青花菜及近缘种属种质资源抗根肿病鉴定

根肿病是十字花科蔬菜作物的主要病害之一,造成了蔬菜产业巨大经济损失。青花菜是一种重要的十字花科蔬菜,具有良好的防癌保健功效。近年来青花菜根肿病在我国浙江、云南等青花菜主产区发生日益严重,鉴定和筛选青花菜抗根肿病资源,从而培育抗病品种是防治该病最经济有效的方法。为挖掘和丰富可利用的根肿病抗源,本试验针对我国优势根肿菌小种—4号小种,利用苗期人工接种鉴定方法—伤根灌菌法对531份青花菜及其近缘种属材料进行了抗根肿病鉴定。结果显示,446份青花菜材料(其中高代自交系393份,杂交种53份)中缺乏高抗(HR)和抗病(R)材料,包括中抗(MR)材料5份,均为自交系,占供试种质的1.12%,感病(S)材料189份,占供试种质的42.38%,高感(HS)材料252份,占供试种质的56.50%。85份近缘种属材料(其中甘蓝9份,花椰菜32份,大白菜7份,芜菁4份,芥蓝12份,苤蓝8份,菜心8份,油菜2份,野生种2份,欧洲山芥1份)中,包括免疫(I)材料1份,高抗(HR)材料1份,抗病(R)材料5份,中抗(MR)材料2份,感病(S)材料39份,高感(HS)材料37份。总体上高抗青花菜材料缺乏,近缘种属材料中抗源材料比例略高,这些材料为青花菜及甘蓝类蔬菜抗根肿病病育种提供了抗性资源。     

结球甘蓝根肿菌鉴定和种质抗性评价

采集湖北省长阳县火烧坪乡根肿病重发区的病土和病根,通过病原菌形态和PCR鉴定,确定是芸薹根肿菌,然后利用欧洲ECD鉴别系统确定生理小种为ECD17/31/13,此病原菌致病力极强。采用田间苗期人工接种鉴定,与田间成株期自然诱发鉴定相结合,对88份甘蓝种质进行抗性评价和筛选,结果表明:苗期获得1份高抗,7份抗病,17份耐病材料;成株期获得4份高抗,4份抗病,15份耐病材料。2个时期88份材料群体抗性鉴定级别基本一致,93.18%材料成株期病指比苗期高。CR21在2个时期均为高抗,抗性最强,表现稳定;CR55在苗期发病最严重,病指达到76.19,成株期为74.10;CR54在成株期发病最严重,病指达到81.54,苗期为75.97,2个时期发病率均达到100%。根肿病菌的鉴定和致病力的确定,及甘蓝种质抗性评价为抗病品种选育和抗病机理的研究奠定基础。     

水稻白叶枯病抗性基因定位及其小种专化性

利用 3个致病性不同的水稻白叶枯病菌小种 ,对由Lemont/特青培育的 31 5个F₁₀ 重组自交系群体进行抗性基因 (QTL)RFLP分析 .共发现 1个主基因、1 0个QTL及 9对互作位点与白叶枯病菌抗性有关 .其中 ,主基因Xa4定位于第 1 1染色体上 .Xa4对CR4和CX0 8表现显性主基因遗传 ,但对CR6则表现为一个主要的加性QTL的作用 .主基因小种专化性明显大于QTL .QTL之间以及QTL与主基因之间效应累加 ,共同提供抗病性的强度和稳定性 .在感病亲本中 ,亦存在抗性QTL .因此 ,来源不同的中抗材料可能是水平抗性的良好基因源 .研究还表明 ,所定位的QTL与其他研究发现的抗不同病原菌的基因 (QTL)处于相近的染色体位置 ,意味着它们可能是同一抗性基因族的成员 .     

小麦类Mla基因的分离与特征分析

根据大麦MLa基因的保守区域设计了4对家族性引物.通过用家族性引物对小麦(Triticum aestivum L.)抗白粉病品系TAM104R在接种和未接种两种条件下的基因差异表达进行RT-PCR分析,获得了一个在接种条件下特异表达的基因片段RJ-3-3L,并用RACE方法获得了其cDNA全长,命名为TaMla1.序列比对显示:TaMlal与大麦MLa位点的基因家族成员具有高度同源性,TaMla1编码的氨基酸功能基序扫描表明其为一个CC-NBS-LRR型抗病蛋白.用一套中国春缺-四体材料将TaMla1定位到了小麦的1A染色体上,这正是大麦MLa基因位点在小麦中的同源区段所在的染色体.这些结果表明,TaMla1为一个类MLa抗白粉病基因.同时我们还获得了一个在不接种条件下特异表达的基因片段RW-2-3L,序列分析表明它与MLa基因也高度同源,推测其可能是一个小麦白粉病的敏感基因或抗性负调控因子.     

水稻白叶枯病候选抗性基因SHNLR的RGAs克隆及分析

旨在从含有疣粒野生稻抗白叶枯病基因的新种质SH5、SH76基因组中克隆抗病基因。利用RGAs法得到1个NBS-LRR类同源基因,暂命名为SHNLR(登录号为JF934724)。结果表明,SHNLR的开放阅读框长度为3 105 bp,编码1 034个氨基酸,含有CC、NB-ARC与LRR结构域,具备CC-NBS-LRR类植物抗病基因的结构特征。BLASTn和BLASTp比对显示SHNLR是单拷贝基因,未发现同源性较高且功能已知的基因,仅NBS保守域序列与番茄Prf基因的相似度最高。对SHNLR基因电子定位,发现其位于水稻第11号染色体的长臂末端,但与11号染色体上已定位或克隆的8个白叶枯病抗性基因具有不同序列或处于不同的位置。半定量RT-PCR分析表明,SHNLR在抗病新种质叶片中的表达明显受到白叶枯病菌Zhe173的诱导。因此推测SHNLR可能是1个与抗白叶枯病相关的R基因。     

松花菜种质资源评价及根肿病、黑斑病兼抗材料筛选

松花菜是目前我国花椰菜消费的主要类型。根肿病和黑斑病是直接影响松花菜产量及品质的重要病害。选育商品性好、高抗多抗品种是松花菜的主要育种目标之一。本研究首次建立了松花菜种质资源花球性状评价体系,从花球紧实度、球形、球面光滑度、球面颜色、球面蕾粒大小、二级侧枝长度、花梗颜色、球面长毛情况8个方面对66份松花菜自交系进行评价,并对不同性状赋值以便统计、比较。利用上述体系共筛选出11份花球性状优良的材料。采用苗期人工接种技术分别对松花菜根肿病和黑斑病抗性进行鉴定评价,结果显示无免疫根肿病材料,有2份高抗材料,9份抗病,16份中抗;无免疫和高抗黑斑病材料,有4份抗病材料,10份中抗。另外,兼抗两种病害的材料较少,其中GY-40对两种病害均表现抗病,GY-21对根肿病表现抗病,对黑斑病表现中抗,GY-39对两种病害均表现中抗。值得一提的是,GY-40性状优良且同时对根肿病和黑斑病具有较高抗性,是选育商品性好、抗病性强松花菜品种的理想亲本。本研究结果为评价松花菜种质资源花球相关性状提供了参考,对于规范资源的收集、整理和保存具有重要意义,同时为开展抗根肿病和黑斑病松花菜品种选育提供了优异材料。     

甘薯近缘野生种的抗病性鉴定与新型种间杂种的获得

为了发掘甘薯近缘种抗茎线虫病、病毒病基因资源,改良栽培种抗性,拓宽甘薯遗传基础,本文利用田间自然病圃对30份甘薯近缘野生种进行抗茎线虫病鉴定,利用硝化纤维素膜-酶联免疫(NCM-ELISA)对20份野生种进行了抗病毒病筛选.以筛选到的抗性材料为父本、栽培种徐薯18为母本,采用生长调节剂处理方法进行种间杂交,结果得到8份高抗、10份抗茎线虫病野生种,5份高抗、8份抗病毒病材料;获得4个新型种间杂种.经过染色体计数和ISSR分子标记鉴定,证实了所得杂种的真实性.表明甘薯近缘野生材料中存在着栽培种所需要的抗性基因,通过有性杂交手段可以获得含野生种染色体组的种间杂种新类型,为渐渗野生抗性基因起到"桥梁"作用.     

小偃麦衍生品系CH7086抗白粉基因的遗传及SSR分析

CH7086是兼抗白粉病、条锈病的小麦新品系,衍牛于来自十倍体长穗偃麦草的八倍体小偃麦与普通小麦的杂种后代.温室接种鉴定结果显示,CH7086对白粉病菌系E09、E21、E26均表现为免疫,且其抗件来自长穗偃麦草.抗性遗传分析表明CH7086的白粉病抗性由1对显性基因控制,暂定名为MlCH86.应用分离群体分组法(BSA)对从CH5241×CH7086的F2中随机选取的95个单株进行微卫星标记检测,发现位于2BL、2DL上的SSR位点Xbarc159在双亲和抗、感池间有特异性,并与抗性基因MlCH86连锁,其遗传距离为10.8 cM.用中国春第2部分同源群的缺体-四体系和双端体系进行验证,进一步将MlCH86定位在2BL上.用白粉病菌系E21、E26接种鉴定表明,MlCH86的抗性反应明显不同于2BL上已命名的抗性基因Pm6、Pm33.根据抗性基因的来源、染色体位置及抗性反应,初步推断存在于CH7086的抗性基因来自长穗偃麦草,它不同于已有的抗白粉病基因,可能是一个新基因.     

芒果炭疽病菌β-微管蛋白基因的克隆及其与多菌灵抗药性发生的关系

参照豆科合萌属 (Aeschynomene)作物炭疽病菌的tub1和tub2基因序列设计了 2对引物 ,分别从芒果 (Man gifera)炭疽病菌对多菌灵 (MBC)田间抗药性 (MBCR)和敏感 (MBCS)的菌株中扩增 β_微管蛋白基因。结果只有以tub2为参照设计的引物扩增到了特异片段。进一步对全基因进行了克隆和测序。该基因序列全长 1344bp ,编码4 4 7aa ,其核苷酸和氨基酸序列与豆科合萌属炭疽病菌的tub2基因高度同源。对芒果炭疽病菌抗、感菌株 β_微管蛋白氨基酸序列进行比较分析 ,发现第 181、2 37和 36 3位氨基酸发生了突变 ,而其它位置 (如第 198位或 2 0 0位 )均不变     

一种快速、精确构建大肠杆菌组氨酸营养缺陷型的方法*

将表达Red体内重组蛋白的质粒pKD46转化大肠杆菌DH5α,用 5′端与组氨酸基因同源 ,3′端与卡那霉素抗性基因同源的引物获得具有卡那霉素抗性基因的PCR产物 ,然后电击转化DH5α,在λRed重组系统的帮助下 ,通过卡那霉素抗性基因两侧的组氨酸基因序列在体内与大肠杆菌染色体上的组氨酸基因发生同源重组 ,置换了DH5α组氨酸操纵元中的hisDCB基因 ,最后利用卡那霉素抗性基因两端的FRT位点 ,通过FTP位点专一性重组将卡那霉素抗性基因去除 ,最终获得了不具抗性的大肠杆菌组氨酸营养缺陷型菌株。为在大     

不结球白菜抗根肿病渐渗系的分子辅助选育

该研究基于与大白菜抗根肿病连锁的分子标记,设计特异引物,获得简便实用的SCAR标记,并用于分子标记辅助选择,创制不结球白菜抗根肿病新材料。结果发现,在设计的8对特异引物中,有1对特异引物在抗、感亲本间表现出多态性。F2群体验证发现,该标记与已有SSR标记及根肿病抗性共分离,能够用于抗根肿病鉴定,定名为CRb-R-25。通过亚种间杂交并回交,利用标记CRb-R-25辅助选择将大白菜根肿病抗性转入不结球白菜中,获得抗根肿病不结球白菜渐渗系材料TQ14-1-15。     

大白菜骨干自交系的苗期抗病性评价

为明确大白菜骨干自交系的抗病性,本研究于2012-2014年,对课题组保存和创制的203个大白菜自交系进行了霜霉病、病毒病、黑腐病、黄萎病和根肿病的苗期抗性评价。结果显示,高抗上述病害的自交系分别有7、9、0、31和12个;只抗其中一种病害的自交系82个;兼抗两种病害的有61个,兼抗三种病害的自交系有28个,兼抗四种病害的自交系有4个。自交系11-234、04-622、12-85、13-108和09-894综合抗病性最优。此外,春大白菜、夏大白菜和秋大白菜三种生态类群间,以及四种叶球抱合类群间的抗病性表现出明显差异。     

Mapping of isolate-specific QTLs for clubroot resistance in Chinese cabbage (<Emphasis Type="Italic">Brassica rapa</Emphasis> L. ssp. <Emphasis Type="Italic">pekinensis</Emphasis>)

A number of clubroot resistant (CR) Chinese cabbage cultivars have been developed in Japan using resistant genes from CR European fodder turnips (B. rapa ssp. rapifera). Clubroot resistance in European fodder turnips are known to be controlled by the combined action of several dominant resistance genes. We have developed three Chinese cabbage clubroot-resistant doubled haploid (DH) lines-T136-8, K10, and C9-which express resistance in different manners against two isolates of Plasmodiophora brassicae, M85 and K04. Depending on the isolates, we identified two CR loci, CRk and CRc. CRk was identified by quantitative trait loci (QTL) analysis of an F(2) population derived from a cross between K10 and Q5. This locus showed resistance to both isolates and is located close to Crr3 in linkage group R3. The other locus, CRc was identified by QTL analysis of an F(2) population derived from a cross between C9 and susceptible DH line, 6R. This locus was mapped to linkage group R2 and is independent from any published CR loci. We developed sequence-tagged site markers linked to this locus.     

Identification of two loci for resistance to clubroot (<Emphasis Type="Italic">Plasmodiophora brassicae</Emphasis> Woronin) in <Emphasis Type="Italic">Brassica rapa</Emphasis> L.

In an analysis of 114 F₂ individuals from a cross between clubroot-resistant and susceptible lines of Brassica rapa L., 'G004' and 'Hakusai Chukanbohon Nou 7' (A9709), respectively, we identified two loci, Crr1 and Crr2, for clubroot (caused by Plasmodiophora brassicae Woronin) resistance. Each locus segregated independently among the F₂ population, indicating that the loci reside on a different region of chromosomes or on different chromosomes. Genetic analysis showed that each locus had little effect on clubroot resistance by itself, indicating that these two loci are complementary for clubroot resistance. The resistance to clubroot was much stronger when both loci were homozygous for resistant alleles than when they were heterozygous. These results indicate that clubroot resistance in B. rapa is under oligogenic control and at least two loci are necessary for resistance.Communicated by H.C. Becker     

抗根肿病大白菜的花药培养

大白菜是中国北方的重要蔬菜之一,根肿病是危害大白菜生产世界性病害,利用花药培养可以大大加速抗根肿病大白菜杂交育种工作的进程。对33份抗根肿病大白菜品种(品系)进行花药培养,有24个品种诱导出胚,品种诱导率为72.7%,以东方皇冠×C11的诱导率最高,为1.86胚/蕾。对大部分基因型来说,在培养基中添加0.4 g/L谷氨酰胺的诱导效果最好。研究还发现生长在温室中的供体植株更容易诱导出胚状体。变绿的子叶型胚转到B5+0.2 mg/L BA+0.1 mg/L NAA+0.1%活性炭的胚分化培养基上可诱导生芽。     

Simple sequence repeat-based comparative genomics between Brassica rapa and Arabidopsis thaliana: the genetic origin of clubroot resistance

An SSR-based linkage map was constructed in Brassica rapa. It includes 113 SSR, 87 RFLP, and 62 RAPD markers. It consists of 10 linkage groups with a total distance of 1005.5 cM and an average distance of 3.7 cM. SSRs are distributed throughout the linkage groups at an average of 8.7 cM. Synteny between B. rapa and a model plant, Arabidopsis thaliana, was analyzed. A number of small genomic segments of A. thaliana were scattered throughout an entire B. rapa linkage map. This points out the complex genomic rearrangements during the course of evolution in Cruciferae. A 282.5-cM region in the B. rapa map was in synteny with A. thaliana. Of the three QTL (Crr1, Crr2, and Crr4) for clubroot resistance identified, synteny analysis revealed that two major QTL regions, Crr1 and Crr2, overlapped in a small region of Arabidopsis chromosome 4. This region belongs to one of the disease-resistance gene clusters (MRCs) in the A. thaliana genome. These results suggest that the resistance genes for clubroot originated from a member of the MRCs in a common ancestral genome and subsequently were distributed to the different regions they now inhabit in the process of evolution.     

Genetics of Clubroot Resistance in <Emphasis Type="Italic">Brassica</Emphasis> Species

Clubroot disease, caused by the obligate plant pathogen Plasmodiophora brassicae Wor., is one of the most economically important diseases affecting Brassica crops in the world. The genetic basis of clubroot resistance (CR) has been well studied in three economically important Brassica species: B. rapa, B. oleracea, and B. napus. In B. rapa, mainly in Chinese cabbage, one minor and seven major CR genes introduced from European fodder turnips have been identified. Mapping of these CR genes localized Crr1 on R8, Crr2 on R1, CRc on R2, and Crr4 on R6 linkage groups of Chinese cabbage. Genes Crr3, CRa, CRb, and CRk mapped to R3, but at two separate loci, CRa and CRb are independent of Crr3 and CRk, which are closely linked. Further analysis suggested that Crr1, Crr2, and CRb have similar origins in the ancestral genome as in chromosome 4 of Arabidopsis thaliana. Genetic analysis of clubroot resistance genes in B. oleracea suggests that they are quantitative traits. Twenty-two quantitative trait loci (QTLs) were mapped in different linkage groups of B. oleracea. In B. napus, genetic analysis of clubroot resistance was found to be governed by one or two dominant genes, whereas resistance conferred by two recessive genes is reported. The quantitative analysis approach, however, proved that they are polygenic. In total, at least 16 QTLs have been detected on eight chromosomes of B. napus, N02, N03, N08, N09, N13, N15, N16, and N19. The chromosomal location of the other six QTLs is not clear. Cloning of any of these QTLs or resistance loci was not, however, possible until recently. Progress in genomics, particularly the techniques of comparative mapping and genome sequencing, supplements cloning and allows improved characterization of CR genes. Further development of DNA markers linked to CR genes will in turn hasten the breeding of clubroot-resistant Brassica cultivars.     

Screening and evaluation of resistance to downy mildew (Peronospora parasitica) and clubroot (Plasmodiophora brassicae) in genetic resources of Brassica oleracea

52 entries including landraces, old cultivars and wild accessions of B. oleracea and closely related Brassica species were screened for resistance against downy mildew and clubroot. Several accessions resistant to downy mildew and a few to clubroot were found. Genetic inheritance of the resistance in downy mildew was investigated by screening F1 and BC1F1 offspring from three resistant landrace accessions crossed with both a resistant and a susceptible father. The seedling resistance against downy mildew was found to be inherited recessively. This is a bit surprising as earlier papers mostly report of inheritance controlled by a single dominant gene. Previous screenings of B. oleracea resistance against downy mildew at the cotyledon stage have been done with P. parasitica isolated from B. oleracea as the original host plant. The recessive nature of the cotyledon resistance found in this screening might be due to the fact that the P. parasitica isolate was collected from B. napus fields. The clubroot seedling resistance was found to be controlled by recessive inheritance after screening the F1 offspring, this in agreement with earlier results/reports.     

Selection for resistance to clubroot (Plasmodiophora brassicae) in marrowstem kale (Brassica oleracea var. acephala L.)

Ninety-six cultivars of Brassica oleracea were screened for clubroot resistance in a seedling test using two populations of Plasmodiophora brassicae. The most resistant cultivars were kales. Sixteen resistant marrowstem kale cultivars of diverse geographical origin were used to start a selection programme for clubroot resistance. Four generations of selection, involving single plants, half-sib and full-sib families, reduced a disease index averaged over six clubroot populations from 41.2 to 12.5. This was lower than the most resistant cultivar in the original population, cv. Mixti 28.8, and as good as a German landrace of cabbage noted for its resistance, Bohmerwaldkohl 10.5. In comparison, the mean of five kale controls, cvs Bittern, Canson, Condor, Kestrel and Merlin, was 61.1 and the value for the most susceptible control, cabbage cv. Septa, was 89.3. In the final assessment, there were no clubroot population x B. oleracea genotype interactions and in the initial assessment of cultivars there were only small interactions which could be removed by an angular transformation of the data. It was concluded that a high level of non-differential resistance had been achieved and that it may prove durable. It was also concluded from a small field trial that this level of resistance would prevent serious yield losses in practice.     

Molecular characterization of the CRa gene conferring clubroot resistance in Brassica rapa

Clubroot disease is one of the major diseases affecting Brassicaceae crops, and a number of these crops grown commercially, such as Chinese cabbage (Brassica rapa L. ssp. pekinensis), are known to be highly susceptible to clubroot disease. To provide protection from this disease, plant breeders have introduced genes for resistance to clubroot from the European turnip into susceptible lines. The CRa gene confers specific resistance to the clubroot pathogen Plasmodiophora brassicae isolate M85. Fine mapping of the CRa locus using synteny to the Arabidopsis thaliana genome and partial genome sequences of B. rapa revealed a candidate gene encoding a TIR-NBS-LRR protein. Several structural differences in this candidate gene were found between susceptible and resistant lines, and CRa expression was observed only in the resistant line. Four mutant lines lacking clubroot resistance were obtained by the UV irradiation of pollen from a resistant line, and all of these mutant lines carried independent mutations in the candidate TIR-NBS-LRR gene. This genetic and molecular evidence strongly suggests that the identified gene is CRa. This is the first report on the molecular characterization of a clubroot Resistance gene in Brassicaceae and of the disease resistance gene in B. rapa.