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香蕉枯萎病菌RAPD分析及4号生理小种的快速检测 总被引:3,自引:0,他引:3
用随机扩增多态性DNA(RAPD)技术,对采自广东、广西的香蕉和粉蕉上的30个香蕉枯萎病菌(Fusarium oxysporum f.sp.cubense)菌株和3个其它尖孢镰刀菌专化型的菌株进行比较及聚类分析。在遗传相似系数0.67时,可将供试菌株划分为3个RAPD群(RGs),其中香蕉枯萎病菌4号生理小种(FOC4)共15个菌株属于RGⅠ,1号生理小种(FOC1)共15个菌株属于RGⅡ,供试的其它尖孢镰刀菌专化型的3个菌株则属于RGⅢ。这说明香蕉枯萎病菌和供试3个其它专化型菌株与致病性间存在明显的相关性。1号生理小种内菌株间的遗传分化大于4号生理小种内菌株间的遗传分化。从90条RAPD随机引物中筛选出2条引物可产生4号生理小种的RAPD标记2个。将这2个RAPD标记电泳切胶回收、克隆及测序,并根据这2个特异片段序列设计SCAR上下游特异引物,通过对30个菌株的PCR扩增检验,其中一个RAPD标记成功地转化为SCAR标记,初步建立了以此为基础的4号生理小种快速检测技术,其检测灵敏度为2 ng新鲜菌丝。对采自不同地区的显症样品、吸芽、室内接种未显症的香蕉苗以及发病的香蕉植株不同部位进行检测,能够准确灵敏地鉴定出4号生理小种,从而为香蕉枯萎病菌的快速检测及防治奠定了基础。同时,快速检测结果发现,田间发病植株果柄的各部位及果实内并没有枯萎病菌的存在。 相似文献
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甘蓝枯萎病菌生理小种传统鉴定方法费时费力,不能满足生产的要求,因此需要建立一种快速、可靠的分子检测技术。本研究在甘蓝枯萎病菌1号和2号生理小种基因组测序的基础上,通过比较基因组学方法筛选1、2号生理小种各自的特异基因片段并设计引物,并分别以10个甘蓝枯萎病菌1号生理小种菌株、2个2号生理小种菌株、7个尖孢镰刀菌其他专化型菌株及4个外围菌株DNA为模板进行常规PCR扩增,筛选出甘蓝枯萎病菌1号和2号生理小种特异性引物,同时引入尖孢镰刀菌通用引物W106R/W106S,建立起一步三重PCR检测甘蓝枯萎病菌1、2号生理小种的分子检测技术。结果表明,该分子检测技术实现了在一次PCR反应中快速、准确地同步检测出甘蓝枯萎病菌DNA、罹病甘蓝组织和土壤中的甘蓝枯萎病菌1号和2号生理小种,对检测甘蓝植株是否感染枯萎菌及甘蓝种植区土壤是否受到枯萎菌的污染有实用价值。 相似文献
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以ITS测序与SCAR分子标记相结合的香蕉病原菌FOC4分子检测方法,利用通用引物ITS1和ITS4对病原菌SF001的rDNA中ITS序列进行PCR扩增,获得560bp左右的特异条带。经Blast分析比对,确定该菌为FOC。再利用FOC4的特异引物PCL/PDL对基因组上的特征序列扩增区域(SCAR)进行PCR扩增,获得677bp的特有序列,鉴定菌株SF001是尖孢镰刀菌古巴专化型4号生理小种。经过致病性测试,菌株SF001表现出典型4号生理小种的病理特征。 相似文献
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香蕉枯萎病拮抗细菌的分离筛选与鉴定 总被引:8,自引:0,他引:8
从采集的香蕉根际土壤中经分离、纯化获得细菌菌株74个,采用对峙培养法,获得对香蕉枯萎病菌4号小种具有强抑制作用的菌株S-1,相对抑制率达76%。抑菌谱测定表明,菌株S-1对尖孢镰刀菌古巴专化型1号小种、番茄枯萎病菌、玉米弯孢叶斑病菌、胶孢炭疽病菌、棉花枯萎病菌、棉花黄萎病菌、小麦赤霉病菌、西瓜枯萎病菌等病原菌具有抑制作用。经Biolog系统鉴定及16S rDNA序列同源性分析,菌株S-1为枯草芽孢杆菌。该菌株理想的培养条件为:PYTG或PDA培养基,26-30℃,pH值7.0-8.0,振荡培养40-48h。 相似文献
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香蕉枯萎病菌致病力分化与ISSR遗传多样性分析 总被引:1,自引:0,他引:1
香蕉枯萎病是一种破坏香蕉维管束的全株性土传病害。本研究旨在探讨香蕉枯萎病菌致病力分化和遗传多样性。以30株采自我国广西的香蕉枯萎病菌,16株分别来自澳大利亚和我国广东、海南、福建、云南等地的香蕉枯萎病菌为对象,采用伤根灌淋法测定香蕉枯萎病菌的致病力,然后用筛选到的ISSR引物对46个香蕉枯萎病菌菌株和4个对照菌株(3个非致病性尖孢镰刀菌和1个茄腐镰刀菌)进行ISSR遗传多样性分析。结果显示,分离到广西香蕉枯萎病菌1号生理小种(FOC1)8株,致病力强、中、弱类型比例分别为62.5%、12.5%和25%;广西香蕉枯萎病菌4号生理小种(FOC4)22株,致病力强、中、弱类型比例分别为18.18%、63.64%和18.18%。14条ISSR引物扩增出237个条带,多态性条带161个,多态性比例为67.93%,遗传相似系数0.76~0.96。聚类分析显示,以遗传距离0.80为阈值时菌株被分为8个类群,所占比例分别为4%、10%、60%、16%、4%、2%、2%、2%。第三类群全部为香蕉枯萎病菌4号生理小种。第一、二、四和五类群总量的70.59%为香蕉枯萎病菌1号生理小种。第八类群为香蕉枯萎病菌3号生理小种。结果表明,在香蕉枯萎病菌与寄主协同进化中,广西的FOC1和FOC4出现明显致病力分化。1号生理小种的遗传多样性比4号生理小种丰富。广西香蕉枯萎病菌4号生理小种与海南、广东的FOC4遗传相似性较高。香蕉枯萎病菌生理小种类型与遗传多样性相关。致病力变异与遗传多样性无相关性。研究结果对香蕉枯萎病菌种群扩张机制探讨、遗传动态分析以及有效防控措施的制定具有一定的指导意义。 相似文献
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对分离获得的32株苦瓜枯萎病菌菌株进行形态学特征和寄主专化型测定, 结果表明, 测试的苦瓜枯萎病菌株均为尖孢镰刀菌苦瓜专化型 (Fusarium oxysporum f. sp. momordicae), 这些菌株可以侵染苦瓜和瓠瓜幼苗, 但不侵染其他葫芦科瓜类作物。对苦瓜枯萎病菌菌株的rDNA-ITS区 (ITS1、5.8S和ITS2)序列进行扩增测序, 结果显示其序列长度均为456 bp;聚类分析表明测序菌株与镰刀菌属中尖孢镰刀菌不同专化型的菌株聚为一群。利用RAPD标记技术分析苦瓜枯萎病菌的遗传多样性, 结果显示苦瓜枯萎病菌株与其他葫芦科瓜类作物枯萎病菌株间的遗传相似系数范围为0.59~0.99, 当遗传相似系数为0.85时, 供试的48个菌株分成10个类群 (G1~10)。在RAPD聚类树中所有苦瓜枯萎病菌株聚在一个分支上 (G1群), 菌株间的遗传相似系数范围为0.92~1.00, 具有较高的遗传相似性, 且菌株的聚群与地理来源存在一定的相关性。 相似文献
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尖孢镰刀菌的遗传多态性 总被引:13,自引:0,他引:13
尖孢镰刀菌是重要的植物维管束病原真菌。近年来,有关该菌的遗传多态性研究报道很多,本文着重综述了利用营养体亲和群、DNA多态性技术研究尖孢镰刀菌专化型、小种及其相互关系等方面的进展,同时介绍了对棉花枯萎病菌、瓜类枯萎病菌及尖孢镰刀菌小种起源等的研究概况。 相似文献
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对30个西瓜枯萎病菌Fusarium oxysporum f.sp.niveum菌株基因组DNA进行相关序列扩增多态性(SRAP)分子标记分析,以探究其遗传多样性与地理来源的关系。采用尖孢镰刀菌西瓜专化型Fusarium oxysporumf.sp.niveum0、1、2号生理小种的基因组DNA为模板,对225对SRAP引物进行筛选,筛选出20对多态性、重复性较好且条带清晰的引物,对30个菌株进行PCR扩增,共扩增出386条带,其中多态性条带有371条,多态性比率为96.11%,平均每对引物扩增出19.3个位点和18.55个多态性位点。UPGMA法聚类分析结果显示,供试菌株两两之间的遗传相似系数范围为0.69~0.90,平均为0.79,说明尖孢镰刀菌西瓜专化型的遗传多样性较为丰富。基于SRAP标记聚类分析表明,30个菌株在遗传相似系数为0.70处被划分为3个类群,I类群包含24个菌株,其中18个来自湖南省,Ⅱ类群只包含1个来自黑龙江省哈尔滨市的菌株,它和另一个来自黑龙江地区的菌株被划分到不同的类群,且遗传距离相对较远;Ⅲ类群包含了5个菌株,其中3个来自海南三亚,其余两个来自湖南省。根据菌株的分布情况来看,菌株的聚集与地理来源没有明显的相关性。 相似文献
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小麦条锈菌水源11类群的RAPD分析及SCAR标记的建立 总被引:2,自引:0,他引:2
鉴于水源11类群近年来一直处于优势地位,为简化其检测手段,本研究利用RAPD技术对该类群的8个主要致病类型进行了多态性分析,以寻找其中主要流行类型的特异性分子标记。结果如下:共筛选出10个碱基随机引物190条,其中94条可得到稳定清晰的扩增图谱,用该94条引物进行RAPD分析,发现各致病类型间遗传变异丰富;以引物S1410扩增得到了水源11-4的特异性DNA条带;以引物S1412和S1304扩增得到了水源11-14的特异性DNA条带;对引物S1304扩增得到的特异性DNA条带回收、克隆和测序,设计了1对19bp/18bp的引物,并成功地将其转化为对水源11-14特异的SCAR标记。以上结果表明,通过规模筛选来寻找小麦条锈菌生理小种的特异性DNA片段,并将其转化为稳定的SCAR标记,有可能建立起中国小麦条锈菌流行生理小种的快速分子鉴定体系。 相似文献
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ABSTRACT Specific primers and polymerase chain reaction (PCR) assays that identify Fusarium oxysporum f. sp. ciceris and each of the F. oxysporum f. sp. ciceris pathogenic races 0, 1A, 5, and 6 were developed. F. oxysporum f. sp. ciceris- and race-specific random amplified polymorphic DNA (RAPD) markers identified in a previous study were cloned and sequenced, and sequence characterized amplified region (SCAR) primers for specific PCR were developed. Each cloned RAPD marker was characterized by Southern hybridization analysis of Eco RI-digested genomic DNA of a subset of F. oxysporum f. sp. ciceris and nonpathogenic F. oxysporum isolates. All except two cloned RAPD markers consisted of DNA sequences that were found highly repetitive in the genome of all F. oxysporum f. sp. ciceris races. F. oxysporum f. sp. ciceris isolates representing eight reported races from a wide geographic range, nonpathogenic F. oxysporum isolates, isolates of F. oxysporum f. spp. lycopersici, melonis, niveum, phaseoli, and pisi, and isolates of 47 different Fusarium spp. were tested using the SCAR markers developed. The specific primer pairs amplified a single 1,503-bp product from all F. oxysporum f. sp. ciceris isolates; and single 900- and 1,000-bp products were selectively amplified from race 0 and race 6 isolates, respectively. The specificity of these amplifications was confirmed by hybridization analysis of the PCR products. A race 5-specific identification assay was developed using a touchdown-PCR procedure. A joint use of race 0- and race 6-specific SCAR primers in a single-PCR reaction together with a PCR assay using the race 6-specific primer pair correctly identified race 1A isolates for which no RAPD marker had been found previously. All the PCR assays described herein detected up to 0.1 ng of fungal genomic DNA. The specific SCAR primers and PCR assays developed in this study clearly identify and differentiate isolates of F. oxysporum f. sp. ciceris and of each of its pathogenic races 0, 1A, 5, and 6. 相似文献
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Jyuichi Shimazu Norihito Yamauchi Tadaharu Hibi Mamoru Satou Seizo Horiuchi Takashi Shirakawa 《Journal of General Plant Pathology》2005,71(3):183-189
By random amplified polymorphic DNA (RAPD) analysis of the representative isolates of each race of Fusarium oxysporum f. sp. lactucae, RAPD fragments of 0.6, 1.6, and 2.9kb were obtained. The 0.6-kb RAPD fragment was common to the representative isolates of all three races. Amplification of the 1.6- and 2.9-kb fragments were unique to the isolates of races 1 and 2, respectively. Sequence tagged site (STS) marker FLA0001, FLA0101, and FLA0201 were generated from the 0.6-, 1.6-, and 2.9-kb RAPD fragments, respectively. Polymerase chain reaction (PCR) analysis showed that FLA0001 was common to all 49 isolates of F. oxysporum f. sp. lactucae. FLA0101 was specifically generated from all 23 isolates of race 1 but not from races 2 or 3. FLA0201 was specifically amplified from all 12 isolates of race 2 but not from races 1 or 3. In two isolates of F. oxysporum f. sp. lactucum, PCR amplified FLA0001 and FLA0101 but not FLA0201. On the other hand, these STS markers were not detected from isolates of five other formae speciales. Because these STS markers were not generated from isolates of other plant pathogenic fungi, bacteria, or plant materials examined in this study, PCR analysis combined with the three STS markers should be a useful means for rapid identification of races of F. oxysporum f. sp. lactucae. 相似文献
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Fusarium oxysporum f.sp. gladioli (FOG) race 1 infects both large- and small-flowered Gladiolus cultivars. Race 2 isolates infect only small-flowered cultivars but can be present as epiphytes on large-flowered plants. When 160 arbitrary 10-mer oligonucleotide primers were tested on FOG by PCR to find RAPD markers specific for race 1, the RAPD primer G12 amplified two discriminating DNA fragments, AB (609 bp) and EF (1196 bp), in race 1 isolates only. Both fragments were cloned and sequenced. Two pairs of race 1-specific primers for multiplex PCR were designed. Tests of 112 F. oxysporum isolates by PCR showed that, in almost all cases, race 1 isolates of vegetative compatibility group 0340 could be distinguished with these primers. Seven putative race 1 isolates did not react in multiplex PCR; hybridization studies with labelled AB and EF DNA fragments showed that these isolates belong to separate groups. A bioassay was developed to detect corms that were latently infected with FOG race 1. Gladiolus corms were homogenized and incubated for 5 days at 28°C in a semiselective medium to induce growth of Fusarium . Cultivated mycelium was isolated and subjected to the developed multiplex PCR after standard DNA isolation or disruption by microwave treatment. 相似文献
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Carmen Gómez-Lama Cabanás Antonio Valverde-Corredor Encarnación Pérez-Artés 《European journal of plant pathology / European Foundation for Plant Pathology》2012,132(4):561-576
Fusarium wilt, caused by Fusarium oxysporum f. sp. dianthi (Fod), is the most important carnation disease worldwide. The knowledge of the diversity of the soil population of the pathogen
is essential for the choice of suitable resistant cultivars. We examined the genetic diversity of Fod isolates collected during the period 1998–2008, originating from soils and carnation plants in the most important growing
areas in Spain. Additionally, we have included some Fod isolates from Italy as a reference. Random amplified polymorphic DNA (RAPD) fragments generated by single-primer PCR were
used to compare the relationship between isolates. UPGMA analysis of the RAPD data separated Fod isolates into three clusters (A, B, and C), and this distribution was more related to aggressiveness than to the race of
the isolates. The results obtained in PCR amplifications using specific primers for race 1 and race 2, and SCAR primers developed
in this work, correlated with the molecular groups previously determined from the RAPD analysis, and provided new molecular
markers for the precise identification of the isolates. Results from successive pathogenicity tests showed that molecular
differences between isolates of the same race corresponded with differences in aggressiveness. Isolates of races 1 and 2 in
cluster A (R1I and R2I isolates) and cluster C (R1-type isolates) were all highly aggressive, whereas isolates of races 1
and 2 in cluster B (R1II and R2II isolates) showed a low aggressiveness profile. The usefulness of the molecular markers described
in this study has been proved in double-blind tests with Fod isolates collected in 2008. Results from this work indicate a change in the composition of the Spanish Fod population over time, and this temporal variation could be related to the continuous change in the commercial carnation cultivars
used by growers. This is the first report of genetic diversity among Fod isolates in the same race. 相似文献