A comparative genomics approach identifies a PPR-DYW protein that is essential for C-to-U editing of the <i>Arabidopsis</i> chloroplast <i>accD</i> transcript

Robbins, John C.; Heller, Wade P.; Hanson, Maureen R.

doi:10.1261/rna.1533909

Cited by 110 publications

(126 citation statements)

References 63 publications

(82 reference statements)

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“…Unlike the majority of the previously characterized editing mutants (Okuda et al, 2006(Okuda et al, , 2007(Okuda et al, , 2009Chateigner-Boutin et al, 2008;Kim et al, 2009;Yu et al, 2009;Zhou et al, 2009), which were identified via visible growth or fluorescence phenotypes, these mutants were identified directly via a screen for unedited RNAs. It is striking that of the eight mutants discovered in this way, including RARE1 (Robbins et al, 2009) and MEF1 (Zehrmann et al, 2009), none have growth or The curve shows a typical trace of chlorophyll fluorescence in the wild type and a mutant totally impaired in NDH activity (crr21) (Okuda et al, 2007) compared with traces from otp85 and two independent otp84 mutants (otp84-1 and otp84-2). Leaves were exposed to actinic light (AL) (50 mmol of photons m À2 s À1 ) for 5 min.…”

Section: Discussionmentioning

confidence: 96%

“…Investigation of Arabidopsis mutants with such phenotypes has identified a number of nuclear genes suspected to encode RNAediting specificity factors (Kotera et al, 2005;Okuda et al, 2007Okuda et al, , 2009Chateigner-Boutin et al, 2008;Cai et al, 2009;Kim et al, 2009;Robbins et al, 2009;Yu et al, 2009;Zehrmann et al, 2009;Zhou et al, 2009). In each case, loss of one of these factors leads to a specific loss of editing of one or at most a few sites.…”

Section: Introductionmentioning

confidence: 99%

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A Study of New Arabidopsis Chloroplast RNA Editing Mutants Reveals General Features of Editing Factors and Their Target Sites

et al. 2009

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RNA editing in higher plant organelles results in the conversion of specific cytidine residues to uridine residues in RNA. The recognition of a specific target C site by the editing machinery involves trans-acting factors that bind to the RNA upstream of the C to be edited. In the last few years, analysis of mutants affected in chloroplast biogenesis has identified several pentatricopeptide repeat (PPR) proteins from the PLS subfamily that are essential for the editing of particular RNA transcripts. We selected other genes from the same subfamily and used a reverse genetics approach to identify six new chloroplast editing factors in Arabidopsis thaliana (OTP80, OTP81, OTP82, OTP84, OTP85, and OTP86). These six factors account for nine editing sites not previously assigned to an editing factor and, together with the nine PPR editing proteins previously described, explain more than half of the 34 editing events in Arabidopsis chloroplasts. OTP80, OTP81, OTP85, and OTP86 target only one editing site each, OTP82 two sites, and OTP84 three sites in different transcripts. An analysis of the target sites requiring the five editing factors involved in editing of multiple sites (CRR22, CRR28, CLB19, OTP82, and OTP84) suggests that editing factors can generally distinguish pyrimidines from purines and, at some positions, must be able to recognize specific bases.

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Section: Discussionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

A Study of New Arabidopsis Chloroplast RNA Editing Mutants Reveals General Features of Editing Factors and Their Target Sites

et al. 2009

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“…RNA extraction and RT-PCR methods were as previously described (4) and chloroplast isolation as described in Hayes and Hanson (55). Primers to amplify the mitochondrial and plastid transcripts have been previously described (4,29,56). Analysis of RNA editing by PPE was done as in ref.…”

Section: Methodsmentioning

confidence: 99%

“…Analysis of RNA editing by PPE was done as in ref. 29. The editing extent in maize plastid genes was measured primarily by bulk-sequencing of RT-PCR products amplified with primers listed in Table S4.…”

Section: Methodsmentioning

confidence: 99%

“…The editing extent of these sites is severely reduced to more than 90% in the orrm1 mutant (Table S1). In the Y2H analysis we also included RARE1 and OTP84, which are required for the editing of accD-794, ndhF-290, ndhB-1481, and psbZ-50, respectively (29,30). The editing extent of accD-794, ndhF-290, ndhB-1481, and psbZ-50 in the orrm1 mutant is identical to the wild-type plant (Table S1).…”

Section: Orrm1 Interacts With An Editing Recognition Trans-factor Thrmentioning

confidence: 99%

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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.

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133

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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RNA editing in plant mitochondria: 20 years later

Gray

2009

IUBMB Life

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SummaryIn 1989, three laboratories (in Canada, France and Germany) independently and simultaneously reported the discovery of C-to-U RNA editing in plant mitochondria (1-3). To mark the 20th anniversary of this finding, the leaders of the three research teams have written personal essays describing the events leading up to the discovery in each of their laboratories. These essays are intended not only to capture historical facts but also to illustrate unexpected convergence in the process of scientific discovery, with different groups coming to the same conclusion, often very close together in time, drawing on different types of evidence and via sometimes quite different hypotheses and approaches. Essential background information pertaining to RNA editing in general and RNA editing in plant organelles in particular is provided in this overview.

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A comparative genomics approach identifies a PPR-DYW protein that is essential for C-to-U editing of the Arabidopsis chloroplast accD transcript

Cited by 110 publications

References 63 publications

A Study of New Arabidopsis Chloroplast RNA Editing Mutants Reveals General Features of Editing Factors and Their Target Sites

A Study of New Arabidopsis Chloroplast RNA Editing Mutants Reveals General Features of Editing Factors and Their Target Sites

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

RNA editing in plant mitochondria: 20 years later

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