Detection of <Emphasis Type="Italic">Agrobacterium vitis</Emphasis> by PCR using novel <Emphasis Type="Italic">virD2</Emphasis> gene-specific primers that discriminate two subgroups

Tumour tissue samples were collected from vines grown in various regions of Italy and other parts of Europe and extracted for detection of Agrobacterium vitis. Fifty strains were isolated on agar plates and screened by PCR with consensus primers from the virD2 gene. They were confirmed as A. vitis with a species-specific monoclonal antibody. The isolates were further analyzed by PCR for their opine synthase genes and ordered into octopine, nopaline and vitopine strains. Primers designed on the octopine synthase gene did not detect octopine strains of Agrobacterium tumefaciens. For quantitative PCR, virD2 fragments were sequenced: two classes of virD2 genes were found and two primer sets designed, which detected octopine and nopaline strains or only vitopine strains. For simultaneous identification of all opine-type strains, multiplex real-time PCR with either primer pair and SYBR Green was performed: the combined sets of primers gave signals with DNA from any A. vitis strain. Specificity of the new primers for real-time PCR was evaluated using several unidentified bacterial isolates from grapevines and other plant species. An elevated level of non-specific background was observed when the combined primer sets were used in multiplex PCR assays. The real-time PCR protocol was also used to detect A. vitis cells directly from grapevine tumours; avoiding direct isolation procedures a sensitivity in the range of one to ten cells per assay was found. Inhibition of the PCR reaction by plant material was overcome by treating tumour extracts with a DNA purification kit as a step for the isolation of nucleic acids.     

Development of a polyvalent RT‐PCR detection assay covering the genetic diversity of Cherry capillovirus A

The variability of Cherry capillovirus A (CVA) was analysed using a short, 275‐bp region of the viral RNA‐dependent RNA polymerase gene amplified by a polyvalent RT‐PCR assay. As for other members of the family Betaflexiviridae, CVA appears to show significant diversity, with an average pairwise nucleotide divergence of 9·4% between isolates in the analysed region. Phylogenetic analyses provide evidence for the existence of at least five clusters of CVA isolates, one of which is associated with noncherry hosts of the virus, providing evidence that transmission of CVA isolates between cherry and noncherry hosts is probably rare. Comparison of existing detection techniques using a panel of CVA isolates representative of the various phylogenetic groups indicated that dot‐blot hybridization assays show high polyvalence but may lack the sensitivity to detect CVA in some samples. On the other hand, available detection primers failed to amplify a wide range of CVA isolates. Partial genome sequencing of two divergent isolates allowed the identification of conserved genomic regions and the design of new primer pairs with improved polyvalence. These new primer pairs were used to develop PCR assays allowing the reliable detection of CVA isolates belonging to all phylogenetic clusters.     

PCR-based assays to detect and quantify <Emphasis Type="Italic">Phomopsis sclerotioides</Emphasis> in plants and soil

We developed polymerase chain reaction (PCR) assays to detect and quantify Phomopsis sclerotioides, the causal agent of black root rot of cucurbits. We used internal transcribed spacers 1 and 2 of the ribosomal DNA (rDNA) from representative isolates to search for target sequences. Primer pairs were selected after testing against 40 fungal isolates including 13 Ph. sclerotioides isolates, 9 Phomopsis isolates other than Ph. sclerotioides, and 18 soilborne fungi that were either pathogenic or nonpathogenic to cucurbits. Conventional PCR assays with the primer pair of CPs-1 (forward) and CPs-2 (reverse) produced target DNA amplicons from all Ph. sclerotioides isolates but none of the other isolates tested. From soil and root samples collected from fields naturally infested with black root rot of cucumber and melon, the CPs-1/CPs-2 primer pair successfully amplified target DNA fragments in conventional PCR assays. Moreover, we applied the CPs-1/CPs-2 primer pair in a real-time PCR assay with SYBR Green I, and PCR-amplified products were successfully quantified by reference to a standard curve generated by adding known amounts of target DNA. Target Ph. sclerotioides DNA fragments were similarly detected in artificially inoculated roots of cucumber, melon, pumpkin, and watermelon, but quantities of Ph. sclerotioides DNA in their hypocotyls of the hosts varied as follows: melon ≥ cucumber ≥ watermelon > pumpkin. These results suggest that Ph. sclerotioides infection is not species-specific but the rate of infection may differ among host species.     

First report of <Emphasis Type="Italic">Candidatus</Emphasis> Phytoplasma prunorum infecting almonds in Tunisia

Candidatus Phytoplasma prunorum was detected for the first time in almond (Prunus dulcis Mill.) cv. ‘Abiod’ in Tunisia. Infected trees showed emergence of new growth during dormancy and leafed out before flowers opened in addition to early defoliation in summer. Phytoplasma was detected by nested polymerase chain reaction (PCR) using universal phytoplasma primer pairs P1/P7 and F2n/R2. A band with expected size was observed in samples collected from five symptomatic, but not symptomless almond trees. PCR products (1.2 kbp) were used for restriction fragment length polymorphism (RFLP) analysis after digestion with endonucleases RsaI and SspI. RFLP patterns obtained were similar to those reported previously for the European stone fruit yellows (ESFY, 16SrX-B). Identification has been further confirmed by PCR using ESFY specific primer pairs (ECA1/ECA2). This is the first report of Ca. Phytoplasma prunorum infecting almonds in Tunisia.     

Monitoring changing virulence patterns of <Emphasis Type="Italic">Uromyces appendiculatus</Emphasis> in the resistant pinto bean cultivar Olathe by rep-PCR

Corresponding molecular markers associated with avirulence or virulence genes in the bean rust pathogen are currently unknown, although host resistance genes have been linked to molecular markers in bean. The changing virulence patterns in pathotypes of Uromyces appendiculatus collected over a 14-year period after the release of the Ur-6 resistance gene on the USA high plains were therefore analyzed using rep-PCR molecular markers. Isolates from two neighbouring pathotype groups from Colorado and Nebraska were screened using the rep-PCR primer Box-AIR. The PCR fragment Box ₄₇₅ was cloned and sequenced and a specific primer set ATA-2 was designed. This primer yielded 10 polymorphic products which allowed separation of these isolates into two distinct groups and will be useful for future analysis of the population genetics of this organism.     

A Phytophthora conserved transposon‐like DNA element as a potential target for soyabean root rot disease diagnosis

A transposon‐like element, A3aPro, with multiple copies in the Phytophthora sojae genome, was identified as a suitable detection target for this devastating soyabean root rot pathogen. The PCR primers TrapF1/TrapR1 were designed based on unique sequences derived from the transposon‐like sequence. A 267‐bp DNA fragment was amplified using this primer pair, the specificity of which was evaluated against 118 isolates of P. sojae, 72 isolates of 25 other Phytophthora spp., isolates of Pythium spp. and isolates of true fungi. In tests with P. sojae genomic DNA, detection sensitivities of 10 pg and 10 fg DNA were achieved in standard PCR (TrapF1/TrapR1) and nested PCR (TrapF1/TrapR1 and TrapF2/TrapR2), respectively. Meanwhile, PCR with TrapF1/TrapR1 primers detected the pathogen at the level of a single oospore, and even one zoospore. These primers also proved to be efficient in detecting pathogens from diseased soyabean tissues, residues and soils. In addition, real‐time quantitative PCR (qPCR) assays coupled with the TrapF1/TrapR1 primers were developed to detect and quantify the pathogen. The results demonstrated that the TrapF1/TrapR1 and TrapF2/TrapR2 primer‐based PCR assay provides a rapid and sensitive tool for the detection of P. sojae in plants and in production fields.     

Differentiation of two powdery mildews of sunflower (<Emphasis Type="Italic">Helianthus annuus</Emphasis>) by a PCR-mediated method based on ITS sequences

Powdery mildew can be found in most sunflower fields during the winter season in Taiwan and causes severe yellowing on the blade, petiole, stem, and calyx, as well as serious defoliation. Two types of powdery mildew fungi isolated from sunflower leaves showed variable status for fibrosin bodies. But only the cleistothecium of Podosphaera xanthii, one of the pathogens causing this disease, was observed on samples from Chungpu County at the beginning of 2005. With a species-specific primer pair, PN23/PN34, no specific PCR product was amplified from the pathogen’s genomic DNA. Based upon the ITS sequence of rDNA, three PCR primer sets (S1/S2, G1/G2, and L1/L2) specific to P. xanthii, Golovinomyces cichoracearum and Leveillula taurica, respectively, were designed to detect and differentiate pathogens causing powdery mildews on sunflower. Only the primer pairs S1/S2 and G1/G2 could amplify PCR products, with product sizes of 454 and 391 bp, respectively. Four samples of fungal DNA were subjected to a multiplex PCR amplification with primer pairs S1/S2 and G1/G2; P. xanthii and G. cichoracearum were successfully detected. These results suggest that the multiplex PCR method is a rapid, simple, and effective technique to detect and differentiate powdery mildews, for example P. xanthii and G. cichoracearum, found on sunflower. With morphologic characteristics, ITS sequence analysis and pathogenicity testing, P. xanthii and G. cichoracearum, the first case, are two powdery mildews on sunflower in Taiwan.     

A novel pair of universal primers for the detection of potyviruses

A novel pair of universal primers was developed to detect potyvirus species after conserved sites were identified using all full‐length potyvirus sequences available by 2005. The breadth of specificity of the new primers, NIb2F and NIb3R, was investigated and compared with the specificity of two routinely used primer pairs in plant virus diagnostic laboratories. RNA from 40 potyvirus isolates representing 23 recognized and three possible new species was tested. Reactions with NIb2F and NIb3R produced amplicons of 350 bp from all 40 virus isolates tested. Reactions with the previously published WCIEN and Potyvirid primers amplified cDNA from 32 and 21 isolates, representing possibly 21 and 15 species, respectively. The identity of 12 unknown potyvirus isolates was confirmed by sequencing and three were found to be potentially distinct potyvirus species. Gel banding patterns from reactions with NIb2F and NIb3R were simpler to interpret than those from reactions with the other two primer sets; fewer products were visible and the cDNA fragments were less variable in size. RT‐PCR with the novel primers is predicted to be able to detect virus isolates from all major groups within the genus Potyvirus and its reliability makes it well suited for use as a routine diagnostic assay.     

PCR‐based identification of Pythium spp. causing cavity spot in carrots and sensitive detection in soil samples

On the basis of ITS sequences PCR primers were designed for the identification of the five Pythium species found to be most important for the development of carrot cavity spot in Norway: P. intermedium, P. sulcatum, P. sylvaticum, P. violae and P. ‘vipa’. The P. ‘vipa’ isolates had a unique ITS sequence, differed morphologically from all other Pythium isolates, and thus probably represent a new species. The PCR primers were species‐specific with no cross‐reaction to other Pythium species or to fungal isolates from carrot tested. The detection limits varied for the different primer pairs. The two most sensitive assays allowed detection of as little as 5 fg DNA. All five Pythium species could be detected in lesions from diseased carrots. Weak positive signals were obtained from some carrot samples without symptoms. PCR assays allowed detection of pathogens in soil. In samples of soil known to produce cavity spots on cropped carrots, strong signals were obtained. In several soil samples more than one of the five Pythium species could be detected. The utilization of this diagnostic PCR assay in analysis of field soil and carrot tissue might in the future be exploited to reduce the incidence of this serious carrot disease.     

Identification and Detection of Rosellinia Necatrix by Conventional and Real-time Scorpion-PCR

Several polymerase chain reaction (PCR) primers were designed from the internal transcribed spacer (ITS) regions of the rDNA genes of Rosellinia necatrix to develop a PCR-based identification method. Screening the primers against two isolates of R. necatrix and six other Rosellinia species resulted in the amplification of a single specific product from R. necatrix for most of the primer pairs. Two primer pairs (R2-R8 and R10-R7) confirmed their specificity when tested against 72 isolates of R. necatrix and 93 other fungi from different hosts and geographic areas. The R10 primer was modified to obtain a Scorpion primer for detecting a specific 112bp amplicon by fluorescence emitted from a fluorophore in a self-probing PCR assay. This assay specifically recognised the target sequence of R. necatrix over a large number of other fungal species. In conventional PCR, with primer pairs R2-R8 and R10-R7, 10-fold dilutions of R. necatrix DNA indicated a detection limit of 10pgul^-1 using a single set of primers and 10fgl^-1 in nested-PCR. For Scorpion-PCR, the detection limit was 1pgl^-1 and 1fgl^-1 in nested Scorpion-PCR, i.e. 10 times more sensitive than conventional PCR. A simple and rapid procedure for DNA extraction directly from soil was modified and developed to yield DNA of purity and quality suitable for PCR assays. Combining this protocol with the nested Scorpion-PCR procedure it has been possible to specifically detect R. necatrix from artificially inoculated soils in approximately 6h.     

Detection of Phytophthora nicotianae and P. citrophthora in Citrus Roots and Soils by Nested PCR

The polymerase chain reaction (PCR) was used for the specific detection of Phytophthora nicotianae and P. citrophthora in citrus roots and soils. Primers were based on the nucleotide sequences of the internal transcribed space regions (ITS1 and ITS2) of 16 different species of Phytophthora. Two primer pairs, Pn5B–Pn6 and Pc2B–Pc7, were designed specifically to amplify DNA from P. nicotianae and P. citrophthora, respectively. Another primer pair (Ph2–ITS4) was designed to amplify DNA from many Phytophthora species. All primer pairs were assessed for specificity and absence of cross-reactivity, using DNA from 118 isolates of Phytophthora and 82 of other common soil fungi. In conventional PCR, with a 10-fold dilution series of template DNA, the limit of detection was of 1pgl^–1 DNA for all the primer pairs (Ph2–ITS4, Pn5B–Pn6, and Pc2B–Pc7). In nested PCR, with primers Ph2–ITS4 in the first round, the detection limit was of 1fgl^–1 for both the primer sets (Pn5B–Pn6 and Pc2B–Pc7). Simple, inexpensive and rapid procedures for direct extraction of DNA from soil and roots were developed. The method yielded DNA of a purity and quality suitable for PCR within 2–3h. DNA extracted from soil and roots was amplified by nested PCR utilizing primers Ph2–ITS4 in the first round. In the second round the primer pairs Pn5B–Pn6 and Pc2B–Pc7 were utilized to detect P. nicotianae and P. citrophthora, respectively. Comparison between the molecular method and pathogen isolation by means of a selective medium did not show any significant differences in sensitivity.     

Development of a molecular marker for specific detection of <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> f. sp. <Emphasis Type="Italic">cubense</Emphasis> race 4

Fusarium oxysporum f. sp. cubense is the causal agent of Panama disease of banana. A rapid and reliable diagnosis is the foundation of integrated disease management practices in commodity crops. For this diagnostic purpose, we have developed a reliable molecular method to detect Foc race 4 isolates in Taiwan. By PCR amplification, the primer set Foc-1/Foc-2 derived from the sequence of a random primer OP-A02 amplified fragment produced a 242 bp size DNA fragment which was specific to Foc race 4. With the optimized PCR parameters, the molecular method was sensitive and could detect small quantities of Foc DNA as low as 10 pg in 50 to 2,000 ng host genomic DNA with high efficiency. We also demonstrated that by using our PCR assay with Foc-1/Foc-2 primer set, Foc race 4 could be easily distinguished from other Foc races 1 and 2, and separated other formae speciales of F. oxysporum. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

New natural host plants of ‘Candidatus Phytoplasma pini’ in Poland and the Czech Republic

The presence of phytoplasmas in seven coniferous plant species (Abies procera, Pinus banksiana, P. mugo, P. nigra, P. sylvestris, P. tabuliformis and Tsuga canadensis) was demonstrated using nested PCR with the primer pairs P1/P7 followed by R16F2n/R16R2. The phytoplasmas were detected in pine trees with witches’ broom symptoms growing in natural forest ecosystems and also in plants propagated from witches’ brooms. Identification of phytoplasmas was done using restriction fragment length polymorphism analysis (RFLP) of the 16S rDNA gene fragment with AluI, MseI and RsaI endonucleases. All samples showed RFLP patterns similar to the theoretical pattern of ‘Candidatus Phytoplasma pini’, based on the sequence of the reference isolate Pin127S. Nested PCR‐amplified products, obtained with primers R16F2n/R16R2, were sequenced. Comparison of the 16S rDNAs obtained revealed high (99·8–100%) nucleotide sequence identity between the phytoplasma isolates. The isolates were also closely related to four other phytoplasma isolates found in pine trees previously. Based on the results of RFLP and sequence analyses, the phytoplasma isolates tested were classified as members of the ‘Candidatus Phytoplasma pini’, group 16SrXXI.     

十字花科蔬菜黑斑病菌的PCR鉴定

 在对十字花科蔬菜黑斑病菌(Alternaria sp.)3个种及相近种的5.8SrDNA和其侧翼ITS区进行测序的基础上,分别设计合成了鉴定白菜黑斑病菌3个种的特异性引物。PCR扩增结果表明:Abre1和Abre2引物对能特异性扩增芸苔链格孢(A.brassicae)371bp的片段,Abra1和Abra2引物对能特异性扩增甘蓝链格孢(A.brassicicola)457bp的片段,Ajap1和Ajap2引物对能特异性扩增萝卜链格孢(A.japonica)411bp的片段,而且其它近源种未扩增出目标片段,说明这3个引物对可以作为十字花科蔬菜黑斑病菌3个种快速检测鉴定的分子特征标记。     

Rapid detection of Phytophthora cinnamomi using PCR with primers derived from the Lpv putative storage protein genes

Phytophthora cinnamomi is an ecologically and economically important pathogen. In this study, PCR assays were developed with primer pair LPV2 or LPV3 for rapid detection and identification of this organism. Both primer pairs were selected from putative storage protein genes. The specificity of these primer pairs was evaluated against 49 isolates of P. cinnamomi , 102 isolates from 30 other Phytophthora spp., 17 isolates from nine Pythium spp. and 43 isolates of other water moulds, bacteria and true fungi. PCR with both primer pairs amplified the DNA from all isolates of P. cinnamomi regardless of origin. The LPV3 primers showed adequate specificity among all other species tested. The LPV2 primers cross-reacted with some species of Pythium and true fungi, but not with any other Phytophthora species. PCR with the LPV3 primers detected the pathogen at levels of a single chlamydospore or 10 zoospores in repeated tests. The PCR assay was at least 10 times more sensitive than the plating method for detection of the pathogen from artificially infested soilless medium, and, to a lesser extent, from naturally infected plants. PCR with LPV3 primers can be a useful tool for detecting P. cinnamomi from soilless media and plant tissues at ornamental nurseries, whereas the LPV2 primers can be an effective alternative for identification of this species from pure culture. Applications of these assays for detection of P. cinnamomi in other environments were also discussed.     

Enhanced detection and isolation of the walnut pathogen <Emphasis Type="Italic">Brenneria rubrifaciens</Emphasis>, causal agent of deep bark canker

Deep bark canker (DBC) of walnut is caused by the bacterium Brenneria rubrifaciens which produces the red pigment rubrifacine. This disease of English walnut trees, is characterized by deep vertical cankers which exude sap laden with B. rubrifaciens. Although DBC is not observed on young trees, it is hypothesized that B. rubrifaciens is present in host tissue years before symptom development. Therefore, a sensitive technique would be useful in detecting B. rubrifaciens in asymptomatic trees. Tn5 mutants deficient in rubrifacine production (pig ⁻) were generated and DNA sequences from pig ⁻ mutants were used to design two primer sets; GSP1F–GSP1R and GSP2F–GSP2R. A third primer pair, BR1–BR3 was designed from the 16S rRNA gene. The three primer pairs did not amplify the diagnostic bands from members of the following bacterial genera: Agrobacterium, Erwinia, Pseudomonas, Ralstonia, and Rhizobium. In addition, no amplification was observed using DNA from the following Brenneria species, alni, nigrifluens, quercina, or salicis. All three DNA primer sets detected B. rubrifaciens in spiked greenhouse soil and infiltrated walnut leaf tissue. PCR detection limits for BR, GSP1, and GSP2 primer pairs were 254, 254, and 2.54 × 10⁴ colony forming units (CFU) respectively. Real-time PCR detection limit for BR primers was 8 CFU. The differential medium, yeast extract dextrose calcium carbonate agar (YDCA) was amended with novobiocin, and bacitracin, to enhance isolation from environmental samples. The improved detection and isolation methods described here will facilitate examination of B. rubrifaciens ecology under both nursery and orchard conditions.     

Species-specific PCRs differentiate <Emphasis Type="Italic">Rosellinia necatrix</Emphasis> from <Emphasis Type="Italic">R. compacta</Emphasis> as the prevalent cause of white root rot in Japan

Rosellinia compacta, described recently, resembles R. necatrix and also causes white root rot. Here a species-specific PCR was developed for R. compacta, and the two R. necatrix-specific primer sets already available were validated in terms of species specificity. PCRs using the primer sets for R. necatrix amplified specific products exclusively from R. necatrix isolates. The R. compacta-specific primer set exclusively detected R. compacta, which appears to be a rare but widely distributed species. We conclude that R. necatrix is the major cause of the disease in Japan but that the involvement of R. compacta should be studied further.     

Monilinia species identified on peach and nectarine in Croatia,with the first record of Monilinia fructicola

During 2012, an official survey was conducted for Monilinia species present on peach and nectarine in Croatia. In total, 169 Monilinia spp. isolates were collected from 24 commercial orchards and identified according to morphology in culture and PCR. Eighty of the isolates were identified as Monilinia laxa, 70 as M. fructigena and 19 as M. fructicola. M. fructicola was found only at one location in the Mediterranean part of the country, and this is the first record of this quarantine fungus in Croatia. PCR diagnostic tests using M. fructicola‐specific primer pair MO368‐5/MO368‐10R repeatedly gave false negatives for some isolates. PCR tests using primer pair ITS1‐Mfc1/ITS4‐Mfc1 amplified M. fructicola‐specific product in all isolates and was therefore shown to be more suitable for diagnostic purposes.     

大豆疫霉多态性SSR标记开发及遗传多样性分析

 用FastPCR软件在大豆疫霉全基因组中搜索到1 234个含2~4个重复基元精确SSRs。选择260个SSRs设计引物,经对大豆疫霉5个分离物的基因组DNA检测,有212对(81.5%)有效扩增出SSR特征条带,112对(52.8%)扩增多态性。用18对多态性SSR引物分析了来自美国、中国黑龙江省和福建省大豆疫霉分离物的遗传多样性,在73个分离物中共扩增出112个等位变异,变异范围为4~9,平均为6.22个,表明选择的引物对具有高的多态性。在3个大豆疫霉群体中,黑龙江省和福建省分离物的遗传距离最近,美国和福建省分离物的遗传距离最远。UPGMA聚类将73个分离物划分为6组,其中8个美国分离物(72.73%)和53个中国分离物(85.48%)被聚类在一起,表明大豆疫霉中国分离物与美国分离物可能具有共同的祖先,中国分离物可能为外来种。     

PCR detection of Fusarium oxysporum f.sp. gladioli race 1, causal agent of Gladiolus yellows disease, from infected corms

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.