A chloride efflux transporter,BIG RICE GRAIN 1, is involved in mediating grain size and salt tolerance in rice

Grain size is determined by the size and number of cells in the grain. The regulation of grain size is crucial for improving crop yield; however, the genes and molecular mechanisms that control grain size remain elusive. Here, we report that a member of the detoxification efflux carrier /Multidrug and Toxic Compound Extrusion (DTX/MATE) family transporters, BIG RICE GRAIN 1 (BIRG1), negatively influences grain size in rice (Oryza sativa L.). BIRG1 is highly expressed in reproductive organs and roots. In birg1 grain, the outer parenchyma layer cells of spikelet hulls are larger than in wild-type (WT) grains, but the cell number is unaltered. When expressed in Xenopus laevis oocytes, BIRG1 exhibits chloride efflux activity. Consistent with this role of BIRG1, the birg1 mutant shows reduced tolerance to salt stress at a toxic chloride level. Moreover, grains from birg1 plants contain a higher level of chloride than those of WT plants when grown under normal paddy field conditions, and the roots of birg1 accumulate more chloride than those of WT under saline conditions. Collectively, the data suggest that BIRG1 in rice functions as a chloride efflux transporter that is involved in mediating grain size and salt tolerance by controlling chloride homeostasis.     

一个新的OsBRI1弱等位突变体的鉴定及其调控种子大小的功能研究

水稻(Oryza sativa)籽粒大小是影响其产量的关键农艺性状, 克隆并研究水稻籽粒大小相关基因对于提高水稻产量具有重要意义。为深入探究水稻籽粒大小的调控机制, 通过EMS诱变品种宽叶粳(KYJ), 分离了一系列水稻籽粒大小改变的突变体, 其中smg12表现为籽粒变小, 株高变矮, 一级枝梗数和二级枝梗数减少。遗传分析表明, 该小粒突变体受隐性单基因控制。细胞学分析显示, 该突变体颖壳纵向细胞长度显著变短, 表明SMG12主要影响细胞扩展。利用Mutmap方法对候选基因进行克隆, 筛选出SMG12的候选基因OsBRI1, 该基因编码油菜素内酯受体激酶。OsBRI1外显子上的第2 074个碱基发生了由C到T的置换, 产生非同义突变, 使得该位置编码的脯氨酸变为丝氨酸, 从而影响OsBRI1的功能。综上, 该研究鉴定了OsBRI1基因的1个新等位变异, 揭示了油菜素内酯途径调控水稻籽粒大小的细胞和分子基础。     

Two <Emphasis Type="Italic">FERONIA-like receptor</Emphasis> (<Emphasis Type="Italic">FLR</Emphasis>) genes are required to maintain architecture,fertility, and seed yield in rice

The Arabidopsis gene FERONIA (FER) regulates cell elongation and fertility. Although the function of FER in promoting plant growth and regulating fructification in dicotyledon Arabidopsis has been investigated, how homologous FERONIA-like receptors (FLRs) function in the monocotyledon rice crop is little known. In this study, we generated flr1 and flr2 T-DNA insertion null mutants and investigated potential role of FLRs in rice yield. We observed that both FLR1 and FLR2 were involved in tillering of rice, but at different levels. Interestingly, FLR1 and FLR2 showed different functions related to fertility, and FLR1 might be specifically involved in rice male gametophyte development. With these similar but different functions, we suggest that FLR1 and FLR2 might function in complementary ways to regulate the yield of rice. The similar and different functions of FLR1 and FLR2 also suggest that there might be differentiation from FER to the duplication of FLRs, with FLR1 and FLR2 taking on partial functions from FER.     

水稻SL基因调控水稻的粒形

水稻产量和稻米品质的提高是水稻研究的中心问题。水稻产量主要取决于单株穗数、每穗粒数和粒重;粒重作为一个非常重要的产量性状,由粒长、粒宽和粒厚所决定。影响粒重和粒形的基因多为数量性状基因,精细定位并克隆到的较少。本研究中,我们克隆到一个影响粒形的基因SL,超表达（SL-OE）转基因植株表现出粒长增加、粒宽减小、叶宽减小的表型;同时,SL-RNAi的转基因植株呈现出粒长缩短、叶宽增加的表型。颖壳表面细胞在超表达转基因植株中伸长,而在RNAi转基因植株中缩短。叶片横向细胞数目在转基因植株中发生变化,推测乩基因可能与细胞分裂相关。SL-OE转基因植株中G嗽因被明显上调,说明盟基因可能通过调节GW2的表达对水稻粒宽造成影响。另外,观基因影响稻米的品质。     

The pleiotropic ABNORMAL FLOWER AND DWARF1 affects plant height,floral development and grain yield in rice

Moderate plant height and successful establishment of reproductive organs play pivotal roles in rice grain production. The molecular mechanism that controls the two aspects remains unclear in rice. In the present study, we characterized a rice gene, ABNORMAL FLOWER AND DWARF1 (AFD1) that determined plant height, floral development and grain yield. The afd1 mutant showed variable defects including the dwarfism, long panicle, low seed setting and reduced grain yield. In addition, abnormal floral organs were also observed in the afd1 mutant including slender and thick hulls, and hull‐like lodicules. AFD1 encoded a DUF640 domain protein and was expressed in all tested tissues and organs. Subcellular localization showed AFD1‐green fluorescent fusion protein (GFP) was localized in the nucleus. Meantime, our results suggested that AFD1 regulated the expression of cell division and expansion related genes.     

Global gene expression analysis of a rice high-tillering dwarf mutant

Plant height and tiller number are indispensible for the establishment of grain production in rice (Oryza sativa L.). A new rice mutant high-tillering dwarf 3 (htd3) exhibiting more tiller number and shorter culm length than the wild-type Guichao 2 (GC2, an indica cultivar) was used to investigate the global gene expression patterns at days after germination 25 (DAG25) and DAG60. In this study, we identified 305 and 987 genes with at least twofold change in gene expression level at DAG25 and DAG60 respectively using the rice microarray chip. Gene ontology enrichment analysis of these twofold change regulated genes revealed that large numbers of genes were involved in binding activity, catalytic activity and metabolic process. The chip results also showed that some of the regulated genes involved in diverse molecular pathways, including gibberellin pathway, brassinosteroid pathway and auxin signal, had significant differences in gene expression abundance at DAG60. This genome-wide gene expression analysis could provide a new opportunity to uncover the regulation mechanisms of the development of culm and tiller, two important components of yields in rice.     

Down‐regulation of OsSPX1 caused semi‐male sterility,resulting in reduction of grain yield in rice

OsSPX1, a rice SPX domain gene, involved in the phosphate (Pi)‐sensing mechanism plays an essential role in the Pi‐signalling network through interaction with OsPHR2. In this study, we focused on the potential function of OsSPX1 during rice reproductive phase. Based on investigation of OsSPX1 antisense and sense transgenic rice lines in the paddy fields, we discovered that the down‐regulation of OsSPX1 caused reduction of seed‐setting rate and filled grain number. Through examination of anthers and pollens of the transgenic and wild‐type plants by microscopy, we found that the antisense of OsSPX1 gene led to semi‐male sterility, with lacking of mature pollen grains and phenotypes with a disordered surface of anthers and pollens. We further conducted rice whole‐genome GeneChip analysis to elucidate the possible molecular mechanism underlying why the down‐regulation of OsSPX1 caused deficiencies in anthers and pollens and lower seed‐setting rate in rice. The down‐regulation of OsSPX1 significantly affected expression of genes involved in carbohydrate metabolism and sugar transport, anther development, cell cycle, etc. These genes may be related to pollen fertility and male gametophyte development. Our study demonstrated that down‐regulation of OsSPX1 disrupted rice normal anther and pollen development by affecting carbohydrate metabolism and sugar transport, leading to semi‐male sterility, and ultimately resulted in low seed‐setting rate and grain yield.     

一份水稻矮杆小粒突变体的形态特征和基因定位

从水稻T-DNA插入突变体库中鉴定出一个矮杆小粒突变体t129,该突变体与野生型植株相比,植株明显矮化,籽粒粒长明显缩短,千粒重下降。遗传分析表明,t129的突变性状由一对隐性核基因控制,该基因(T129)经图位克隆定位于水稻第5染色体长臂上,引物InDel43和InDel57之间,物理距离为430 kb,并与标记InDel51共分离。本研究明确了该矮杆小粒突变体的表型特征及遗传规律,为进一步研究调控水稻株高和粒型基因奠定基础。     

Engineering OsBAK1 gene as a molecular tool to improve rice architecture for high yield

Generating a new variety of plant with erect-leaf is a critical strategy to improve rice grain yield, as plants with this trait can be dense-planted. The erect-leaf is a significant morphological trait partially regulated by Brassinosteroids (BRs) in rice plants. So far, only a few genes can be used for molecular breeding in rice. Here, we identified OsBAK1 as a potential gene to alter rice architecture. Based on rice genome sequences, four closely related homologs of Arabidopsis BAK1 ( AtBAK1 ) gene were amplified. Phylogenetic analysis and suppression of a weak Arabidopsis mutant bri1-5 indicated that OsBAK1 (Os08g0174700) is the closest relative of AtBAK1. Genetic, physiological, and biochemical analyses all suggest that the function of OsBAK1 is conserved with AtBAK1 . Overexpression of a truncated intracellular domain of OsBAK1 , but not the extracellular domain of OsBAK1 , resulted in a dwarfed phenotype, similar to the rice BR-insensitive mutant plants. The expression of OsBAK1 changed important agricultural traits of rice such as plant height, leaf erectness, grain morphologic features, and disease resistance responses. Our results suggested that a new rice variety with erect-leaf and normal reproduction can be generated simply by suppressing the expression level of OsBAK1 . Therefore, OsBAK1 is a potential molecular breeding tool for improving rice grain yield by modifying rice architecture.     

WIDE AND THICK GRAIN 1, which encodes an otubain‐like protease with deubiquitination activity,influences grain size and shape in rice

Grain size and shape are two crucial traits that influence grain yield and grain appearance in rice. Although several factors that affect grain size have been described in rice, the molecular mechanisms underlying the determination of grain size and shape are still elusive. In this study we report that WIDE AND THICK GRAIN 1 (WTG1) functions as an important factor determining grain size and shape in rice. The wtg1‐1 mutant exhibits wide, thick, short and heavy grains and also shows an increased number of grains per panicle. WTG1 determines grain size and shape mainly by influencing cell expansion. WTG1 encodes an otubain‐like protease, which shares similarity with human OTUB1. Biochemical analyses indicate that WTG1 is a functional deubiquitinating enzyme, and the mutant protein (wtg1‐1) loses this deubiquitinating activity. WTG1 is expressed in developing grains and panicles, and the GFP–WTG1 fusion protein is present in the nucleus and cytoplasm. Overexpression of WTG1 results in narrow, thin, long grains due to narrow and long cells, further supporting the role of WTG1 in determining grain size and shape. Thus, our findings identify the otubain‐like protease WTG1 to be an important factor that determines grain size and shape, suggesting that WTG1 has the potential to improve grain size and shape in rice.     

Identification of rice genes induced in a rice blast-resistant mutant

To clarify mechanisms of rice blast resistance in rice plants we used suppression subtractive hybridization (SSH) to isolate genes induced upon rice blast inoculation in a rice blast-resistant mutant. A total of 26 rice cDNAs were isolated and found to have elevated expression upon rice blast infection in a rice blast-resistant derivative, SHM-11, of the rice cultivar, Sanghaehyanghyella. Sequencing of the cDNAs revealed that many of the proteins they encoded had been previously described as involved in plant responses against pathogen attack. Two interesting groups of the defense-related proteins consisted of three different PR5 homologues and four different protease inhibitors, all highly expressed in the rice blast mutant. Genes encoding proteins involved in signal transduction and regulation were also identified, including translation initiation factor eIF5A, C2 domain DNA binding protein, putative rice EDS and putative receptor like kinase. Most of the identified cDNAs were highly expressed 24 h after blast inoculation. Our results suggest that a pathway regulating defense gene expression may be altered in the mutant, resulting in early induction of the defense genes upon fungal infection.