The development of a PCR-based method for detecting <Emphasis Type="Italic">Puccinia striiformis</Emphasis> latent infections in wheat leaves

Stripe rust of wheat caused by Puccinia striiformis f. sp. tritici is one of the most important diseases on wheat worldwide, especially in temperate regions with cool moist weather conditions. A rapid and reliable detection of the pathogen in latent infected wheat leaves during overwintering of the fungus in the dormant stage will contribute to determine the initial inoculum potential and thus to predict early outbreak and to improve effective management of the disease. To achieve this aim, a PCR-based method was developed for specific and sensitive detection of P. striiformis. Specific primers were designed according to a genome-specific sequence of P. striiformis. To evaluate the specificity of the primers, seven different isolates and races of P. striiformis as well as six other pathogens of wheat were tested. All isolates of P. striiformis yielded a distinct band of a fragment of 470 bp, while using DNA of the other wheat pathogens as a template no amplification product was detected. The sensitivity of the primers was tested using serial dilutions of total DNA from P. striiformis; the limit of detection was 10 pg of DNA. Using extracts from P. striiformis-infected wheat leaves, the fungus could be determined in the leaves before symptoms appeared. The stripe rust could also be detected in the dormant stage by the PCR assay in samples of wheat leaves taken during the winter season. The application of the PCR assay may be useful for rapid and reliable detection of P. striiformis in latent infected leaves of overwintering wheat plants.     

Development of specific PCR primers for identification and detection of <Emphasis Type="Italic">Phytophthora capsici</Emphasis> Leon

A PCR-based method was developed for the identification and detection of Phytophthora capsici in pepper plants. Three PCR primers (CAPFW, CAPRV1 and CAPRV2) specific for P. capsiciwere designed based on the sequence of its internal transcribed spacer regions. CAPFW/CAPRV1 amplify a 452 bp product from P. capsici DNA whereas CAPFW/CAPRV2 a 595 bp fragment; neither set amplifies DNA from pepper or several fungi pathogenic to pepper. In conventional (single-round) PCR, the limit of detection was 5 pg DNA for both primer sets, whereas in nested PCR the detection limit for both was of 0.5 fg. However, when the dilution series of target DNA were spiked with plant DNA, amplification declined two-fold in both conventional and nested PCR. The CAPFW/CAPRV2 set in conventional PCR was used to detect P. capsici DNA in inoculated plants. Detection occurred as soon as 8h post-inoculation in stem samples from infected but still symptomless plants. The method was also tested to detect fungal DNA in infected soils.     

Sensitive detection of Xanthomonas axonopodis pv. dieffenbachiae on Anthurium andreanum by immunocapture-PCR (IC-PCR) using primers designed from sequence characterized amplified regions (SCAR) of the blight pathogen

One of the most devastating Xanthomonas diseases affecting the Anthurium cut flower industry worldwide is the bacterial blight caused by Xanthomonas axonopodis pv. dieffenbachiae (Xad). The disease can be spread through latently infected tissue-cultured plants that are used for the propagation of Anthurium worldwide. Current disease diagnostic techniques involve the use of semi-selective media and serological tests. This study describes the development of a PCR tool combined with a genus-specific monoclonal antibody for the sensitive detection of the pathogen directly from plants. It was demonstrated that the immunocapture PCR (IC-PCR) was more sensitive than the conventional PCR and even more sensitive than indirect ELISA for the detection of the pathogen. Latently infected plants could be positively screened for the presence of the pathogen. Three sets of primers were designed from DNA probes that were reported to show some specificity to the pathovar dieffenbachiae. The use of all three sets of primers in a single reaction successfully amplified the three individual loci when bacterial DNA was used as a template. The multiplex PCR generated PCR profiles that could differentiate between the reference strains of X. axonopodis pv. dieffenbachiae from other control bacteria. The new primers could therefore be used both for the diagnosis of Anthurium blight in single PCR reactions and also for the profiling of Xanthomonas. pv. dieffenbachiae strains using the multiplex PCR technique.     

Detection of <Emphasis Type="Italic">Phytophthora nicotianae</Emphasis> and <Emphasis Type="Italic">P. palmivora</Emphasis> in citrus roots using PCR-RFLP in comparison with other methods

Phytophthora nicotianae and P. palmivora are the most important soil-borne pathogens of citrus in Florida. These two species were detected and identified in singly and doubly infected plants using polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) of internal transcribed spacer (ITS) regions of ribosomal DNA. The sensitivity of the PCR-RFLP was analyzed and the usefulness of the method evaluated as an alternative or supplement to serological methods and recovery on semi-selective medium. In a semi-nested PCR with universal primers ITS4 and ITS6, the detection limit was 1 fg of fungal DNA, which made it 1000× more sensitive than a single-step PCR with primers ITS4 and DC6. The sensitivity of detection for P. nicotianae was shown to be ten-fold lower than for P. palmivora, limiting its detection with restriction profiles in plants infected by both fungal species. Phytophthora nicotianae was detected with species-specific primers in all samples inoculated with this species despite the absence of species-specific patterns in RFLP. In contrast, the incidence of detection of P. palmivora in the presence of P. nicotianae was considerably lower using plating and morphological detection methods. Due to its high sensitivity, PCR amplification of ribosomal ITS regions is a valuable tool for detecting and identifying Phytophthora spp. in citrus roots, provided a thorough knowledge of reaction conditions for the target species is established prior to the interpretation of data.     

Development of PCR-based Detection Methods for the Quarantine Phytopathogen <Emphasis Type="Italic">Synchytrium endobioticum</Emphasis>, Causal Agent of Potato Wart Disease

PCR-based methods were developed for the detection and quantification of the potato pathogen Synchytrium endobioticum in soil extracts and in planta. PCR primers, based on the internal transcribed spacer region of the multi-copy gene rDNA were tested for specificity, sensitivity and reproducibility in conventional and real-time PCR assays. Soil extraction procedures compared included the Hendrickx centrifugation (HC) procedure, nested wet sieving (NWS) and a method used by the Plant Protection Service (PPS). The primers amplified a 472 bp product from S. endobioticum DNA, but did not amplify DNA from other potato pathogens, other plant pathogens, and related species. Standard cell disruption and DNA extraction and purification methods were optimized for amplification of S. endobioticum DNA from resting sporangia. DNA was successfully amplified from a single sporangium and equivalent DNA preparations from soil extracts. Low levels of target DNA in water did not amplify, possibly due to DNA loss during final purification steps. A real-time PCR assay, developed for soil-based extracts using primers and probe based on the rDNA gene sequences, involved co-amplification of target DNA along with an internal DNA fragment. Both conventional and real-time PCR methods performed well with HC- and NWS-extracts having a threshold sensitivity of 10 sporangia per PCR assay. Of the three soil extraction methods, only with the HC method could 100 g soil samples be efficiently processed in one single PCR assay. Such a high capacity assay could be useful for routine soil analysis in respect to disease risk assessments and to secure de-scheduling according to EPPO guidelines.     

Conventional PCR and real time quantitative PCR detection of <Emphasis Type="Italic">Phytophthora cryptogea</Emphasis> on <Emphasis Type="Italic">Gerbera jamesonii</Emphasis>

A conventional PCR and a SYBR Green real-time PCR assays for the detection and quantification of Phytophthora cryptogea, an economically important pathogen, have been developed and tested. A conventional primer set (Cryp1 and Cryp2) was designed from the Ypt1 gene of P. cryptogea. A 369 bp product was amplified on DNA from 17 isolates of P. cryptogea. No product was amplified on DNA from 34 other Phytophthora spp., water moulds, true fungi and bacteria. In addition, Cryp1/Cryp2 primers were successfully adapted to real-time PCR. The conventional PCR and real-time PCR assays were compared. The PCR was able to detect the pathogen on naturally infected gerbera plants and on symptomatic artificially infected plants collected 21 days after pathogen inoculation. The detection limit was 5 × 10³ P. cryptogea zoospores and 16 fg of DNA. Real-time PCR showed a detection limit 100 times lower (50 zoospores, 160 ag of DNA) and the possibility of detecting the pathogen in symptomless artificially infected plants and in the re-circulating nutrient solution of closed soilless cultivation systems.     

PCR-based monitoring of recent isolates of tobacco blue mold from Europe reveals the presence of two genetically distinct phenotypes differing in fungicide sensitivity

Bioassays testing the fungicide sensitivity against metalaxyl of Peronospora tabacina isolates collected in German tobacco fields in 2005 revealed the presence of two phenotypes, resistant and sensitive. DNA fingerprints using SSR and minisatellite primers allowed separation of the samples into two groups. The differences in amplification patterns coincided with the sensitive and resistant reaction of the isolates in metalaxyl bioassays. New primers were developed which allowed PCR-based detection of P. tabacina and differentiation of the metalaxyl-sensitive and the metalaxyl-resistant phenotype, respectively. Screening of recent blue mold isolates from Germany and other European countries for metalaxyl sensitivity with leaf disk bioassays coincided completely with the PCR-based identification of the two phenotypes. In Germany, exclusively resistant isolates were found between 2002 and 2004. These still dominate. Since 2005 the co-occurrence of sensitive isolates has been shown. No similar monitoring has been done in any other European country. However, we found the resistant phenotype reaction in a French isolate of 2004 and in two out of three Italian isolates in 2007. Two isolates from Poland and Bulgaria in 2007 were sensitive to metalaxyl. For all 58 isolates tested since 2002 the metalaxyl bioassay-based resistance type and the PCR-based tests for sensitive and resistant genotype coincided. Using genotype-specific primers for future population studies may help to trace the sources of the pathogen from which yearly propagation starts.     

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.     

Improved PCR detection of potyviruses in <Emphasis Type="Italic">Allium</Emphasis> species

Protocols for producing virus-free Allium plants require an indexing system that is more sensitive than DAS-ELISA and can detect low virus concentrations in infected plants. In the present work, degenerate primers were designed and a one-step IC-RT-PCR protocol was developed to differentiate between Leek yellow stripe virus (LYSV) and Onion yellow dwarf virus (OYDV) in single and mixed infections in several Allium spp. A 566-bp band was observed for LYSV, a 489-bp band for OYDV in single infections, and two bands of the same sizes in mixed infections in different species of Alliaceae. A 508-bp band of Shallot yellow stripe virus and a 594-bp band of Turnip mosaic virus were also amplified with the same primers. RT-nested-PCR was also conducted directly in microtitre plate wells after negative or questionable reactions were produced in an ELISA experiment. The detection limit of the DAS-ELISA for LYSV was 16.5–27.3 ng ml⁻¹. The RT-nested-PCR done after DAS-ELISA was 10² times more sensitive than the DAS-ELISA alone. In parallel, an IC-RT-nested-PCR in microcentrifuge tubes was 10⁴ times more sensitive than the DAS-ELISA. The DAS-ELISA-RT-nested-PCR enables the initial screening of samples by DAS-ELISA to eliminate a high percentage of virus-positive plants, considerably reducing the number of plants to analyze further by RT-PCR.     

Detection of the Defoliating Pathotype of Verticillium dahliae in Infected Olive Plants by Nested PCR

Spread of Verticillium wilt into newly established olive orchards in Andalucía, southern Spain, has caused concern in the olive industry in the region. This spread may result from use of Verticillium dahliae-infected planting material, which can extend distribution of the highly virulent, defoliating (D) pathotype of V. dahliae to new areas. In this study, a molecular diagnostic method for the early in planta detection of D V. dahliae was developed, aimed especially at nursery-produced olive plants. For this purpose, new primers for nested PCR were designed by sequencing a 992-bp RAPD marker of the D pathotype. The use of the specific primers and different nested-PCR protocols allowed the detection of V. dahliae pathotype D DNA in infected root and stem tissues of young olive plants. Detection of the pathogen was effective from the very earliest moments following inoculation of olive plants with a V. dahliae pathotype D conidia suspension as well as in inoculated, though symptomless, plants.     

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.     

<Emphasis Type="Italic">Ageratum</Emphasis><Emphasis Type="Italic">yellow vein virus</Emphasis> isolated from tomato plants with leaf curl on Ishigaki Island,Okinawa, Japan

In 2005, severe leaf curling and yellowing were observed on tomato plants on Ishigaki Island. Because the symptoms were consistent with infection by a begomovirus, we used a polymerase chain reaction (PCR) with specific primers for begomovirus DNA-A and DNA satellite component (DNA-β) and detected products of the expected sizes from symptomatic tomato plant samples. DNA sequence analyses of the PCR products revealed that the symptomatic tomato plants were associated with Ageratum yellow vein virus (AYVV) infection. We confirmed AYVV transmission from the naturally infected weed host, Ageratum conyzoides, to healthy tomato plants by the insect vector Bemisia tabaci B biotype. This report is the first of AYVV occurrence in Japan.     

Description and molecular phylogeny of <Emphasis Type="Italic">Ditylenchus gilanicus</Emphasis> n. sp. (Nematoda: Anguinidae) from northern forests of Iran

Commercial areas containing Eucalyptus plantations have expanded in recent years due to increased demands for pulp, paper and bioenergy. One of the threats that can reduce Eucalyptus production is the eucalyptus rust disease caused by Austropuccinia psidii, a biotrophic fungus that affects a broad range of Myrtaceae. An accurate diagnosis tool for the early detection of rust disease could be useful in breeding programs for selection of resistant plants against rust, in phytosanitary purposes or in rust epidemics studies. The aim of the present work was to develop a SYBR Green-based quantitative real-time PCR (qPCR) assay for the early detection and quantification of A. psidii in Eucalyptus grandis leaves. Three sets of primers based on the A. psidii ribosomal DNA intergenic space region (IGS), beta-tubulin and elongation factor genes were designed and evaluated. The assays using the IGS primer set resulted in the highest detection efficiency, detecting a lower limit of 0.5 pg of A. psidii DNA. Under artificial inoculation in plants, A. psidii was detected immediately after pathogen inoculation until 240 h post-inoculation using qPCR. In field validation of the method, A. psidii was detected using qPCR in naturally infected leaves with or without rust symptoms. This easy and fast method can be used for an efficient detection of A. psidii in E. grandis leaves. The implications of this tool for rust studies are discussed below.     

Sensitive Detection of a Phytoplasma Associated with Little Leaf Symptoms in Withania somnifera

Withania somnifera is an important medicinal plant native to the Indian-sub continent. Owing to the presence of a number of precious alkaloids, flavonoids and withanolides, it is widely used in the Indian and African systems of medicines. It is severely affected by phytoplasma present in the sieve tubes of phloem. With a view to micropropagate phytoplasma-free W. somnifera plants, an efficient and effective nested PCR-based system was developed for detection of associated phytoplasmas. Universal primers, designed from the 16S rDNA sequences of phytoplasmas, were applied in direct/nested-PCR. Total DNA extracts from leaf tissues of 33 suspected symptomatic and 11 non-symptomatic plants were subjected to direct PCR. The direct PCR products were subsequently employed as templates in nested PCR. The nested PCR could reamplify direct PCR products yielding a DNA fragment of 1.4 kb. A phytoplasma was detected in all the diseased plants and not from the healthy looking plants. Further, it was sensitive enough to amplify phytoplasma DNA obtained from crude DNA diluted up to 2500 times from naturally infected plants and also from various stages of in vitro-propagated diseased plants. Identical restriction fragment polymorphism enzyme profiles were obtained following restriction enzyme digestion of nested PCR products, obtained from five different plants, by EcoRI, AluI and RsaI restriction endonucleases. The developed nested PCR based system should facilitate indexing of the phytoplasma in different stages of in vitro-generated plants and probably identification of, as yet unknown, hosts and vectors of phytoplasma associated with phytoplasma disease of W. somnifera.     

Development and validation of a quantitative PCR assay method of assessing relative resistance of oat (Avena sativa) to crown rust (Puccinia coronata f. sp. avenae)

Evaluation of oat crown rust resistance is usually based on visual assessment of disease severity or infection types. Visual assessment is subjective, prone to rater bias and requires expert knowledge. PCR-based quantitative assays can overcome challenges associated with visual assessment. New TaqMan primers and probes were designed from Puccinia coronata f. sp. avenae (Pca) sequences. The primer–probe sets were specific to Pca, amplified using as little as 0.5 pg fungal DNA (fDNA) and allowed for scaling to variation in sample total DNA quantity. The quantitative PCR (qPCR) assay was validated using oat recombinant inbred lines (RILs) from the Provena × 94197A1-9-2-2-2-5 cross evaluated under a controlled environment. For comparison with fDNA load, inoculation with the Pca race LCBB provided segregation data on the hypersensitive response, while Pca race LSLG provided data on segregation for reduced pustule number. fDNA content was positively correlated with both pustule number and infection type (IT). Composite interval mapping identified two quantitative trait loci (QTLs) on oat linkage groups Mrg12 and Mrg20 using visual and qPCR assessments (pustule number, IT and fDNA). In this study a qPCR assay method that can be used to assess the relative resistance of oat to crown rust was refined and validated, and single nucleotide polymorphisms (SNPs) closely linked with two QTLs derived from the crown rust resistant line 94197A1-9-2-2-2-5 were identified.     

Improved PCR-based Assays for Pre-symptomatic Diagnosis of Light Leaf Spot and Determination of Mating Type of Pyrenopeziza Brassicae on Winter Oilseed Rape

An existing PCR-based method for diagnosis of the winter oilseed rape (Brassica napus ssp oleifera) fungal pathogen Pyrenopeziza brassicae (cause of light leaf spot) was improved by the development of a pair of primers (PbN1 and PbN2) for use in nested-PCR reactions. The nested-PCR technique improved the detection of P. brassicae DNA in vitro by three orders of magnitude over that achieved using the first-round PCR primers (Pb1 and Pb2). In controlled environment experiments, the nested-PCR assay detected P. brassicae within infected B. napus leaves before visible light leaf spot symptoms developed and earlier than was possible by incubating infected leaves in polyethylene bags to promote sporulation of P. brassicae. A three-primer PCR technique using the primers PbM-1-3, PbM-2 and Mt3 was developed to distinguish between the two mating types (MAT-1 and MAT-2) of P. brassicae. This technique was able to determine the mating types present within DNA extracted from infected plant tissue, including tissue infected with both mating types together.     

In planta-polymerase-chain-reaction detection of the wilt-inducing pathotype ofFusarium oxysporumf.sp.cicerisin chickpea (Cicer arietinumL.)

A 1.6 kb fragment of random amplified polymorphic DNA (RAPD-PCR, polymerase chain reaction), which was specific for race 5, a wilt-inducing isolate ofFusarium oxysporumf.sp.ciceris(Foc), was cloned and sequenced. This fragment was not detected in RAPD-PCR reactions with DNA from yellowing-inducing pathotypes ofFoc, or from other fungi tested. Specific PCR primers were designed from the sequence data and used to detect the presence of the fungus in genomic DNA isolated from symptomless chickpea plants, 16 days after inoculation. A single, 1.5 kb PCR product was only observed in PCR reactions with DNA from plants infected with a wilt-inducing isolate. No products were observed in reactions with DNA from plants infected with yellowing-inducing pathotypes, or from DNA isolated from uninfected chickpea cultivar controls. Southern hybridization demonstrated homology between the second PCR product and the original specific wilt-associated RAPD fragment. PCR products were detected with DNA extracted from roots and stem tissue, but no fungal DNA was detected in leaf tissue of the same infected plants. In a blind trial, the specific primers correctly identified the fungal pathotype in four different, wilt-infected chickpea cultivars.     

Validation of a real‐time PCR method for the detection of Phytophthora ramorum1

To validate a real‐time PCR method for the detection of Phytophthora ramorum, an intra‐laboratory procedure was developed. The specificity of the TaqMan probe/primer sets was determined by carrying out real‐time PCR on total DNA extracted from pure culture of several Phytophthora species. The limit of detection and the potential effects of plant substrates were evaluated by conducting the test on total DNA from healthy plant materials (Rhododendron spp., Viburnum spp. and Pieris spp.) spiked with known amounts of P. ramorum genomic DNA. The PCR efficiency was estimated through the linear regression of the dilution curve. Precision of the TaqMan assay was assessed on material from a single artificially infected plant (Rhododendron spp.). Two kinds of tissues were tested: a severely infected twig and an apparently healthy leaf. Intra‐assay repeatability was evaluated on 10 replicates of the same DNA sample analysed in a single assay. Inter‐assay reproducibility was evaluated on the same DNA sample amplified over five separate assays while the intersample reproducibility was evaluated on separate DNA extractions of four samples from both plant tissues amplified in a single assay.     

Improved PCR for identification of members of the genus Xanthomonas

A PCR-based system was developed to reliably and robustly identify group I and II members of the genus Xanthomonas. Primer sets developed from three gene targets namely fyuA, ITS and gumD were evaluated in the study. Primer sets were evaluated using DNA extracted from 45 Xanthomonas strains representing 25 species broadly covering the genus. Fifteen non-Xanthomonas strains of plant-associated bacteria including phylogenetically closely related species Stenotrophomonas maltophilia and Xylella fastidiosa were also tested. The primers targeting fyuA amplified DNA from all xanthomonads except X. theicola, while the ITS primers amplified a DNA fragment of 254 bp in all 45 Xanthomonas strains; whereas no amplification was observed for non-xanthomonads. The gumD primers allowed efficient amplification of DNA in 38 out of 39 isolates from Group II, whereas no or very weak amplification occurred with DNA from Group I members. Internal controls of primers targeting bacterial 16S rDNA or plant 26S mitochondrial rDNA were successfully applied in multiplex PCRs for testing bacterial cultures or plant tissue, respectively. The findings give us a PCR based approach that can reliably and effectively differentiate xanthomonads from non-xanthomonads as well as separating the strains belonging to the two described groups of the genus Xanthomonas. The study thus offers valuable tools for disease surveillance and management. It can effectively be applied in rapid assessment of new disease occurrences, for which no specific detection tools could be in place.     

Characterisation of <Emphasis Type="Italic">Phoma tracheiphila</Emphasis> by RAPD-PCR,microsatellite-primed PCR and ITS rDNA sequencing and development of specific primers for <Emphasis Type="Italic">in planta</Emphasis> PCR detection

Thirty six isolates of Phoma tracheiphila from Italy, the causal agent of the mal secco disease on Citrus species, were characterised by different molecular tools in comparison with representative isolates of other phytopathogenic Phoma species. These included analysis of the distribution of RAPD and microsatellite markers and sequencing of the internal transcribed spacer (ITS) region of the nuclear rRNA genes. The results obtained with 12 RAPD primers (92 markers) and 7 microsatellite primers (56 markers) suggest that Italian isolates of P. tracheiphila are genetically homogeneous, leading to identical patterns upon amplification with all the tested primers. Accordingly, ITSI-5.8S-ITS2 sequences were highly conserved (98–100% identity along a 544-characters alignment) among all the isolates of P. tracheiphila. A neighbor-joining analysis of ITS sequences of P. tracheiphila in comparison with those of other Phoma species, as well as with alignable sequences from anamorphic and teleomorphic taxa retrieved in BLAST searches, revealed a close relationship between P. tracheiphila and Leptosphaeria congesta. A pair of P. tracheiphila-specific primers was designed on the consensus sequence (555 residues) obtained from the alignment of the newly generated P. tracheiphila ITS sequences. A PCR-based specific assay coupled to electrophoretic separation of amplicons made it possible to detect P. tracheiphila in naturally infected Citrus wood tissue collected from both symptomatic and symptomless plants. The limit of detection was 10 pg of genomic DNA and 5 fg of the ITS target sequence.