Mitochondrially-targeted expression of a cytoplasmic male sterility-associated <Emphasis Type="Italic">orf220</Emphasis> gene causes male sterility in <Emphasis Type="Italic">Brassica juncea</Emphasis>

Background  

The novel chimeric open reading frame (orf) resulting from the rearrangement of a mitochondrial genome is generally thought to be a causal factor in the occurrence of cytoplasmic male sterility (CMS). Both positive and negative correlations have been found between CMS-associated orfs and the occurrence of CMS when CMS-associated orfs were expressed and targeted at mitochondria. Some orfs cause male sterility or semi-sterility, while some do not. Little is currently known about how mitochondrial factor regulates the expression of the nuclear genes involved in male sterility. The purpose of this study was to investigate the biological function of a candidate CMS-associated orf220 gene, newly isolated from cytoplasmic male-sterile stem mustard, and show how mitochondrial retrograde regulated nuclear gene expression is related to male sterility.     

Analysis of genetic diversity in cytoplasmic male sterility,and association of mitochondrial genes with petaloid-type cytoplasmic male sterility in tuber mustard (<Emphasis Type="Italic">Brassica juncea</Emphasis> var. <Emphasis Type="Italic">tumida</Emphasis> Tsen et Lee)

In our previous study, we bred a stable cytoplasmic male sterility (CMS) line of tuber mustard by using distant hybridization and subsequent backcrosses. In this CMS plants, all floral organs are normal except the anthers, which are transformed into petals or tubular structures. Recently, 2 mitochondrial genes—atpA and orf220—that are distinctively present in the CMS line of tuber mustard were cloned and partially characterized. In our study of genetic diversity analysis of CMS, 7 species of Brassica and Raphanus crops, which included 5 CMS lines and their respective maintainer lines, were used to compare the constitution of protein-coding genes in the mitochondrial genomes. In 4 of the 43 mitochondrial genes, namely, atpA, orf220, orf256, and orf305/orf324, polymorphisms were detected among the tuber mustard CMS line and its maintainer line. The results of a cluster analysis indicate that petaloid CMS phenotype of tuber mustard is a novel CMS type and is nearer to the nap CMS in Brassica napus at the phylogenetic level. The results of individual amplifications of these genes indicate the presence of 4 sequence-characterized amplified region (SCAR) markers, which enable rapid and reliable identification of this CMS. Expressions of the orf220 and orf256 genes were detected only in the CMS line, while expression of the orf305 gene was detected in the maintainer line. The different expression patterns of different mitochondrial-specific marker genes indicate that the quantity of mitochondrial proteins is differentially regulated during organ/tissue development in tuber mustard. The results of this study suggest that the above mentioned 4 mitochondrial genes are associated with the petaloid CMS phenotype in tuber mustard.     

Molecular basis of cytoplasmic male sterility and fertility restoration in rice

Cytoplasmic male sterility (CMS) is a maternally inherited trait that causes dysfunctions in pollen and anther development. CMS is caused by the interaction between nuclear and mitochondrial genomes. A product of a CMS-causing gene encoded by the mitochondrial genome affects mitochondrial function and the regulation of nuclear genes, leading to male sterility. In contrast, the RESTORER OF FERTILITY gene (Rf gene) in the nuclear genome suppresses the expression of the CMS-causing gene and restores male fertility. An alloplasmic CMS line is often bred as a result of nuclear substitution, which causes the removal of functional Rf genes and allows the expression of a CMS-causing gene in mitochondria. The CMS/Rf system is an excellent model for understanding the genetic interactions and cooperative functions of mitochondrial and nuclear genomes in plants, and is also an agronomically important trait for hybrid seed production. In this review article, pollen and anther phenotypes of CMS, CMS-associated mitochondrial genes, Rf genes, and the mechanism that causes pollen abortion and its agronomical application for rice are described.     

Reduced expression of BjRCE1 gene modulated by nuclear-cytoplasmic incompatibility alters auxin response in cytoplasmic male-sterile Brassica juncea

The signal from organelle to nucleus, namely retrograde regulation of nuclear gene expression, was largely unknown. Due to the nuclear-cytoplasmic incompatibility in cytoplasmic male-sterile (CMS) plants, we employed CMS Brassica juncea to investigate the retrograde regulation of nuclear gene expression in this study. We studied how reduced BjRCE1 gene expression caused by the nuclear-cytoplasmic incompatibility altered the auxin response in CMS of B. juncea. We isolated the BjRCE1 gene that was located in the nucleus from B. juncea. Over-expression of BjRCE1 enhanced auxin response in transgenic Arabidopsis. The expression of BjRCE1 was significantly reduced in CMS compared with its maintainer fertile (MF) line of B. juncea. There were fewer lateral roots in CMS than MF under normal and treatment of indole-3-acetic acid (IAA) conditions. Expression patterns of several auxin-related genes together with their phenotypes indicated a reduced auxin response in CMS compared to MF. The phenotypes of auxin response and auxin-related gene expression pattern could be mimicked by inhibiting mitochondrial function in MF. Taken together, we proposed reduced expression of BjRCE1 gene modulated by nuclear-cytoplasmic incompatibility alters auxin response in CMS B. juncea. This may be an important mechanism of retrograde regulation of nuclear gene expression in plants.     

Genetic characterization of a pentatricopeptide repeat protein gene,orf687, that restores fertility in the cytoplasmic male-sterile Kosena radish

Cytoplasmic male sterility (CMS) in plants is a maternally inherited inability to produce functional pollen, and is often associated with mitochondrial DNA abnormalities. Specific nuclear loci that suppress CMS, termed as restorers of fertility (Rf), have been identified. Previously, we identified an Rf for the CMS Kosena radish and used genetic analysis to identify the locus and create a contig covering the critical interval. To identify the Rf gene, we introduced each of the lambda and cosmid clones into the CMS Brassica napus and scored for fertility restoration. Fertility restoration was observed when one of the lambda clones was introduced into the CMS B. napus. Furthermore, introduction of a 4.7-kb BamHI/HpaI fragment of the lambda clone is enough to restore male fertility. A cDNA strand isolated from a positive fragment contained a predicted protein (ORF687) of 687 amino acids comprising 16 repeats of the 35-amino acid pentatricopeptide repeat (PPR) motif. Kosena CMS radish plants were found to express an allele of this gene possessing four substituted amino acids in the second and third repeats of the PPR suggesting that the domains formed by these repeats in ORF687 are essential for fertility restoration. Protein levels of the Kosena CMS-associated mitochondrial protein ORF125 were considerably reduced in plants in which fertility was restored, although mRNA expression was normal. Regarding the possible role for PPR-containing proteins in the regulation of the mitochondrial gene, we propose that ORF687 functions either directly or indirectly to lower the levels of ORF125, resulting in the restoration of fertility in CMS plants.     

Cytoplasmic male sterility: a window to the world of plant mitochondrial-nuclear interactions

Mitochondrial function depends on the coordinate action of nuclear and mitochondrial genomes. The genetic dissection of these interactions presents special challenges in obligate aerobes, because the viability of these organisms depends on mitochondrial respiration. The plant trait cytoplasmic male sterility (CMS) is determined by the mitochondrial genome and is associated with a pollen sterility phenotype that can be suppressed or counteracted by nuclear genes known as restorer-of-fertility genes. Here, I review the nature and the origin of the genes that determine CMS, together with recent investigations that have exploited CMS to provide new insights into plant mitochondrial-nuclear communication. These studies have implicated mitochondrial signaling pathways, including those involved in regulating cell death and nuclear gene expression, in the elaboration of CMS. The molecular cloning of nuclear genes that restore fertility (i.e. restorer-of-fertility genes) has identified genes encoding pentatricopeptide-repeat proteins as key regulators of plant mitochondrial gene expression.     

Alterations of RNA Editing for the Mitochondrial ATP9 Gene in a New orf220-type Cytoplasmic Male-sterile Line of Stem Mustard （Brassica juncea var. tumida）

RNA editing for the mitochondrlal ATP9 gene of encoding regions has been observed in both cytoplasmic malesterile and maintainer lines of stem mustard, where its editing capacity varied spatially and temporally in the cytoplasmic male sterility （CMS） line. There were four RNA editing sites for the mitochondrial ATP9 gene according to Its normal editing sites in mustard, of which three sites occurred as C-to-U changes and one as a U-to-C change. As a result, the hydrophobicity of deduced ATP9 protein was reduced due to the conversions at its 17th, 45th and 64th positions. Meanwhile, the conservation of deduced ATP9 protein was enhanced by changes at the 56th position. Loss of a specific editing site for ATP9 was observed in juvenile roots, senile roots, senile leaves and floret buds of the CMS line. Comparatively, complete RNA editing for ATP9 gene was retained in juvenile roots, juvenile leaves and floret buds of its maintainer line; however, the loss of a specific editing site for ATP9 gene occurred at senile roots and senile leaves in its maintainer line. These observations allow us to produce a hypothesis that the dysfunction of a specific mitochondrial gene arising from RNA editing could probably be a factor triggering CMS and organ senescence through unknown cross-talk pathways during development.     

Cytoplasmic male sterility and restoration of pollen fertility in higher plants

The review deals with cytoplasmic male sterility (CMS) in higher plants: impairment of the pollen formation resulting from interaction of the nuclear and mitochondrial genomes. The information on the known nuclear restorer-of-fertility genes and their effects on the expression of CMS-associated mitochondrial loci are considered. Heteroplasmy of mtDNA in plants and its potential association with CMS inheritance, as well as possible mechanisms of the observed direct and reverse association between altered expression of the CMS-inducing mitochondrial genome, metabolic defects, and pollen sterility are discussed.     

Cytoplasmic male sterility and restoration of pollen fertility in higher plants

The review deals with cytoplasmic male sterility (CMS) in higher plants: impairment of the pollen formation resulting from interaction of the nuclear and mitochondrial genomes. The information on the known nuclear restorer-of-fertility genes and their effects on the expression of CMS-associated mitochondrial loci are considered. Heteroplasmy of mtDNA in plants and its potential association with CMS inheritance, as well as possible mechanisms of the observed direct and reverse association between altered expression of the CMS-inducing mitochondrial genome, metabolic defects, and pollen sterility are discussed.     

Genome barriers between nuclei and mitochondria exemplified by cytoplasmic male sterility

Since plants retain genomes of an extremely large size in mitochondria (200-2,400 kb), and mitochondrial protein complexes are comprised of chimeric structures of nuclear- and mitochondrial-encoded subunits, coordination of gene expression between the nuclei and mitochondria is indispensable for sound plant development. It has been well documented that the nucleus regulates organelle gene expression. This regulation is called anterograde regulation. On the other hand, recent studies have demonstrated that signals emitted from organelles regulate nuclear gene expression. This process is known as retrograde signaling. Incompatibility caused by genome barriers between a nucleus and foreign mitochondria destines the fate of pollen to be dead in cytoplasmic male sterility (CMS), and studies of CMS confirm that pollen fertility is associated with anterograde/retrograde signaling. This review summarizes the current perspectives in CMS and fertility restoration, mainly from the viewpoint of anterograde/retrograde signaling.     

Identification of cytoplasms using the polymerase chain reaction to aid in the extraction of maintainer lines from open-pollinated populations of onion

S-cytoplasm is the most common source of cytoplasmic-genic male sterility (CMS) used to produce hybrid-onion seed. Identification of the cytoplasm of a single plant takes from 4 to 8 years and is complicated by the segregation of a nuclear gene that restores fertility. Although CMS in onion may be due to an incompatibility between the mitochondrial and nuclear genomes, Southern analyses of DNA from individual plants from crosses of S- and N-cytoplasmic plants supported maternal inheritance of the chloroplast and mitochondrial DNA and, therefore, polymorphisms in the chloroplast DNA may be used to classify cytoplasms. Amplification by the polymerase chain reaction of a fragment that carries an autapomorphic 100-bp insertion in the chloroplast DNA of N-cytoplasm offers a significantly quicker and cheaper alternative to crossing or Southern analysis. Molecular characterization of N- and S-cytoplasms and frequencies of the nuclear non-restoring allele allow onion breeders to determine the proportion of plants in open-pollinated populations that maintain CMS and can significantly reduce the investment required to identify individual maintainer plants.     

A light and electron microscopy analysis of the events leading to male sterility in Ogu-INRA CMS of rapeseed (Brassica napus)

Ogura cytoplasmic male sterility (CMS) occurs naturally in radishand has been introduced into rapeseed (Brassica napus) by protoplastfusion. As with all CMS systems, it involves a constitutivelyexpressed mitochondrial gene which induces male sterility tootherwise hermaphroditic plants (so they become females) anda nuclear gene named restorer of fertility that restores pollenproduction in plants carrying a sterility-inducing cytoplasm.A correlative approach using light and electron microscopy wasapplied to define what stages throughout development were affectedand the subcellular events leading to the abortion of the developingpollen grains upon the expression of the mitochondrial protein.Three central stages of development (tetrad, mid-microsporeand vacuolate microspore) were compared between fertile, restored,and sterile plants. At each stage observed, the pollen in fertileand restored plants had similar cellular structures and organization.The deleterious effect of the sterility protein expression startedas early as the tetrad stage. No typical mitochondria were identifiedin the tapetum at any developmental stage and in the vacuolatemicrospores of the sterile plants. In addition, some strikingultrastructural alterations of the cell's organization werealso observed compared with the normal pattern of development.The results showed that Ogu-INRA CMS was due to premature celldeath events of the tapetal cells, presumably by an autolysisprocess rather than a normal PCD, which impairs pollen developmentat the vacuolate microspore stage, in the absence of functionalmitochondria. Key words: Brassica napus, cell death, light and electron microscopy, mitochondria, plastids, pollen development, Ogu-INRA cytoplasmic male sterility, transgenic-restored plants, tapetum Received 30 September 2007; Revised 11 December 2007 Accepted 20 December 2007     

An alloplasmic male-sterile line of Brassica oleracea harboring the mitochondria from Diplotaxis muralis expresses a novel chimeric open reading frame, orf72

Nuclear so-called fertility-restorer genes reverse the pollen sterility of cytoplasmic male-sterile (CMS) plants caused by disturbed mitochondrial-nuclear interactions. We identified a CMS-associated chimeric mitochondrial gene in an alloplasmic CMS line of Brassica oleracea in the 'mur' system. This novel chimeric gene, orf72, was found in the mitochondrial genome of donor cytoplasm. It was located downstream of normal rps7 and contained part of atp9 (atp9-b). It was expressed specifically on the nuclear background of CMS B. oleracea, partially suppressed in the fertility-restored line and entirely suppressed in the cytoplasmic donor.     

Reduced expression of CTR1 gene modulated by mitochondria causes enhanced ethylene response in cytoplasmic male-sterile Brassica juncea

We studied how mitochondria affect ethylene response via modulation of CTR1 expression in cytoplasmic male-sterile (CMS) Brassica juncea. The expression of CTR1 gene was reduced in CMS compared with male-fertile (MF) lines. We observed that hypocotyl and root lengths were shorter than in the MF line during germination in the dark. An enhanced ethylene response was observed in CMS plants as shown by the CMS and maintainer line phenotypes treated with 1-aminocyclopropane-1-carboxylic acid. The phenotype in CMS plants could be recovered to the maintainer line when treated with Ag(+) . One ethylene response gene, plant defensin gene, was detected to be induced in CMS. The behavior of this phenotype could be mimicked by treating the maintainer line with antimycin A that disturbs mitochondrial function, which showed reduced length of hypocotyl and roots, and resulted in similar expression patterns of ethylene-related genes as in CMS. The reduced length of hypocotyl and roots could be recovered to the maintainer line by treatment with gibberellic acid (GA(3) ). In addition, the GA(3) content was reduced in CMS plants and in the MF line treated with antimycin A. Ethylene treatment markedly affects GA(3) content; however, GA(3) did not significantly affect ethylene-related gene expression in regards to regulation of hypocotyl and root length, which suggests that ethylene acts upstream via gibberellin to regulate hypocotyls and root development. Taken together, our results suggest a link between mitochondrial modulation of the ethylene and gibberellin pathway that regulates the development of hypocotyl and roots.