云南野生稻抗白叶枯病类Xa21基因的鉴定

水稻白叶枯病是水稻生产上的主要细菌病害之一。从野生稻中发掘优异的水稻白叶枯病抗性材料,可以拓宽栽培稻抗白叶枯病遗传基础。经过温室接菌鉴定和PCR标记分析,对云南野生稻进行Xa21基因的检测鉴定。温室接菌鉴定表明,云南野生稻对广谱致病小种PX099及云南强致病菌Y8具有较好的抗性能力,特别是疣粒野生稻对致病菌株达到免疫程度;PCR标记分析表明,云南野生稻不含有Xa21基因,但含有与Xa21基因某些区域同源的片段。本研究结果为寻找新的抗源材料及快速发掘利用云南野生稻中的抗白叶枯病基因提供理论依据。     

云南野生稻中的抗白叶枯病基因Xa21的鉴定

水稻白叶枯病是水稻生产上的主要细菌病害之一。从野生稻中发掘优异的水稻白叶枯病抗性材料,可以拓宽栽培稻抗白叶枯病遗传基础。经过温室接菌鉴定和PCR标记分析,对云南野生稻进行Xa21基因的检测鉴定。温室接菌鉴定表明,云南野生稻对广谱致病小种PX099及云南强致病菌Y8具有较好的抗性能力,特别是疣粒野生稻对致病菌株达到免疫程度;PCR标记分析表明,云南野生稻不含有Xa21基因,但含有与Xa21基因某些区域同源的片段。本研究结果为寻找新的抗源材料及快速发掘利用云南野生稻中的抗白叶枯病基因提供理论依据。     

水稻品种对白背飞虱的抗源筛选及其抗性遗传分析

通过抗性鉴定,筛选出6个抗白背飞虱的国内品种:鬼衣谷、大花谷、大齐谷、便谷、滇瑞336.3和HA 79317-7(前4个品种均系云南地方品种)。遗传分析证明,这6个品种对白背飞虱的抗性均受单显性基因控制。HA 79317-7的抗性基因与Wbph1等位,滇瑞336-3的抗性基因与Wbph2等位。鬼衣谷、大齐谷、大花谷和便谷的抗性基因均与Wbph1、Wbph2非等位。它们与Wbph3、Wbph5的等位关系还有待进一步研究。     

云南水稻品种冬糯的白叶枯病抗性基因定位研究——Ⅰ.抗病基因的初级三体分析定位

本文研究了云南稻品种冬糯对我国水稻白叶枯病(Xanthomonas campestris pv. oryxac)菌系“江陵691”的抗性遗传和抗病基因与初级三体额外染色体的关系。冬糯对白叶枯病菌系“江陵691"的抗性受一对隐性基因控制(xa-k);该抗病基因分别与Xa-a、xa-c、Xa-(?)、Xa-f和Xa-i不等位,并呈独立遗传;与Xa-g不等位,呈连锁遗传,重组值为28.7%。冬糯抗病基因与Triplo-7的额外染色体即第7染色体有关,推定冬糯所带的抗病基因位于第7染色体上。以IR36为遗传背景的初级三体系带有一对显性抗白叶枯病基因,该抗病基因位于第11染色体上。     

来自中国云南野生稻的抗稻瘟病遗传资源

与Pi-ta^＋等位基因相比,含有Pi-ta^＋等位基因的栽培稻具有抗稻瘟病特性。本研究用基因序列分析的方法检测了来自云南的不同栽培稻品种以及不同类型和来源的普通野生稻种和非洲长雄蕊野生稻种中的Pi-ta^＋基因,发现Pi-ta地基因在稻属植物中高度保守,但Pi-ta^＋等位基因的存在极其稀有。在所检测的栽培稻和野生稻中仅有来源于云南景洪的直立型普通野生稻中含有Pi-ta^＋等位基因。而与Pi-ta基因相比,另一个水稻抗稻瘟病基因Pib,经部分同源序列克隆及测序发现该基因在不同野生稻中的变异较大。在所克隆的不同野生稻Pib基因同源序列中,也只有来源于直立型普通野生稻的序列能按该基因的开放阅读框进行正常翻译。对不同类型普通野生稻的抗稻瘟病能力的初步鉴定结果表明,直立型普通野生稻对供试的本地稻瘟病生理小种具有较强抗性,其抗性可能源于所含的Pi=ta^＋等位基因及可能有功能的Pib基因。由于普通野生稻与栽培稻同属AA基因组型,因此,云南直立型普通野生稻可通过杂交育种或基因工程途径用于栽培稻的抗稻瘟病性能改良。     

中国发现水稻新基因

据最新出版的《水稻基因通讯》报道,中国水稻研究所博士李西明等科研人员,从云南地方品种鬼衣谷等材料中研究发现的1个名为抗白背飞虱的新基因Wbph6(t),已经被国际水稻基因命名组织正式命名为Wbph6,这是中国在水稻抗白背飞虱研究领域中注册的第1个抗性基因。国际水稻基因命名组织称,此前国际上关于水稻白背飞虱抗性基因命名的抗性基因有5个,它们分别是Wbph1、 Wbph2、Wbph3、Wbph4和Wbph5。中国水稻研究所的这一发现使白背飞虱的抗性标准基因上升到6个。     

白叶枯病菌胁迫下云南普通野生稻SSH文库的构建及抗病相关基因分析

以云南普通野生稻为材料,利用抑制差减杂交技术（SSH）,构建了白叶枯病菌胁迫的云南普通野生稻特异表达基因的差减文库.通过对文库所有阳性单克隆进行测序,聚类分析后共获得494条高质量的表达序列标签（EST）.经过BlastN分析,有417条与已知功能的序列有较高同源性;经BlastX分析,有104条EST与未知功能蛋白或假定蛋白有较高相似性,49条EST未能找到同源匹配,341条EST与已知功能蛋白有较高同源性.初步分析发现,这些基因主要涉及能量代谢、蛋白质代谢、核酸代谢、防御与抗逆应答反应、信号转导、光合作用及膜运输等代谢过程.使用半定量RT-PCR研究了7个可能与白叶枯病抗性相关的EST序列在云南普通野生稻对照和白叶枯病菌处理的叶片中的表达情况,并获得这些基因的表达谱.结果发现,克隆编号为OR7,OR68和OR826的EST受白叶枯病菌胁迫诱导上调表达,其中OR826 EST在蛋白数据库中无同源序列,可能是一类新的白叶枯病抗性基因,而组成型表达的OR143 EST在对照和接菌处理的叶片中均能检测到其mRNA的表达,但其表达量在白叶枯病菌胁迫48 h后逐渐增强,推测这些基因直接参与了云南普通野生稻抗病防御反应.本研究为从云南普通野生稻中发掘和克隆新的白叶枯病抗性基因提供了理论依据,为进一步研究云南普通野生稻抗白叶枯病的分子机制奠定了基础.     

硬粒小麦—粗山羊草双二倍体白粉病抗性的遗传分析与基因推导

对９９份硬粒小麦－粗山羊草双二倍体用北京地区流行的１５号粉菌生理小种进行了白粉病抗性鉴定,筛选出１１个苗期抗病的双二倍体材料和２个全生育期抗病的材料Ｍ５３和Ｍ８１。对53几Ｍ８１及其硬粒小麦和粗山羊草亲本进行的抗白粉病鉴定结果表明,其抗性来源于粗山羊草,与Ｍ５３和Ｍ８１具有相同硬粒小麦亲本、不同粗山羊草亲本双二倍体的抗性结果也表明抗性基因来源于粗山羊草,对Ｍ５３和Ｍ８１的抗性遗传分析表明,它们均携带１个单显性抗病基因,用１４个白粉菌生理小种对已知抗病基因品系与Ｍ５３和Ｍ８１两份待测材料进行接种鉴定,结果表明,Ｍ５３和Ｍ８１与已知基因的抗菌谱均不相同,Ｍ５３与Ｍ８１的抗菌谱也不相同,说明Ｍ５３和Ｍ８１各自分别携带１个新的显抗性白粉病基因。     

转座子Tn233(CH)中链霉素和磺胺抗性基因的精确定位

重组质粒pTH3和pTB3分别是转座子Tn233(CH)中含Sm抗性基因和同时含Sm和Su抗性基因的DNA片段克隆到pBR322上得到的。将Tn5转座到pTH3或pTB3上,分离到一些对Sm敏感或仍有抗性的突变株。比较变种及亲本质粒DNA的限制图谱,测出了Tn5的插入位点,并测得pTH3的Sm抗性基因在大肠杆菌极大细胞中指令一个分子量约为32K的多肽合成。据此我们绘制了pTH3中Sm抗性基因的位置与长度。用相似方法也绘制出了Su抗性基因在pTB3上的位置与长度。利用Tn5的极性效应,推测Tn233(CH)中Su和Sm抗性基因不构成一个操纵子。     

番茄抗黄化曲叶病毒育种研究进展

本文分别对近年番茄抗黄化曲叶病毒的传统育种、分子辅助育种、基因工程育种进展进行了综述.栽培番茄均不抗番茄黄化曲叶病毒,所以传统育种采用从野生近缘种中筛选抗性材料,以其为亲本与栽培番茄进行杂交来获得抗性;野生近缘种中的抗性位点Ty-1、Ty-2和Ty-3及一些QTLs先后被定位,也筛选出了可鉴定Ty-1基因的SSR-47标记及鉴定Ty-3的SCAR标记;通过转基因技术获得抗性是研究热点之一,目前转入番茄后表现出抗性的序列有TYLCV病毒的CP基因、尺EP基因的部分序列或反义序列、不编码的保守序列以及源于白粉虱的GroEL基因.同时讨论了今后的主要发展方向.     

Microsatellite and sequence-tagged site markers diagnostic for the rice bacterial leaf blight resistance gene xa-5

 Microsatellite and sequence-tagged site (STS) markers tightly linked to the bacterial leaf blight (BLB) resistance gene xa-5 were identified in this study. A survey was conducted to find molecular markers that detected polymorphisms between the resistant (IRBB5) and susceptible (‘IR24’) nearly isogenic lines for xa-5, and between Chinsurah Boro II (CBII), an alternative source of xa-5, and a widely planted variety (‘IR64’) that lacks xa-5. Two F₂ populations, from the crosses ‘IR24’×IRBB5 and CBIIבIR64’, were used to estimate linkage based on marker genotype and reaction to disease inoculation with Xanthomonas oryzae pv. oryzae. Two RFLP clones, RZ390 and RG556, were found to co-segregate with xa-5 and were converted into STS markers. A microsatellite marker, RM390, was developed based on a simple sequence repeat in the 5′ untranslated region of the cDNA probe, RZ390, and found to co-segregate with resistance. Two other microsatellites, RM122 and RM13, were located 0.4 cM and 14.1 cM away from xa-5. A germplasm survey of diverse lines containing BLB resistance genes using automated fluorescent detection indicated the range of allelic diversity for each of the microsatellite loci linked to xa-5 and confirmed their usefulness in following genes through the narrow crosses typical of a breeding program. The limited number of alleles observed at the microsatellite loci linked to the resistance gene in 35 xa-5-containing accessions suggested either a single ancestral origin or a few independent origins of the xa-5 gene. PCR-based markers, like the ones developed in this study, are economical and easy to use, and have applicability in efforts to pyramid the recessive xa-5 gene with other BLB resistance genes. Received: 27 September 1996/Accepted: 7 February 1997     

RAPD and RFLP mapping of the bacterial blight resistance gene xa-13 in rice

Bacterial blight (BB) caused by Xanthomonas oryzae pv oryzae (Xoo) is one of the most serious diseases of rice. The recessive gene xa-13 confers resistance to Philippine race 6 of Xoo. To tag xa-13 with molecular markers, RAPD analysis was conducted with the combined use of near-isogenic lines and bulked segregant analysis. From the survey of 260 arbitrary 10-nucleotide primers, one primer (OPAC05) was detected to amplify specifically a 0.9-kb band from the DNA of susceptible plants. The distance between the RAPD marker OPAC05-900 and xa-13 was estimated to be 5.3 cM. The RAPD marker was then mapped on chromosome 8 using a mapping population of doubled haploid lines derived from the cross of IR64/Azucena. The linkage between RFLP markers and the RAPD marker was analyzed using an F₂ population of 135 plants derived from a cross between a near-isogenic line for xa-13, IR66699-5-5-4-2, and IR24. No recombinants were found between RZ28 and CDO116 and their distance from xa-13 was estimated to be 4.8 cM. RG136 was located at 3.7 cM on the other side of xa-13. The mapping of xa-13 with closely linked DNA markers provides the basis for marker-aided selection for rice improvement.Department of Agronomy, South China Agricultural University, Guangzhou, China     

Pyramiding of bacterial blight resistance genes in rice: marker-assisted selection using RFLP and PCR

 DNA marker-assisted selection was used to pyramid four bacterial blight resistance genes, Xa-4, xa-5, xa-13 and Xa-21. Breeding lines with two, three and four resistance genes were developed and tested for resistance to the bacterial blight pathogen (Xanthomonas oryzae pv. oryzae). The pyramid lines showed a wider spectrum and a higher level of resistance than lines with only a single gene. To speed up the gene pyramiding process and to facilitate future marker-aided selection, we developed PCR markers for the two recessive genes, xa-5 and xa-13, and used these to survey a range of rice germplasm. The results of the germplasm survey will be useful for the selection of parents in breeding programs aimed at transferring these bacterial blight resistance genes from one varietal background to another. Received: 6 December 1996/Accepted: 20 December 1996     

水稻细菌性条斑病和白叶枯病抗性遗传研究

分析了Ｈａｓｈｉｋａｌｍｉ,Ｄｕｌａｒ和９０ＩＲＢＢＮ４４三个抗源品种对水稻细菌性条斑病Ｓ－１０３菌株和白叶枯病Ｐ１菌系的抗性遗传。结果表明,Ｈａｓｈｉｋａｌｍｉ和Ｄｕｌａｒ对Ｓ－１０３的抗性均由２对隐性基因所控制,９０ＩＲＢＢＮ４４则带有１对隐性抗性基因。经等位性测定表明,Ｈａｓｈｉｋａｌｍｉ和Ｄｕｌａｒ的２对基因中至少有１对是等位的,但它们与９０ＩＲＢＢＮ４４的１对基因均不等位。３个抗源品种对Ｐ１的抗性都受１对隐性基因控制,该基因与ｘａ－５等位。连锁遗传分析表明,Ｈａｓｈｉｋａｌｍｉ和Ｄｕｌａｒ对Ｓ－１０３的２对抗细条病基因中的１对与ｘａ－５相连锁,而９０ＩＲＢＢＮ４４的１对抗性基因与ｘａ－５呈独立遗传。本文还就开展水稻抗细菌性条斑病育种进行了讨论。     

水稻花粉株系白叶枯病抗性遗传

本文研究了粳稻感病品种沈农1033分别与7个抗白叶枯病的品种（其中汕稻有75－34,辛尼斯,1R20;粳稻有早生爱国3号,邳早15,蚌珠芒,爪哇14）杂交,F花粉培养并观察了花粉株系第二代（H2）的抗性转移及遗传表现和花粉株系第三代,第四代抗性稳定性,572个株系的性状是整齐一致的,占95．5％,其中抗病（高抗和中抗）株系有376个,占62．9％,感病系有196个,占32．7％,表现有分离的杂合系约4．5％,不同组合的H2与F2群体中抗,感反应变异幅度不同,对同一组合不同熟期花粉株系其生育日数与抗病性间存在着极显著相关性,生育期长的株系抗性较强。花粉再生植株后代H2在生育期,株高,穗长,粒重等性状上十分多样,白叶枯病抗性遗传分析结果表明,在4个组合中抗性均由1个显性上位基因控制,抗病性广义遗传力在80％以上。杂种花粉植株第二,第三,第四代的农艺性状以及白叶枯病的抗性持续地稳定,不因世代的增加其性状的整齐度不降,抗性减弱。     

Tagging and combining bacterial blight resistance genes in rice using RAPD and RFLP markers

Four genes of rice,Oryza sativa L., conditioning resistance to the bacterial blight pathogenXanthomonas oryzae pv.oryzae (X. o. pv.oryzae), were tagged by restriction fragment length polymorphism (RFLP) and random amplified polymorphic DNA (RAPD) markers. No recombinants were observed betweenxa-5 and RFLP marker lociRZ390, RG556 orRG207 on chromosome 5.Xa-3 andXa-4 were linked to RFLP locusXNpb181 at the top of chromosome 11, at distances of 2.3 cM and 1.7 cM, respectively. The nearest marker toXa-10, also located on chromosome 11, was the RAPD locusO07 ₂₀₀₀ at a distance of 5.3 cM. From this study, the conventional map [19, 28] and two RFLP linkage maps of chromosome 11 [14, 26] were partially integrated. Using the RFLP and RAPD markers linked to the resistance genes, we selected rice lines homozygous for pairs of resistance genes,Xa-4 +xa-5 andXa-4 +Xa-10. Lines carryingXa-4 +xa-5 andXa-4 +Xa-10 were evaluated for reaction to eight strains of the bacterial blight pathogen, representing eight pathotypes and three genetic lineages. As expected, the lines carrying pairs of genes were resistant to more of the isolates than their single-gene parental lines. Lines carryingXa-4 +xa-5 were more resistant to isolates of race 4 than were either of the parental lines (quantitative complementation). No such effects were seen forXa-4 +Xa-10. Thus, combinations of resistance genes provide broader spectra of resistance through both ordinary gene action expected and quantitative complementation.     

Durable resistance to two leaf blights in two maize inbred lines

Summary It has been determined that the occurrence of durable resistance as defined by Johnson and Kranz operates in maize inbred lines CM104 and CM105 against the leaf blight pathogens Setosphaeria turcica (= Exserohilum turcicum) and Drechslera maydis (=Cochliobolus heterostrophus), by analyzing data for 16 and 14 years, respectively. Essentially the methodology estimated the longevity of cultivar resistance by determining whether the regression coefficient of linear regression with years of testing and mean disease intensity is zero or not significantly different from zero. The values for both Turcicum Leaf Blight and Maydis Leaf Blight were not significantly different from zero. The resistant inbred lines have been used in hybrid combinations and have the potential to transmit this resistance to progenies in hybrid combinations that are governed by additive gene action.     

Identification of a family of avirulence genes from Xanthomonas oryzae pv. oryzae.

Races of Xanthomonas oryzae pv. oryzae, the causal agent of bacterial blight of rice, interact with cultivars of rice in a gene-for-gene specific manner. Multiple DNA fragments of various sizes from all strains of X. o. pv. oryzae hybridized with avrBs3, an avirulence gene from Xanthomonas campestris pv. vesicatoria, in Southern blots; this suggests the presence of several homologs and possibly a gene family. A genomic library of a race 2 strain of X. o. pv. oryzae, which is avirulent on rice cultivars carrying resistance genes xa-5, Xa-7, and Xa-10, was constructed. Six library clones, which hybridized to avrBs3, altered the interaction phenotype with rice cultivars carrying either xa-5, Xa-7, or Xa-10 when present in a virulent race 6 strain. Two avirulence genes, avrXa7 and avrXa10, which correspond to resistance genes Xa-7 and Xa-10, respectively, were identified and partially characterized from the hybridizing clones. On the basis of transposon insertion mutagenesis, sequence homology, restriction mapping, and the presence of a repeated sequence, both genes are homologs of avirulence genes from dicot xanthomonad pathogens. Two BamHI fragments that are homologous to avrBs3 and correspond to avrXa7 and avrXa10 contain a different number of copies of a 102-bp direct repeat. The DNA sequence of avrXa10 is nearly identical to avrBs3. We suggest that avrXa7 and avrXa10 are members of an avirulence gene family from xanthomonads that control the elicitation of resistance in mono- and dicotyledonous plants.     

Genetic Diversity of Xanthomonas oryzae pv. oryzae in Asia

Restriction fragment length polymorphism and virulence analyses were used to evaluate the population structure of Xanthomonas oryzae pv. oryzae, the rice bacterial blight pathogen, from several rice-growing countries in Asia. Two DNA sequences from X. oryzae pv. oryzae, IS1112, an insertion sequence, and avrXa10, a member of a family of avirulence genes, were used as probes to analyze the genomes of 308 strains of X. oryzae pv. oryzae collected from China, India, Indonesia, Korea, Malaysia, Nepal, and the Philippines. On the basis of the consensus of three clustering statistics, the collection formed five clusters. Genetic distances within the five clusters ranged from 0.16 to 0.51, and distances between clusters ranged from 0.48 to 0.64. Three of the five clusters consisted of strains from a single country. Strains within two clusters, however, were found in more than one country, suggesting patterns of movement of the pathogen. The pathotype of X. oryzae pv. oryzae was determined for 226 strains by inoculating five rice differential cultivars. More than one pathotype was associated with each cluster; however, some pathotypes were associated with only one cluster. Most strains from South Asia (Nepal and India) were virulent to cultivars containing the bacterial blight resistance gene xa-5, while most strains from other countries were avirulent to xa-5. The regional differentiation of clusters of X. oryzae pv. oryzae in Asia and the association of some pathotypes of X. oryzae pv. oryzae with single clusters suggested that strategies that target regional resistance breeding and gene deployment are feasible.     

A new gene for resistance to green leafhopperNephotettix virescens (Distant) in rice

The mode of inheritance of resistance to green leafhopper in 12 cultivars of riceOryza saliva L. was studied. Seedlings of parent and hybrid populations were artificially infested with second- and third-instar virus-free green leafhopper nymphs. Seedling reaction was scored when TNI, the susceptible check, was completely killed. The results revealed that single dominant genes confer resistance in six varieties, two independent dominant genes in four varieties, and single recessive genes in two varieties. The single dominant genes in Sri Gaya, ARC 7320, and T23 and one of the two genes in Aswina and Bhura Rata 2 are allelic toGlh-1; while Bhawalia hasGlh-5 gene. The second gene of Bhura Rata 2 is allelic to IR28 gene. Resistance in Chamar is controlled by two independent genes one of which is allelic toGlh-5 and the other allelic to IR28 gene. Bazal hasGlh-2 andGlh-5. The single recessive gene in ARC 7012 is allelic toglh-4 but the single recessive gene in DV85 is nonallelic to and independent ofglh-4. This new recessive gene is designated asglh-8. The single dominant genes of Dumai, Gadur, and the second gene of Aswina are nonallelic to all the known genes for resistance.