Sequencing, processing, and localization of the petunia CMS‐associated mitochondrial protein

Nivison, Helen T.; Sutton, C. A.; Wilson, Robin K.; Hanson, Maureen R.

doi:10.1111/j.1365-313x.1994.00613.x

Cited by 54 publications

(45 citation statements)

References 13 publications

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“…Though many mitochondrial DNA-encoded proteins contain membrane-spanning domains, which could conceivably be deleterious when expressed in chloroplasts, coxII exon 2 does not specify such a hydrophobic polypeptide. Most importantly, coxII exon 2 sequences had already been observed to be edited in a disturbed context in a naturally occurring chimeric gene (21). Even when flanked on the 5Ј side by a partial atp9-derived sequence and incomplete coxII exon 1 sequences and on the 3Ј end by an unidentified reading frame, and even though the large group II intron is missing, coxII exon 2 sequences are edited when located in the abnormal petunia pcf gene (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Though several mitochondrial sequences in both petunia and maize plants have been shown to be edited in abnormal contexts in naturally occurring chimeric mitochondrial genes (16,21), comparable edited recombined genes have not been detected in chloroplasts. It is possible that editing of chloroplast transcripts is more tightly regulated and has speciesspecific components.…”

Section: Discussionmentioning

confidence: 99%

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A Plant Mitochondrial Sequence Transcribed in Transgenic Tobacco Chloroplasts Is Not Edited

Sutton

Zoubenko

Hanson

et al. 1995

Molecular and Cellular Biology

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RNA editing occurs in two higher-plant organelles, chloroplasts and mitochondria. Because chloroplasts and mitochondria exhibit some similarity in editing site selection, we investigated whether mitochondrial RNA sequences could be edited in chloroplasts. We produced transgenic tobacco plants that contained chimeric genes in which the second exon of a Petunia hybrida mitochondrial coxII gene was under the control of chloroplast gene regulatory sequences. coxII transcripts accumulated to low or high levels in transgenic chloroplasts containing chimeric genes with the plastid ribosomal protein gene rps16 or the rRNA operon promoter, respectively. Exon 2 of coxII was chosen because it carries seven editing sites and is edited in petunia mitochondria even when located in an abnormal context in an aberrant recombined gene. When editing of the coxII transcripts in transgenic chloroplasts was examined, no RNA editing at any of the usual sites was detected, nor was there any novel editing at any other sites. These results indicate that the RNA editing mechanisms of chloroplasts and mitochondria are not identical but must have at least some organelle-specific components.The mRNAs of both plant mitochondria and chloroplasts have been shown to be subject to RNA editing (8,11,13,14). T's are found in cDNAs of both chloroplasts and mitochondria where C's are located in genomic DNA. Conversion of cytidine to uridine has been demonstrated to occur in plant mitochondria (23). Most mitochondrial mRNAs have been shown to contain one or more RNA editing sites (12,24). In contrast, many fewer editing events have been found in chloroplast mRNAs (15). Nevertheless, some sequence similarities exist between chloroplast and mitochondrial RNA editing sites. Editing occurs in transcripts of the chloroplast ndhA and ndhB and mitochondrial nad1 and nad2 genes at sites which are homologous at the protein level (17,18). Both editing systems exhibit a biased codon transition frequency in which serine and proline codons are more likely to be targets of editing than other C-containing codons. C's in the third position of the codon or C's that follow G residues are the least likely to be edited (7). Editing can occur before transcript splicing in both organelles. However, unspliced transcripts in both mitochondria and chloroplasts are less likely to be edited in all potential editing sites than spliced transcripts (10, 27, 31), suggesting that editing in both organelles is a posttranscriptional process.We wished to test whether mitochondrial sequences could be targets for the editing machinery of chloroplasts. To that end, we cloned the coding portion of the second exon of petunia coxII-2 into two different tobacco plastid expression cassettes and introduced the chimeric genes into the tobacco plastid genome. The coxII-2 second exon contains seven sites that are edited in petunia mitochondria. Although coxII transcripts from both chimeric genes were detected in chloroplasts of transgenic tobacco plants, we observed no RNA editing. Evidently, the ...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

A Plant Mitochondrial Sequence Transcribed in Transgenic Tobacco Chloroplasts Is Not Edited

Sutton

Zoubenko

Hanson

et al. 1995

Molecular and Cellular Biology

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“…The mitochondrial protein degradation system is also associated with the anther-specific accumulation of the CMS-associated ORF239 polypeptide in the common bean [98]. The petunia CMS-associated PCF protein is trimmed into a smaller polypeptide from a precursor [75]. Therefore, it seems likely that most unique polypeptides are degraded.…”

Section: Why Do Most Of the Unique Orfs Not Matter In Angiosperm Mitomentioning

confidence: 99%

“…An example is the maize urf13-T gene, which contains two duplicated segments of rrn26, forming an ORF that encodes 115 amino acid residues [74]. A second example is the petunia pcf gene, which contains a duplicated segment of atp9, two duplicated segments of cox2, and a sequence of unknown origin, forming an ORF that encodes 402 amino acid residues [75]. There is no sequence homology between any of the known CMS-associated ORFs except in two cases: orf224, associated with Brassica pol CMS, and orf222, associated with Brassica nap CMS, exhibit 79% homology at the amino acid level [36]; and rice orf79 and sorghum orf107 show some similarity.…”

Section: Why Do Most Of the Unique Orfs Not Matter In Angiosperm Mitomentioning

confidence: 99%

Cost of Having the Largest Mitochondrial Genome: Evolutionary Mechanism of Plant Mitochondrial Genome

Kitazaki

Kubo

2010

Journal of Botany

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The angiosperm mitochondrial genome is the largest and least gene-dense among the eukaryotes, because its intergenic regions are expanded. There seems to be no functional constraint on the size of the intergenic regions; angiosperms maintain the large mitochondrial genome size by a currently unknown mechanism. After a brief description of the angiosperm mitochondrial genome, this review focuses on our current knowledge of the mechanisms that control the maintenance and alteration of the genome. In both processes, the control of homologous recombination is crucial in terms of site and frequency. The copy numbers of various types of mitochondrial DNA molecules may also be controlled, especially during transmission of the mitochondrial genome from one generation to the next. An important characteristic of angiosperm mitochondria is that they contain polypeptides that are translated from open reading frames created as byproducts of genome alteration and that are generally nonfunctional. Such polypeptides have potential to evolve into functional ones responsible for mitochondrially encoded traits such as cytoplasmic male sterility or may be remnants of the former functional polypeptides.

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“…One class of transcripts, those that terminate at -121 before the pcf gene, are reduced in restored lines (Young and Hanson, 1987), and the abundance of the protein products of the pcf gene is greatly reduced . pcf encodes a 45-kD protein that is processed to a 19.5-kD protein that exhibits a mobility of 25 kD on acrylamide gels Nivison et al, 1994). The larger precursor protein appears to be efficiently processed and is present in much lower quantities than is the 19.5-kD protein.…”

Section: Complex Mitochondrial Loci Associated With Cms the Multiply mentioning

confidence: 99%

Interactions of Mitochondrial and Nuclear Genes That Affect Male Gametophyte Development

Hanson

Bentolila

2004

THE PLANT CELL ONLINE

754

623

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Sequencing, processing, and localization of the petunia CMS‐associated mitochondrial protein

Cited by 54 publications

References 13 publications

A Plant Mitochondrial Sequence Transcribed in Transgenic Tobacco Chloroplasts Is Not Edited

A Plant Mitochondrial Sequence Transcribed in Transgenic Tobacco Chloroplasts Is Not Edited

Cost of Having the Largest Mitochondrial Genome: Evolutionary Mechanism of Plant Mitochondrial Genome

Interactions of Mitochondrial and Nuclear Genes That Affect Male Gametophyte Development

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