Stéphane Bentolila scite author profile

Known in over 150 species, cytoplasmic male sterility is encoded by aberrant mitochondrial genes that prevent pollen development. The RNA-or protein-level expression of most of the mitochondrial genes encoding cytoplasmic male sterility is altered in the presence of one or more nuclear genes called restorers of fertility that suppress the male-sterile phenotype. Cytoplasmic male sterility͞restorer systems have been proven to be an invaluable tool in the production of hybrid seeds. Despite their importance for both the production of major crops such as rice and sunflower and the study of organelle͞nuclear interactions in plants, none of the nuclear fertility-restorer genes that reduce the expression of aberrant mitochondrial proteins have previously been cloned. Here we report the isolation of a gene directly involved in the control of the expression of a cytoplasmic male sterility-encoding gene. The Petunia restorer of fertility gene product is a mitochondrially targeted protein that is almost entirely composed of 14 repeats of the 35-aa pentatricopeptide repeat motif. In a nonrestoring genotype we identified a homologous gene that exhibits a deletion in the promoter region and is expressed in roots but not in floral buds.

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RIP1, a member of an Arabidopsis protein family, interacts with the protein RARE1 and broadly affects RNA editing

Bentolila¹,

Heller²,

Sun³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

214

266

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Transcripts of plant organelle genes are modified by cytidine-touridine (C-to-U) RNA editing, often changing the encoded amino acid predicted from the DNA sequence. Members of the PLS subclass of the pentatricopeptide repeat (PPR) motif-containing family are site-specific recognition factors for either chloroplast or mitochondrial C targets of editing. However, other than PPR proteins and the cis-elements on the organelle transcripts, no other components of the editing machinery in either organelle have previously been identified. The Arabidopsis chloroplast PPR protein Required for AccD RNA Editing 1 (RARE1) specifies editing of a C in the accD transcript. RARE1 was detected in a complex of >200 kDa. We immunoprecipitated epitope-tagged RARE1, and tandem MS/MS analysis identified a protein of unknown function lacking PPR motifs; we named it RNA-editing factor interacting protein 1 (RIP1). Yeast two-hybrid analysis confirmed RIP1 interaction with RARE1, and RIP1-GFP fusions were found in both chloroplasts and mitochondria. Editing assays for all 34 known Arabidopsis chloroplast targets in a rip1 mutant revealed altered efficiency of 14 editing events. In mitochondria, 266 editing events were found to have reduced efficiency, with major loss of editing at 108 C targets. Virusinduced gene silencing of RIP1 confirmed the altered editing efficiency. Transient introduction of a WT RIP1 allele into rip1 improved the defective RNA editing. The presence of RIP1 in a protein complex along with chloroplast editing factor RARE1 indicates that RIP1 is an important component of the RNA editing apparatus that acts on many chloroplast and mitochondrial C targets.nucleoid | RNA editosome | dual targeting P osttranscriptional C-to-U RNA editing occurs in plastid and plant mitochondrial transcripts. In a typical vascular plant, ∼30 C targets in chloroplasts and over 500 C targets in mitochondria are targeted for editing (1, 2). The majority of the editing events results in encoding of a different amino acid than the one predicted from the genomic sequence. The editing-encoded amino acid is usually more conserved relative to residues present in homologous proteins in other organisms than the genomically encoded amino acid. Because there is presently no known case in which useful genetic variation results from partial editing of a transcript population, the current concept is that editing is a correction mechanism for thymidine-to-cytidine (T-to-C) mutations that have arisen in plant organelle genomes (1,3,4).Little is known about the molecular apparatus that is responsible for recognizing the correct C target for editing and converting it to U, although plant mitochondrial RNA editing was discovered over 20 y ago (5-7). cis-Elements for recognition of editing sites have been identified proximal and 5′ to the nucleotide to be modified (8-10). As few as 22 nt in sequence surrounding the C target is sufficient to specify RNA editing (9). In 2005, a pentatricopeptide repeat (PPR) motif-containing protein termed CRR4 was discovered to ...

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Comprehensive High-Resolution Analysis of the Role of an Arabidopsis Gene Family in RNA Editing

et al. 2013

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In flowering plants, mitochondrial and chloroplast mRNAs are edited by C-to-U base modification. In plant organelles, RNA editing appears to be generally a correcting mechanism that restores the proper function of the encoded product. Members of the Arabidopsis RNA editing-Interacting Protein (RIP) family have been recently shown to be essential components of the plant editing machinery. We report the use of a strand- and transcript-specific RNA-seq method (STS-PCRseq) to explore the effect of mutation or silencing of every RIP gene on plant organelle editing. We confirm RIP1 to be a major editing factor that controls the editing extent of 75% of the mitochondrial sites and 20% of the plastid C targets of editing. The quantitative nature of RNA sequencing allows the precise determination of overlapping effects of RIP factors on RNA editing. Over 85% of the sites under the influence of RIP3 and RIP8, two moderately important mitochondrial factors, are also controlled by RIP1. Previously uncharacterized RIP family members were found to have only a slight effect on RNA editing. The preferential location of editing sites controlled by RIP7 on some transcripts suggests an RNA metabolism function for this factor other than editing. In addition to a complete characterization of the RIP factors for their effect on RNA editing, our study highlights the potential of RNA-seq for studying plant organelle editing. Unlike previous attempts to use RNA-seq to analyze RNA editing extent, our methodology focuses on sequencing of organelle cDNAs corresponding to known transcripts. As a result, the depth of coverage of each editing site reaches unprecedented values, assuring a reliable measurement of editing extent and the detection of numerous new sites. This strategy can be applied to the study of RNA editing in any organism.

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An RNA recognition motif-containing protein is required for plastid RNA editing in Arabidopsis and maize

Sun

Germain

Giloteaux

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

136

185

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Plant RNA editing modifies cytidines (C) to uridines (U) at specific sites in the transcripts of both mitochondria and plastids. Specific targeting of particular Cs is achieved by pentatricopeptide proteins that recognize cis elements upstream of the C that is edited. Members of the RNA-editing factor interacting protein (RIP) family in Arabidopsis have recently been shown to be essential components of the plant editosome. We have identified a gene that contains a pair of truncated RIP domains (RIP-RIP). Unlike any previously described RIP family member, the encoded protein carries an RNA recognition motif (RRM) at its C terminus and has therefore been named Organelle RRM protein 1 (ORRM1). ORRM1 is an essential plastid editing factor; in Arabidopsis and maize mutants, RNA editing is impaired at particular sites, with an almost complete loss of editing for 12 sites in Arabidopsis and 9 sites in maize. Transfection of Arabidopsis orrm1 mutant protoplasts with constructs encoding a region encompassing the RIP-RIP domain or a region spanning the RRM domain of ORRM1 demonstrated that the RRM domain is sufficient for the editing function of ORRM1 in vitro. According to a yeast two-hybrid assay, ORRM1 interacts selectively with pentatricopeptide transfactors via its RIP-RIP domain. Phylogenetic analysis reveals that the RRM in ORRM1 clusters with a clade of RRM proteins that are targeted to organelles. Taken together, these results suggest that other members of the ORRM family may likewise function in RNA editing.

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