The Petal-Specific InMYB1 Promoter Functions by Recognizing Petaloid Cells.

The InMYB1 gene in Japanese morning glory (Ipomoea nil) is a member of the MYB transcription factor family. The promoter of InMYB1 has been reported to induce petal-specific gene expression in Arabidopsis and Eustoma, and has the same function in several other dicotyledonous plants. Most flowers consist of sepals, petals, stamens and a carpel, whose identity establishment is explained by the ABC model. The establishment of the identity of petals is determined by the expression of class A and B genes in whorl 2. The aim of this study was to clarify whether the InMYB1 promoter functions by recognizing whorl position or petal identity by examining its activity in various mutant and transgenic Arabidopsis thaliana plants in which genes related to the ABC model have been modified. In plants defective in class C gene function, the InMYB1 promoter functioned not only in petals generated in whorl 2 but also in petaloid organs generated in whorl 3; while in the plants defective in class B gene function, the InMYB1 promoter did not function in the sepaloid organs generated in whorl 2. Plants overexpressing class A, B and E genes set flowers with petaloid sepals in whorl 1, i.e. the lateral parts were white and looked like petals, while the central parts were green and looked like sepals. The InMYB1 promoter functioned in the lateral white parts but not in the central green parts. These results show that the InMYB1 promoter functions by recognizing petal identity at the cellular level rather than the whorl position. The petal-specific function of the InMYB1 promoter could be used as a marker to identify petaloid cells.

A petal-specific InMYB1 promoter from Japanese morning glory: a useful tool for molecular breeding of floricultural crops.

Production of novel transgenic floricultural crops with altered petal properties requires transgenes that confer a useful trait and petal-specific promoters. Several promoters have been shown to control transgenes in petals. However, all suffer from inherent drawbacks such as low petal specificity and restricted activity during the flowering stage. In addition, the promoters were not examined for their ability to confer petal-specific expression in a wide range of plant species. Here, we report the promoter of InMYB1 from Japanese morning glory as a novel petal-specific promoter for molecular breeding of floricultural crops. First, we produced stable InMYB1_1kb::GUS transgenic Arabidopsis and Eustoma plants and characterized spatial and temporal expression patterns under the control of the InMYB1 promoter by histochemical ß-glucuronidase (GUS) staining. GUS staining patterns were observed only in petals. This result showed that the InMYB1 promoter functions as a petal-specific promoter. Second, we transiently introduced the InMYB1_1 kb::GUS construct into Eustoma, chrysanthemum, carnation, Japanese gentian, stock, rose, dendrobium and lily petals by particle bombardment. GUS staining spots were observed in Eustoma, chrysanthemum, carnation, Japanese gentian and stock. These results showed that the InMYB1 promoter functions in most dicots. Third, to show the InMYB1 promoter utility in molecular breeding, a MIXTA-like gene function was suppressed or enhanced under the control of InMYB1 promoter in Arabidopsis. The transgenic plant showed a conspicuous morphological change only in the form of wrinkled petals. Based on these results, the InMYB1 promoter can be used as a petal-specific promoter in molecular breeding of floricultural crops.

Genome sequence of Hydrangea macrophylla and its application in analysis of the double flower phenotype.

Owing to its high ornamental value, the double flower phenotype of hydrangea (Hydrangea macrophylla) is one of its most important traits. In this study, genome sequence information was obtained to explore effective DNA markers and the causative genes for double flower production in hydrangea. Single-molecule real-time sequencing data followed by a Hi-C analysis were employed. Two haplotype-phased sequences were obtained from the heterozygous genome of hydrangea. One assembly consisted of 3,779 scaffolds (2.256 Gb in length and N50 of 1.5 Mb), the other also contained 3,779 scaffolds (2.227 Gb in length, and N50 of 1.4 Mb). A total of 36,930 genes were predicted in the sequences, of which 32,205 and 32,222 were found in each haplotype. A pair of 18 pseudomolecules was constructed along with a high-density single-nucleotide polymorphism (SNP) genetic linkage map. Using the genome sequence data, and two F2 populations, the SNPs linked to double flower loci (djo and dsu) were discovered. DNA markers linked to djo and dsu were developed, and these could distinguish the recessive double flower allele for each locus, respectively. The LEAFY gene is a very likely candidate as the causative gene for dsu, since frameshift was specifically observed in the double flower accession with dsu.

Impact of Phosphorus Fertilization on Tomato Growth and Arbuscular Mycorrhizal Fungal Communities.

Understanding the impact of phosphorus (P) addition on arbuscular mycorrhizal fungi (AMF) is crucial to understanding tomato (Solanum lycopersicum L.) P nutrition. However, it remains unknown how P fertilization is associated with the structure of AMF communities on tomato plants. Thus, we investigated whether levels of P fertilizer interacted with the colonization and structure of AMF in tomato roots in a field trial. In this study, we established three different amounts of P fertilizer treatments (0 kg ha-1, 50 kg ha-1, and 100 kg ha-1). We investigated AMF root colonization and community structure, as well as plant growth in tomatoes at seven weeks following transplantation. The structure of the AMF communities in the roots of tomato were determined by MiSeq amplicon sequencing. As expected, P fertilizer input enhanced the P uptake and plant biomass. In contrast, the P fertilizer level did not affect the AMF root colonization and diversity or the structure of the AMF communities in the tomato. However, we found a negative correlation between AMF colonization and richness in the roots of the tomato plants. Therefore, we need to investigate whether and how AMF communities and P fertilization develop more effective P management for tomato plants.

Dissecting promoter of InMYB1 gene showing petal-specific expression.

We had previously reported that the InMYB1 promoter, the 1023 bp upstream region of InMYB1, works petal-specifically in various dicot plants by recognizing petal identity at a cellular level. To determine the petal-specific region in the InMYB1 promoter, Arabidopsis plants harboring InMYB1_1023b::GUS (ß-glucuronidase), InMYB1_713b::GUS, InMYB1_506b::GUS, InMYB1_403b::GUS, InMYB1_332b::GUS, InMYB1_200b::GUS and InMYB1_140b::GUS were produced and confirmed a shortest region, which has the petal-specific promoter activity by using histochemical GUS assay. Petal-specific GUS staining was not observed in the Arabidopsis plants transformed with InMYB1_200b::GUS and InMYB1_140b::GUS, but observed in transgenic Arabidopsis plants harboring from InMYB1_1023b::GUS to InMYB1_332b::GUS. cDNA sequence of InMYB1 shows that 120 bp upstream region of InMYB1 is 5' untranslated region, suggesting that the 332-121 bp upstream region of InMYB1 contains an important element for petal-specific gene expression. In the Arabidopsis harboring the InMYB1_332-121b×3_TATA_Ω::GUS, petal-specific GUS staining was observed and the staining was stronger than in the Arabidopsis harboring InMYB1_1023b::GUS. This result shows that the 332-121 bp region is enough and essential for the petal specificity and the InMYB1_332-121b×3_TATA_Ω could be used for the molecular breeding of floricultural crops.