Whole mitochondrial genome sequencing and transcriptional analysis to uncover an RT102-type cytoplasmic male sterility-associated candidate Gene Derived from Oryza rufipogon.

Cytoplasmic male sterility (CMS) is a maternally inherited trait in which plants fail to produce functional pollen and is associated with the expression of a novel open reading frame (orf) gene encoded by the mitochondrial genome. An RT102A CMS line and an RT102C fertility restorer line were obtained by successive backcrossing between Oryza rufipogon W1125 and O. sativa Taichung 65. Using next-generation pyrosequencing, we determined whole-genome sequences of the mitochondria in RT102-CMS cytoplasm. To identify candidates for the CMS-associated gene in RT102 mitochondria, we screened the mitochondrial genome for the presence of specific orf genes that were chimeric or whose products carried predicted transmembrane domains. One of these orf genes, orf352, which showed different transcript sizes depending on whether the restorer of fertility (Rf) gene was present or not, was identified. The orf352 gene was co-transcribed with the ribosomal protein gene rpl5, and the 2.8 kb rpl5-orf352 transcripts were processed into 2.6 kb transcripts with a cleavage at the inside of the orf352 coding region in the presence of the Rf gene. The orf352 gene is an excellent candidate for the CMS-associated gene for RT102-CMS.

Whole genomic sequencing of RT98 mitochondria derived from Oryza rufipogon and northern blot analysis to uncover a cytoplasmic male sterility-associated gene.

Cytoplasmic male sterility (CMS) is a maternally inherited trait resulting in the failure to produce functional pollen and is often observed when an alien cytoplasm is transferred into a cultivated species. An RT98A CMS line and an RT98C fertility restorer line were obtained by successive backcrossing between Oryza rufipogon W1109 and Oryza sativa cultivar Taichung 65. To uncover the CMS-associated mitochondrial genes, we determined the complete sequence of the RT98-CMS mitochondrial genome using next-generation pyrosequencing, and searched new open reading frames (orfs) absent in a reported mitochondrial genome of O. sativa Nipponbare. Then, six candidates were selected for the CMS-associated genes based on the criteria in which they were chimeric in structure or encoded a peptide with transmembrane domains. One of the candidates, orf113, showed different transcript sizes between RT98A and RT98C on Northern blot analysis. The orf113 gene was shown to be co-transcribed with atp4 and cox3 encoding ATP synthase F0 subunit 4 and Cyt c oxidase subunit 3, respectively, and their transcripts were distinctly processed in the presence of a fertility restorer gene. Our results indicate that orf113 is a CMS-associated gene of RT98-CMS.

Genetic analysis of root elongation induced by phosphorus deficiency in rice (Oryza sativa L.): fine QTL mapping and multivariate analysis of related traits.

Root elongation induced by phosphorus deficiency has been reported as one of the adaptive mechanisms in plants. Genetic differences were found in rice for the root elongation under phosphorus deficiency (REP), for which a distinct quantitative trait locus (QTL) was detected on the long arm of chromosome 6. Subsequently, the effect and position of the QTL, designated as qREP-6, were confirmed using chromosome segment substitution lines (CSSLs), in which the background of a japonica cultivar, 'Nipponbare' with non-REP, was partially substituted by chromosomal segments from an indica cultivar, 'Kasalath' with remarkable REP. Out of 54 CSSLs, two lines (CSSL28 and CSSL29) that retain a common 'Kasalath'-derived segment on the long arm of chromosome 6 showed a significantly high REP. The high REP lines also showed high adaptabilities such as enhanced tillering ability and shoot phosphorus content. Accordingly, conditional dependencies between the related traits were assessed using a graphical Gaussian model (GGM). Direct interactions between REP and root length, and between root length and tiller number were detected under P deficiency in CSSLs. Furthermore, qREP-6 for REP and qTNP-6 for tiller number under P deficiency were fine-mapped with an F(2) population of a cross between Nipponbare and CSSL29. A region containing qREP-6 accounted for more than half of the phenotypic variance, the most plausible interval of which contained 37 candidate genes. The result provides a foundation for cloning of the qREP-6 gene which will be applicable to study P deficiency-dependent response and to improve rice's adaptability to P deficiency stress.