Jungil Yang

Rice OGR1 encodes a pentatricopeptide repeat–DYW protein and is essential for RNA editing in mitochondria

RNA editing is the alteration of RNA sequences via insertion, deletion and conversion of nucleotides. In flowering plants, specific cytidine residues of RNA transcribed from organellar genomes are converted into uridines. Approximately 35 editing sites are present in the chloroplasts of higher plants; six pentatricopeptide repeat genes involved in RNA editing have been identified in Arabidopsis. However, although approximately 500 editing sites are found in mitochondrial RNAs of flowering plants, only one gene in Arabidopsis has been reported to be involved in such editing. Here, we identified rice mutants that are defective in seven specific RNA editing sites on five mitochondrial transcripts. Their various phenotypes include delayed seed germination, retarded growth, dwarfism and sterility. Mutant seeds from heterozygous plants are opaque. This mutation, named opaque and growth retardation 1 (ogr1), was generated by T-DNA insertion into a gene that encodes a pentatricopeptide repeat protein containing the DYW motif. The OGR1-sGFP fusion protein is localized to mitochondria. Ectopic expression of OGR1 in the mutant complements the altered phenotypes. We conclude that OGR1 is essential for RNA editing in rice mitochondria and is required for normal growth and development.

OsCOL4 is a constitutive flowering repressor upstream of Ehd1 and downstream of OsphyB

Plants recognize environmental factors to determine flowering time. CONSTANS (CO) plays a central role in the photoperiod flowering pathway of Arabidopsis, and CO protein stability is modulated by photoreceptors. In rice, Hd1, an ortholog of CO, acts as a flowering promoter, and phytochromes repress Hd1 expression. Here, we investigated the functioning of OsCOL4, a member of the CONSTANS-like (COL) family in rice. OsCOL4 null mutants flowered early under short or long days. In contrast, OsCOL4 activation-tagging mutants (OsCOL4-D) flowered late in either environment. Transcripts of Ehd1, Hd3a, and RFT1 were increased in the oscol4 mutants, but reduced in the OsCOL4-D mutants. This finding indicates that OsCOL4 is a constitutive repressor functioning upstream of Ehd1. By comparison, levels of Hd1, OsID1, OsMADS50, OsMADS51, and OsMADS56 transcripts were not significantly changed in oscol4 or OsCOL4-D, suggesting that OsCOL4 functions independently from previously reported flowering pathways. In osphyB mutants, OsCOL4 expression was decreased and osphyB oscol4 double mutants flowered at the same time as the osphyB single mutants, indicating OsCOL4 functions downstream of OsphyB. We also present evidence for two independent pathways through which OsPhyB controls flowering time. These pathways are: (i) night break-sensitive, which does not need OsCOL4; and (ii) night break-insensitive, in which OsCOL4 functions between OsphyB and Ehd1.

Cloning Vectors for Rice

We developed various binary vectors that can be used for expressing a foreign gene in rice. Vectors pGA3426, pGA3436, and pGA3626 are intended for overexpression of a gene using the maize Ubiquitin promoter, whereas pGA3780 is for rather mild expression of a gene using the rice Actin1 promoter. Vector pGA3777 is for expressing two genes simultaneously. We also developed binary vectors for expressing a fusion protein with a tag. Four vectors (pGA3427, pGA3428, pGA3429, and pGA3438) are for protein tags with sGFP, HA, His, and Myc, respectively. Vector pGA3383 is for analyzing promoter activity using the GUS reporter. In this vector, multiple cloning sites in front of GUS can be utilized for accepting a promoter fragment. We also generated transient expression vectors for studying the subcellular localization of a protein. Vectors pGA3452, pGA3651, and pGA3652 are for GFP fusion; pGA3574 for RFP fusion; pGA3697 for Myc tag; and pGA3698 for HA tag. In addition, we generated pGA3506, pGA3516, pGA3592, and pGA3593 for facilitating the subcloning of full-length cDNA clones into our binary vectors.

Mutation in Wilted Dwarf and Lethal 1 (WDL1) causes abnormal cuticle formation and rapid water loss in rice

Epidermal cell layers play important roles in plant defenses against various environmental stresses. Here we report the identification of a cuticle membrane mutant, wilted dwarf and lethal 1 (wdl1), from a rice T-DNA insertional population. The muant is dwarf and die at seedling stage due to increased rates of water loss. Stomatal cells and pavement cells are smaller in the mutant, suggesting that WDL1 affects epidermal cell differentiation. T-DNA was inserted into a gene that encodes a protein belonging to the SGNH subfamily, within the GDSL lipase superfamily. The WDL1–sGFP signal coincided with the RFP signal driven by AtBIP–mRFP, indicating that WDL1 is an ER protein. SEM analyses showed that their leaves have a disorganized crystal wax layer. Cross-sectioning reveals loose packing of the cuticle and irregular thickness of cell wall. Detailed analyses of the epicuticular wax showed no significant changes either in the total amount and amounts of each monomer or in the levels of lipid polymers, including cutin and other covalently bound lipids, attached to the cell wall. We propose that WDL1 is involved in cutin organization, affecting depolymerizable components.

Map-based Cloning and Characterization of the BPH18 Gene from Wild Rice Conferring Resistance to Brown Planthopper (BPH) Insect Pest

Brown planthopper (BPH) is a phloem sap-sucking insect pest of rice which causes severe yield loss. We cloned the BPH18 gene from the BPH-resistant introgression line derived from the wild rice species Oryza australiensis. Map-based cloning and complementation test revealed that the BPH18 encodes CC-NBS-NBS-LRR protein. BPH18 has two NBS domains, unlike the typical NBS-LRR proteins. The BPH18 promoter::GUS transgenic plants exhibited strong GUS expression in the vascular bundles of the leaf sheath, especially in phloem cells where the BPH attacks. The BPH18 proteins were widely localized to the endo-membranes in a cell, including the endoplasmic reticulum, Golgi apparatus, trans-Golgi network, and prevacuolar compartments, suggesting that BPH18 may recognize the BPH invasion at endo-membranes in phloem cells. Whole genome sequencing of the near-isogenic lines (NILs), NIL-BPH18 and NIL-BPH26, revealed that BPH18 located at the same locus of BPH26. However, these two genes have remarkable sequence differences and the independent NILs showed differential BPH resistance with different expression patterns of plant defense-related genes, indicating that BPH18 and BPH26 are functionally different alleles. These findings would facilitate elucidation of the molecular mechanism of BPH resistance and the identified novel alleles to fast track breeding BPH resistant rice cultivars.

Controlling flowering time by histone methylation and acetylation in arabidopsis and rice

Arabidopsis thaliana plants flower in Spring in order to produce offspring before they are out-competed by other species. By contrast, rice (Oryza sativa) flowers in Summer after a lengthy period of vegetative growth that will support the maximum amount of seed production. As model systems, these two species are valuable for studies that explore how plants perceive their environmental conditions and optimize the timing of floral development. In both Arabidopsis and rice, FLOWERING LOCUS T (FT) family proteins, or florigens, are produced in the leaf phloem and moved to the shoot apical meristem (SAM). Whereas the florigens in rice immediately induce downstream genes in the SAM to initiate the transition from vegetative to reproductive growth, their functioning in Arabidopsis is inhibited by FLOWERING LOCUS C (FLC). Transcript levels of FT and FLC are regulated epigenetically. Lysine residues of the histone N-tails covering the FT and FLC chromatins are methylated by SET-domain group (SDG) proteins that contain the evolutionarily conserved SET domain while the methyl groups are removed by Jumonji C domain-containing demethylases. Transcript levels of both genes are also modulated by altering the acetylation of the histone tail. In rice, expression by Heading date 3a and Rice FT 1 (RFT1) that produces major florigens are epigenetically controlled by OsSDG724 and OsSDG725. These SDG proteins also methylate OsMADS50 chromatin, a long daypreferential flowering activator. Two other methyltransferases, OsSDG711 and OsSDG718, down-regulate OsLF, a repressor of Heading date 1. Finally, the demethylase OsJMJ701 protein delays flowering by suppressing RFT1 expression.

Alanine aminotransferase 1 (OsAlaAT1) plays an essential role in the regulation of starch storage in rice endosperm.

Alteration of storage substances, in particular the major storage form starch, leads to floury endosperm. Because floury mutants have physical attributes for milling processes, identification and characterization of those mutants are valuable. In this study we identified a floury endosperm mutant caused by a T-DNA insertion in Oryza sativa alanine-aminotransferase1 (OsAlaAT1). OsAlaAT1 is localized in the cytosol and has aminotransferase enzyme activity. The osalaat1 mutant has less amylose and its amylopectin is structurally altered. OsAlaAT1 is predominantly expressed in developing seeds during active starch synthesis. AlaAT catalyzes the interconversion of pyruvate to alanine, and this pathway is activated under low-oxygen conditions. Consistently, OsAlaAT1 is induced by such conditions. Expression of the starch synthesis genes AGPases, OsSSI, OsSSIIa, and OsPPDKB is decreased in the mutant. Thus, our observations suggest that OsAlaAT1 plays an essential role in starch synthesis in developing seeds that are exposed to low concentrations of oxygen.

Identification of root-preferential transcription factors in rice by analyzing GUS expression patterns of T-DNA tagging lines

T-DNA tagging lines are useful for analyzing the functions of genes and regulatory elements. We have previously generated approximately 100,000 insertional mutants in japonica rice (Oryza sativa), using T-DNA vectors carrying the promoter-less GUS reporter gene. In this study, we conducted GUS assays of seedlings from 430 lines in which TDNA was inserted into transcription factor genes. Among the 75 lines that showed GUS signals, nine displayed an endospermpreferential expression pattern; two lines demonstrated GUS signals in both endosperm and roots; 21 lines had GUS expression mainly in leaves; 19 lines showed GUS signal in both leaves and roots; and 24 lines expressed GUS predominantly in the roots. Co-segregation analyses of 49 homozygous lines indicated that the GUS expression patterns observed from 38 lines were due to the T-DNA insertion. We also identified fusion transcripts between tagged genes and the GUS reporter in six lines. Quantitative RT-PCR confirmed that the GUS expression patterns of those tagged lines indeed represent organ- and tissue-preferential expression of the tagged genes. The GUS-tagged transcription factor lines identified here will be useful for functional analysis of these candidates.

OsVIL1 controls flowering time in rice by suppressing OsLF under short days and by inducing Ghd7 under long days

Key messageOsVIL1 is associated with a PRC2-like complex through its fibronectin type III domain to activate flowering by suppressingOsLFunder SD and delay flowering by inducingGhd7under LD.AbstractPolycomb repressive complex 2 (PRC2) inhibits the expression of target genes by modifying histone proteins. Although several genes that epigenetically regulate flowering time have been identified in Arabidopsis thaliana and rice (Oryza sativa), the molecular mechanism by which PRC2 affects flowering time has not been well understood in rice. We investigated the role of Oryza sativa VERNALIZATION INSENSITIVE3-LIKE 1 (OsVIL1), which is homologous to the flowering promoter OsVIL2. The reduction in OsVIL1 expression by RNA interference (RNAi) caused a late flowering phenotype under short days (SD). In the RNAi lines, OsLF expression was increased, but transcripts of Early heading date 1 (Ehd1), Heading date 3a (Hd3a), and RICE FLOWERING LOCUS T 1 (RFT1) were reduced. By contrast, OsVIL1-overexpressing (OX) transgenic lines displayed an early flowering phenotype under SD. Levels of OsLF transcript were reduced while those of Ehd1, Hd3a, and RFT1 were enhanced in the OX lines. Under long days (LD), the OsVIL1-OX lines flowered late and Grain number, plant height, and heading date 7 (Ghd7) expression was higher. We also demonstrated that the plant homeodomain region of OsVIL1 binds to native histone H3 in vitro. Our co-immunoprecipitation assays showed that OsVIL1 interacts with OsVIL2 and that the fibronectin type III domain of OsVIL1 is associated with O. sativa EMBRYONIC FLOWER 2b (OsEMF2b). We propose that OsVIL1 forms a PRC2-like complex to induce flowering by suppressing OsLF under SD but delay flowering by elevating Ghd7 expression under LD.

Chromatin interacting factor OsVIL2 increases biomass and rice grain yield

Summary Grain number is an important agronomic trait. We investigated the roles of chromatin interacting factor Oryza sativa VIN3‐LIKE 2 (OsVIL2), which controls plant biomass and yield in rice. Mutations in OsVIL2 led to shorter plants and fewer grains whereas its overexpression (OX) enhanced biomass production and grain numbers when compared with the wild type. RNA‐sequencing analyses revealed that 1958 genes were up‐regulated and 2096 genes were down‐regulated in the region of active division within the first internodes of OX plants. Chromatin immunoprecipitation analysis showed that, among the downregulated genes, OsVIL2 was directly associated with chromatins in the promoter region of CYTOKININ OXIDASE/DEHYDROGENASE2 (OsCKX2), a gene responsible for cytokinin degradation. Likewise, active cytokinin levels were increased in the OX plants. We conclude that OsVIL2 improves the production of biomass and grain by suppressing OsCKX2 chromatin.