Kazuhiko Tarora

Digital Transcriptome Analysis of Putative Sex-Determination Genes in Papaya (Carica papaya)

Papaya (Carica papaya) is a trioecious plant species that has male, female and hermaphrodite flowers on different plants. The primitive sex chromosomes genetically determine the sex of the papaya. Although draft sequences of the papaya genome are already available, the genes for sex determination have not been identified, likely due to the complicated structure of its sex-chromosome sequences. To identify the candidate genes for sex determination, we conducted a transcriptome analysis of flower samples from male, female and hermaphrodite plants using high-throughput SuperSAGE for digital gene expression analysis. Among the short sequence tags obtained from the transcripts, 312 unique tags were specifically mapped to the primitive sex chromosome (X or Yh) sequences. An annotation analysis revealed that retroelements are the most abundant sequences observed in the genes corresponding to these tags. The majority of tags on the sex chromosomes were located on the X chromosome, and only 30 tags were commonly mapped to both the X and Yh chromosome, implying a loss of many genes on the Yh chromosome. Nevertheless, candidate Yh chromosome-specific female determination genes, including a MADS-box gene, were identified. Information on these sex chromosome-specific expressed genes will help elucidating sex determination in the papaya.

Mapping of the Gynoecy in Bitter Gourd (Momordica charantia) Using RAD-Seq Analysis

Momordica charantia is a monoecious plant of the Cucurbitaceae family that has both male and female unisexual flowers. Its unique gynoecious line, OHB61-5, is essential as a maternal parent in the production of F1 cultivars. To identify the DNA markers for this gynoecy, a RAD-seq (restriction-associated DNA tag sequencing) analysis was employed to reveal genome-wide DNA polymorphisms and to genotype the F2 progeny from a cross between OHB61-5 and a monoecious line. Based on a RAD-seq analysis of F2 individuals, a linkage map was constructed using 552 co-dominant markers. In addition, after analyzing the pooled genomic DNA from monoecious or gynoecious F2 plants, several SNP loci that are genetically linked to gynoecy were identified. GTFL-1, the closest SNP locus to the putative gynoecious locus, was converted to a conventional DNA marker using invader assay technology, which is applicable to the marker-assisted selection of gynoecy in M. charantia breeding.

Draft genome sequence of bitter gourd (Momordica charantia), a vegetable and medicinal plant in tropical and subtropical regions

Abstract Bitter gourd (Momordica charantia) is an important vegetable and medicinal plant in tropical and subtropical regions globally. In this study, the draft genome sequence of a monoecious bitter gourd inbred line, OHB3-1, was analyzed. Through Illumina sequencing and de novo assembly, scaffolds of 285.5 Mb in length were generated, corresponding to ∼84% of the estimated genome size of bitter gourd (339 Mb). In this draft genome sequence, 45,859 protein-coding gene loci were identified, and transposable elements accounted for 15.3% of the whole genome. According to synteny mapping and phylogenetic analysis of conserved genes, bitter gourd was more related to watermelon (Citrullus lanatus) than to cucumber (Cucumis sativus) or melon (C. melo). Using RAD-seq analysis, 1507 marker loci were genotyped in an F2 progeny of two bitter gourd lines, resulting in an improved linkage map, comprising 11 linkage groups. By anchoring RAD tag markers, 255 scaffolds were assigned to the linkage map. Comparative analysis of genome sequences and predicted genes determined that putative trypsin-inhibitor and ribosome-inactivating genes were distinctive in the bitter gourd genome. These genes could characterize the bitter gourd as a medicinal plant.

Genome sequence comparison reveals a candidate gene involved in male–hermaphrodite differentiation in papaya ( Carica papaya ) trees

AbstractThe sex type of papaya (Carica papaya) is determined by the pair of sex chromosomes (XX, female; XY, male; and XYh, hermaphrodite), in which there is a non-recombining genomic region in the Y and Yh chromosomes. This region is presumed to be involved in determination of males and hermaphrodites; it is designated as the male-specific region in the Y chromosome (MSY) and the hermaphrodite-specific region in the Yh chromosome (HSY). Here, we identified the genes determining male and hermaphrodite sex types by comparing MSY and HSY genomic sequences. In the MSY and HSY genomic regions, we identified 14,528 nucleotide substitutions and 965 short indels with a large gap and two highly diverged regions. In the predicted genes expressed in flower buds, we found no nucleotide differences leading to amino acid changes between the MSY and HSY. However, we found an HSY-specific transposon insertion in a gene (SVPlike) showing a similarity to the Short Vegetative Phase (SVP) gene. Study of SVP-like transcripts revealed that the MSY allele encoded an intact protein, while the HSY allele encoded a truncated protein. Our findings demonstrated that the SVP-like gene is a candidate gene for male-hermaphrodite determination in papaya.

Leaf margin phenotype-specific restriction-site-associated DNA-derived markers for pineapple (Ananas comosus L.)

To explore genome-wide DNA polymorphisms and identify DNA markers for leaf margin phenotypes, a restriction-site-associated DNA sequencing analysis was employed to analyze three bulked DNAs of F1 progeny from a cross between a ‘piping-leaf-type’ cultivar, ‘Yugafu’, and a ‘spiny-tip-leaf-type’ variety, ‘Yonekura’. The parents were both Ananas comosus var. comosus. From the analysis, piping-leaf and spiny-tip-leaf gene-specific restriction-site-associated DNA sequencing tags were obtained and designated as PLSTs and STLSTs, respectively. The five PLSTs and two STSLTs were successfully converted to cleaved amplified polymorphic sequence (CAPS) or simple sequence repeat (SSR) markers using the sequence differences between alleles. Based on the genotyping of the F1 with two SSR and three CAPS markers, the five PLST markers were mapped in the vicinity of the P locus, with the closest marker, PLST1_SSR, being located 1.5 cM from the P locus. The two CAPS markers from STLST1 and STLST3 perfectly assessed the ‘spiny-leaf type’ as homozygotes of the recessive s allele of the S gene. The recombination value between the S locus and STLST loci was 2.4, and STLSTs were located 2.2 cM from the S locus. SSR and CAPS markers are applicable to marker-assisted selection of leaf margin phenotypes in pineapple breeding.

Retrotransposon-based insertion polymorphism markers in mango

Retrotransposons are major components of eukaryotic genomes and are present in high copy numbers. We developed retrotransposon-based insertion polymorphism (RBIP) markers based on long terminal repeat (LTR) sequences and flanking genome regions by using shotgun genome sequence data of mango (Mangifera indica L.). Three novel LTR sequences were identified based on two LTR retrotransposon structural features; a 5′ LTR located upstream of the primer binding site and a 3′ LTR showing high sequence similarity to the 5′ LTR. Starting with 377 unique sequences containing both 3′ LTR and downstream genome region sequences, we developed 82 RBIP markers that were applied to DNA fingerprinting of 16 mango accession. Five RBIP markers were enough to distinguish all 16 accessions. Our result showed that LTR identification from shotgun genome sequences was effective for development of retrotransposon-based DNA markers without whole-genome sequence information. We discuss application of the developed RBIP markers for identification of genetic diversity and construction of a genetic linkage map.

Production of backcross plants between intergeneric hybrids ( Carica papaya × Vasconcellea cundinamarcensis ) and C. papaya , as a novel breeding material for Papaya leaf distortion mosaic virus resistance

摘 要 パパイヤ奇形葉モザイクウイルス(Papaya leaf distortion mosaic virus: PLDMV)抵抗性を持つ属間 雑種個体(パパイヤ Carica papaya × Vasconcellea cundinamarcensis)にパパイヤを戻し交雑し,胚培 養による戻し交雑個体の作出を試みた.戻し交雑後 180~210 日に供試した 5,762 の種子から,胚を 持つ 45 の種子が得られ,最終的に 32 個体の再生植物体が得られた.PCR によって,性染色体型を 調査した結果,32 個体の内,19 個体に戻し交雑親の Y 染色体の保有が確認できたことから,戻し 交雑個体であることが確認できた.全ての戻し交雑個体は,母本として用いた属間雑種の性染色体 を持っていたことから,非還元配偶子が形成されている可能性が示唆された.戻し交雑個体の PLDMV 抵抗性を評価するため,PLDMV の人工接種を行った結果,66%が PLDMV に対して全く病徴を示さ ない抵抗性であった.残りの戻し交雑個体は,接種上位葉に壊疽斑点を生じたが,PLDMV の拡大 を妨げた.従って,戻し交雑個体は全て PLDMV に対して抵抗性を有していた.これらの戻し交雑 個体は,沖縄県で問題となっている PLDMV へのパパイヤ抵抗性品種育成において有望な育種素材 と考えられる.

Development of plants resistant to Papaya leaf distortion mosaic virus by intergeneric hybridization between Carica papaya and Vasconcellea cundinamarcensis

In this study, we confirmed that Vasconcellea cundinamarcensis resists Papaya leaf distortion mosaic virus (PLDMV), and used it to produce intergeneric hybrids with Carica papaya. From the cross between C. papaya and V. cundinamarcensis, we obtained 147 seeds with embryos. Though C. papaya is a monoembryonic plant, multiple embryos were observed in all 147 seeds. We produced 218 plants from 28 seeds by means of embryo-rescue culture. All plants had pubescence on their petioles and stems characteristic of V. cundinamarcensis. Flow cytometry and PCR of 28 plants confirmed they were intergeneric hybrids. To evaluate virus resistance, mechanical inoculation of PLDMV was carried out. The test showed that 41 of 134 intergeneric hybrid plants showed no symptoms and were resistant. The remaining 93 hybrids showed necrotic lesions on the younger leaves than the inoculated leaves. In most of the 93 hybrids, the necrotic lesions enclosed the virus and prevented further spread. These results suggest that the intergeneric hybrids will be valuable material for PLDMV-resistant papaya breeding.