Transgenic male-sterile plant induced by an unedited atp9 gene is restored to fertility by inhibiting its expression with antisense RNA.

Zabaleta, Eduardo; Mouras, A.; Hernould, Michel; Suharsono, Suharsono; Araya, Alejandro

doi:10.1073/pnas.93.20.11259

Cited by 53 publications

(32 citation statements)

References 29 publications

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“…These results thus suggest that the cis-elements have evolved between the two plant species, and it thus can be assumed that also the respective trans-elements have changed and presently differ between the pea and the cauliflower. Nevertheless, the basic mode of editing site specification has of necessity been conserved in evolution between these two flowering plants, since both definitely require this C-to-U alteration for a functional mitochondrial ATPase (Hernould et al 1993;Zabaleta et al 1996).…”

Section: Discussionmentioning

confidence: 99%

An in vitro RNA editing system from cauliflower mitochondria: Editing site recognition parameters can vary in different plant species

Neuwirt¹,

Takenaka²,

Merwe³

et al. 2005

RNA

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Most of the 400 RNA editing sites in flowering plant mitochondria are found in mRNAs. Consequently, the sequence vicinities of homologous sites are highly conserved between different species and are presumably recognized by likewise conserved transfactors. To investigate the evolutionary adaptation to sequence variation, we have now analyzed the recognition elements of an editing site with divergent upstream sequences in the two species pea and cauliflower. This variation is tolerated at the site selected, because the upstream cis-elements reach into the 5 0 -UTR of the mRNA. To compare cis-recognition features in pea and cauliflower mitochondria, we developed a new in vitro RNA editing system for cauliflower. In vitro editing assays with deleted and mutated template RNAs show that the major recognition elements for both species are located within the conserved sequence. In cauliflower, however, the essential upstream nucleotides extend further upstream than they do in pea. In-depth analysis of single-nucleotide mutations reveals critical spacing of the editing site and the specific recognition elements, and shows that the +1 nucleotide identity is important in cauliflower, but not in pea.

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Section: Discussionmentioning

confidence: 99%

An in vitro RNA editing system from cauliflower mitochondria: Editing site recognition parameters can vary in different plant species

Neuwirt¹,

Takenaka²,

Merwe³

et al. 2005

RNA

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“…As detailed above male sterility was obtained by engineering plants able to synthesize an unedited mitochondrial protein in the cytosolic ribosomes which was further addressed to the mitochondria. Our approach to restore fertility was based on the antisense strategy (Zabaleta et al, 1996). The working hypthesis was that crossing the male-sterile plants produced as described above with plants expressing the same mRNA but in the antisense orientation should lead to the formation of a dsRNA.…”

Section: Recovering the Fertility Of Artificially Created Malesterilementioning

confidence: 99%

“…Our approach to restore fertility was based on the antisense strategy (Zabaleta et al, 1996). The working hypthesis was that crossing the male-sterile plants produced as described above with plants expressing the same mRNA but in the antisense orientation should lead to the formation of a dsRNA.…”

mentioning

confidence: 99%

RNA editing in plant mitochondria, cytoplasmic male sterility and plant breeding

Araya¹

1998

Electron. J. Biotechnol.

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RNA editing in plant mitochondria is a post-transcriptional process involving the partial change of C residues into U. These C to U changes lead to the synthesis of proteins with an amino acid sequence different to that predicted from the gene. Proteins produced from edited mRNAs are more similar to those from organisms where this process is absent. This biochemical process involves cytidine deamination. The cytoplasmic male sterility (CMS) phenotype generated by the incompatibility between the nuclear and the mitochondrial genomes is an important agronomical trait which prevents inbreeding and favors hybrid production. The hypothesis that RNA editing leads to functional proteins has been proposed. This hypothesis was tested by constructing transgenic plants expressing a mitochondrial protein translated fom unedited mRNA. The transgenic "unedited" protein was addressed to the mitochondria leading to the appearance of mitochondrial dysfunction and generating the male sterile phenotype in transgenic tobacco plants. Male sterile plants were also obtained by expressing specifically a bacterial ribonuclease in the anthers. The economical benefits of artificially engineered male-sterile plants or carrying the (native) spontaneous CMS phenotype, implies the restoration to obtain fertile hybrids that will be used in agriculture. Restoration to fertility of transgenic plants was obtained either by crossing male-sterile plants carrying the "unedited" mRNA with plants carrying the same RNA, but in the antisense orientation or, in the case of plants expresing the ribonuclease, by crossing male-sterile plants with plants expressing an inhibitor specific of this enzyme. RNA editingGeneralities. The first time the word "RNA editing" was used, a dozen years ago, concerned the insertion or deletion of uridine residues in the mitochondrial RNAs of some trypanosomes. After that, RNA editing has been found in mitochondria and chloroplasts from land plants, in the mitochondria of some fungi, in the nuclear-cytoplasmic compartments from animal cells and in the genomes of some viruses. The RNA editing process involves in some cases the modification of residues in RNA or, in other cases, the insertion and/or deletion of nucleotides in messenger RNA (for some reviews see Adler and Hadjuk, 1994;Araya et al., 1994;Schuster and Brennicke, 1994;Scott, 1995;Smith et al., 1997;Stuart et al., 1997). The consequences of the RNA editing process are either the modification of the coded information for some amino acids or the generation of new initiation and/or termination codons. In organisms where RNA editing is active the protein sequence predicted from the gene may be different from that of the mRNA translated protein. While RNA editing is abondantly found in mitochondria and to a lesser extent in the chloroplast compartment of higher plants, it is not present in algae. RNA editing has also been descriibed in mitochondria from other organisms such as Physarum polycephalum, but not in yeast organelles. When detected in mammalian nuclear transcr...

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“…Pollen abortion was induced after transforming an incompletely edited atp9 gene in tobacco; however, normal fertility remained the same after transforming a completely edited atp9 gene in tobacco (Hernould et al, 1993). Further study showed that the fertility of tobacco could be restored by inhibiting expression of the incompletely edited atp9 gene (Zabaleta et al, 1996). In addition, CMS was obtained by transforming unedited atp9 gene into tobacco (Araya et al, 1998).…”

Section: Protein Trans-membrane Structure Predictionmentioning

confidence: 82%

A comparative study of ATPase subunit 9 (Atp9) gene between cytoplasmic male sterile line and its maintainer line in soybeans

Jiang¹,

Yang²,

Yu³

et al. 2011

Afr. J. Biotechnol.

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ATPase subunit 9 gene (Atp9) is an important functional gene in mitochondria, and is closely related with energy supply. RNA editing of atp9 gene was associated with male sterility in plants. In this study, the atp9 gene in soybeans was cloned from a soybean cytoplasmic male sterile line NJCMS2A and its maintainer line NJCMS2B. Sequence alignment was performed, and protein structures were analyzed and compared between the soybean cytoplasmic male sterile line NJCMS2A and its maintainer line NJCMS2B. The results show that the fragments with identical sequences of atp9 gene were amplified from the genomic DNA of NJCMS2A and NJCMS2B, while the sequences of atp9 were different when they were amplified from cDNAs of NJCMS2A and NJCMS2B. RNA editing of atp9 gene in the maintainer line NJCMS2B was detected with two nucleotide sites (C to U) in the conserved region, leading to conversion of hydrophilic amino acid serine into hydrophobic leucine. No RNA editing was detected in atp9 gene in the male sterile line NJCMS2A. The putative trans-membrane structures of the atp9 proteins were different, and their trans-membrane directions were opposite.

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Transgenic male-sterile plant induced by an unedited atp9 gene is restored to fertility by inhibiting its expression with antisense RNA.

Cited by 53 publications

References 29 publications

An in vitro RNA editing system from cauliflower mitochondria: Editing site recognition parameters can vary in different plant species

An in vitro RNA editing system from cauliflower mitochondria: Editing site recognition parameters can vary in different plant species

RNA editing in plant mitochondria, cytoplasmic male sterility and plant breeding

A comparative study of ATPase subunit 9 (Atp9) gene between cytoplasmic male sterile line and its maintainer line in soybeans

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