水稻淡褐斑叶突变体lbsl1的遗传分析与基因定位

 通过EMS诱变籼稻品种IR64获得一个稳定遗传的淡褐色斑点叶突变体lbsl1（light brown spotted leaf 1）。在自然条件下,突变体播种后10~14 d,叶片上出现淡褐色斑点,随后逐渐扩散至全叶,第1叶至剑叶上均有淡褐色斑,为全生育期性状。斑点性状的表达对株高、生育期、结实率和千粒重等农艺性状具有显著的影响。遗传分析结果表明,该淡褐色斑点叶性状受一个隐性核基因控制。将突变体lbsl1与正常叶色水稻Morobereken杂交构建F2定位群体,利用SSR标记,最终将该淡褐叶基因lbsl1(t)定位在第6染色体短臂上一个约130 kb的区段上。定位的结果和发展的群体为该基因的进一步精细定位和克隆奠定了基础。     

水稻突变体的创制与遗传分析

本文综述了水稻突变体的创制与遗传分析、基因定位的研究进展,包括1698个水稻突变体／基因的分类和已公布的30个图位克隆的水稻基因。并提出了利用水稻突变体的展望。     

水稻叶色突变基因的遗传研究进展

介绍了水稻叶色突变体的类型及来源,综述了水稻叶色突变相关基因的发掘、定位和克隆进展情况,从细胞核遗传的突变、细胞质遗传的突变以及核质互作的突变等方面详细阐述了水稻叶色突变的遗传机理,并对其作为标记性状在育种上的应用提出了展望,旨在为水稻叶色突变体的研究与应用提供参考。     

水稻类病变突变体性状及分子机理研究进展

类病变突变体是植物在无显著逆境或损伤情况下以及未受到病原物危害时叶片上自然形成的类似病斑的一类突变体。水稻类病变突变体的产生常伴有抗病性的增强,其中涉及到防御相关基因的表达。相关研究主要集中于各种突变体的定位和克隆以及突变体的抗病性和抗病机制。综述了水稻类病变突变基因的性状及抗病性的研究进展,特别是对水稻类病变突变体形成原因、遗传特性、调控途径进行了梳理,并提出对水稻抗病育种的展望,以期为进一步分析类病变突变体的各种机制奠定理论基础,并为水稻育种提供参考。     

水稻温敏感叶色突变体研究进展

温度是影响水稻生长发育的一个重要因素,由温度引起水稻叶色改变的一类突变体统称为水稻温敏感叶色突变体。探讨温度影响水稻叶色的机理,对促进水稻遗传改良与高产育种具有重要意义。对已发掘的水稻温敏感突变体在温度对突变体的表型影响、基因定位及克隆、分子作用机理和育种利用及其研究进展等方面进行了分类讨论。     

水稻斑点叶突变体hm197的鉴定及其基因定位

通过双环氧丁烷 (diepoxybutane)诱变籼稻品种IR64获得遗传稳定的水稻褐色斑点叶突变体hm197。在自然条件下,该突变体褐色斑点自播种后10周开始于叶尖出现,而后慢慢扩散至全叶。遗传分析表明,该褐色斑点性状受一对隐性核基因控制,暂名spl^hm197,并将其定位在第4染色体长臂上140 kb的区段内。与野生型IR64相比,突变体株高、结实率和千粒重等农艺性状均显著下降。遮光处理表明,hm197褐色斑点的形成受自然光照的诱导。此外,hm197光合色素含量和光合效率也比野生型显著降低。组织化学分析表明,突变体中有过氧化氢和大量超氧阴离子O_{2 ?}的沉积。与IR64相比,hm197叶片中清除氧自由基酶系统中SOD和APX活性极显著上升,其余均极显著下降,同时伴随总可溶蛋白含量下降以及MDA含量上升,hm197表现出早衰迹象。抗病性鉴定表明,与野生型相比突变体对白叶枯病菌的抗性显著增强。     

稻瘟病抗性基因研究进展与展望

稻瘟病严重影响水稻的产量和品质,抗病品种的培育和种植是控制该病害最经济有效的措施。当今水稻抗稻瘟病育种的关键是抗性基因的发掘和合理利用。据报道,至少有68个稻瘟病位点的83个主效基因得到定位,其中23个被成功克隆。概述了稻瘟病的抗性遗传、稻瘟病抗性基因定位与克隆及抗性基因在育种上的应用研究进展,并对稻瘟病抗性育种面临的问题和应用前景进行了讨论和展望。     

白叶枯病菌xopXoo基因在致病性中的作用

辣椒斑点病菌(Xanthomonas campestris pv. vesicatoria,Xcv)在非寄主烟草上的过敏反应与xopX基因有关,但在白叶枯病菌(Xanthomonas oryzae pv. oryzae, Xoo)基因组中并未标注xopX同源基因的功能。为研究白叶枯病菌中xopX同源基因在致病性中的作用,对白叶枯病菌的xopXoo基因进行了克隆和突变,并对xopXoo突变体在非寄主烟草上的过敏反应、水稻苗期的水浸症状以及成株期的致病性和病菌生长能力进行了分析。测定结果显示,xopXoo基因突变并不改变白叶枯病菌在烟草上激发过敏反应和在水稻上产生水浸症状能力,但突变菌株在成株期水稻上的致病性和菌体生长能力显著下降。遗传互补能够恢复xopXoo突变体的致病性和菌体生长能力,表明xopXoo是白叶枯病菌的致病性基因。还对白叶枯病菌激发非寄主烟草产生过敏反应的可能基因进行了讨论。     

水稻矮秆突变体Zj88d的鉴定与基因定位

 用甲基磺酸乙酯诱变处理常规粳稻浙粳88,获得了矮秆水稻突变体Zj88d,多代自交稳定遗传。遗传分析表明突变体Zj88d的矮秆性状受一对隐性核基因控制。采用图位克隆方法,将目的基因定位在水稻第7染色体短臂末端7 44w和RM5344间的603 kb区间。排查该区间包含的100个候选基因,发现已克隆的矮秆基因OSH15也位于其中。测序结果显示,突变体Zj88d中的OSH15基因在第2内含子最末位发生“g→a”单碱基突变。     

水稻皱曲叶突变体rtl1的遗传分析与分子定位

 水稻扭曲叶突变体rtl1是利用甲基磺酸乙酯（EMS）诱变粳稻品种日本晴获得的。在苗期,该突变体的叶片就表现出皱缩和扭曲状。将该突变体分别与籼稻品种台中本地1号和浙辐802进行配组。遗传分析表明该突变体性状受1对隐性单基因控制。通过混合分离法,找到了位于第4染色体上的紧密连锁SSR标记RM1155,通过新发展的多态性STS标记,最终将该基因定位在STS标记T1591和SSR标记RM1359之间,其遗传距离分别为0.48和0.96 cM。为进一步克隆该基因打下了基础。     

Spotted-Leaf Mutants of Rice(Oryza sativa)

Many rice spotted-leaf(spl) mutants are ideal sources for understanding the mechanisms involved in blast resistance,bacterial blight resistance and programmed cell death in plants.The genetic controls of 50 spotted-leaf mutants in rice have been characterized and a few spotted-leaf genes have been isolated as well.This article reviews the origin,genetic modes,isolation and characterization of spotted-leaf genes responsible for their phenotypes,and their resistance responses to main rice diseases.     

Genetic Analysis and Gene Mapping of Light Brown Spotted Leaf Mutant in Rice

A light brown spotted-leaf mutant of rice was isolated from an ethane methyl sulfonate (EMS)- induced IR64 mutant bank. The mutant, designated as lbsl1 (light brown spotted-leaf 1), displayed light brown spot in the whole growth period from the first leaf to the flag leaf under natural summer field conditions. Agronomic traits including plant height, growth duration, number of filled grains per panicle, seed-setting rate and 1000-grain weight of the mutant were significantly affected. Genetic analysis showed that the mutation was controlled by a single recessive gene, tentatively named lbsl1(t), which was mapped to the short arm of chromosome 6. By developing simple sequence repeat (SSR) markers, the gene was finally delimited to an interval of 130 kb between markers RM586 and RM588. The lbsl1(t) gene is likely a novel rice spotted-leaf gene since no other similar genes have been identified near the chromosomal region. The genetic data and recombination populations provided will facilitate further fine-mapping and cloning of the gene.     

Characterization of a Novel Gain-of-Function Spotted-Leaf Mutant with Enhanced Disease Resistance in Rice

We here reported the identification and characterization of a novel gain-of-function spotted-leaf 26(Spl26) mutant from an ethylmethylsulfone(EMS)-induced rice cultivar IR64. Spl26 displayed reddishbrown lesions that firstly appeared on the leaf tips at the early tillering stage and spread gradually downward to cover the whole leaf blades that wilted subsequently. The lesion development was lightdependent under natural conditions. Spl26 exhibited impaired photosynthetic capacity with decreased chlorophyll content and lowered photosynthetic parameters which ultimately led to the poor performance of agronomic traits. Severe cell death occurred in Spl26 in accompany with increased malonaldehyde level and membrane ion leakage rate, elevated reactive oxygen species(ROS) accumulation, altered ROS scavenging activities, increased DNA fragmentation and decreased soluble protein levels. Defense responses were activated in Spl26 with enhanced resistance to rice bacterial blight, up-regulation of defense response genes and altered endogenous hormone levels. The spotted-leaf phenotype is controlled by a single dominant nuclear gene localized to a 305 kb region between RM5490 and In Del42 on the short arm of chromosome 7. The data suggested that Spl26 is a novel gain-of-function spotted-leaf mutant with enhanced bacterial disease resistance and immunity-associated premature leaf senescence and would provide the basis for cloning of the target gene.     

应用DNA标记分析稻飞虱的抗性基因

简要地回顾了水稻抗飞虱的遗传位点定位和作图的新进展.来自具有不同基因组的野生稻渗入系的4个抗褐飞虱基因Bph 1、 bph 2、 bph 4和Bph 9,以及4个暂定名抗褐飞虱基因Bph 10(t)、bph 11(t)、bph 12(t)和Bph 13(t),目前已被定位于水稻12条染色体中的5条.其中,Bph 1、 bph 2、 Bph 9和Bph 10(t)在水稻第12染色体的长臂上形成1个连锁区段,位于bph 2位点附近约25 cM.检测出几个对田间抗性和杀卵作用有影响的QTL.抗白背飞虱基因Wbph 1、 Wbph 2和Wbph 6(t)已经或暂时定位了.粳稻中对白背飞虱具有杀卵抗性的QTL已进行了详细的分析,在第6染色体的短臂上检测到有效的QTL,在同一位点鉴定出1个显性的杀卵基因Ovc.在杀卵基因Ovc存在时,第1染色体上的1个QTL和第5染色体上的2个QTL增加白背飞虱的卵死亡率.用DNA标记进行QTL作图可以加深人们对作物抗虫性中复杂的生理和遗传机理的理解.标记辅助选择可以加速培育具多基因抗虫性的作物,还可以将野生种中的有利抗虫特性转入改良品种中,增加作物抗虫性的持久性和遗传多样性.     

野生稻优良基因资源的研究与应用进展

野生稻是栽培稻的野生近缘种,作为重要的基因资源,具有诸多的优良性状,如野生稻对病虫害的抗性、对各种逆境的耐受性以及胞质雄性不育等,已被广泛应用于现代栽培稻的育种改良,成为栽培稻遗传改良的丰富基因源和不可替代的物质基础。本文综述了野生稻优良基因的发掘和种质资源的利用现状,总结了野生稻保护和利用目前存在的问题,并对其在水稻育种中的应用潜力做出了展望。     

Strategy for Use of Rice Blast Resistance Genes in Rice Molecular Breeding

Rice blast is one of the most destructive diseases affecting rice production worldwide. The development and rational use of resistant varieties has been the most effective and economical measure to control blast. In this review, we summarized the cloning and utilization of rice blast resistance genes, such as Pi1, Pi2, Pi9, Pi54, Pigm and Piz-t. We concluded that three main problems in the current breeding of rice blast resistance are: availability of few R(resistance) genes that confer resistance to both seedling and panicle blast, the resistance effect of pyramided lines is not the result of a simple accumulation of resistance spectrum, and only a few R genes have been successfully used for molecular breeding. Therefore, novel utilization strategies for rice blast R genes in molecular breeding were proposed, such as accurately understanding the utilization of R genes in main modern rice varieties, creating a core resistant germplasm with excellent comprehensive traits, screening and utilizing broadspectrum and durable resistance gene combinations. Lastly, the trends and possible development direction of blast resistance improvement were also discussed, including new genes regulating resistance identified via GWAS(genome-wide association study) and improving rice blast resistance using genetic editing.     

水稻稻瘟病抗性基因及稻瘟病菌无毒基因研究进展

稻瘟病是水稻生产上最为重要的病害之一,可引起大幅度减产.水稻—稻瘟病菌互作机制是目前研究植物与病原物互作的模式系统.关于稻瘟病抗性基因、稻瘟病菌无毒基因的研究取得显著进展,为水稻抗稻瘟病分子标记辅助育种、基因工程育种及稻瘟病绿色防治提供了广阔的前景.对稻瘟病菌侵染机制、稻瘟病抗性基因定位与克隆、抗病基因和无毒基因的互作...