多基因聚合改良杂交稻恢复系福恢676的稻瘟病抗性

福恢676是一个综合性状优良但稻瘟病抗性不强的杂交水稻恢复系,该父本已测配育成的18个杂交稻品种通过了省级以上品种审定.为了改良其稻瘟病抗性,延长该恢复系在生产上的应用期限.以携带3个稻瘟病抗性基因(Pi-1、Pi-9和Pi-k^(h))的优质恢复系金恢1059为供体亲本,以福恢676为轮回亲本,通过回交导入、分子标记辅助选择及田间稻瘟病抗性鉴定相结合的方法,选育出5个抗病的稳定株系,其中3个株系聚合了Pi-1、Pi-9和Pi-kh.对这5个株系的综合农艺性状、品质和配合力等进行系统比较,并结合稻瘟病抗性鉴定.结果表明,与福恢676相比,改良株系及其与广8A、荃9311A和广占63-4S等不育系配制的杂种F1均表现出稻瘟病抗性明显增强,而其中株系6综合表现最优,遗传背景恢复率为97.1%,且其生育期、株高等主要农艺性状与福恢676测配组合无显著差异,但产量有所提高,品质得到改善.改良的株系6保留了福恢676产量高、恢复力强、配合力好等优良特点,品质有所提升,具有较好的应用前景.

籼稻福香占耐储藏性的蛋白质组学分析

稻谷耐储藏性对于国家粮食安全、种质资源保存及种业安全具有非常重要的意义.本研究通过人工老化处理分析福香占和航2号种子活力的变化趋势,扫描电子显微镜观察老化21 d后糙米淀粉粒结构,并对关键时间点的种胚蛋白质组进行定量分析.结果表明,人工老化后14~21 d,航2号种子活力快速下降,淀粉粒结构受到严重破坏,种子耐储藏性较差.而福香占在人工老化21 d后仍具有较强种子活力,淀粉粒结构保持良好,耐储藏性优;蛋白质组分析表明,福香占和航2号在人工老化的不同阶段,脂类、蛋白质、碳水化合物等生物合成及代谢、遗传信息加工、转录调控、营养保持、信息传递、氧化还原调节等方面均表现出差异;差异蛋白质显著富集到4个代谢通路,即亚油酸代谢,角质、木栓和蜡质的生物合成,谷胱甘肽代谢和甘油磷脂代谢.老化21 d与处理前相比较,福香占真核生物核糖体生物发生、萜类骨架生物合成、叶酸生物合成等代谢通路发生差异表达,而航2号主要为氮代谢、淀粉和蔗糖代谢及mRNA监测等途径.本研究为稻谷耐储藏性遗传机理的深入解析及培育耐储藏水稻新品种奠定了基础.

水稻卷叶突变体基因shallot like1-Fuhui673鉴定、克隆与序列分析

叶片是水稻进行光合作用的重要器官,其形态直接影响光合作用的强弱.叶片适度卷曲可以使叶片保持直立,改善群体内部透光状况,提高光能利用率,进而提高水稻产量.本研究通过Co60-γ辐照诱变杂交水稻恢复系福恢673,获得一个卷叶突变体,命名为sll1-fh673(shallot-like1 from Fuhui673).经遗传学分析表明,该突变体sll1-fh673卷叶性状受1对隐性基因控制,结合混合群体(BSA)和隐性群体(RCA)分离分析法,将该基因ssl1-fh673精细定位于水稻第9染色体的inD el标记Ri9-20与Ri9-7之间52 kb的区域内.测序结果表明,sll1-fh673(LOC_Os09g23200)的核苷酸序列在第1个外显子第447 bp处由C替换为A,447 bp后缺失5个碱基,导致编码的氨基酸序列从第148位起发生改变并移码,造成蛋白功能异常.因此,推测sll1-fh673是SLL1的新等位基因,该新等位基因的挖掘丰富了SLL1基因的等位资源,有助于深入研究叶片卷曲的形成机理.

稻谷人工老化后种胚异构天冬氨酸动态监测与总蛋白差异表达分析

蛋白质中天冬氨酸和天冬酰胺自发形成的异构天冬氨酸残基是组织细胞中常见的蛋白质共价损伤.在前人的研究中,PIMT1介导的种子寿命提高,很可能是由于修复了种胚中因老化处理而过量累积的含异构天冬氨酸(isoaspartyl,isoAsp)蛋白,维持了种胚的活性.然而,异构天冬氨酸蛋白甲基转移酶(protein L-isoaspartyl methyltransferase,PIMT)对于水稻种子活力的作用机制,仍然不甚明确.本研究利用RNAi干扰技术获得了稳定的OsPIMT1的低表达株系.种子经人工老化后,结果表明OsPIMT1的低表达影响种子发芽活力.随后对种胚中含异构天冬氨酸的蛋白进行动态检测,结果显示在未吸胀和吸胀过后的种子中,种胚中的OsPIMT1的表达都能降低isoAsp的累积.而RNAi株系中OsPIMT1的低表达导致isoAsp的过度积累,进而影响种子活力.同时利用老化5 d后的水稻种胚蛋白进行双向电泳,分析RNAi干扰种子老化过程中异构天冬氨酸过度积累对于种胚蛋白的影响,鉴定到与种子老化相关的氧化胁迫相关蛋白、糖酵解以及热激蛋白分子伴侣等蛋白.为进一步研究OsPIMT1表达对于种子老化后细胞各代谢途径的影响奠定了基础.

水稻早衰突变体w14的生理学特性分析及其基因的精细定位

水稻叶片早衰对水稻的产量及品质均有重要影响,研究早衰的机理对于延缓衰老和选育良种具有重要意义.本文以甲基磺酸乙酯(ethylmethylsulfone,EMS)诱变野生型粳稻品种云引(Yunyin,YY)获得的水稻早衰突变体w14为材料,研究了早衰突变体全生育期的生理及组织亚显微结构的变化.研究结果表明,突变体从分蘖盛期开始表现出生长势弱,生长速度慢,抽穗期出现明显的叶片早衰症状,最终突变体整株呈现衰老枯萎.亚显微结构观察表明,突变体出现明显衰老表型后,叶片表面泡状细胞破损,细胞结构排列松散,完整性降低,突变体细胞中细胞核数目明显减少,胞内细胞核降解.分别在衰老症状出现前后(苗期和成株期)对突变体和野生型的可溶性蛋白、叶绿素、脂质过氧化物(lipid peroxidation,LPO)及丙二醛(malondialdehyde,MDA)含量和过氧化物酶(peroxidase,POD)、超氧化物歧化酶(superoxide dismutase,SOD)及过氧化氢酶(catalase,CAT)活性进行了系统检测,表明突变体的衰老症状可能主要是由于组织CAT的活性下降导致活性氧(reactive oxygen species,ROS)的累积引起.通过图位克隆方法将目的基因w14定位于水稻3号染色体上,位于InDel标记3-7和3-9之间大约76 kb的物理区间内.该区间内共包含8个候选基因,为该突变性状基因w14的克隆、功能研究和深入了解该突变体早衰的机制奠定了基础.

粳稻云引稻瘟病抗性近等基因系与免疫应答相关的LRR-RLKs差异基因分析

在广谱抗稻瘟病品种云引与普感稻瘟病品种丽江新团黑谷(Lijiangxintuanheigu,LTH)构建的近等基因系抗、感病子代基因组重测序的差异基因中,从与免疫应答(immune response)相关的分类单元里得到8个基因序列有差异的基因.它们都为编码富含亮氨酸重复序列的类受体蛋白激酶基因,并聚集于11号染色体的邻近位置,且与已知的白叶枯病抗性基因Xa21具有一定同源性.为进一步探究这些类受体蛋白激酶类基因在稻瘟病抗性中可能发挥的功能,我们分析了这些基因的结构、进化及抗感子代间的序列差异类型,同时还分别采用离体和喷雾接菌的方式对云引和LTH进行稻瘟病接种并取样.通过实时荧光定量PCR(quantitative real time polymerase chain reaction,q RT-PCR)发现,部分基因能受到稻瘟病菌的诱导,推测它们可能在水稻对抗稻瘟病病菌中发挥一定作用,为进一步挖掘稻瘟病相关抗性基因奠定基础.

Proteomic analysis of blast-resistant near-isogenic lines derived from japonica rice, var. Yunyin, infected with Magnaporthe oryzae

Rice blast is one of the most devastating diseases in the world and outbreaks occur frequently.The differences in protein expression between blast resistant and susceptible near-isogenic lines(NILs)of japonica rice var.Yunyin infected with Magnaporthe oryzae were analyzed using proteomics,indicated that 67 different proteins were identified from 75 obtained proteins using the matrixassisted laser desorption/ionization time-of-flight mass spectrometry technique.Seven specific expression proteins,43 up-regulated proteins and 17 down-regulated proteins were identified among the 67 proteins.The bioinformatical analysis demonstrated that these 67 different proteins were involved in many biological physiological processes including five proteins related to photosynthesis,25 proteins related to metabolism,six proteins related to antioxidants,10 proteins related to protein synthesis and modification,five proteins related to signal transduction,four proteins related to adversity stress and 12 non-functional proteins.These identified proteins were directly or indirectly related to stress.Five proteins related to different physiological processes were selected.Their cDNA sequences were predicted and their expression patterns were analyzed using real-time PCR,demonstrated that the genes would response to M.oryzae and the response blindingly different between blast resistant and blast susceptible NILs.

SH3P2,an SH3 domain-containing protein that interacts with both Pib and AvrPib,suppresses effector-triggered,Pib-mediated immunity in rice

Plants usually keep resistance(R)proteins in a static state under normal conditions to avoid autoimmunity and save energy for growth,but R proteins can be rapidly activated upon perceiving pathogen invasion.Pib,the first cloned blast disease R gene in rice,encoding a nucleotide-binding leucine-rich repeat(NLR)protein,mediates resistance to the blast fungal(Magnaporthe oryzae)isolates carrying the avirulence gene AvrPib.However,the molecular mechanisms about how Pib recognizes AvrPib and how it is inactivated and activated remain largely unclear.In this study,through map-based cloning and CRISPR-Cas9 gene editing,we proved that Pib contributes to the blast disease resistance of rice cultivar Yunyin(YY).Furthermore,an SH3 domain-containing protein,SH3P2,was found to associate with Pib mainly at clathrin-coated vesicles in rice cells,via direct binding with the coiled-coil(CC)domain of Pib.Interestingly,overexpression of SH3P2 in YY compromised Pib-mediated resistance to M.oryzae isolates carrying AvrPib and Pib-AvrPib recognition-induced cell death.SH3P2 competitively inhibits the self-association of the Pib CC domain in vitro,suggesting that binding of SH3P2 with Pib undermines its homodimerization.Moreover,SH3P2 can also interact with AvrPib and displays higher affinity to AvrPib than to Pib,which leads to dissociation of SH3P2 from Pib in the presence of AvrPib.Taken together,our results suggest that SH3P2 functions as a“protector”to keep Pib in a static state by direct interaction during normal growth but could be triggered off by the invasion of AvrPib-carrying M.oryzae isolates.Our study reveals a new mechanism about how an NLR protein is inactivated under normal conditions but is activated upon pathogen infection.