Identification of two novel inactive DFR-A alleles responsible for failure to produce anthocyanin and development of a simple PCR-based molecular marker for bulb color selection in onion (Allium cepa L.).

Two novel inactive alleles of Dihydroflavonol 4-reductase-A (DFR-A) were identified in yellow onion (Allium cepa L.) cultivars and breeding lines from Korea and Japan. Unlike the previously reported inactive yellow DFR-A allele, designated as DFR-A ( TRN ) , in which the 3' portion of the coding sequences was deleted, an allele containing a premature stop codon, DFR-A ( PS ) , was isolated from the majority of cultivars. Co-segregation of DFR-A ( PS ) and color phenotypes in the F(2) population from a cross between yellow and red parents showed that inactivation of DFR-A was responsible for lack of anthocyanin in these yellow onions. In addition, RT-PCR analysis of F(2) population showed that the transcription level of the DFR-A ( PS ) allele was significantly reduced owing to non-sense-mediated mRNA decay. A 20-bp deletion of a simple sequence repeat in the promoter region of the DFR-A ( PS ) allele was used to develop a simple PCR-based molecular marker for selection of the DFR-A ( PS ) allele. All genotypes of 138 F(2) individuals were clearly distinguished by this molecular marker. In addition to the DFR-A ( PS ) allele, another DFR-A allele, DFR-A ( DEL ) , was identified in some cultivars. In case of the DFR-A ( DEL ) allele, no PCR products were amplified throughout DFR-A sequences including promoter regions, suggesting deletion of the entire DFR-A gene. Co-segregation of the absence of DFR-A and color phenotypes was confirmed in another F(2) population. Furthermore, RT-PCR results showed that no DFR-A transcript was detected in any yellow F(2) individuals.

Identification of a novel chimeric gene, orf725, and its use in development of a molecular marker for distinguishing among three cytoplasm types in onion (Allium cepa L.).

A novel chimeric gene with a 5' end containing the nearly complete sequence of the coxI gene and a 3' end showing homology with chive orfA501 was isolated by genome walking from two cytoplasm types: CMS-S and CMS-T, both of which induce male-sterility in onion (Allium cepa L.). In addition, the normal active and variant inactive coxI genes were also isolated from onions containing the normal and CMS-S cytoplasms, respectively. The chimeric gene, designated as orf725, was nearly undetectable in normal cytoplasm, and the copy number of the normal coxI gene was significantly reduced in CMS-S cytoplasm. RT-PCR results showed that orf725 was not transcribed in normal cytoplasm. Meanwhile, the normal coxI gene, which is essential for normal mitochondrial function, was not expressed in CMS-S cytoplasm. However, both orf725 and coxI were transcribed in CMS-T cytoplasm. The expression of orf725, a putative male-sterility-inducing gene, was not affected by the presence of nuclear restorer-of-fertility gene(s) in male-fertility segregating populations originating from the cross between a male-sterile plant containing either CMS-T or CMS-S and a male-fertile plant whose genotypes of nuclear restorer gene(s) might be heterozygous. The specific stoichiometry of orf725 and coxI in the mtDNA of the three cytoplasm types was consistent among diverse germplasm. Therefore, a molecular marker based on the relative copy numbers of orf725 and coxI was designed for distinguishing among the three cytoplasm types by one simple PCR. The reliability and applicability of the molecular marker was shown by testing diverse onion germplasm.