The process of RNA editing in plant mitochondria

RNA editing changes more than 400 cytidines to uridines in the mRNAs of mitochondria in flowering plants. In other plants such as ferns and mosses, RNA editing reactions changing C to U and U to C are observed at almost equal frequencies. Development of transfection systems with isolated mitochondria and of in vitro systems with extracts from mitochondria has considerably improved our understanding of the recognition of specific editing sites in the last few years. These assays have also yielded information about the biochemical parameters, but the enzymes involved have not yet been identified. Here we summarize our present understanding of the process of RNA editing in flowering plant mitochondria.     

高等植物叶绿体RNA编辑研究进展

RNA编辑普遍存在于陆生植物中,在高等植物叶绿体中以C→U的替换为主,可能是叶绿体产生功能蛋白的重要方式。近年来,使用体外分析、叶绿体转化和紫外交联等技术,使叶绿体RNA编辑机制的研究取得较大进展。本文对这些新的进展进行了概述,并对高等植物叶绿体RNA编辑研究中有待解决的问题进行了展望。     

MEF10 is required for RNA editing at nad2-842 in mitochondria of Arabidopsis thaliana and interacts with MORF8

A forwards genetic screen of a chemically mutated plant population identified mitochondrial RNA editing factor 10 (MEF10) in Arabidopsis thaliana. MEF10 is a trans-factor required specifically for the C to U editing of site nad2-842. The MEF10 protein is characterized by a stretch of pentatricopeptide repeats (PPR) and a C-terminal extension domain ending with the amino acids DYW. Editing is lost in mutant plants but is recovered by transgenic introduction of an intact MEF10 gene. The MEF10 protein interacts with multiple organellar RNA editing factor 8 (MORF8) but not with other mitochondrial MORF proteins in yeast two hybrid assays. These results support the model that specific combinations of MORF and MEF proteins are involved in RNA editing in plant mitochondria.     

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.     

Trans splicing integrates an exon of 22 nucleotides into the nad5 mRNA in higher plant mitochondria.

The genes coding for NADH dehydrogenase subunit 5 (nad5) in mitochondria of the higher plants Oenothera and Arabidopsis are split into five exons that are located in three distant genomic regions. These encode exons a + b, c and d + e, respectively. Maturation of the mRNAs requires two trans splicing events to integrate exon c of only 22 nucleotides. Both trans splicing reactions involve mitochondrial group II intron sequences that allow base pairings in the interrupted domain IV, demonstrating the flexibility of intron structures. The observation of fragmented intron sequences in plant mitochondria suggests that trans splicing is more widespread than previously assumed. RNA editing by C to U alterations in both Oenothera and Arabidopsis open reading frames improves the evolutionary conservation of the encoded polypeptides. Three C to U RNA editing events were observed in intron sequences.     

棉花叶绿体基因RNA编辑位点的测定及分析

陆生植物叶绿体RNA编辑是转录后基因表达调控的一种重要方式。该文在预测棉花（Gossypium hirsutum）叶绿体基因RNA编辑位点的基础上,选取中棉10（CRRI 10）为实验材料,采用PCR、RT-PCR及测序等方法,确定CRRI 10的27个叶绿体蛋白编码基因共有55个编辑位点,均是C→U的转换。与棉种柯字310（C310）的编辑位点比对后发现,CRRI 10多出accD-468和rpoC1-163两个编辑位点,同时缺失psbN-10。利用生物信息学分析这3个位点,rpoC1-163和psbN-10的编辑可能会改变各自蛋白的二级结构。对CRRI 10中55个编辑位点上游的顺式作用元件（？30–？1）分析显示,共有8组顺式作用元件的相似性达到60%或以上,推测各组中的编辑位点可能由相同的反式作用因子来识别。     

The DYW-class PPR protein MEF7 is required for RNA editing at four sites in mitochondria of Arabidopsis thaliana

In plant mitochondria and plastids, RNA editing alters about 400 and about 35 C nucleotides into Us, respectively. Four of these RNA editing events in plant mitochondria specifically require the PPR protein MEF7, characterized by E?and DYW extension domains. The gene for MEF7 was identified by genomic mapping of the locus mutated in plants from EMS treated seeds. The SNaPshot screen of the mutant plant population identified two independent EMS mutants with the same editing defects as a corresponding T-DNA insertion line of the MEF7 gene. Although the amino acid codons introduced by the editing events are conserved throughout flowering plants, even the combined failure of four editing events does not impair the growth efficiency of the mutant plants. Five nucleotides are conserved between the four affected editing sites, but are not sufficient for specific recognition by MEF7 since they are also present at three other sites which are unaffected in the mutants.     

Molecular and Functional Diversity of RNA Editing in Plant Mitochondria

RNA editing is a fundamental biochemical process relating to the modification of nucleotides in messenger RNAs of functional genes in cells. RNA editing leads to re-establishment of conserved amino acid residues for functional proteins in nuclei, chloroplasts, and mitochondria. Identification of RNA editing factors that contributes to target site recognition increases our understanding of RNA editing mechanisms. Significant progress has been made in recent years in RNA editing studies for both animal and plant cells. RNA editing in nuclei and mitochondria of animal cells and in chloroplast of plant cells has been extensively documented and reviewed. RNA editing has been also extensively documented on plant mitochondria. However, functional diversity of RNA editing factors in plant mitochondria is not overviewed. Here, we review the biological significance of RNA editing, recent progress on the molecular mechanisms of RNA editing process, and function diversity of editing factors in plant mitochondrial research. We will focus on: (1) pentatricopeptide repeat proteins in Arabidopsis and in crop plants; (2) the progress of RNA editing process in plant mitochondria; (3) RNA editing-related RNA splicing; (4) RNA editing associated flower development; (5) RNA editing modulated male sterile; (6) RNA editing-regulated cell signaling; and (7) RNA editing involving abiotic stress. Advances described in this review will be valuable in expanding our understanding in RNA editing. The diverse functions of RNA editing in plant mitochondria will shed light on the investigation of molecular mechanisms that underlies plant development and abiotic stress tolerance.     

The evolution of chloroplast RNA editing

RNA editing alters the nucleotide sequence of an RNA molecule so that it deviates from the sequence of its DNA template. Different RNA-editing systems are found in the major eukaryotic lineages, and these systems are thought to have evolved independently. In this study, we provide a detailed analysis of data on C-to-U editing sites in land plant chloroplasts and propose a model for the evolution of RNA editing in land plants. First, our data suggest that the limited RNA-editing system of seed plants and the much more extensive systems found in hornworts and ferns are of monophyletic origin. Further, although some eukaryotic editing systems appear to have evolved to regulate gene expression, or at least are now involved in gene regulation, there is no evidence that RNA editing plays a role in gene regulation in land plant chloroplasts. Instead, our results suggest that land plant chloroplast C-to-U RNA editing originated as a mechanism to generate variation at the RNA level, which could complement variation at the DNA level. Under this model, many of the original sites, particularly in seed plants, have been subsequently lost due to mutation at the DNA level, and the function of extant sites is merely to conserve certain codons. This is the first comprehensive model for the evolution of the chloroplast RNA-editing system of land plants and may also be applicable to the evolution of RNA editing in plant mitochondria.     

In vitro RNA editing in pea mitochondria requires NTP or dNTP,suggesting involvement of an RNA helicase

To analyze the biochemical parameters of RNA editing in plant mitochondria and to eventually characterize the enzymes involved we developed a novel in vitro system. The high sensitivity of the mismatch-specific thymine glycosylase is exploited to facilitate reliable quantitative evaluation of the in vitro RNA editing products. A pea mitochondrial lysate correctly processes a C to U editing site in the cognate atp9 template. Reaction conditions were determined for a number of parameters, which allow first conclusions on the proteins involved. The apparent tolerance against specific Zn2+ chelators argues against the involvement of a cytidine deaminase enzyme, the theoretically most straightforward catalysator of the deamination reaction. Participation of a transaminase was investigated by testing potential amino group receptors, but none of these increased the RNA editing reaction. Most notable is the requirement of the RNA editing activity for NTPs. Any NTP or dNTP can substitute for ATP to the optimal concentration of 15 mm. This observation suggests the participation of an RNA helicase in the predicted RNA editing protein complex of plant mitochondria.     

RNA editing sites in plant mitochondria can share cis-elements

RNA editing in flowering plant mitochondria alters numerous C nucleotides in a given mRNA molecule to U residues. To investigate whether neighbouring editing sites can influence each other we analyzed in vitro RNA editing of two sites spaced 30 nt apart. Deletion and competition experiments show that these two sites carry independent essential specificity determinants in the respective upstream 20-30 nucleotides. However, deletion of a an upstream sequence region promoting editing of the upstream site concomitantly decreases RNA editing of the second site 50-70 nucleotides downstream. This result suggests that supporting cis-/trans-interactions can be effective over larger distances and can affect more than one editing event.     

RNA Editing of Cytochrome Oxidase Subunit III in Sunflower Mitochondria

Direct sequencing of cytochrome oxidase subunit III (coxIII) mRNA with a specific primer confirms RNA editing in sunflower (Helianthus annus) mitochondria. Six instances of mRNA editing could be verified, one of these specific to this species. All the editing events involve C to U transitions in the coxIII mRNA causing codon changes that lead to amino acids better conserved in evolution than those encoded in the genomic DNA. This observation confirms RNA editing to be widespread in higher plant mitochondria.