水稻内颖畸形或缺失基因OsAPP1的图位克隆及表达分析

在育种基地材料中发现一株内颖畸形或缺失(abnormal or absent palea)突变体,将其命名为app1。该突变体在营养生长时期发育正常,但抽穗后突变体表现出内颖畸形(比外稃短导致颖壳不闭合,或者出现两个内稃)或缺失,其花粉育性为55.52%,结实率为6.48%,千粒重为10.811 g,种子发芽率为55.21%。以突变体app1与日本晴杂交构建了F1和F2群体,F1颖壳表型正常,F2群体出现内颖畸形和正常表型分离,内颖正常和突变表型分离比例为3∶1,表明app1内颖突变表型由单隐性核基因控制。以F2为分离群体,将app1精细定位于第3染色体上,位于分子标记ID4231和ID4246之间,遗传距离1.3 cM,对应物理距离为13.2 kb。该区段内完全包含1个开放阅读框,包含两个部分开放阅读框,经过测序分析发现候选基因LOC_Os03g11614启动子区发生点突变和245 bp缺失,qRT-PCR分析证实LOC_Os03g11614为OsAPP1基因。已有报道LOC_Os03g11614编码OsMADS1,是调控水稻花器官发育的重要明星基因,其不同位置的突变可以导致叶状颖壳和不育、以及控制籽粒大小。与3000份水稻种子资源SNP/Indel变异类型对比分析发现,突变体app1启动子的突变完全不同于现已OsMADS1研究报道突变类型,且与数据库中的自然突变类型多数不同。因此,本研究发现的app1突变体,是以往报道中从未出现的OsMADS1启动子发生突变的新型突变,且该类突变导致了其降低表达量,并产生了不同于前人研究的新表型,这为深入研究OsMADS1基因在水稻花器官发育中的功能提供了新的种质资源和思路。     

Molecular mapping of split rice spikelet mutantsrs-1 and analysis of its homeotic function in rice

srs-1, a new floral organ identity gene in rice, was mapped using RAPD and RFLP markers. Firstly, the cross was made between "ZhaiYeQing 8" (ZYQ8, indica) and split rice spikelet (SRS, japonica) mutant. The ratio of wild-type individuals and mutant plants in F2 population is 3:1, which indicates that the mutant characteristics are controlled by single recessive gene, srs-1. Consequently, BSA method was adopted and 520 random 10-mer primers were used to screen polymorphic bands between two bulks. Six primers could amplify polymorphic bands, of which S465 generates the most stable RAPD patterns. Then, S465 that cosegregates in F2 population has been converted into an RFLP marker successfully. Furthermore, srs-1 gene was mapped on chromosome 3 using DH mapping population. The effect of srs-1 gene results in the mutant of split rice spikelet. The mutant has longer and softer palea/lemma than those of wild-type, and two small palea/lemma-like organs between palea and lemma. In addition, there is a flower wit     

一个水稻畸形颖壳突变体ah的鉴定及其突变性状的遗传分析

水稻畸形颖壳突变体ah是双胚苗品系W2555中自然突变产生的。该突变体的内外稃畸形,退化;雄蕊雌蕊化,雌蕊败育;浆片同源转化为类内外稃的结构,推测该突变体可能影响B功能基因的正常发育。与野生型相比,突变体的小穗分支稀疏,每级枝梗上颖花数目减少,一般为4～6朵;小穗顶端的颖花经常不能成熟,表现为颖花始终泛白,不能转绿,因此该突变也影响花序分生组织的发育。进一步的研究证明,该突变体的发育受外界环境的影响。突变性状的遗传分析表明,该突变体由单隐性基因控制。     

Identification of a novel <Emphasis Type="Italic">SPLIT</Emphasis>-<Emphasis Type="Italic">HULL</Emphasis> (<Emphasis Type="Italic">SPH</Emphasis>) gene associated with hull splitting in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

Key message

The split-hull phenotype caused by reduced lemma width and low lignin content is under control of SPH encoding a type-2 13-lipoxygenase and contributes to high dehulling efficiency.

Abstract

Rice hulls consist of two bract-like structures, the lemma and palea. The hull is an important organ that helps to protect seeds from environmental stress, determines seed shape, and ensures grain filling. Achieving optimal hull size and morphology is beneficial for seed development. We characterized the split-hull (sph) mutant in rice, which exhibits hull splitting in the interlocking part between lemma and palea and/or the folded part of the lemma during the grain filling stage. Morphological and chemical analysis revealed that reduction in the width of the lemma and lignin content of the hull in the sph mutant might be the cause of hull splitting. Genetic analysis indicated that the mutant phenotype was controlled by a single recessive gene, sph (Os04g0447100), which encodes a type-2 13-lipoxygenase. SPH knockout and knockdown transgenic plants displayed the same split-hull phenotype as in the mutant. The sph mutant showed significantly higher linoleic and linolenic acid (substrates of lipoxygenase) contents in spikelets compared to the wild type. It is probably due to the genetic defect of SPH and subsequent decrease in lipoxygenase activity. In dehulling experiment, the sph mutant showed high dehulling efficiency even by a weak tearing force in a dehulling machine. Collectively, the results provide a basis for understanding of the functional role of lipoxygenase in structure and maintenance of hulls, and would facilitate breeding of easy-dehulling rice.

     

Molecular mapping of split rice spikelet mutant srs-1 and analysis of its homeotic function in rice

srs-1, a new floral organ identity gene in rice, was mapped using RAPD and RFLP markers. Firstly, the cross was made between "ZhaiYeQing 8" (ZYQ8, indica) and split rice spikelet (SRS, japonica) mutant. The ratio of wild-type individuals and mutant plants in F2 population is 3:1, which indicates that the mutant characteristics are controlled by single recessive gene, srs-1. Consequently, BSA method was adopted and 520 random 10-mer primers were used to screen polymorphic bands between two bulks. Six primers could amplify polymorphic bands, of which S465 generates the most stable RAPD patterns. Then, S465 that cosegregates in F2 population has been converted into an RFLP marker successfully. Furthermore, srs-1 gene was mapped on chromosome 3 using DH mapping population. The effect of srs-1 gene results in the mutant of split rice spikelet. The mutant has longer and softer palea/lemma than those of wild-type, and two small palea/lemma-like organs between palea and lemma. In addition, there is a flower with three stamens and carpel in the axil of lemma. Thus, there are nine stamens and two carpels in the spikelet of mutant. srs-1 gene may belong to homeotic gene of class A according to the mutant characteristics and ABC model.     

一个水稻内颖退化突变体的形态特征及基因的精确定位

水稻产量和品质受花器官发育的直接影响,因此对水稻颖花发育机理的研究将有助于水稻产量提高和品质的改良。文章利用60Coγ射线辐照亲本8PW33(籼稻背景)获得一个性状能稳定遗传的内颖退化突变体(编号:MU102),并对其农艺性状和花器官进行了观察和分析。结果显示,相对于野生型,该突变体的株高、每穗总粒数及剑叶宽均显著增加,而结实率则显著降低,差异均达显著水平。解剖镜下观察表明,该突变体内颖退化,外颖弯曲呈现镰刀状,其余器官与野生型表型基本一致。扫描电镜观察显示,突变体与野生型叶片维管束的结构组成以及外颖表皮细胞组成、排列均正常,没有明显差异;与野生型相比,突变体内颖表皮细胞排列较为紧密,推测可能是内颖收缩退化导致的。遗传分析显示该突变性状是由隐性单基因控制,并命名为pd2。利用实验室现有的SSR分子标记将PD2基因定位于水稻第9号染色体上,通过进一步扩大群体和开发新的Indel标记,将PD2基因定位在2个Indel标记之间,两者间的物理距离大约是82 kb。在该物理区间内有一个已经克隆的内颖发育基因REP1,经过测序和比对分析,推测REP1与PD2为等位基因。     

水稻雄性不育突变体D63的育性基因遗传分析与精细定位

利用化学诱变剂甲基磺酸乙酯(EMS)处理籼稻品种冈46B获得雄性不育突变体D63,并对该突变体进行表型鉴定、遗传分析和基因定位。结果显示D63突变体花药瘦小呈乳白色,花药内完全无花粉粒,属于无花粉型雄性不育。与野生型亲本冈46B相比,D63突变体成熟期株高降低了13.7%,穗伸出度减少了266.7%,自交结实率为0,其他农艺性状无显著差异。遗传分析表明该不育性状受1对隐性核基因控制,该突变基因定位于第2号染色体长臂靠近着丝粒区域In Del标记J2和J4之间,与J2和J4的遗传距离分别为0.2 c M和0.1 c M,该定位区间的物理距离为105.8 kb。候选基因分析结果表明,D63突变体在编码分泌性成束糖蛋白基因LOC_Os02g28970编码区第1580位碱基A突变为C,使编码蛋白的氨基酸序列第527位组氨酸(His)突变为脯氨酸(Pro)。D63突变体与已报道的mtr1突变体表型上不同之处主要是后者花药含有败育花粉粒,二者表型上的差异可能是由于LOC_Os02g28970基因序列突变位点不同,以及它们分别属于籼、粳亚种2个不同遗传背景所致。     

Molecular and genetic analyses of the silky1 gene reveal conservation in floral organ specification between eudicots and monocots

The degree to which the eudicot-based ABC model of flower organ identity applies to the other major subclass of angrosperms, the monocots, has yet to be fully explored. We cloned silky1 (si1), a male sterile mutant of Zea mays that has homeotic conversions of stamens into carpels and lodicules into palea/lemma-like structures. Our studies indicate that si1 is a monocot B function MADS box gene. Moreover, the si1 zag1 double mutant produces a striking spikelet phenotype where normal glumes enclose reiterated palea/lemma-like organs. These studies indicate that B function gene activity is conserved among monocots as well as eudicots. In addition, they provide compelling developmental evidence for recognizing lodicules as modified petals and, possibly, palea and lemma as modified sepals.     

Identification and fine mapping of a mutant gene for palealess spikelet in rice

In grass, the evolutionary relationship between lemma and palea, and their relationship to the flower organs in dicots have been variously interpreted and wildely debated. In the present study, we carried out morphological and genetic analysis of a palealess mutant (pal) from rice (Oryza sativa L.), and fine mapping the gene responsible for the mutated trait. Together, our findings indicate that the palea is replaced by two leaf-like structures in the pal flowers, and this trait is controlled by one recessive gene, termed palealess1 (pal1). With a large F2 segregating population, the pal1 gene was finally mapped into a physical region of 35 kb. Our results also suggest that the lemma and palea of rice are not homologous organs, palea is likely evolutionarily equivalent to the eudicot sepal, and the pal1 should be an A function gene for rice floral organ identity.     

RETARDED PALEA1 controls palea development and floral zygomorphy in rice

Poaceae, one of the largest flowering plant families in angiosperms, evolved distinct inflorescence and flower morphology diverging from eudicots and other monocots. However, the mechanism underlying the specification of flower morphology in grasses remains unclear. Here we show that floral zygomorphy along the lemma-palea axis in rice (Oryza sativa) is partially or indirectly determined by the CYCLOIDEA (CYC)-like homolog RETARDED PALEA1 (REP1), which regulates palea identity and development. The REP1 gene is only expressed in palea primordium during early flower development, but during later floral stages is radially dispersed in stamens and the vascular bundles of the lemma and palea. The development of palea is significantly retarded in the rep1 mutant and its palea has five vascular bundles, which is similar to the vascular pattern of the wild-type lemma. Furthermore, ectopic expression of REP1 caused the asymmetrical overdifferentiation of the palea cells, altering their floral asymmetry. This work therefore extends the function of the TCP gene family members in defining the diversification of floral morphology in grasses and suggests that a common conserved mechanism controlling floral zygomorphy by CYC-like genes exists in both eudicots and the grasses.     

Map-based cloning of the ERECT PANICLE 3 gene in rice

Panicle architecture in rice can have a strong influence on yield. Using N-methyl-N-nitrosourea mutagenesis, we isolated an erect panicle mutant, Hep, from Hwasunchalbyeo, a glutinous japonica rice cultivar. Genetic analysis revealed that the erect panicle phenotype was controlled by a single recessive mutation designated erect panicle 3 (ep3). Genetic mapping revealed that the ep3 mutation was located on the short arm of chromosome 2 in a 0.1 cM region delimited by the STS markers STS5803-5 and STS5803-7. The ep3 locus corresponded to 46.8 kb region and contained six candidate genes. Comparison of the DNA sequences of the candidate genes from wild-type and erect panicle plants revealed a single base-pair change in the second exon of LOC_Os02g15950, which is predicted to result in a nonsense mutation. LOC_Os02g15950 encodes a putative F-box protein containing 515 amino acids and is expressed throughout the plant during all growth stages. A line carrying a T-DNA insertion in LOC_ Os02g15950 was obtained and shown to have the same phenotype as the ep3 mutant, thus confirming the identification of LOC_Os02g15950 as the ERECT PANICLE 3 (EP3) gene. The ep3 mutation causes a significant increase in the number of small vascular bundles as well as the thickness of parenchyma in the peduncle, which results in the erect panicle phenotype.     

Ectopic expression of <Emphasis Type="Italic">OsMADS1</Emphasis> caused dwarfism and spikelet alteration in rice

In rice, an E-class gene, OsMADS1, acts to specify the identities of the lemma and palea. In this study, the OsMADS1 gene with a CaMV35S promoter was transformed into a japonica cultivar, Zhonghua 11. All transgenic plants successfully showed similar phenotypes, including dwarfism, distorted panicles, decreased numbers of branches and spikelets, and elongated sterile lemma. Histological analysis showed that the elongated sterile lemma developed with silicified epidermal and sclerenchymal cells, which were lacking in the wild-type sterile lemma, suggesting that the elongated sterile lemma had assumed the identity of the lemma or palea. Some marker genes were subjected to a detailed analysis of the distribution of their expression among the lemma, palea and sterile lemma. DROOPING LEAF (DL) and OsMADS6 genes were only expressed in the normal lemma or palea, respectively. In the elongated sterile lemma, a high level of DL gene expression was detected, while no expression of OsMADS6 was found, implying that the sterile lemma transformed into the lemma but not the palea. These results provide clues to elucidate the mechanism of evolution from lemma to sterile lemma in rice. qPCR analysis also suggested that the ectopic expression of OsMADS1 induced abnormal brassinosteroid and gibberellin acid activation, and then resulted in developmental defects in the stem and panicle.     

Crinkly4 receptor-like kinase is required to maintain the interlocking of the palea and lemma, and fertility in rice, by promoting epidermal cell differentiation

The palea and lemma are unique organs in grass plants that form a protective barrier around the floral organs and developing kernel. The interlocking of the palea and lemma is critical for maintaining fertility and seed yield in rice; however, the molecules that control the interlocking structure remain largely unknown. Here, we showed that when OsCR4 mRNA expression was knocked down in rice by RNA interference, the palea and lemma separated at later spikelet stages and gradually turned brown after heading, resulting in the severe interruption of pistil pollination and damage to the development of embryo and endosperm, with defects in aleurone. The irregular architecture of the palea and lemma was caused by tumour-like cell growth in the outer epidermis and wart-like cell masses in the inner epidermis. These abnormal cells showed discontinuous cuticles and uneven cell walls, leading to organ self-fusion that distorted the interlocking structures. Additionally, the faster leakage of chlorophyll, reduced silica content and elevated accumulation of anthocyanin in the palea and lemma indicated a lesion in the protective barrier, which also impaired seed quality. OsCR4 is an active receptor-like kinase associated with the membrane fraction. An analysis of promoter::GUS reporter plants showed that OsCR4 is specifically expressed in the epidermal cells of paleas and lemmas. Together, these results suggest that OsCR4 plays an essential role in maintaining the interlocking of the palea and lemma by promoting epidermal cell differentiation.