Real-time Scorpion-PCR detection and quantification of <Emphasis Type="Italic">Erwinia amylovora</Emphasis> on pear leaves and flowers

A specific primer couple (E3–E4) amplifying a single DNA fragment of 111 bp from plasmid pEA29 was designed to identify, detect and quantify Erwinia amylovora by real-time Scorpion-PCR. Specificity of primers and probe was assessed both by means of BLAST analyses and by using genomic DNA from a large number of E. amylovora isolates and other bacteria. In Scorpion-PCR, the limit of detection was of 1 pg of total DNA and a high correlation (r = 0.999) was achieved between target DNA quantity and cycle threshold (Ct). Combining two sequential amplifications with conventional reported primers (PEANT1–PEANT2) and Scorpion primers (E3 Scorpion-E4) the detection limit was of 1 fg (nested Scorpion-PCR). Using serial dilution of the bacterial suspensions the limit of detection was 3.2 × 10⁴ CFU ml⁻¹ in Scorpion-PCR and 2.8 × 10² CFU ml⁻¹ in nested Scorpion-PCR. Real-time PCR combined with effective procedures for DNA extraction enabled the detection and the quantification of the epiphytic population of E. amylovora in the washings of flowers and leaves of artificially inoculated pear. A significant correlation (r = 0.92) was achieved between pathogen CFU on semi-selective media and the corresponding target DNA concentration evaluated by real-time PCR.     

Development of Real-Time PCR for in wood-detection of Ceratocystis platani, the agent of canker stain of Platanus spp.

Ceratocystis platani is a quarantine fungal pathogen agent of canker stain, a destructive disease affecting Platanus. Despite its diagnosis being critical for disease control, there is still no effective diagnostic tool as all known mycological and biological detection assays are problematical. In this study we developed highly effective Real-Time PCR methods based on the use of an intercalating dye, EvaGreen, and on a Taqman probe. We designed primers and probe on the internal transcribed spacer (ITS) region of rDNA, and used them for the amplification and detection of a 95?bp C. platani amplicon. Inference of standard curves revealed that both Real-Time procedures have similar and high values of amplification efficiency when applied to a range of templates, e.g. genomic fungal DNA and DNA extracted from diseased wood. The methods were sensitive with a detection limit of 10?fg???l^?1? C. platani genomic DNA. They were specific as they did not yield any detection signal when applied to non-target fungal taxa colonizers of Platanus wood. Reliability was demonstrated through the positive detection of a collection of C. platani isolates and of wood samples collected from naturally infected trees. Robustness was positively verified through detection on artificially infected trees, which were tested at different times after death, up to 27?months. Generating a standard curve with a target-amplicon-containing plasmid enabled an absolute quantification and a comparison between the discoloured wood of resistant and susceptible genotypes. The importance of the methods for studies on pathogen epidemiology and host resistance is also discussed.     

Molecular detection of Phytophthora capsici in infected plant tissues, soil and water

A species-specific PCR assay was developed for rapid and accurate detection of the pathogenic oomycete Phytophthora capsici in diseased plant tissues, soil and artificially infested irrigation water. Based on differences in internal transcribed spacer (ITS) sequences of Phytophthora spp. and other oomycetes, one pair of species-specific primers, PC-1/PC-2, was synthesized. After screening 15 isolates of P. capsici and 77 isolates from the Ascomycota, Basidiomycota, Deuteromycota and Oomycota, the PC-1/PC-2 primers amplified only a single PCR band of c . 560 bp from P. capsici . The detection sensitivity with primers PC-1/PC-2 was 1 pg genomic DNA (equivalent to half the genomic DNA of a single zoospore) per 25- µ L PCR reaction volume; traditional PCR could detect P. capsici in naturally infected plant tissues, diseased field soil and artificially inoculated irrigation water. Using ITS1/ITS4 as the first-round primers and PC-1/PC-2 in the second round, nested PCR procedures were developed, increasing detection sensitivity to 1 fg per 25- µ L reaction volume. The results suggested that the assay detected the pathogen more rapidly and accurately than standard isolation methods. The PCR-based methods developed here could simplify both plant disease diagnosis and pathogen monitoring, as well as guiding plant disease management.     

The development of a rapid PCR assay for detection of Fusarium moniliforme

The fungus Fusarium moniliforme infects a wide range of crops throughout the world. In maize (Zea mays L.) it causes seedling blight and root, stalk, and ear rots. A simple procedure that can be used to detect infection by F. moliliforme from infected plant tissues has been developed. A F. moniliforme genomic library was prepared and used to identify the recombinant clones containing fungal DNA sequences not hybridizing with the DNA of the host plant, maize. Based on the nucleotide sequence information obtained from the F. moniliforme pUCF2 genomic clone, specific oligonucleotides were designed and used as primers for in vitro DNA amplification by the polymerase chain reaction. An amplification product was obtained with F. moniliforme DNA preparations whereas no amplified DNA was detected with DNAs from other fungal pathogens, including various Fusarium species, or from the host plant. This PCR analysis was successfully employed to identify F. moniliforme directly from the mycelia that develop from naturally infected maize seeds, with no need to obtain pure fungal cultures for reliable diagnosis. The protocol can be used for the diagnosis of infected plants and soils in epidemiological studies of Fusarium diseases, for seed health testing, and for evaluation of susceptibility to colonization in commercial maize hybrids.     

Specific detection of Phytophthora cactorum in diseased strawberry plants using nested polymerase chain reaction

Validated protocols for DNA purification and PCR amplification are reported for detection of Phytophthora cactorum in diseased strawberry plants. To remove PCR inhibitors, necrotic strawberry tissues were soaked in 5% alconox solution for >12 h before DNA extraction, and the extracted genomic DNA was embedded in an agarose gel chamber and subjected to electrophoresis. The purified DNA was amplified reliably by PCR. Nested PCR was used to detect a portion of the rRNA gene of P. cactorum in samples. In the first round of PCR, primers ITS1 and ITS4 amplified fragments of varying sizes from total genomic DNA from diseased strawberry plants. In the second round of PCR, a 1:25 dilution of the first-round PCR products was used as template with two P. cactorum- specific primer pairs (BPhycacL87FRG and BPhycacR87RRG, which amplified a 340-bp fragment and a 480-bp fragment from the rRNA gene; and BPhycacL89FRG and BPhycacR176RRG, which amplified a 431-bp fragment). Validation tests using culture-based isolations as a standard for comparison indicated that the DNA purification and PCR primers and amplification protocols were reliable and specifically amplified a portion of the rRNA gene of P. cactorum from necrotic root, crown and petiole tissues of strawberry naturally infected by the pathogen.     

Reliable detection of unevenly distributed Verticillium dahliae in diseased olive trees

Verticillium wilt caused by Verticillium dahliae is one of the most threatening diseases of olive worldwide. For pre‐planting and post‐planting control of verticillium wilt in olive trees, availability of a rapid, reliable and non‐destructive method for detection of V. dahliae is essential. For such a method, suitable and easily performed sampling and efficient processing of samples for extraction of DNA are necessary. In this study, the suitability of young twig and leaf samples of olive trees, which are easy to collect and extract DNA from, were assessed for the detection of V. dahliae in routine procedures. The lower (about 50 cm from the tip) and top parts (about 5 cm from the tip) of twigs, as well as leaves from infected olive trees were screened for V. dahliae infection and distribution using real‐time PCR. The biomass of V. dahliae detected in individual twigs was highly variable, but there was no significant difference between mean quantities of V. dahliae DNA detected in top and lower parts of twigs. Furthermore, it was demonstrated that analysis of combined samples containing DNA extracted from five twigs of an infected tree accurately detected the presence of the pathogen. Similarly, testing combined samples of 5–10 leaves enabled reliable detection of the pathogen in an infected tree. The development of this assay enables reliable detection of V. dahliae in infected olive trees that can aid in management decisions for the implementation of integrated disease management.     

Rapid preparation of Fusarium DNA from cereals for diagnostic PCR u sing sonification and an extraction kit

Several PCR methods have recently been developed for Fusarium analysis in pure cultures. To use these new techniques in mycological studies and in industrial quality control, a protocol was set up for the rapid preparation of fungal DNA from cereals. An ultrasonification probe (sonotrode) and a lysis buffer were used for mechanical lysis of mycelia from infected grains. Following ultrasonification, DNA was isolated using a commercially available kit. DNA preparation was completed within 5 min per sample. The method resulted in DNA of sufficient quality and quantity for diagnostic PCR. Group- and species-specific primers were used to detect DNA of Fusarium graminearum and F. culmorum in species-specific assays as well as trichothecene-producing Fusarium spp. in a group-specific system. A minimum of one F. graminearum -infected grain added to an uninfected 40 g wheat sample was detectable with a species-specific PCR. The PCR signals produced with primers specific for the tri5 gene of trichothecene-producing Fusarium spp. and with primers for the detection of F. graminearum (gaoA) were in accordance with corresponding concentrations of deoxynivalenol (DON) found in samples by HPLC analysis. The speed of the protocol developed may promote the use of PCR in routine applications in an agro-industrial context.     

PCR-based detection of Colletotrichum acutatum on strawberry

An oligonucleotide primer ( Ca Int 2) was synthesized from the variable internal transcribed spacer (ITS) 1 region of ribosomal DNA (rDNA) from Colletotrichum acutatum . PCR with primers Ca Int2 and ITS4 (from a conserved sequence of the rDNA) amplified a 490 bp fragment from several isolates of C. acutatum but not from other members of the genus Colletotrichum . Amplification of this fragment was achieved from 100 fg of fungal DNA. These primers amplified a fragment of the same size from DNA extracted from strawberry tissues infected by C. acutatum . Southern hybridization analysis confirmed the 490 bp fragment from C. acutatum DNA and infected strawberry to be identical. The species-specific primer ( Ca Int2) developed in this work could be used for the accurate identification of C. acutatum and its detection on other host plants.     

Development of RT‐PCR assays using fluorogenic‐3′ minor groove binder DNA probes for detection of fruit tree viruses*

In phytosanitary certification, there is currently a need for the development of reliable, sensitive and rapid tests for the routine detection of Ilarviruses and latent viruses from fruit trees during the dormant season. We have developed real‐time RT‐PCR assays that allow the reliable detection of Prunus necrotic ringspot ilarvirus, Apple chlorotic leafspot trichovirus and Apple stem pitting virus in bark tissues of dormant wood. These assays are well adapted for the routine detection of these three viruses because they eliminate one risk of contamination by performing the whole test in a single closed tube.     

A nested-polymerase chain reaction protocol for the detection of Mycosphaerella nawae in persimmon

Mycosphaerella nawae is the causal agent of circular leaf spot of persimmon. A polymerase chain reaction (PCR) based protocol was developed for M. nawae-specific identification from pure culture, or infected symptomatic and asymptomatic persimmon tissues. Variation among the internal transcribed spacer regions (ITS) of the ribosomal DNA (rDNA) sequences of potentially related fungal species in persimmon orchards was analyzed for a primer pair design. Specificity was confirmed using multiple isolates of these species, other fungal pathogens that cause foliar diseases in persimmon and contaminants commonly obtained in the isolation process. The detection threshold for M. nawae DNA was lowered from 50 pg to 500 fg when nested-PCR was evaluated instead of single PCR. The nested-PCR protocol developed in this study showed its suitability to be applied for the specific detection of M. nawae from three types of naturally infected persimmon tissues: from lesions in fresh leaves, from pseudothecia present in lesions in leaf litter, and from infected asymptomatic leaves. The protocol can be useful for routine diagnosis, disease monitoring programs and for epidemiological research.     

A real‐time (TaqMan) PCR assay to differentiate Monilinia fructicola from other brown rot fungi of fruit crops

To prevent the entry and spread of the brown rot fungus Monilinia fructicola in Europe, a fast and reliable method for detection of this organism is essential. In this study, an automated DNA extraction method combined with a multiplex real‐time PCR based on TaqMan chemistry was developed for fast, convenient and reliable detection of both the EU quarantine organism Monilinia fructicola and the three other brown rot fungi M. fructigena, M. laxa and Monilia polystroma. Using the internal transcribed spacer (ITS) region of the nuclear ribosomal RNA gene repeat, a Monilinia genus‐specific primer pair and two differently labelled fluorogenic probes specific for M. fructicola and the group M. fructigena/M. laxa/Monilia polystroma were developed. The analytical specificity of the assay was assessed by testing 33 isolates of the four brown rot fungi and 13 isolates of related fungal species or other fungal species that can be present on stone and pome fruit. No cross‐reactions were observed. The assay was found to have a detection limit of 0·6 pg of DNA, corresponding to 27 haploid genomes or four conidia. Comparison of a manual DNA isolation followed by a conventional PCR with an automated DNA isolation combined with the presently developed real‐time PCR showed that the latter method gave improved results when tested with 72 naturally infected stone fruit samples. The detection rate increased from 65 to 97%.     

Development and application of a PCR-based 'molecular tool box' for the identification of Phytophthora species damaging forests and natural ecosystems

A PCR-based 'molecular tool box', based on a region of the ras-related protein gene Ypt 1, was developed for the identification of 15 Phytophthora species that damage forests and trees: P. cactorum , P. cambivora , P. cinnamomi , P. citricola , P. europaea , P. inundata , P. lateralis , P. megasperma , P. nemorosa , P. kernoviae , P. pseudosyringae , P. psychrophila , P. quercina , P. ramorum and P. ilicis . Most primers proved highly specific in blast analyses and in tests with DNA from 72 isolates of 35 species of Phytophthora and nine species representative of Pythium . Exceptions were primers designed for P. cactorum and P. ilicis , which cross-reacted with P. idaei and P. nemorosa , respectively. Amplification with Phytophthora -genus-specific primers before amplification with the various species-specific primers (nested PCR) increased the sensitivity of detection over amplification with species-specific primers only: detection limits ranged between 100 and 10 pg target DNA µ L⁻¹ in the latter, compared with 100 fg µ L⁻¹ in nested PCR. Using existing methods for rapid extraction and purification of DNA, single-round amplification was appropriate for detection of target Phytophthora species in leaves, but nested PCR was required for soil and water samples. The quarantine pathogens P. ramorum and P. kernoviae were detected in a number of naturally infected leaves collected in England and Wales, whereas P. citricola was commonest in water and soil samples from natural Scottish ecosystems.     

Direct molecular detection of the pinewood nematode, <Emphasis Type="Italic">Bursaphelenchus xylophilus</Emphasis>, from pine wood,bark and insect vector

The pinewood nematode (PWN), Bursaphelenchus xylophilus, is the causal agent of pine wilt disease. The international economic impact of the introduction of the PWN into new areas has highlighted the need for the development of accurate and reliable detection methods of B. xylophilus, which are essential to define aspects of its control and management. In the present study, a methodology was developed for the direct detection of PWN by conventional PCR assay, with a species specific set of primers based on PWN satellite DNA, using total DNA extracted directly from maritime pine, Pinus pinaster, wood and bark samples, and from the insect vector, Monochamus galloprovincialis. This methodology involves homogenisation of wood, bark and insects using liquid nitrogen, DNA extraction and one or two PCR amplification steps, which permit the rapid and direct detection of one single nematode present in 100 mg of wood and bark and in one entire insect without the preliminary steps of nematode extraction.     

基于Ypt1基因为靶标的木香疫病病组织及病田土壤分子检测技术

A species-specific PCR assay was established for rapid and accurate detection of the oomycete pathogen Phytophthora tentaculata in diseased plant tissues and infected soil.A pair of species-specific primers Pt1/Pt2 were designed on the basis of Ras-related protein(Ypt1) gene sequences of the Phytophthora species.PCR amplification with the Pt primers resulted in a 386 bp product only from isolates of P.tentaculata.The detection threshold with Pt primers was 100 pg of genomic DNA.A nested PCR procedure was developed using Ypt1F/Ypt1R as the first-round amplification primers and Pt1/Pt2 as the second-round primers,which increased the detection sensitivity 100-fold to 1 pg.PCR using these Pt primers can also be used to detect P.tentaculata in naturally infected plant tissues and soil.The PCR-based method developed in this study provides a rapid and sensitive tool for detection of P.tentaculata.     

Development of a One-Step Real-Time Polymerase Chain Reaction Assay for Diagnosis of Phytophthora ramorum

ABSTRACT Phytophthora ramorum is a recently described pathogen causing bleeding cankers, dieback, and leaf blight on trees and shrubs in parts of Europe and North America, where the disease is commonly known as sudden oak death. This article describes the development of a single-round real-time polymerase chain reaction (PCR) assay based on TaqMan chemistry, designed within the internal transcribed spacer 1 region of the nuclear ribosomal (nr)RNA gene for detection of P. ramorum in plant material. Unlike previously described methods for the molecular detection of P. ramorum, this assay involves no post amplification steps or multiple rounds of PCR. The assay was found to have a limit of detection of 10 pg of P. ramorum DNA, and could detect P. ramorum in plant material containing 1% infected material by weight within 36 cycles of PCR. The assay also was used to test DNA from 28 other Phytophthora spp. to establish its specificity for P. ramorum. A quick and simple method was used to extract DNA directly from host plant material, and detection of P. ramorum was carried out in multiplex with an assay for a gene from the host plant in order to demonstrate whether amplifiable DNA had been extracted. Amplifiable DNA was extracted from 84.4% of samples, as demonstrated by amplification of host plant DNA. The real-time protocol was used to test 320 plant samples (from 19 different plant species) from which DNA extraction had been successful, and was shown to give results comparable with a traditional isolation technique for diagnosis of P. ramorum in plant material from common U.K. hosts.     

Reliable RT-PCR detection of Apple stem pitting virus in pome fruits and its association with quince fruit deformation disease

In this study a spot nested RT-PCR assay was developed for the detection of Apple stem pitting virus (ASPV). A one step RT-PCR for the generic detection of foveaviruses using degenerate primers that target a conserved region of the RNA-dependent RNA polymerase (RdRp) gene was followed by a nested PCR that amplifies a 312 bp ASPV specific product. The method is rapid, simple and displays high sensitivity and broad detection range, overcoming the virus molecular variability. The optimum sampling conditions for reliable virus detection were also investigated. ASPV was detected throughout the year in different plant tissues of affected trees, thus the method could be used for routine screening and in certification schemes of pome fruits. ASPV was detected in quince orchards in Greece in all trees that were tested, showing a fruit deformation disorder. Sequencing and phylogenetic analysis of amplicons generated by RT-PCR from plant tissue affected with the deformation disease indicated that the agent responsible was a variant of ASPV.     

Seasonal detection of pear decline phytoplasma by nested-PCR in different pear cultivars

Seasonal detection of pear decline phytoplasma was studied in three pear cultivars: Bartlett, Limonera and Blanquilla. Samples from 43 infected trees were collected monthly over 2 years and analysed by nested PCR. The three cultivars each showed a different pattern of phytoplasma detection. The maximum detection rate of pear decline phytoplasma occurred in December in the three orchards, and it remained high throughout the winter months. In spring, when new buds appeared and sap was produced, the detection rate decreased. Leaf midribs, buds and stems were compared to determine which sample was more reliable for phytoplasma detection. The best indicators were stems. The presence of phytoplasma in sieve tubes during the dormant season was determined by grafting. The results suggest that phytoplasmas could overwinter in shoots, with the implication that vegetative propagation during this period could also disseminate the disease.     

以Ypt1基因序列为靶标的辣椒疫病菌快速分子检测

PCR primers were designed based on the sequence of Ras-related protein gene (Ypt1) of P. capsici. According to the multiple sequence alignment, Ypt1 has the sufficiently polymorphic intron region for the development of P. capsici-specific primers (PcYpt1F/PcYpt1R). One primer pair was developed which can amplify one P. capsici-specific fragment of 156 bp. Using the primer pair, the P. capsici infected plants and soils were detected. Additionally, Ypt1 has an appropriate region for the development of Phytophthora genus-specific primers (Ypt1F/Ypt1R), which can amplify a fragment of about 540 bp from 14 different Phytophthora specices and a fragment of about 350 bp in Pythium species, with no amplification from fungal species. By PCR optimization using P. capsici genomic DNA, the detection sensitivities of 10 pg and 10 fg DNA were achieved in standard PCR (PcYpt1F/PcYpt1R) and nested PCR (Ypt1F/Ypt1R and PcYpt1F/PcYpt1R), respectively. The developed primers were proved to be efficient in detection of Phytophthora pathogens from diseased plant tissues and residues in soils.