Incorporating molecular tools into routine HAB monitoring programs: Using qPCR to track invasive Prymnesium

Microscopy, a staple of monitoring programs for tracking the occurrence and abundance of harmful algal bloom (HAB) species, is time consuming and often characterized by high uncertainty. Alternate methods that allow rapid and accurate assessment of presence and abundance of HAB species are needed. For many HAB species, such as the toxigenic haptophyte, Prymnesium parvum, molecular methods including quantitative real-time PCR (qPCR) have been developed with the suggestion that they should be useful for monitoring programs. However, this suggestion rarely has been put into action. In this study, we modified a recently developed method for detecting P. parvum using qPCR and tested its efficacy as an alternative to microscopy for P. parvum detection and enumeration in a long-term monitoring program in a recently invaded subtropical US reservoir. Abundance estimates of P. parvum were similar for both methods, but we detected P. parvum at multiple sites using qPCR where it previously had gone undetected by microscopy. Using qPCR, we substantially reduced processing time, increased detection limit and reduced error in P. parvum abundance estimates compared to microscopy. Thus, qPCR is an effective tool for detecting and monitoring P. parvum, particularly at pre-bloom densities, and should likewise prove useful in monitoring programs for the other HAB species for which qPCR methods have been developed.     

LNA probes in a real‐time TaqMan PCR assay for genotyping of Giardia duodenalis in wastewaters

Aims: This study describes an approach for genotyping Giardia cysts obtained from wastewater treatment plants (WTPs) in Spain using real‐time PCR (qPCR) in combination with immunomagnetic beads. Methods and Results: A 50‐cycle amplification of a 74‐bp fragment of the Giardia beta‐giardin gene was adopted from a previous qPCR method. Additionally, two locked nucleic acid (LNA) probes were designed (LNA P434 P1 for assemblage A and LNA P434 H3 for assemblage B). All 16 wastewater samples analysed were positive with the immunofluorescence assay (IFA). Assemblage A was detected in all WTP samples using primer–LNA probe P434 P1 set. Giardia duodenalis identification was confirmed by PCR–RFLP analysis and sequencing of the β‐giardin gene in the water samples found positive by IFA and qPCR. Among the 16 assemblage A isolates that were sequenced, two subtypes were identified; 11 corresponded to the A2 subgenotype, whereas three corresponded to the subgenotype A3. A mixture of subgenotypes was found in the remaining two isolates. Conclusions: The newly developed qPCR assays were able to discern G. duodenalis assemblages A and B in wastewater. Significance and Impact of the Study: The real‐time PCR assays provided a rapid method for detection and one‐step genotyping of G. duodenalis from wastewater samples, and its application would contribute to understanding the distribution and abundance of G. duodenalis assemblages A and B in wastewater.     

DEVELOPMENT OF SEMI‐QUANTITATIVE PCR ASSAYS FOR THE DETECTION AND ENUMERATION OF GAMBIERDISCUS SPECIES (GONYAULACALES,DINOPHYCEAE)1

Ciguatera fish poisoning (CFP) is a serious health problem in tropical regions and is caused by the bioaccumulation of lipophilic toxins produced by dinoflagellates in the genus Gambierdiscus. Gambierdiscus species are morphologically similar and are difficult to distinguish from one another even when using scanning electron microscopy. Improved identification and detection methods that are sensitive and rapid are needed to identify toxic species and investigate potential distribution and abundance patterns in relation to incidences of CFP. This study presents the first species‐specific, semi‐quantitative polymerase chain reaction (qPCR) assays that can be used to address these questions. These assays are specific for five Gambierdiscus species and one undescribed ribotype. The assays utilized a SYBR green format and targeted unique sequences found within the SSU, ITS, and the D1/D3 LSU ribosomal domains. Standard curves were constructed using known concentrations of cultured cells and 10‐fold serial dilutions of rDNA PCR amplicons containing the target sequence for each specific assay. Assay sensitivity and accuracy were tested using DNA extracts purified from known concentrations of multiple Gambierdiscus species. The qPCR assays were used to assess Gambierdiscus species diversity and abundance in samples collected from nearshore areas adjacent to Ft. Pierce and Jupiter, Florida USA. The results indicated that the practical limit of detection for each assay was 10 cells per sample. Most interestingly, the qPCR analysis revealed that as many as four species of Gambierdiscus were present in a single macrophyte sample.     

Detection and quantification of Prymnesium parvum (Haptophyceae) by real-time PCR

Aims: The ichthyotoxic species Prymnesium parvum (Haptophyceae) is difficult to quantify in a microscopy‐based monitoring programme, because the cells are very small, fragile and their morphology can be distorted by the use of fixatives. In the attempt to overcome these problems, a real‐time PCR‐based method for the rapid and sensitive identification and quantification of P. parvum was developed. Methods and Results: A quantitative real‐time PCR assay was optimized with primers designed on the internal transcribed spacer 2 rDNA region of P. parvum. This PCR assay was specific, showing no amplification of DNA extracted from closely related species, and sensitive. Moreover, this method was able to detect and reliably quantify P. parvum cells in preserved environmental samples artificially spiked with known amounts of cultured cells. Conclusions: Considering the specificity, sensitivity and applicability to preserved environmental samples, this method may be a useful tool for the monitoring of this toxic species. Significance and Impact of the Study: The real‐time PCR method described in this study may represent a progress towards the rapid detection and quantification of P. parvum cells in water‐monitoring programmes, allowing the early application of strategies to control bloom events, such as the use of clay minerals.     

INTER- AND INTRASPECIFIC GENETIC VARIATION IN TWELVE PRYMAESIUM (HAPTOPHYCEAE) CLONES1

The haptophytes Prymnesium parvum Carter and Prymnesium patelliferum Green, Hibberd, and Pienaar are two closely related species, which can only be distinguished by minor differences in the morphology of their organic body scales. The two Prymnesium species are reported to coexist at several locations, including the Sands-fjord system in southwestern Norway. Comparisons of physiology and toxicity within the two species have failed to reveal differences that can add to the small morphological distinctions used to separate them. To investigate the genetic relationship between the two species, we compared the sequence of the first internal transcribed spacer region (ITS1)and length variation in one intron separating calmodulin genes for four P. parvum strains and eight P. patelliferum strains. Both the ITS1 sequence and the banding patterns obtained by PCR amplification of one intron in the calmodulin genes indicated that the Prymnesium isolates are related by their geographic origin instead of 4 their species affiliation. The results indicate that P. parvum and P. patelliferum are so closely related that they could be considered one species. Alternatively, we discuss the possibility that the two species might be joined in a heteromorphic haploid-diploid life cycle, as is now widely reported for other haptophycean algae.     

Improved detection of <Emphasis Type="Italic">Rhodococcus coprophilus</Emphasis> with a new quantitative PCR assay

Agricultural practices, such as spreading liquid manure or the utilisation of land as animal pastures, can result in faecal contamination of water resources. Rhodococcus coprophilus is used in microbial source tracking to indicate animal faecal contamination in water. Methods previously described for detecting of R. coprophilus in water were neither sensitive nor specific. Therefore, the aim of this study was to design and validate a new quantitative polymerase chain reaction (qPCR) to improve the detection of R. coprophilus in water. The new PCR assay was based on the R. coprophilus 16S rRNA gene. The validation showed that the new approach was specific and sensitive for deoxyribunucleic acid from target host species. Compared with other PCR assays tested in this study, the detection limit of the new qPCR was between 1 and 3 log lower. The method, including a filtration step, was further validated and successfully used in a field investigation in Switzerland. Our work demonstrated that the new detection method is sensitive and robust to detect R. coprophilus in surface and spring water. Compared with PCR assays that are available in the literature or to the culture-dependent method, the new molecular approach improves the detection of R. coprophilus.     

Rapid Quantification of the Toxic Alga Prymnesium parvum in Natural Samples by Use of a Specific Monoclonal Antibody and Solid-Phase Cytometry

The increasing incidence of harmful algal blooms around the world and their associated health and economic effects require the development of methods to rapidly and accurately detect and enumerate the target species. Here we describe use of a solid-phase cytometer to detect and enumerate the toxic alga Prymnesium parvum in natural samples, using a specific monoclonal antibody and indirect immunofluorescence. The immunoglobulin G antibody 16E4 exhibited narrow specificity in that it recognized several P. parvum strains and a Prymnesium nemamethecum strain but it did not cross-react with P. parvum strains from Scandinavia or any other algal strains, including species of the closely related genus Chrysochromulina. Prymnesium sp. cells labeled with 16E4 were readily detected by the solid-phase cytometer because of the large fluorescence signal and the signal/noise ratio. Immunofluorescence detection and enumeration of cultured P. parvum cells preserved with different fixatives showed that the highest cell counts were obtained when cells were fixed with either glutaraldehyde or formaldehyde plus the cell protectant Pluronic F-68, whereas the use of formaldehyde alone resulted in significantly lower counts. Immunofluorescence labeling and analysis with the solid-phase cytometer of fixed natural samples from a bloom of P. parvum occurring in Lake Colorado in Texas gave cell counts that were close to those obtained by the traditional method of counting using light microscopy. These results show that a solid-phase cytometer can be used to rapidly enumerate natural P. parvum cells and that it could be used to detect other toxic algae, with an appropriate antibody or DNA probe.     

Development of Streptococcus gordonii‐specific quantitative real‐time polymerase chain reaction primers based on the nucleotide sequence of rpoB

In this study, Streptococcus gordonii‐specific quantitative real‐time polymerase chain reaction (qPCR) primers, RTSgo‐F2/RTSgo‐R2, were developed based on the nucleotide sequences of RNA polymerase β‐subunit gene (rpoB). The specificity of the RTSgo‐F2/RTSgo‐R2 primers was assessed by conventional PCR on 99 strains comprising 63 oral bacterial species, including the type strain and eight clinical isolates of S. gordonii. PCR products were amplified from the genomic DNAs of only S. gordonii strains. The qPCR primers were able to detect as little as 40 fg of S. gordonii genomic DNA at a cycle threshold value of 33. These findings suggest that these qPCR primers detect S. gordonii with high specificity and sensitivity.     

Detection of a novel spotted fever group rickettsia in <Emphasis Type="Italic">Amblyomma parvum</Emphasis> ticks (Acari: Ixodidae) from Argentina

The present study evaluated the rickettsial infection in Amblyomma parvum ticks collected in Northwestern Córdoba Province, Argentina. Each tick was subjected to DNA extraction and tested by polymerase chain reaction (PCR) targeting fragments of the rickettsial genes gltA and ompB. Nine (69.2%) out of 13 adult ticks yielded expected PCR products for the two rickettsial genes. Products from the ompB PCR were sequenced, generating DNA sequences 100% identical for the nine PCR-positive ticks. Three of these ticks were tested in another battery of PCR targeting fragments of the rickettsial genes gltA, htrA, and ompA. Products from the gltA, htrA, and ompA PCRs were sequenced generating DNA sequences 100% identical for the three PCR-positive ticks. The rickettsia detected in the A. parvum ticks was designated as Rickettsia sp. strain Argentina. Phylogenetic analyses performed with partial sequences of the rickettsial genes gltA, htrA, ompB, and ompA showed that Rickettsia sp. strain Argentina belonged to the spotted fever group, being distinct from all known Rickettsia species and genotypes available in GenBank, representing possibly a new Rickettsia species. This was the first evidence of rickettsial infection in the tick A. parvum, and the third report of rickettsial infection among the Argentinean tick fauna. The role of Rickettsia sp. strain Argentina as a human pathogen is unknown. Further studies are needed to obtain tissue-cultured isolates of Rickettsia sp. strain Argentina, in order to better characterize it and to determine its taxonomic status as a new species.     

Ten real‐time PCR assays for detection of fish predation at the community level in the San Francisco Estuary–Delta

The effect of predation on native fish by introduced species in the San Francisco Estuary–Delta (SFE) has not been thoroughly studied despite its potential to impact species abundances. Species‐specific quantitative PCR (qPCR) is an accurate method for identifying species from exogenous DNA samples. Quantitative PCR assays can be used for detecting prey in gut contents or faeces, discriminating between cryptic species, or detecting rare aquatic species. We designed ten TaqMan qPCR assays for fish species from the SFE watershed most likely to be affected by non‐native piscivores. The assays designed are highly specific, producing no signal from co‐occurring or related species, and sensitive, with a limit of detection between 3.2 and 0.013 pg/μL of target DNA. These assays will be used in conjunction with a high‐throughput qPCR platform to compare predation rates between native and non‐native piscivores and assess the impacts of predation in the system.     

Allelopathic Effects of Toxic Haptophyte <Emphasis Type="Italic">Prymnesium parvum</Emphasis> Lead to Release of Dissolved Organic Carbon and Increase in Bacterial Biomass

The haptophyte Prymnesium parvum has lytic properties, and it affects coexisting phytoplankton species through allelopathy. We studied the effect of P. parvum allelochemicals on the lysis of the nontoxic and nonaxenic cryptomonad Rhodomonas salina and the consequent release of dissolved organic carbon (DOC). Changes in production, cell density, and biomass of associated bacteria were measured over 12 h. Six different combinations of P. parvum and R. salina cultures, their cell- and bacteria-free filtrates, and growth media as controls were used in the experiments. When P. parvum and R. salina cells were mixed, a significant increase in DOC concentration was measured within 30 min. Bacterial biomass increased significantly during the next 6 to 12 h when R. salina was mixed either with the P. parvum culture or the cell-free P. parvum filtrates (allelochemicals only). In contrast, bacterial biomass did not change in the treatments without the allelopathic action (without R. salina cells). Blooms of P. parvum alter the functioning of the planktonic food web by increasing carbon transfer through the microbial loop. In addition, P. parvum may indirectly benefit from the release of DOC as a result of its ability to ingest bacteria, by which it can acquire nutrients during limiting conditions.     

Multiplex real‐time PCR assays for detection of four seedborne spinach pathogens

Aims

To develop multiplex TaqMan real‐time PCR assays for detection of spinach seedborne pathogens that cause economically important diseases on spinach.

Methods and Results

Primers and probes were designed from conserved sequences of the internal transcribed spacer (for Peronospora farinosa f. sp. spinaciae and Stemphylium botryosum), the intergenic spacer (for Verticillium dahliae) and the elongation factor 1 alpha (for Cladosporium variabile) regions of DNA. The TaqMan assays were tested on DNA extracted from numerous isolates of the four target pathogens, as well as a wide range of nontarget, related fungi or oomycetes and numerous saprophytes commonly found on spinach seed. Multiplex real‐time PCR assays were evaluated by detecting two or three target pathogens simultaneously. Singular and multiplex real‐time PCR assays were also applied to DNA extracted from bulked seed and single spinach seed.

Conclusions

The real‐time PCR assays were species‐specific and sensitive. Singular or multiplex real‐time PCR assays could detect target pathogens from both bulked seed samples as well as single spinach seed.

Significance and Impact of the Study

The freeze‐blotter assay that is currently routinely used in the spinach seed industry to detect and quantify three fungal seedborne pathogens of spinach (C. variabile, S. botryosum and V. dahliae) is quite laborious and takes several weeks to process. The real‐time PCR assays developed in this study are more sensitive and can be completed in a single day. As the assays can be applied easily for routine seed inspections, these tools could be very useful to the spinach seed industry.     

Species‐Specific PCR‐Based Assay for Identification and Detection of Phomopsis (Diaporthe) azadirachtae Causing Die‐Back Disease in Azadirachta indica

Die‐back disease caused by Phomopsis (Diaporthe) azadirachtae is the devastating disease of Azadirachta indica. Accurate identification of P. azadirachtae is always problematic due to morphological plasticity and delayed appearance of conidia. A species‐specific PCR‐based assay was developed for rapid and reliable identification of P. azadirachtae by designing a species‐specific primer‐targeting ITS region of P. azadirachtae isolates. The assay was validated with DNA isolated from different Phomopsis species and other fungal isolates. The PCR assay amplified 313‐bp product from all the isolates of P. azadirachtae and not from any other Phomopsis species or any genera indicating its specificity. The assay successfully detected the pathogen DNA in naturally and artificially infected neem seeds and twigs indicating its applicability in seed quarantine and seed health testing. The sensitivity of the assay was 100 fg when genomic DNA of all isolates was analysed. The PCR‐based assay was 92% effective in comparison with seed plating technique in detecting the pathogen. This is the first report on the development of species‐specific PCR assay for identification and detection of P. azadirachtae. Thus, PCR‐based assay developed is very specific, rapid, confirmatory and sensitive tool for detection of pathogen P. azadirachtae at early stages.     

Failure To Differentiate Cryptosporidium parvum from C. meleagridis Based on PCR Amplification of Eight DNA Sequences

In order to determine the specificities of PCR-based assays used for detecting Cryptosporidium parvum DNA, eight pairs of previously described PCR primers targeting six distinct regions of the Cryptosporidium genome were evaluated for the detection of C. parvum, the agent of human cryptosporidiosis, and C. muris, C. baileyi, and C. meleagridis, three Cryptosporidium species that infect birds or mammals but are not considered to be human pathogens. The four Cryptosporidium species were divided into two groups: C. parvum and C. meleagridis, which gave the same-sized fragments with all the reactions, and C. muris and C. baileyi, which gave positive results with primer pairs targeting the 18S rRNA gene only. In addition to being genetically similar at each of the eight loci analyzed by DNA amplification, C. parvum and C. meleagridis couldn’t be differentiated even after restriction enzyme digestion of the PCR products obtained from three of the target genes. This study indicates that caution should be exercised in the interpretation of data from water sample analysis performed by these methods, since a positive result does not necessarily reflect a contamination by the human pathogen C. parvum.     

Sequence-based diagnostics and phylogenetic approach of uncultured freshwater dinoflagellate <Emphasis Type="BoldItalic">Peridinium</Emphasis> (Dinophyceae) species,based on single-cell sequencing of rDNA

The armoured dinoflagellate Peridinium is widely distributed in freshwater environments worldwide and contains a large number of species. Their identity, however, has remained elusive, since the small cells tend to be morphologically similar. To help resolve this, a sequence-based diagnostics for uncultured Peridinium cells from field samples was applied, using single-cell PCR and direct DNA sequencing of the PCR products. Single cells were isolated randomly from field samples, and PCR successfully amplified the target rDNA regions from the crude lysates. Phylogenetic trees showed that all the cells were strongly grouped into the same clade (> 99% bootstrap value), including the previously identified P. bipes f. occultatum, and apparently separated from relatives such as P. cinctum, P. volzii and P. willei. All 17 isolates were genotypically identified as P. bipes f. occultatum, based on over than 99% of sequence similarities, and the organism was responsible for water blooms at different seasons in Korean waters. The sequence-based typing could clearly resolve P. bipes f. occultatum from the various Peridinium cells, and that the method is accurate and more labor-saving than the conventional method to monitor Peridinium species. This protocol may be useful for the application of molecular tools to uncultured Peridinium cells.     

Long‐term stability of entomopathogenic nematode spatial patterns in soil as measured by sentinel insects and real‐time PCR assays

Quantitative real‐time PCR (qPCR) techniques are being increasingly used to provide accurate and reliable methods to identify and quantify cryptic organisms in soil ecology. Entomopathogenic nematode (EPN) diversity in Florida is known to be extensive and our phylogenetic studies of the D2D3 and ITS regions showed the occurrence of an additional species‐complex in the Steinernema glaseri‐ group in widely separated locations of the peninsula. To address ecological studies, we developed and used qPCR assays to detect and quantify six species of EPN that are naturally distributed in Florida citrus orchards (Steinernema diaprepesi, Steinernema riobrave, Heterorhabditis indica, Heterorhabditis zealandica, Heterorhabditis floridensis and an undescribed species in the S. glaseri group) and an exotic species, S. glaseri. Species‐specific primers and TaqMan® probes were designed from the ITS rDNA region. No nonspecific amplification was observed in conventional or qPCR when the primers and probes were tested using several populations of each of the Florida species and other exotic EPN species. Standard curves were established using DNA from pure cultures. We optimised a protocol for extracting nematodes and DNA from soil samples that can detect one EPN added to nematode communities recovered by conventional extraction protocols. A survey of an 8‐ha orchard in April 2009 compared the EPN spatial patterns derived from qPCR to that obtained by baiting soil samples with Galleria mellonella larvae. The patterns were also compared to those derived from the same site in 2000–01 by repeatedly (12 sampling events) baiting soil in situ with caged larvae of the root weevil Diaprepes abbreviatus. The qPCR assay was more efficient than the Galleria baiting method for detecting the EPN species composition in population mixtures. Moreover, the spatial patterns of EPN in this orchard were remarkably stable over the course of nearly a decade. The pattern of H. zealandica detected at the site 8 years earlier was related to those derived by qPCR (P = 0.002) and from sample baiting (P = 0.02). The spatial pattern of H. indica derived from qPCR, but not that from sample baiting, was also related to the earlier pattern (P = 0.01). The qPCR assay developed here is a fast, affordable and accurate method to detect and quantify these EPN species in soil and offers great potential for studying the ecology of EPN.     

Application of EMA-qPCR as a complementary tool for the detection and monitoring of <Emphasis Type="Italic">Legionella</Emphasis> in different water systems

Legionella are prevalent in human-made water systems and cause legionellosis in humans. Conventional culturing and polymerase chain reaction (PCR) techniques are not sufficiently accurate for the quantitative analysis of live Legionella bacteria in water samples because of the presence of viable but nonculturable cells and dead cells. Here, we report a rapid detection method for viable Legionella that combines ethidium monoazide (EMA) with quantitative real-time PCR (qPCR) and apply this method to detect Legionella in a large number of water samples from different sources. Results yielded that samples treated with 5 μg/ml EMA for 10 min and subsequently exposed to light irradiation for 5 min were optimal for detecting Legionella. EMA treatment before qPCR could block the signal from approximately 4 log₁₀ of dead cells. When investigating environmental water samples, the percent-positive rate obtained by EMA-qPCR was significantly higher than conventional PCR and culture methods, and slightly lower than qPCR. The bacterial count of Legionella determined by EMA-qPCR were mostly greater than those determined by culture assays and lower than those determined by qPCR. Acceptable correlations were found between the EMA-qPCR and qPCR results for cooling towers, piped water and hot spring water samples (r = 0.849, P < 0.001) and also found between the EMA-qPCR and culture results for hot spring water samples (r = 0.698, P < 0.001). The results indicate that EMA-qPCR could be used as a complementary tool for the detection and monitoring of Legionella in water systems, especially in hot spring water samples.     

Development of DNA macroarrays for genome scanning of <Emphasis Type="Italic">Ureaplasma parvum</Emphasis> strains

DNA macroarrays were developed on the basis of the known Ureaplasma parvum genome, which enabled rapid acquisition of the information on the changes in the microbial genome. For amplification of the PCR gene copies, 613 pairs of oligonucleotide primers were developed. Optimal conditions were determined for immobilization of the PCR products on a Nylon membrane and for hybridization with U. parvum chromosomal DNA. The DNA macroarrays were used to compare the nucleotide sequences of the genomes of laboratory strains of U. parvum and U. urealyticum.     

Diversity of <Emphasis Type="Italic">Burkholderia cepacia</Emphasis> Complex from the Moso Bamboo (<Emphasis Type="Italic">Phyllostachys edulis</Emphasis>) Rhizhosphere Soil

The purpose of this study was to determine the existence of Burkholderia cepacia complex (Bcc) at species level and the predominant species in the environment of moso bamboo plantations in Hangzhou, China. A total of 423 isolates were recovered from moso bamboo rhizhosphere soil samples of three sites on the selective medium during 2007–2008. Isolates were identified by Bcc-specific PCR assays, followed by recA-restriction fragment length polymorphism assays, species-specific PCR analysis, recA gene sequencing, multilocus sequence typing (MLST) scheme, and BOX-PCR fingerprinting for genomic diversity. Out of 423 isolates, 278 isolates were assigned to the following Bcc species, eight B. stabilis, 26 B. anthina, 193 B. pyrrocinia, and 51 B. arboris, which indicated B. pyrrocinia as the most dominant species followed by B. arboris. Moreover, false positives were observed in certain isolates of B. arboris while performing species-specific PCR test. Furthermore, the results of recA gene sequence similarity and MLST data demonstrated that nine isolates formed a single discrete cluster but were PCR negative to species-specific primers representing novel species may exist within the Bcc. In addition, BOX-PCR fingerprinting for all the Bcc isolates also showed the strain diversity. It is the first report of the existence of B. arboris and predominance of B. pyrrocinia in the moso bamboo environment.     

Specific and Sensitive Detection of Phytophthora nicotianae by Nested PCR and Loop‐mediated Isothermal Amplification Assays

Phytophthora nicotianae is an important soilborne plant pathogen. It causes black shank in tobacco and other commercially important crop diseases. Early and accurate detection of P. nicotianae is essential for controlling these diseases. In this study, primers based on the Ras‐related protein gene (Ypt1) of P. nicotianae were tested for their specific detection of the pathogen using nested PCR and LAMP assays. For specificity testing, DNA extracts from 47 P. nicotianae isolates, 45 isolates of 16 different oomycetes and 25 isolates of other fungal species were used; no cross‐reaction with other pathogens was observed. The sensitivity assay showed that the nested PCR and LAMP assays had detection limits of 100 fg and 10 fg genomic DNA per 25‐μl reaction, respectively. Furthermore, the nested PCR and LAMP assays were used for the detection of DNA from naturally P. nicotianae‐infected tobacco tissues and soil. Our results suggest that the LAMP assay has the greatest potential for the specific detection of P. nicotianae in regions that are at risk of contracting tobacco black shank disease and that the Ypt1 gene is a novel and effective target of P. nicotianae LAMP visual detection.