexes that catalyze U removal or addition and RNA ligation. One of these proteins, KREPA6, interacts with the OB-fold zinc finger protein in each subcomplex that interconnects their two catalytic proteins. Another OB-fold protein, KREPA3, appears to link to the putative endonuclease subcomplex. These results reveal a physical organization that underlies the coordination of the various catalytic and substrate binding activities within the ∼20S editosomes during the editing process.