I. Barker

The detection of Tomato spotted wilt virus (TSWV) in individual thrips using real time fluorescent RT-PCR (TaqMan)

Tomato spotted wilt virus (TSWV) is an important virus, economically in the UK, causing damaging disease in ornamental and vegetable crops. The virus is vectored by several species of thrips, most importantly the western flower thrips (Frankliniella occidentalis Pergande [Thysanoptera: Thripidae]). The vector thrips themselves constitute a damaging pest and are difficult to control completely. Monitoring thrips numbers is an important part of the control of virus, but does not give information on how many of the thrips are viruliferous. Monitoring the presence of viruliferous thrips at an early stage of an epidemic may lead to improved disease control, since virus can be spread effectively whilst vector pressure is low and symptoms may take several weeks to appear on some hosts. This paper describes the development of a sensitive and robust, high-throughput method for the detection of TSWV in individual insects based on TaqMan chemistry. The method incorporates a novel RNA specific internal control to increase the reliability of the results. Results are also presented on comparisons of different extraction methods, including insects taken from sticky traps, for high-throughout testing. Implementation of a method such as this for the reliable detection of TSWV in individual thrips would aid the understanding of the progress of TSWV epidemics, and offer an early disease warning system for growers.

Detection of potato viruses using microarray technology: towards a generic method for plant viral disease diagnosis

Currently, most diagnostic methodology is geared towards detection of a very specific target species and often a number of assays need to be run in parallel to reach a result. The generic methods that are available for virus testing tends to give identification to the genus level only. The method described in this paper addresses this problem by exploiting a technology that has potential to test for a large number of targets in a single assay. Using the array constructed, the method was able to detect several common potato viruses (PVY, PVX, PVA, PVS) in single and mixed infections. The method was shown to be able to discriminate sequences with less than 80% sequence identity but was able to detect sequence variants with greater than 90% sequence identity. Thus the method should be useful for discriminating at the species level, but able to cope well with the intrinsic variability found within the genomes of RNA viruses. The sensitivity of the assay was found to be comparable with ELISA. The paper illustrates a significant step forward in the development of diagnostic methodologies by presenting for the first time a method that could theoretically be used not just for viruses, but for all the plant pathogens and pests that a modern diagnostic laboratory would want to test for, in a single completely generic and highly parallel format.

Molecular Analysis of a Resistance-Breaking Strain of Potato Virus X

Full-length cDNA clones of potato virus X (PVX) strains PVXUK3 and PVXHB have been constructed in plasmid vectors to allow in vitro transcription of infectious PVX RNA. In both instances the transcript-derived virus infected tobacco and potato identically to the respective progenitor strains: in tobacco and susceptible potato cultivars both strains infected systemically, producing symptomless or mild mosaic symptoms. In potato carrying the Rx or Nx resistance genes, the virus derived from the PVXHB cDNA infected systemically, whereas the virus derived from the PVXUK3 cDNA failed to infect the Rx plants or induced apical necrosis, characteristic of a hypersensitive response of the Nx gene. Three hybrid viral genomes were constructed at the cDNA level to localize the resistance breaking determinants of PVXHB. Transcripts of all three hybrids were infectious on tobacco. On potato cultivars with either the Rx or Nx resistance genes, the hybrid viruses infected in the same way as PVXHB, rather than PVXUK3. The common feature of these hybrid viruses, the coat protein gene, is therefore the determinant of Nx and Rx resistance breaking of PVXHB.

Advances in molecular phytodiagnostics - new solutions for old problems

In the last decade, developments in molecular (nucleic acid-based) diagnostic methods have made significant improvements in the detection of plant pathogens. By using methods such as the polymerase chain reaction (PCR), the range of targets that can now be reliably diagnosed has grown to the extent that there are now extremely few, known pathogens that cannot be identified accurately by using laboratory-based diagnostics. However, while the detection of pathogens in individual, infected samples is becoming simpler, there are still many scenarios that present a major challenge to diagnosticians and plant pathologists. Amongst these are the detection of pathogens in soil or viruses in their vectors, high throughput testing and the development of generic methods, that allow samples to be simultaneously screened for large numbers of pathogens. Another major challenge is to develop robust technologies that avoid the reliance on well-equipped central laboratories and making reliable diagnostics available to pathologists in the field or in less-developed countries. In recent years, much of the research carried out on phytodiagnostics has focussed in these areas and as a result many novel, routine diagnostic tests are becoming available. This has been possible due to the introduction of new molecular technologies such real-time PCR and microarrays. These advances have been complemented by the development of new nucleic acid extraction methods, increased automation, reliable internal controls, assay multiplexing and generic amplification methods. With developments in new hardware, field-portable real-time PCR is now also a reality and offers the prospect of ultra-rapid, on-site molecular diagnostics for the first time. In this paper, the development and implementation of new diagnostic methods based upon novel molecular techniques is presented, with specific examples given to demonstrate how these new methods can be used to overcome some long-standing problems.In the last decade, developments in molecular (nucleic acid-based) diagnostic methods have made significant improvements in the detection of plant pathogens. By using methods such as the polymerase chain reaction (PCR), the range of targets that can now be reliably diagnosed has grown to the extent that there are now extremely few, known pathogens that cannot be identified accurately by using laboratory-based diagnostics. However, while the detection of pathogens in individual, infected samples is becoming simpler, there are still many scenarios that present a major challenge to diagnosticians and plant pathologists. Amongst these are the detection of pathogens in soil or viruses in their vectors, high throughput testing and the development of generic methods, that allow samples to be simultaneously screened for large numbers of pathogens. Another major challenge is to develop robust technologies that avoid the reliance on well-equipped central laboratories and making reliable diagnostics available to pathologists in the field or in less-developed countries. In recent years, much of the research carried out on phytodiagnostics has focussed in these areas and as a result many novel, routine diagnostic tests are becoming available. This has been possible due to the introduction of new molecular technologies such real-time PCR and microarrays. These advances have been complemented by the development of new nucleic acid extraction methods, increased automation, reliable internal controls, assay multiplexing and generic amplification methods. With developments in new hardware, field-portable real-time PCR is now also a reality and offers the prospect of ultra-rapid, on-site molecular diagnostics for the first time. In this paper, the development and implementation of new diagnostic methods based upon novel molecular techniques is presented, with specific examples given to demonstrate how these new methods can be used to overcome some long-standing problems.

On-Site DNA Extraction and Real-Time PCR for Detection of Phytophthora ramorum in the Field

ABSTRACT Phytophthora ramorum is a recently described pathogen causing oak mortality (sudden oak death) in forests in coastal areas of California and southern Oregon and dieback and leaf blight in a range of tree, shrub, and herbaceous species in the United States and Europe. Due to the threat posed by this organism, stringent quarantine regulations are in place, which restrict the movement of a number of hosts. Fast and accurate diagnostic tests are required in order to characterize the distribution of P. ramorum, prevent its introduction into pathogen-free areas, and minimize its spread within affected areas. However, sending samples to a laboratory for testing can cause a substantial delay between sampling and diagnosis. A rapid and simple DNA extraction method was developed for use at the point of sampling and used to extract DNAs from symptomatic foliage and stems in the field. A sensitive and specific single-round real-time PCR (TaqMan) assay for P. ramorum was performed using a portable real-time PCR platform (Cepheid SmartCycler II), and a cost-effective method for stabilizing PCR reagents was developed to allow their storage and transportation at room temperature. To our knowledge, this is the first description of a method for DNA extraction and molecular testing for a plant pathogen carried out entirely in the field, independent of any laboratory facilities.

Faster, simpler, more-specific methods for improved molecular detection of Phytophthora ramorum in the field.

ABSTRACT Phytophthora ramorum is the causal agent of sudden oak death. The pathogen also affects a wide range of tree, shrub, and herbaceous species in natural and landscaped environments as well as plants in the nursery industry. A TaqMan real-time PCR method for the detection of this pathogen in the field has been described previously; this paper describes the development of a number of assays based on this method which have various advantages for use in the field. A scorpion real-time PCR assay that is twice as fast as TaqMan was developed, allowing the detection of P. ramorum in less than 30 min. Also designed was a loop-mediated isothermal amplification (LAMP) assay, which allowed sensitive and specific detection of P. ramorum in 45 min using only a heated block. A positive reaction was identified by the detection of the LAMP product by color change visible to the naked eye.

The detection of tuber necrotic isolates of Potato virus Y, and the accurate discrimination of PVYO, PVYN and PVYC strains using RT-PCR

Potato tuber necrotic ringspot disease (PTNRD) is a damaging disease of potatoes, causing unsightly necrotic rings on the surface of tubers. The causal agent is thought to be tuber necrotic isolates of Potato virus Y, known as PVY(NTN). The disease spoils tubers for processing and table use, and the lack of a diagnostic method makes control especially difficult. The development of an RT-PCR assay for the reliable detection of PVY(NTN) and discrimination of all the main strains of PVY (PVY(O), PVY(N) and PVY(C)) is described. An assay was developed, exploiting a recombination site in the coat protein of PVY(NTN), allowing more reliable diagnosis of these isolates. Although the conserved nucleotide differences observed between the strains was very small, competitive PCR and mutagenically separated PCR were both employed in the development of a robust assay. The assay was found to be more reliable than the most commonly used RT-PCR method, and should prove to be an important tool in the confirmation of symptoms and for the detection of PVY(NTN) in symptomless tissue, in disease surveys and seed health schemes.

An improved method for the detection of Tospoviruses using the polymerase chain reaction

A reverse transcription-polymerase chain reaction (RT-PCR)-based assay for the detection of tomato spotted wilt virus (TSWV) has been improved and extended to enable the detection of additional Tospoviruses. In addition to TSWV-specific primers, two further pairs of primers have been designed, one pair which specifically detects impatiens necrotic spot virus (INSV) and another which detects all Tospoviruses tested, including TSWV, INSV, tomato chlorotic spot virus and groundnut ringspot virus. An improved, rapid RNA extraction method is also described.

Strain specific recombinant antibodies to potato virus Y potyvirus.

Single chain Fv antibody fragments have been selected from a synthetic phage-antibody library following three and four rounds of affinity selection with purified potato virus Y, common strain (PVY(O)). The selected fragments were highly specific for PVY and detected seven out of nine isolates of PVY(O) whilst failing to detect three isolates of PVY(N) and 12 isolates of PVY(NTN). Nucleotide sequence of the scFv genes showed the variable heavy fragments belonged to the human VH4 family, whilst the variable light fragments belonged to the Vlambda1 family. The fragments were used in ELISA to detect virus at concentrations of 50 ng/ml in plant sap and in comparisons with commercially available PVY monoclonal antibodies were shown to have similar limits of detection. This is the first report of the selection of a scFv specific for a member of the potyviridae, and its use in detecting and differentiating strains of PVY in infected plant sap. The results highlight the potential of the technology for the selection of strain specific antibodies with an avidity equivalent to traditional monoclonal antibodies raised against viral pathogens and their use for viral diagnosis.

Development of a sequence-specific real-time PCR to the melon thrips Thrips palmi (Thysan., Thripidae).

Abstract:  In recent years, the polyphagous pest Thrips palmi Karny has become a species of major quarantine concern, often intercepted on plant material in international trade. The ability to rapidly identify the species is a critical factor that will determine the success of any campaign to prevent its establishment in Europe or elsewhere. However, the immature stages cannot currently be identified to the species level with certainty by morphological methods. In this study, random amplified polymorphic DNA analysis was performed to identify putative markers, which were then screened by Southern blot analysis. One marker was sequenced and a real‐time polymerase chain reaction assay developed. The assay was screened against 21 thrips species including 10 other species of the genus Thrips and were found to be specific to T. palmi. The assay is rapid, could be completed in as little as 45 min and can be used to aid the identification of T. palmi.