猕猴桃溃疡病菌biovar 3群体MLVA分型技术的建立与应用

 丁香假单胞菌猕猴桃致病变种生物型3(Pseudomonas syringae pv. actinidiae biovar 3,Psa3)是猕猴桃溃疡病菌的世界流行群体,但仅在中国存在复杂的遗传多样性。开发适于Psa3群体分型的MLVA(multilocus variable-number tandem-repeat analysis)技术是探索中国Psa3起源与流行学特性的基础。本研究对7个Psa3菌株进行了全基因组测序,结合已公布的86个全基因组数据,进行比较分析发现,中国Psa3至少存在7个亚群;在各亚群间存在多态性的24个串联重复序列中,其中10个可以通过琼脂糖凝胶电泳区分开且变异指数合适,据此建立了适于Psa3的MLVA技术。采用该技术对分别来自贵州和陕西的62和9个Psa3菌株进行群体分型,分型结果与全基因组分析高度一致,证明该MLVA体系分型准确。MLVA分型结果表明:贵州主产区修文县Psa3有3个MLVA群体,其中亚群4的组内分化明显,代表最早发生的群体;而亚群 1和3的结构单一,且多在新果园发现,是新传入群体。总之,本研究建立了一套可用于Psa3群体分型的MLVA技术,将有助于解析中国各猕猴桃产区Psa3群体结构,以及探索中国Psa3的起源、传播和流行学特征。     

基于全基因组重测序的中国猕猴桃溃疡病菌遗传多样性分析

 由Pseudomonas syringae pv. actinidiae (Psa)引起的猕猴桃细菌性溃疡病是为害猕猴桃的一种毁灭性病害,1996年被列为我国森林植物检疫对象。本研究对来源于我国7个受溃疡病为害最严重地区的21个Psa菌株进行重测序分析,通过主成分分析和系统发育学分析将21个菌株分为三大类群;固定系数分析结果显示所有群体的F_ST值均小于0.05;核苷酸多态性分析结果显示所有菌株的Θπ值仅为3.74×10^-6,且各群体间的差异不明显。这些结果表明Psa在我国的遗传多样性处于低水平状态。基因流(Nm)分析结果显示不同群体之间的Nm值均大于4,表明各群体病原菌之间存在较大的基因交流;Tajima′s D中性检验结果显示所有群体的Tajima′s D值均大于0,暗示各群体都经历平衡选择;Ka/Ks分析结果显示Psa的大部分基因都受到纯化选择,仅有极少数的基因受到正选择。本研究揭示了中国7个受溃疡病危害最严重地区Psa的遗传多样性,并且获得大量基因组数据,可为病害防治、病原菌耐药性以及抗病植株的选育提供理论依据。     

基于全基因组重测序的中国猕猴桃溃疡病菌遗传多样性分析

 由Pseudomonas syringae pv. actinidiae (Psa)引起的猕猴桃细菌性溃疡病是为害猕猴桃的一种毁灭性病害,1996年被列为我国森林植物检疫对象。本研究对来源于我国7个受溃疡病为害最严重地区的21个Psa菌株进行重测序分析,通过主成分分析和系统发育学分析将21个菌株分为三大类群;固定系数分析结果显示所有群体的F_ST值均小于0.05;核苷酸多态性分析结果显示所有菌株的Θπ值仅为3.74×10^-6,且各群体间的差异不明显。这些结果表明Psa在我国的遗传多样性处于低水平状态。基因流(Nm)分析结果显示不同群体之间的Nm值均大于4,表明各群体病原菌之间存在较大的基因交流;Tajima′s D中性检验结果显示所有群体的Tajima′s D值均大于0,暗示各群体都经历平衡选择;Ka/Ks分析结果显示Psa的大部分基因都受到纯化选择,仅有极少数的基因受到正选择。本研究揭示了中国7个受溃疡病危害最严重地区Psa的遗传多样性,并且获得大量基因组数据,可为病害防治、病原菌耐药性以及抗病植株的选育提供理论依据。     

中国4省猕猴桃细菌性溃疡病菌的生物型检测和遗传多样性分析

由丁香假单胞菌猕猴桃致病变种Pseudomonas syringae pv. actinidiae (Psa)侵染引起的猕猴桃细菌性溃疡病(kiwifruit bacterial canker)是全球猕猴桃生产上最具毁灭性的细菌病害。为探明福建、安徽、四川和陕西4省Psa菌株的生物型和遗传多样性,用5对PCR特异性引物PsaJ-F/-R、PsaK-F/-R、Tac-F/-R、Con002-F/-R和avrRps4-F1/-R2检测Psa菌株的生物型;用4对PCR引物27F/1492R、PsaF1/PsaR2、gapA-Fps/Rps和rpoD+364s/-1222ps分别扩增16S rRNA、ITS、gapA和rpoD基因,进行多基因联合分析Psa菌株的遗传多样性。结果表明,特异性引物Tac-F/-R从47株Psa菌株中均能扩增出一条545 bp的特异条带,其他4对引物未扩增出任何条带,说明供试Psa菌株的生物型均为biovar 3。多基因联合分析表明,4省Psa存在丰富的遗传多样性,4个群体共检测出27个单倍型,单倍型多样性为0.955。安徽、福建、四川和陕西群体的单倍型数差异较大,分别为1、8、12个和12个。4个群体的多态性位点数、核苷酸多样性和平均核苷酸差异数差异极显著(P<0.01),其中福建群体的多态性最丰富,而安徽群体的多态性最低。AMOVA分析表明,3.6%的遗传变异来源于种群间,而96.4%的遗传变异来源于种群内,说明种群内变异是遗传变异的主要来源。遗传分化分析表明,安徽省Psa群体与其他3个群体间的遗传分化极高(Fst>0.175),福建、四川和陕西群体间的遗传分化水平较低(Fst<0.017)。研究结果有利于了解福建省Psa的来源,为阻断Psa的传播和猕猴桃细菌性溃疡病的长期可持续控制提供了理论参考。     

猕猴桃溃疡病菌不致病菌株G230的鉴定及形成原因分析

为探索田间猕猴桃溃疡病菌Pseudomonas syringae pv. actinidiae(Psa)致病力丧失的分子机制,针对从猕猴桃果园中分离获得的1株不致病菌株G230,通过特异性引物检测和多基因序列分析明确其分类地位,并设计引物检测其是否由已知遗传变异引起,通过比较基因组学、基因表达、超敏反应和荧光素酶报告菌株检测确定引起菌株G230致病力丧失的原因。结果表明,不致病菌株G230为Psa生物型3(Psa3),其致病缺陷不是由已报道的遗传变异引起;基于基因组比较分析发现菌株G230中的hrpS基因被转座子ISPsy36插入破坏,导致Ⅲ型分泌系统（type Ⅲ secretion system,T3SS）不能正常表达;而在不致病菌株G230中表达hrpS基因后能恢复其T3SS功能,使其具备致病能力及激发非寄主超敏反应的能力。表明转座子ISPsy36插入hrpS基因内部可以破坏Psa的T3SS功能进而使其丧失致病力,这是自然条件下Psa3丧失致病力的一种新型机制。     

猕猴桃溃疡病菌Ⅲ型效应蛋白HopAZ1功能研究与互作蛋白鉴定

细菌Ⅲ型分泌系统可向寄主植物细胞分泌多种效应蛋白,在丁香假单胞菌猕猴桃致病变种(Psa)侵染猕猴桃致病中发挥关键作用.但是,尚不清楚Psa如何利用这些效应蛋白与寄主互作.Psa的5个生物型群体具有不同种类的效应子,但其中共有的14个效应子可能是参与病菌与寄主亲和互作的关键因子.本研究系统调查了其中HopAZ1的功能.结...     

猕猴桃溃疡病菌的分子检测技术研究

 猕猴桃溃疡病是猕猴桃生产上的主要病害,为建立该病的快速诊断技术,本实验通过RAPD分析获得一条1 300 bp左右的致病菌的特异片段,对该片段进行克隆测序,在测序的基础上设计并合成一对特异引物F7/R7,优化特异引物扩增条件,并验证引物的特异性和灵敏性。利用该特异引物对包括猕猴桃溃疡病菌在内的14个菌株基因组DNA进行PCR扩增表明,只有猕猴桃溃疡病菌能扩增出1条约为950 bp的特异条带,其他菌株及对照均未扩增出特异条带。对采自果园的染病枝干组织和接种致病菌的枝干组织的检测表明,该特异引物能特异性地检测到猕猴桃溃疡病菌的存在,其在组织中的检测灵敏度为100 fg/μL。因此,利用设计合成的特异引物F7/R7,参考优化的体系和程序,结合简单的试剂盒法提取猕猴桃溃疡病菌或植物组织DNA,可以在短时间内完成对该病原菌的分子检测。     

基于全基因序列的中国北方3省(区)马铃薯Y病毒遗传多样性分析

本研究以马铃薯Y病毒(PVY)全基因组为基础,分析吉林、黑龙江和内蒙古3省(区)PVY群体遗传多样性和群体分化,并评估突变、重组、选择等遗传力所起的作用。根据已报道的PVY全基因序列保守区设计4对引物,采用片段重叠法对来自内蒙古和吉林的24个PVY分离物全基因序列进行测定,并联合NCBI中已登录的9个黑龙江分离物全基因组序列进行遗传多样性参数评估、群体分化检验和分子变异等分析。结果显示,我国北方3省(区)PVY群体遗传多样性高,其中内蒙古和黑龙江PVY群体遗传多样性高于吉林群体,并且3个群体之间呈现一定程度的遗传分化。分子变异分析发现在PVY基因组中存在1 786个变异位点,表明我国北方3省(区)PVY群体变异程度较高,并且这种高变异度有85.54%来自各个马铃薯种植区内PVY个体的遗传变异。重组分析和系统发育分析发现,我国北方3省(区)PVY群体中重组株系占比高达90.3%,并具有明显的株系多样性,表明PVY重组株系已成为我国北方3省(区)马铃薯种植区的流行株系。选择压力分析显示,使用FEL和IFEL法分别检测出501个和315个净化压力选择位点,这表明3省(区)PVY群体受净化选择压力为主。以上结果表明,中国北方3省(区)PVY群体遗传多样性高,突变、重组和自然选择都对遗传多样性和群体分化存在一定影响。     

湖南猕猴桃溃疡病菌16S rDNA和16S-23S rDNA间隔区序列的克隆与分析

为明确湖南省猕猴桃溃疡病其致病菌的种类与特征,以猕猴桃主栽品种红阳、米良1号的溃疡病感病枝条为材料,采用BPA培养基、平板划线和梯度稀释法分离病原菌。利用引物27F/1492R和Psa F1/Psa R2对湖南省猕猴桃溃疡病菌16S r DNA和16S-23S r DNA间隔区序列(ITS)进行PCR扩增并进行核苷酸序列测定及相似性分析。获得Psa-JSHY株系、Psa-LXHY株系以及Psa-LXML株系的16S r DNA基因片段1 383 bp及16S-23S r DNA间隔区序列280 bp,且序列一致。经序列相似性比较表明:所分离株系的16S r DNA与法国181、新西兰ABAC9、意大利IKB4等株系的16S r DNA基因序列一致,与日本的KW11等株系存在3个碱基的差异,相似性为99.78%,与国内分离的11-830-1株系存在4个碱基的差异,相似性为99.71%;16S-23S r DNA-ITS序列与中国SXHY11-1、西班牙EFA131.1、葡萄牙PA838、韩国KBE9等株系的ITS序列一致。构建16S r DNA及16S-23S r DNA-ITS序列的进化树,可以看出所分离的株系与已报道的P.syringae pv.actinidiae各菌株聚在同一个进化枝上。以上结果表明,湖南地区分离的3个猕猴桃溃疡病菌致病株系均属于P.syringae pv.actinidiae。     

假茄科雷尔氏菌菌株RSCM的全基因组测序及基因组比较分析

为丰富假茄科雷尔氏菌Ralstonia pseudosolanacearum基因组数据库并探索其致病机理，以前期从南瓜上分离的菌株RSCM为研究对象，采用第二代Illumina平台与第三代PacBio平台相结合的测序技术对其进行全基因组测序，利用SMRT Link、Arrow和eggNOG等软件对测序得到的原始数据进行组装、拼接和注释，并通过比较基因组方法分析其与菌株GMI1000的差异。结果表明，菌株RSCM基因组大小约为6 000 712 bp，由3 788 542 bp的环形染色体和2 212 170 bp的环形宏质粒组成，含有5 047个编码基因，其中分别有3 579、4 240、3 171个基因获得GO、COG和KEGG数据库的注释；在菌株RSCM基因组中预测到58个tRNA、4个5S rRNA、4个16S rRNA、4个23S r RNA和4个ncRNA，含有5个前噬菌体序列和35个基因组岛。ANI分析发现研究对象与菌株GMI1000的亲缘性最近，ANI值为99.0%；基因组对比分析结果显示，与菌株GMI1000相比，菌株RSCM中存在易位、倒置、易位兼倒置的基因有571个...     

Highly specific assays to detect isolates of Pseudomonas syringae pv. actinidiae biovar 3 and Pseudomonas syringae pv. actinidifoliorum directly from plant material

Pseudomonas syringae pv. actinidiae (Psa) is responsible for bacterial canker of kiwifruit. Biovar 3 of Psa (Psa3) has been causing widespread damage to yellow‐ and green‐fleshed kiwifruit (Actinidia spp.) cultivars in all the major kiwifruit‐producing countries in the world. In some areas, including New Zealand, P. syringae pv. actinidifoliorum (Pfm), another bacterial pathogen of kiwifruit, was initially classified as a low virulence biovar of Psa. Ability to rapidly distinguish between these pathovars is vital to the management of bacterial canker. Whole genome sequencing (WGS) data were used to develop PCR assays to specifically detect Psa3 and Pfm from field‐collected material without the need to culture bacteria. Genomic data from 36 strains of Psa, Pfm or related isolates enabled identification of areas of genomic variation suitable for primer design. The developed assays were tested on 147 non‐target bacterial species including strains likely to be found in kiwifruit orchards. A number of assays did not proceed because although they were able to discriminate between the different Psa biovars and Pfm, they also produced amplicons from other unrelated bacteria. This could have resulted in false positives from environmental samples, and demonstrates the care that is required when applying assays devised for pure cultures to field‐collected samples. The strategy described here for developing assays for distinguishing strains of closely related pathogens could be applied to other diseases with characteristics similar to Psa.     

茶树叶斑病病原菌可可毛色二孢菌的鉴定

The tea leaf disease, which led to a large loss of production and decrease of quality, was found in the tea region in Huishui county, Guizhou province. Some strains were isolated from the diseased samples, and the representative strains fulfilled Koch’s postulate. Then the isolates were further identified as Lasiodiplodia theobromae based on morphological characters and phylogenetic analysis with internal transcribed spacer (ITS) and elongation factor 1-α (EF-1α) regions. The results showed that the pathogen of the leaf disease occurred in Huishui county, Guizhou province was L. theobromae.     

茶树叶斑病病原菌可可毛色二孢菌的鉴定

<正>可可毛色二孢菌(Lasiodiplodia theobromae Pat. Griffon Maubl.)属葡萄座腔菌属(Botryosphaeria)病原菌的无性型,其有性型为Botryosphaeria rhodina(Berk. M.A. Curtis)Arx[1,2]。该病原菌可导致热带、亚热带地区的植物发生病害,如葡萄树干溃疡和顶梢枯死[3],春芋叶斑病[4],橄榄溃疡病[5]等。叶斑病是茶树的一类重要病害。近年来,不     

Comparative genomics‐informed design of two LAMP assays for detection of the kiwifruit pathogen Pseudomonas syringae pv. actinidiae and discrimination of isolates belonging to the pandemic biovar 3

The aim of this study was to develop a rapid, sensitive and reliable field‐based assay for detection of the quarantine pathogen Pseudomonas syringae pv. actinidiae (Psa), the causal agent of the most destructive and economically important bacterial disease of kiwifruit. A comparative genomic approach was used on the publicly available Psa genomic data to select unique target regions for the development of two loop‐mediated isothermal amplification (LAMP) assays able to detect Psa and to discriminate strains belonging to the highly virulent and globally spreading Psa biovar 3. Both LAMP assays showed specificity in accordance with their target and were able to detect reliably 125 CFU per reaction in less than 30 min. The developed assays were able to detect the presence of Psa in naturally infected kiwifruit material with and without symptoms, thus increasing the potential of the LAMP assays for phytosanitary use.     

Current situation and characterization of Pseudomonas syringae pv. actinidiae on kiwifruit in Galicia (northwest Spain)

Bacterial canker of kiwifruit, caused by Pseudomonas syringae pv. actinidiae (Psa), is a disease that is spreading rapidly in several kiwifruit‐producing countries, causing significant economic losses. In 2011, it was detected for the first time in Spain, in the south of Galicia (northwest Spain). Kiwifruit orchards were therefore inspected and sampled in 2011 and 2012 to determine the pathogen distribution, and the isolates obtained were characterized by morphology, fatty acids profile, biochemical tests and molecular techniques. Isolates were obtained from Actinidia deliciosa ‘Hayward’ (from leaves, canes, flower buds, fruits and roots), from A. deliciosa ‘Summer’, from Actinidia chinensis ‘Jin Tao’ (from canes and leaves) and from A. chinensis pollinator ‘Belén’ (from canes). Results of the analysis of the cfl gene (phytotoxin production‐related), the tox–argK gene cluster and phylogenetic analysis of the cts gene demonstrated that all Psa isolates from northwest Spain correspond to the Psa3 population, which includes strains of haplotype 2. This is the first record of Psa3 and haplotype 2 in Spain.     

Modification of a multiple‐locus variable number tandem repeat analysis (MLVA) for typing isolates of Erwinia amylovora

Erwinia amylovora, the causal agent of fire blight that affects economically important rosaceous plants, is reported among the most important plant pathogenic bacteria. The low genetic diversity within E. amylovora and the lack of simple and high‐resolution genotyping techniques make epidemiology and evolutionary studies challenging for this pathogen. A multiple‐locus variable number tandem repeat analysis (MLVA) based on a set of nine variable number tandem repeat loci was successfully used to type 46 E. amylovora isolates collected from different host plants in 16 countries, mainly Mediterranean. The nine polymorphic loci proved to have high discriminatory power and to increase the resolution of the MLVA. Thirty‐eight haplotypes clustered in seven clonal complexes. The results identified potentially useful genetic markers among the Mediterranean strains, particularly from the Balkan Peninsula and the Eastern Mediterranean countries. Different MLVA types were observed amongst Italian strains only, indicating the possibility of multiple introductions of the disease. MLVA can be used effectively as a fast, cheap, and simple tool to track E. amylovora infection sources, to gain insight into geographic diversity, and to understand the dynamic evolution of the pathogen.