Identification of a candidate gene responsible for the G locus determining chartreuse bulb color in onion (Allium cepa L.) using bulked segregant RNA-Seq.

KEY MESSAGE: A gene encoding a laccase responsible for chartreuse onion bulb color was identified. Markers tagging this gene showed perfect linkage with bulb colors among diverse germplasm. To identify a casual gene for the G locus determining chartreuse bulb color in onion (Allium cepa L.), bulked segregant RNA-Seq (BSR-Seq) was performed using yellow and chartreuse individuals of a segregating population. Through single nucleotide polymorphism (SNP) and differentially expressed gene (DEG) screening processes, 163 and 143 transcripts were selected, respectively. One transcript encoding a laccase-like protein was commonly identified from SNP and DEG screening. This transcript contained four highly conserved copper-binding domains known to be signature sequences of laccases. This gene was designated AcLAC12 since it showed high homology with Arabidopsis AtLAC12. A 4-bp deletion creating a premature stop codon was identified in exon 5 of the chartreuse allele. Another mutant allele in which an intact LTR-retrotransposon was transposed in exon 5 was identified from other chartreuse breeding lines. Genotypes of molecular markers tagging AcLAC12 were perfectly matched with bulb color phenotypes in segregating populations and diverse breeding lines. All chartreuse breeding lines contained inactive alleles of DFR-A gene determining red bulb color, indicating that chartreuse color appeared when both DFR-A and AcLAC12 genes were inactivated. Linkage maps showed that AcLAC12 was positioned at the end of chromosome 7. Transcription levels of structural genes encoding enzymes in anthocyanin biosynthesis pathway were generally reduced in chartreuse bulk compared with yellow bulk. Concentrations of total quercetins were also reduced in chartreuse onion. However, significant amounts of quercetins were detected in chartreuse onion, implying that AcLAC12 might be involved in modification of quercetin derivatives in onion.

Transposition of a non-autonomous DNA transposon in the gene coding for a bHLH transcription factor results in a white bulb color of onions (Allium cepa L.).

KEY MESSAGE: A DNA transposon was found in the gene encoding a bHLH transcription factor. Genotypes of the marker tagging this DNA transposon perfectly co-segregated with color phenotypes in large F2:3 populations A combined approach of bulked segregant analysis and RNA-Seq was used to isolate causal gene for C locus controlling white bulb color in onions (Allium cepa L.). A total of 114 contigs containing homozygous single nucleotide polymorphisms (SNPs) between white and yellow bulked RNAs were identified. Four of them showed high homologies with loci clustered in the middle of chromosome 5. SNPs in 34 contigs were confirmed by sequencing of PCR products. One of these contigs showed perfect linkage to the C locus in F2:3 populations consisting of 2491 individuals. However, genotypes of molecular marker tagging this contig were inconsistent with color phenotypes of diverse breeding lines. A total of 146 contigs showed differential expression between yellow and white bulks. Among them, transcription levels of B2 gene encoding a bHLH transcription factor were significantly reduced in white RNA bulk and F2:3 individuals, although there was no SNP in the coding region. Phylogenetic analysis showed that onion B2 was orthologous to bHLH-coding genes regulating anthocyanin biosynthesis pathway in other plant species. Promoter regions of B2 gene were obtained by genome walking and a 577-bp non-autonomous DNA transposon designated as AcWHITE was found in the white allele. Molecular marker tagging AcWHITE showed perfect linkage with the C locus. Marker genotypes of the white allele were detected in some white accessions. However, none of tested red or yellow onions contained AcWHITE insertion, implying that B2 gene was likely to be a casual gene for the C locus.

Identification of a gene responsible for cytoplasmic male-sterility in onions (Allium cepa L.) using comparative analysis of mitochondrial genome sequences of two recently diverged cytoplasms.

KEY MESSAGE: Almost identical mitochondrial genome sequences of two recently diverged male-fertile normal and male-sterile CMS-T-like cytoplasms were obtained in onions. A chimeric gene, orf725 , was found to be a CMS-inducing gene. In onions (Allium cepa L.), cytoplasmic male-sterility (CMS) has been widely used in hybrid seed production. Two types of CMS (CMS-S and CMS-T) have been reported in onions. A complete mitochondrial genome sequence of the CMS-S cytoplasm has been reported in our previous study. Draft mitochondrial genome sequences of male-fertile normal and CMS-T-like cytoplasms are reported in this study. Raw reads obtained from normal and CMS-T-like cytoplasms were assembled into eight and nine almost identical contigs, respectively. After connection and reorganization of contigs by PCR amplification and genome walking, four scaffold sequences with total length of 339 and 180 bp were produced for the normal cytoplasm. A mitochondrial genome sequence of the CMS-T-like cytoplasm was obtained by mapping trimmed reads of CMS-T onto scaffold sequences of the normal cytoplasm. Compared with the CMS-S mitochondrial genome, the normal mitochondrial genome was highly rearranged with 31 syntenic blocks. A total of 499 single nucleotide polymorphisms (SNPs) or insertions/deletions were identified in these syntenic regions. On the other hand, normal and CMS-T-like mitochondrial genome sequences were almost identical except for orf725, a chimeric gene consisting of cox1 with other sequences. Only three SNPs were identified between normal and CMS-T-like syntenic sequences. These results indicate that orf725 is likely to be the casual gene for CMS induction in onions and that CMS-T-like cytoplasm has recently diverged from the normal cytoplasm by introduction of orf725.

Completion of the mitochondrial genome sequence of onion (Allium cepa L.) containing the CMS-S male-sterile cytoplasm and identification of an independent event of the ccmF N gene split.

Cytoplasmic male-sterility (CMS) conferred by the CMS-S cytoplasm has been most commonly used for onion (Allium cepa L.) F1 hybrid seed production. We first report the complete mitochondrial genome sequence containing CMS-S cytoplasm in this study. Initially, seven contigs were de novo assembled from 150-bp paired-end raw reads produced from the total genomic DNA using the Illumina NextSeq500 platform. These contigs were connected into a single circular genome consisting of 316,363 bp (GenBank accession: KU318712) by PCR amplification. Although all 24 core protein-coding genes were present, no ribosomal protein-coding genes, except rps12, were identified in the onion mitochondrial genome. Unusual trans-splicing of the cox2 gene was verified, and the cox1 gene was identified as part of the chimeric orf725 gene, which is a candidate gene responsible for inducing CMS. In addition to orf725, two small chimeric genes were identified, but no transcripts were detected for these two open reading frames. Thirteen chloroplast-derived sequences, with sizes of 126-13,986 bp, were identified in the intergenic regions. Almost 10 % of the onion mitochondrial genome was composed of repeat sequences. The vast majority of repeats were short repeats of <100 base pairs. Interestingly, the gene encoding ccmFN was split into two genes. The ccmF N gene split is first identified outside the Brassicaceae family. The breakpoint in the onion ccmF N gene was different from that of other Brassicaceae species. This split of the ccmF N gene was also present in 30 other Allium species. The complete onion mitochondrial genome sequence reported in this study would be fundamental information for elucidation of onion CMS evolution.

Identification of candidate genes associated with fertility restoration of cytoplasmic male-sterility in onion (Allium cepa L.) using a combination of bulked segregant analysis and RNA-seq.

KEY MESSAGE: A combination of BSA and RNA-seq was performed to identify candidates for the restorer-of-fertility gene in onion. The AcPMS1 involved in DNA mismatch repair was identified as the best candidate. To identify candidate genes of the restorer-of-fertility gene (Ms) responsible for fertility restoration of onion cytoplasmic male-sterility, a combined approach of bulked segregant analysis and RNA-seq was employed. From 32,674 de novo assembled contigs, 430 perfectly homozygous SNPs between male-fertile (MF) and male-sterile (MS) bulks were identified in 141 contigs. After verifying the homozygosity of the SNPs by PCR amplification and sequencing, the SNPs on 139 of the contigs were genotypes for the two recombinants which contained crossover events between the Ms locus and two tightly linked molecular markers. As a result, 30 contigs showing perfect linkage with the Ms locus in the large-sized segregating population were identified. Among them, 14 showed perfect linkage disequilibrium (LD) with the Ms locus, as determined by genotyping 251 domestic breeding lines. Furthermore, molecular markers tagging the 14 contigs also showed almost perfect LD with each other in 124 exotic accessions introduced from 21 countries, except for one accession which contained a crossover event by which the 14 markers were divided into two groups. After sequencing of the full-length cDNA of the 14 contigs showing perfect LD, the deduced amino acids sequences of the MF and MS alleles were compared. Four genes were shown to harbor putative critical amino acid changes in the known domains. Among them, the gene encoding PMS1, involved in the DNA mismatch repair pathway, was assumed to be the best candidate gene responsible for fertility restoration of male-sterility in onion.

Integrative structural annotation of de novo RNA-Seq provides an accurate reference gene set of the enormous genome of the onion (Allium cepa L.).

The onion (Allium cepa L.) is one of the most widely cultivated and consumed vegetable crops in the world. Although a considerable amount of onion transcriptome data has been deposited into public databases, the sequences of the protein-coding genes are not accurate enough to be used, owing to non-coding sequences intermixed with the coding sequences. We generated a high-quality, annotated onion transcriptome from de novo sequence assembly and intensive structural annotation using the integrated structural gene annotation pipeline (ISGAP), which identified 54,165 protein-coding genes among 165,179 assembled transcripts totalling 203.0 Mb by eliminating the intron sequences. ISGAP performed reliable annotation, recognizing accurate gene structures based on reference proteins, and ab initio gene models of the assembled transcripts. Integrative functional annotation and gene-based SNP analysis revealed a whole biological repertoire of genes and transcriptomic variation in the onion. The method developed in this study provides a powerful tool for the construction of reference gene sets for organisms based solely on de novo transcriptome data. Furthermore, the reference genes and their variation described here for the onion represent essential tools for molecular breeding and gene cloning in Allium spp.

Characterization of three active transposable elements recently inserted in three independent DFR-A alleles and one high-copy DNA transposon isolated from the Pink allele of the ANS gene in onion (Allium cepa L.).

Intact retrotransposon and DNA transposons inserted in a single gene were characterized in onions (Allium cepa) and their transcription and copy numbers were estimated in this study. While analyzing diverse onion germplasm, large insertions in the DFR-A gene encoding dihydroflavonol 4-reductase (DFR) involved in the anthocyanin biosynthesis pathway were found in two accessions. A 5,070-bp long terminal repeat (LTR) retrotransposon inserted in the active DFR-A (R4) allele was identified from one of the large insertions and designated AcCOPIA1. An intact ORF encoded typical domains of copia-like LTR retrotransposons. However, AcCOPIA1 contained atypical 'TG' and 'TA' dinucleotides at the ends of the LTRs. A 4,615-bp DNA transposon was identified in the other large insertion. This DNA transposon, designated AcCACTA1, contained an ORF coding for a transposase showing homology with the CACTA superfamily transposable elements (TEs). Another 5,073-bp DNA transposon was identified from the DFR-A (TRN) allele. This DNA transposon, designated AchAT1, belonged to the hAT superfamily with short 4-bp terminal inverted repeats (TIRs). Finally, a 6,258-bp non-autonomous DNA transposon, designated AcPINK, was identified in the ANS-p allele encoding anthocyanidin synthase, the next downstream enzyme to DFR in the anthocyanin biosynthesis pathway. AcPINK also possessed very short 3-bp TIRs. Active transcription of AcCOPIA1, AcCACTA1, and AchAT1 was observed through RNA-Seq analysis and RT-PCR. The copy numbers of AcPINK estimated by mapping the genomic DNA reads produced by NextSeq 500 were predominantly high compared with the other TEs. A series of evidence indicated that these TEs might have transposed in these onion genes very recently, providing a stepping stone for elucidation of enormously large-sized onion genome structure.

Comparison of mitochondrial and chloroplast genome segments from three onion (Allium cepa L.) cytoplasm types and identification of a trans-splicing intron of cox2.

To study genetic relatedness of two male sterility-inducing cytotypes, the phylogenetic relationship among three cytotypes of onions (Allium cepa L.) was assessed by analyzing polymorphisms of the mitochondrial DNA organization and chloroplast sequences. The atp6 gene and a small open reading frame, orf22, did not differ between the normal and CMS-T cytotypes, but two SNPs and one 4-bp insertion were identified in CMS-S cytotype. Partial sequences of the chloroplast ycf2 gene were integrated in the upstream sequence of the cob gene via short repeat sequence-mediated recombination. However, this chloroplast DNA-integrated organization was detected only in CMS-S. Interestingly, disruption of a group II intron of cox2 was identified for the first time in this study. Like other trans-splicing group II introns in mitochondrial genomes, fragmentation of the intron occurred in domain IV. Two variants of each exon1 and exon2 flanking sequences were identified. The predominant types of four variants were identical in both the normal and the CMS-T cytotypes. These predominant types existed as sublimons in CMS-S cytotypes. Altogether, no differences were identified between normal and CMS-T, but significant differences in gene organization and nucleotide sequences were identified in CMS-S, suggesting recent origin of CMS-T male-sterility from the normal cytotype.

Allelic discrimination of the Restorer-of-fertility gene and its inheritance in peppers (Capsicum annuum L.).

Cytoplasmic male sterility (CMS), one of the most important traits in crop breeding, is used for commercial F(1)-hybrid seed production in peppers (Capsicum annuum L.). A nuclear gene, Restorer-of-fertility (Rf), can induce normal pollen production in CMS plants resulting in fertility. Since the first report of fertility restoration in peppers, various inheritance modes have been suggested, including the presence of a third haplotype of the locus. The pepper Rf gene has not been cloned, and calculated genetic distances of linked markers have varied between research groups. A more precise allelic test and additional genetic mapping are needed to accurately select recombinants for use in marker-assisted backcrossing (MAB). Therefore, the reliability and application of these markers for allelic selection of the Rf gene was tested. Two different F(2) populations, Buja and Tamna, were used for the construction of a linkage map. From these linkage groups, anew closely linked flanking marker of the Rf gene were identified. Previous allelic testing revealed the existence of a third haplotype, Rfls(7701), which can function as dominant (Rf) or recessive (rf). In a previous report, Rfls(7701) was considered to be linked to unstable male sterility (MS). However, our results suggest that unstable MS was induced by a gene residing at another locus rather than by Rfls(7701) haplotype- linked allele.

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.

Discovery of a novel cytoplasmic male-sterility and its restorer lines in radish (Raphanus sativus L.).

A male-sterile (MS) radish (Raphanus sativus L.) was found in an accession collected from Uzbekistan. Unlike Ogura MS radishes in which no pollen grain is typically visible during anthesis, a small number of pollen grains stuck together in the dehiscing anthers was observed in the newly identified MS radish. Fluorescein diacetate tests and scanning electron micrographs showed that pollen grains in the new MS radish were severely deformed and non-viable. Cytological examination of pollen development stages showed a clear difference in the defective stage from that seen in Ogura male-sterility. Reciprocal cross-pollination with diverse male-fertile lines indicated that pollen grains of the new MS radish were completely sterile, and the female organs were fully fertile. When the new MS radish and Ogura MS lines were cross-pollinated with a set of eight breeding lines, all F1 progeny originating from crosses with the new MS radish were male-sterile. In contrast, most of the F1 progeny resulting from crosses with Ogura MS lines were male-fertile. These results demonstrated that factors associated with induction of the newly identified male-sterility are different from those of Ogura male-sterility. The lack of restorer lines for the newly identified male-sterility led us to predict that it might be a complete cytoplasmic male-sterility without restorer-of-fertility genes in nuclear genomes. However, cross-pollination with more diverse radish germplasm identified one accession introduced from Russia that could completely restore fertility, proving the existence of restorer-of-fertility gene(s) for the new male-sterility. Meanwhile, the PCR amplification profile of molecular markers for the classification of radish mitochondrial genome types revealed that the new MS radish contained a novel mitotype.

Identification of a third haplotype of the sequence linked to the Restorer-of-fertility (Rf) gene and its implications for male-sterility phenotypes in peppers (Capsicum annuum L.).

Cytoplasmic male sterility (CMS), one of the most important traits in crop breeding, has been used for commercial seed production by F1 hybrid cultivars of pepper (Capsicum annuum L.). To develop reliable molecular markers for allelic selection of the Restorer-of-fertility (Rf) gene, which is known to be a major determinant of pollen fertility restoration in peppers, a sequence of approximately 10 kb flanking an RAPD fragment closely linked to the Rf locus was obtained by genome walking. A homology search revealed that this sequence contained an LTR retrotransposon and a non-LTR LINE-like retrotransposon. Sequencing of this Rf-linked region to search for polymorphisms between a dominant and recessive allele revealed 98% nucleotide sequence identity between them. A third polymorphic haplotype of the Rf-linked sequence, which has 94-96% nucleotide sequence identity with the two previously isolated haplotypes, was identified among a large number of breeding lines. Utilizing polymorphic sequences in the haplotypes, PCR markers were developed for selection of particular haplotypes and used to examine the distribution of the haplotypes in diverse breeding lines, cultivars, and C. annuum germplasms. Surprisingly, the third haplotype was the predominant type in C. annuum germplasms, while its frequency in F1 hybrid cultivars was relatively low. Meanwhile, analysis of breeding lines whose Rf allele genotypes and male-sterility phenotypes were already known revealed that the third haplotype was mainly present in exotic breeding lines that cause unstable male-sterility when combined with sterile cytoplasms.

Effect of low-level laser treatment after installation of dental titanium implant-immunohistochemical study of RANKL, RANK, OPG: an experimental study in rats.

BACKGROUND AND OBJECTIVES: This experiment using an animal experimental model was conducted in order to investigate the effect of low-level laser therapy (LLLT) on the healing of the dental titanium implant. STUDY DESIGN/MATERIALS AND METHODS: The experimental group received LLLT for a week and the control group did not. Each group consisted of 10 rats. Two rats from the groups were euthenized on the days 1, 3, 7, 14, and 21 of the experiment. The expression of receptor activator of nuclear factor kB ligand (RANKL), osteoprotegerin (OPG), and receptor activator of nuclear factor kB (RANK) were investigated. RESULTS: The expression of RANKL was observed from the initial stage of the installation of the implant for both the experimental and control groups. However, the degree of expression was higher in the experimental group. The degree of expression of OPG increased remarkably in the experimental group, while in the control group the degree of expression increased only slightly. In the experimental group, the expression of RANK was observed from the first day, but in the control group, it was weakly observed after day 3. The overall expression within the bone was slight on day 7 in the control group, while an active expression was observed in the experimental group. Bone density after installation of dental titanium implant during osseointegration in the experimental group was higher than the control group. The surface and structure of the titanium implant was not damaged by low-level laser (LLL). CONCLUSIONS: From the above results, the expression of OPG, RANKL, and RANK during the osseointegration of the dental titanium implant was observed within bone tissue. The application of the LLL influenced the expression of OPG, RANKL, and RANK, and resulted in the expansion of metabolic bone activity and increased the activity of bone tissue cells.

Marker-assisted genotype analysis of bulb colors in segregating populations of onions (Allium cepa).

Bulb color in onions (Allium cepa) is an important trait whose complex inheritance mechanism involves epistatic interactions among major color-related loci. Recent studies revealed that inactivation of dihydroflavonol 4-reductase (DFR) in the anthocyanin synthesis pathway was responsible for the color differences between yellow and red onions, and two recessive alleles of the anthocyanidin synthase (ANS) gene were responsible for a pink bulb color. Based on mutations in the recessive alleles of these two genes, PCR-based markers for allelic selection were developed. In this study, genotype analysis of onions from segregating populations was carried out using these PCR-based markers. Segregating populations were derived from the cross between yellow and red onions. Five yellow and thirteen pink bulbs from one segregating breeding line were genotyped for the two genes. Four pink bulbs were heterozygous for the DFR gene, which explains the continuous segregation of yellow and pink colors in this line. Most pink onions were homozygous recessive for the ANS gene, except for two heterozygotes. This finding indicated that the homozygous recessive ANS gene was primarily responsible for the pink color in this line. The two pink onions, heterozygous for the ANS gene, were also heterozygous for the DFR gene, which indicated that the pink color was produced by incomplete dominance of a red color gene over that of yellow. One pink line and six other segregating breeding lines were also analyzed. The genotyping results matched perfectly with phenotypic color segregation.

Genetic manipulation for enhancing calcium content in potato tuber.

Increased calcium (Ca) in potatoes may increase the production rate by enhancing tuber quality and storability. Additionally, increased Ca levels in important agricultural crops may help ameliorate the incidence of osteoporosis. However, the capacity to alter Ca levels in potato tubers through genetic manipulations has not been previously addressed. Here we demonstrate that potato tubers expressing the Arabidopsis H+/Ca2+ transporter sCAX1 (N-terminal autoinhibitory domain truncated version of CAtion eXchanger 1) contain up to 3-fold more Ca than wild-type tubers. The increased Ca appears to be distributed throughout the tuber. The sCAX1-expressing potatoes have normally undergone the tuber/plant/tuber cycle for three generations; the trait appeared stable through successive generations. The expression of sCAX1 does not appear to alter potato growth and development. Furthermore, increased Ca levels in sCAX1-expressing tubers do not appear to alter tuber morphology or yield. Given the preponderance of potato consumption worldwide, these transgenic plants may be a means of marginally increasing Ca intake levels in the population. To our knowledge, this study represents the first attempts to use biotechnology to increase the Ca content of potatoes.

The L locus, one of complementary genes required for anthocyanin production in onions (Allium cepa), encodes anthocyanidin synthase.

Bulb color in onions (Allium cepa) is an important trait, but its complex, unclear mechanism of inheritance has been a limiting factor in onion cultivar improvement. The identity of the L locus, which is involved in the color difference between Brazilian yellow and red onions, is revealed in this study. A cross was made between a US-type yellow breeding line and a Brazilian yellow cultivar. The segregation ratio of nine red to seven yellow onions in the F(2) population supports the involvement of two complementary genes in anthocyanin production in the F(1) hybrids. The high-performance liquid chromatography (HPLC) and reverse-transcriptase (RT)-PCR analysis of the Brazilian yellow onions indicated that the genes are involved late in the anthocyanin synthesis pathway. The genomic sequence of the anthocyanidin synthase (ANS) gene in Brazilian yellow onions showed a point mutation, which results in an amino acid change of a glycine to an arginine at residue 229. Because this residue is located adjacent to a highly conserved iron-binding active site, this mutation is likely responsible for the inactivation of the ANS gene in Brazilian yellow onions. Following the isolation of the promoter sequence of the mutant allele, a PCR-based marker for allelic selection of the ANS gene was designed. This assay is based on an insertion (larger than 3 kb) mutation. The marker perfectly co-segregated with the color phenotypes in the F(2) populations, thereby indicating that the L locus encodes ANS.

Development of a co-dominant, PCR-based marker for allelic selection of the pink trait in onions (Allium cepa), based on the insertion mutation in the promoter of the anthocyanidin synthase gene.

Bulb color in onions (Allium cepa) is an important trait and is inherited in a complex manner. However, the mechanism of color inheritance is poorly understood at the molecular level. A previous study showed that pink bulb color in onions is inherited as a single recessive trait. This trait is attributable to a significantly reduced transcription of the anthocyanidin synthase (ANS) gene. In this study, we developed a PCR-based marker for an allelic selection of the ANS gene to avoid the laborious progeny tests traditionally employed. To identify polymorphisms between pink and red alleles of the ANS gene, promoter sequences of both alleles were isolated. There was 97% nucleotide sequence identity between the promoter sequences of the two alleles. A 390-bp insertion was identified 632 bp upstream from the putative transcription start site in the pink allele. A pair of primers was designed on the flanking sequences of the inserted region and utilized as a PCR-based marker for allelic selection of the ANS gene. The reliability of the marker was tested using parents, F1 hybrids, and F3 lines whose genotypes had been identified by progeny tests. The marker was also used to evaluate the distribution of the pink allele in white and yellow breeding lines. The results indicated that a majority of the breeding lines tested were homozygous recessive.

Development of a PCR-based marker utilizing a deletion mutation in the dihydroflavonol 4-reductase (DFR) gene responsible for the lack of anthocyanin production in yellow onions (Allium cepa).

Bulb color in onions (Allium cepa) is an important trait, but the mechanism of color inheritance is poorly understood at the molecular level. A previous study showed that inactivation of the dihydroflavonol 4-reductase (DFR) gene at the transcriptional level resulted in a lack of anthocyanin production in yellow onions. The objectives of the present study were the identification of the critical mutations in the DFR gene (DFR-A) and the development of a PCR-based marker for allelic selection. We report the isolation of two additional DFR homologs (DFR-B and DFR-C). No unique sequences were identified in either DFR homolog, even in the untranslated region (UTR). Both genes shared more than 95% nucleotide sequence identity with the DFR-A gene. To obtain a unique sequence from each gene, we isolated the promoter regions. Sequences of the DFR-A and DFR-B promoters differed completely from one another, except for an approximately 100-bp sequence adjacent to the 5'UTR. It was possible to specifically amplify only the DFR-A gene using primers designed to anneal to the unique promoter region. The sequences of yellow and red DFR-A alleles were the same except for a single base-pair change in the promoter and an approximately 800-bp deletion within the 3' region of the yellow DFR-A allele. This deletion was used to develop a co-dominant PCR-based marker that segregated perfectly with color phenotypes in the F2 population. These results indicate that a deletion mutation in the yellow DFR-A gene results in the lack of anthocyanin production in yellow onions.

Development of a codominant PCR-based marker for allelic selection of the pink trait in onions (Allium cepa), based on the insertion mutation in the promoter of the anthocyanidin synthase gene.

Bulb color in onions (Allium cepa) is an important trait and is inherited in a complex manner. However, the mechanism of color inheritance is poorly understood at the molecular level. A previous study showed that pink bulb color in onions is inherited as a single recessive trait. This trait is attributable to a significantly reduced transcription of the anthocyanidin synthase (ANS) gene. In this study, we developed a PCR-based marker for an allelic selection of the ANS gene to avoid the laborious progeny tests traditionally employed. To identify polymorphisms between pink and red alleles of the ANS gene, promoter sequences of both alleles were isolated. There was 97% nucleotide sequence identity between the promoter sequences of the two alleles. A 390-bp insertion was identified 632 bp upstream from the putative transcription start site in the pink allele. A pair of primers was designed on the flanking sequences of the inserted region and utilized as a PCR-based marker for allelic selection of the ANS gene. The reliability of the marker was tested using parents, F1 hybrids, and F3 lines whose genotypes had been identified by progeny tests. The marker was also used to evaluate the distribution of the pink allele in white and yellow breeding lines. The results indicated that a majority of the breeding lines tested were homozygous recessive.