A method combining immunocapture and PCR amplification in a microtiter plate for the detection of plant viruses and subviral pathogens

Optimization of DAC-ELISA and IC-RT-PCR using the developed polyclonal antibody and one-step RT-PCR assays for detection of Indian citrus ringspot virus in kinnow orange of Punjab, India

Indian citrus ringspot virus (ICRSV), a member of the Mandarivirus genus, causes citrus ringspot disease, impacting kinnow orange quality and yield. Early and accurate detection methods are crucial before visible symptoms manifest in plants. In this study, a 507 bp partial coat protein gene (pCPG) segment was amplified from infected kinnow leaf tissues, cloned into a pET28a vector, and transformed into E. coli BL21(DE3) cells. Induced with IPTG, the cells overexpressed a recombinant partial coat protein (rpCP) of approximately 23 kDa, purified using Ni-NTA resin via affinity chromatography. Validated in western blot with an anti-His antibody, rpCP was used to generate an ICRSV-specific polyclonal antibody (PAb) in rabbits. PAb, optimized at 1:1000 dilution, successfully detected ICRSV in infected kinnow orange leaf extracts via DAC-ELISA and IC-RT-PCR assays. ICRSV was detectable in sample dilutions up to 1:640 and 1:10240 (w/v, g mL-1) by DAC-ELISA and IC-RT-PCR, respectively. One-step RT-PCR assays were also optimized, confirming the presence of ICRSV by amplifying a 507 bp pCPG fragment from total RNA extracted from kinnow orange leaves, with dilution up to 1:5120 (w/v, g mL-1). The result demonstrated that IC-RT-PCR has a 16-fold and 2-fold higher sensitivity than DAC-ELISA and one-step RT-PCR assays.

Triplex Immunostrip Assay for Rapid Diagnosis of Tobacco Mosaic Virus, Tobacco Vein Banding Mosaic Virus, and Potato Virus Y

Mixed virus infection has increasingly become a problem in the production of Solanaceae crops in recent years; therefore, a fast and accurate detection method is needed. In this study, a novel triplex immunostrip assay was developed for the simultaneous detection of tobacco mosaic virus (TMV), tobacco vein banding mosaic virus (TVBMV), and potato virus Y (PVY). The limits of detection of this novel immunostrip reached 200 ppb (ng/ml), 1 ppm (µg/ml), and 2 ppm for TMV, PVY, and TVBMV particles, respectively. Importantly, no cross-reactivity was observed among TMV, TVBMV, and PVY or to a nontarget virus. When the assay was applied to suspected virus-infected tobacco, tomato, and potato samples collected from fields in Southwest China, samples of single or mixed virus infection were successfully identified. In conclusion, the triplex immunostrip assay provides a fast and easy to use on-site detection method for field epidemiological studies of TMV, TVBMV, and PVY, and for managing diseases that are caused by them.

Transmission of Areca Palm Velarivirus 1 by Mealybugs Causes Yellow Leaf Disease in Betel Palm (Areca catechu)

Yellow leaf disease (YLD) is the most destructive disease of betel palm (Areca catechu). A strong association between YLD and areca palm velarivirus 1 (APV1) has been observed. However, the causal relationship between APV1 and disease, and the transmission mode, warrant further investigation. This work showed that APV1 was transmitted by both Ferrisia virgata and Pseudococcus cryptus mealybugs and caused YLD symptoms in betel palm seedlings; therefore, we demonstrate that APV1 is a causal agent of YLD. APV1 was detected in the stylets, foreguts, midguts, and hindguts of the vectors via both immunocapture reverse transcription PCR and immunofluorescence assays. APV1 was not transmitted transovarially from viruliferous female F. virgata to their progeny. In summary, the transmission of APV1 by F. virgata may occur in a noncirculative, semipersistent manner. This study fills important gaps in our knowledge of velarivirus transmission, which is critical for developing YLD management practices.

Viruses Infecting Trees and Herbs That Produce Edible Fleshy Fruits with a Prominent Value in the Global Market: An Evolutionary Perspective

Trees and herbs that produce fruits represent the most valuable agricultural food commodities in the world. However, the yield of these crops is not fully achieved due to biotic factors such as bacteria, fungi, and viruses. Viruses are capable of causing alterations in plant growth and development, thereby impacting the yield of their hosts significantly. In this work, we first compiled the world's most comprehensive list of known edible fruits that fits our definition. Then, plant viruses infecting those trees and herbs that produce fruits with commercial importance in the global market were identified. The identified plant viruses belong to 30 families, most of them containing single-stranded RNA genomes. Importantly, we show the overall picture of the host range for some virus families following an evolutionary approach. Further, the current knowledge about plant-virus interactions, focusing on the main disorders they cause, as well as yield losses, is summarized. Additionally, since accurate diagnosis methods are of pivotal importance for viral diseases control, the current and emerging technologies for the detection of these plant pathogens are described. Finally, the most promising strategies employed to control viral diseases in the field are presented, focusing on solutions that are long-lasting.

The C-Terminal Half of SARS-CoV-2 Nucleocapsid Protein, Industrially Produced in Plants, Is Valid as Antigen in COVID-19 Serological Tests

BACKGROUND

The fight against the current coronavirus disease 2019 (COVID-19) pandemic has created a huge demand of biotechnological, pharmaceutical, research and sanitary materials at unprecedented scales. One of the most urgent demands affects the diagnostic tests. The growing need for rapid and accurate laboratory diagnostic tests requires the development of biotechnological processes aimed at producing reagents able to cope with this demand in a scalable, cost-effective manner, with rapid turnaround times. This is particularly applicable to the antigens employed in serological tests. Recombinant protein expression using plants as biofactories is particularly suitable for mass production of protein antigens useful in serological diagnosis, with a neat advantage in economic terms.

METHODS

We expressed a large portion of the nucleoprotein (N) derived from SARS-CoV-2 in Nicotiana benthamiana plants. After purification, the recombinant N protein obtained was used to develop an indirect enzyme-linked immunosorbent assay (ELISA) for detection of antibodies to SARS-CoV-2 in human sera. To validate the ELISA, a panel of 416 sera from exposed personnel at essential services in Madrid City Council were tested, and the results compared to those obtained by another ELISA, already validated, used as reference. Furthermore, a subset of samples for which RT-PCR results were available were used to confirm sensitivity and specificity of the test.

RESULTS

The performance of the N protein expressed in plants as antigen in serologic test for SARS-CoV-2 antibody detection was shown to be highly satisfactory, with calculated diagnostic sensitivity of 96.41% (95% CI: 93.05-98.44) and diagnostic specificity of 96.37 (95% CI: 93.05-98.44) as compared to the reference ELISA, with a kappa (K) value of 0.928 (95% CI:0.892-0.964). Furthermore, the ELISA developed with plant-derived N antigen detected SARS-CoV-2 antibodies in 84 out of 93 sera from individuals showing RT-PCR positive results (86/93 for the reference ELISA).

CONCLUSION

This study demonstrates that the N protein part derived from SARS-CoV-2 expressed in plants performs as a perfectly valid antigen for use in COVID-19 diagnosis. Furthermore, our results support the use of this plant platform for expression of recombinant proteins as reagents for COVID-19 diagnosis. This platform stands out as a convenient and advantageous production system, fit-for-purpose to cope with the current demand of this type of biologicals in a cost-effective manner, making diagnostic kits more affordable.

A Sensitive Immunocapture-RT-PCR Assay for Detection of Maize Iranian Mosaic Virus in Individual Small Brown Planthopper Vector, Laodelphax striatellus

Background:

Sensitive detection of Maize Iranian mosaic virus (MIMV) in its insect vector, Laodelphax striatellus is essential for effective forecast and control of this viral disease.

Objectives:

Three methods of ELISA, RT-PCR and IC-RT-PCR were compared regarding their sensitivity for detection of MIMV in the single planthopper with a series of various dilutions.

Materials and Methods:

To detect MIMV from a single insect vector, the sensitivity of three methods including ELISA, RT-PCR and IC-RT-PCR was evaluated.

Results:

Compared to the other methods, the IC-RT-PCR showed more sensitivity and detected virus at least at the 160 dilution. While, both ELISA and RT-PCR methods could detect up to the 120.

Conclusion:

The results reported herein showed that IC-RT-PCR is a sensitive and simple method to detect MIMV from a single insect vector with high efficiency and reliability. These findings might be useful in the prediction of viral disease incidence in host plants and this method can also be effective to detect other viruses in their insect vectors.

Association between flower stalk elongation, an Arabidopsis developmental trait, and the subcellular location and movement dynamics of the nonstructural protein P3 of Turnip mosaic virus

Virus infections affect plant developmental traits but this aspect of the interaction has not been extensively studied so far. Two strains of Turnip mosaic virus differentially affect Arabidopsis development, especially flower stalk elongation, which allowed phenotypical, cellular, and molecular characterization of the viral determinant, the P3 protein. Transiently expressed wild-type green fluorescent protein-tagged P3 proteins of both strains and selected mutants of them revealed important differences in their behaviour as endoplasmic reticulum (ER)-associated peripheral proteins flowing along the reticulum, forming punctate accumulations. Three-dimensional (3D) model structures of all expressed P3 proteins were computationally constructed through I-TASSER protein structure predictions, which were used to compute protein surfaces and map electrostatic potentials to characterize the effect of amino acid changes on features related to protein interactions and to phenotypical and subcellular results. The amino acid at position 279 was the main determinant affecting stalk development. It also determined the speed of ER-flow of the expressed proteins and their final location. A marked change in the protein surface electrostatic potential correlated with changes in subcellular location. One single amino acid in the P3 viral protein determines all the analysed differential characteristics between strains differentially affecting flower stalk development. A model proposing a role of the protein in the intracellular movement of the viral replication complex, in association with the viral 6K2 protein, is proposed. The type of association between both viral proteins could differ between the strains.

A real-time immunocapture PCR (RT-IPCR) without interference of protein A for convenient detection of staphylococcal enterotoxin B from food and environmental samples

Purpose

A real-time immunocapture PCR (RT-IPCR) has been fabricated for the detection of Staphylococcus aureus enterotoxin B (SEB) from food and environmental samples.

Methods

Considering the fact, anti-SEB immunoglobulin G (IgG) has affinity towards protein A, produced by nearly all S. aureus, and generates false-positive read out in all immuno-based assay. We have employed avian anti-SEB antibody (SEB-IgY) as capture probe, since IgY interact less efficiently to protein A and biotinylated SEB-specific monoclonal antibody (SEB -MAb) conjugated with reporter DNA as revealing probe for real-time PCR amplification and signal generation. Sensitivity and selectivity of the assay were evaluated employing closely related enterotoxins and other toxins.

Results

The RT-IPCR is highly specific and sensitive (100 fg/mL). The practical applicability of the assay was tested using spiked food sample as well as naturally contaminated food samples. The sensitivity and specificity of RT-IPCR were not compromised by the foods tested and was able to detect SEB conveniently. Further, the assay was validated comparing with the in-house developed PCR, and plausible result was obtained.

Conclusion

The developed assay can be utilized as a low-cost detection system of SEB in routine food testing laboratories.

Genome composition analysis of multipartite BNYVV reveals the occurrence of genetic re-assortment in the isolates of Asia Minor and Thrace

Beet necrotic yellow vein virus (BNYVV) is the cause of rhizomania, an important disease of sugar beet around the world. The multipartite genome of the BNYVV contains four or five single-stranded RNA that has been used to characterize the virus. Understanding genome composition of the virus not only determines the degree of pathogenicity but also is required to development of resistant varieties of sugar beet. Resistance to rhizomania has been conferred to sugar beet varieties by conventional breeding methods or modern genome engineering tools. However, over time, viruses undergo genetic alterations and develop new variants to break crop resistance. Here, we report the occurrence of genetic reassortment and emergence of new variants of BNYVV among the isolates of Thrace and Asia Minor (modern-day Turkey). Our findings indicate that the isolates harbor European A-type RNA-2 and RNA-3, nevertheless, RNA-5 is closely related to East Asian J-type. Furthermore, RNA-1 and RNA-4 are either derived from A, B, and P-types or a mixture of them. The RNA-5 factor which enhance the pathogenicity, is rarely found in the isolates studied (20%). The creation of new variants of the virus emphasizes the necessity to develop new generation of resistant crops. We anticipate that these findings will be useful for future genetic characterization and evolutionary studies of BNYVV, as well as for developing sustainable strategies for the control of this destructive disease.

Pest categorisation of Citrus tristeza virus (non-European isolates)

The Panel on Plant Health performed a pest categorisation of non-European isolates of Citrus tristeza virus (CTV) for the EU territory. CTV is a well characterised virus for which efficient detection assays are available. It is transmitted by vegetative multiplication of infected hosts and by aphid vectors. The most efficient one, Toxoptera citricida, has limited EU presence but another one, Aphis gossypii, is broadly distributed. CTV is reported from a range of countries outside the EU and EU isolates are present in seven of the eight citrus-growing member states. Non-EU isolates are not known to occur in the EU and therefore do not meet one of the criteria for being a Union regulated non-quarantine pest. The natural host range of CTV is restricted to Citrus, Fortunella and Poncirus species. CTV non-EU isolates are listed in Annex IIAI of Directive 2000/29/EC and the main pathway for entry, plants for planting, is closed by the existing legislation. CTV isolates may therefore only enter through minor alternative pathways. They have the potential to subsequently spread through plants for planting and through the action of aphid vectors. CTV non-EU isolates are able to cause severe symptoms on a range of citrus crops that EU isolates do not induce. Overall, non-EU CTV isolates meet all the criteria evaluated by EFSA to qualify as Union quarantine pests. The main knowledge gaps and uncertainties concern (1) the status of Rutaceae species other than Citrus, Fortunella and Poncirus as natural hosts for CTV; (2) the potential undetected presence of non-EU CTV isolates in the EU and in particular the prevalence and biological properties of CTV isolates that may be present in ornamental citrus; and (3) the inability of EU CTV isolates apparently related to non-European stem pitting (SP) isolates to cause SP in sweet orange.

A field based detection method for Rose rosette virus using isothermal probe-based Reverse transcription-recombinase polymerase amplification assay

Rose rosette disease, caused by Rose rosette virus (RRV; genus Emaravirus) is a major threat to the rose industry in the U.S. The only strategy currently available for disease management is early detection and eradication of the infected plants, thereby limiting its potential spread. Current RT-PCR based diagnostic methods for RRV are time consuming and are inconsistent in detecting the virus from symptomatic plants. Real-time RT-qPCR assay is highly sensitive for detection of RRV, but it is expensive and requires well-equipped laboratories. Both the RT-PCR and RT-qPCR cannot be used in a field-based testing for RRV. Hence a novel probe based, isothermal reverse transcription-recombinase polymerase amplification (RT-exoRPA) assay, using primer/probe designed based on the nucleocapsid gene of the RRV has been developed. The assay is highly specific and did not give a positive reaction to other viruses infecting roses belonging to both inclusive and exclusive genus. Dilution assays using the in vitro transcript showed that the primer/probe set is highly sensitive, with a detection limit of 1 fg/μl. In addition, a rapid technique for the extraction of viral RNA (<5min) has been standardized from RRV infected tissue sources, using PBS-T buffer (pH 7.4), which facilitates the virus adsorption onto the PCR tubes at 4°C for 2min, followed by denaturation to release the RNA. RT-exoRPA analysis of the infected plants using the primer/probe indicated that the virus could be detected from leaves, stems, petals, pollen, primary roots and secondary roots. In addition, the assay was efficiently used in the diagnosis of RRV from different rose varieties, collected from different states in the U.S. The entire process, including the extraction can be completed in 25min, with less sophisticated equipments. The developed assay can be used with high efficiency in large scale field testing for rapid detection of RRV in commercial nurseries and landscapes.

A new virus discovered by immunocapture of double-stranded RNA, a rapid method for virus enrichment in metagenomic studies

Next-generation sequencing technologies enable the rapid identification of viral infection of diseased organisms. However, despite a consistent decrease in sequencing costs, it is difficult to justify their use in large-scale surveys without a virus sequence enrichment technique. As the majority of plant viruses have an RNA genome, a common approach is to extract the double-stranded RNA (dsRNA) replicative form, to enrich the replicating virus genetic material over the host background. The traditional dsRNA extraction is time-consuming and labour-intensive. We present an alternative method to enrich dsRNA from plant extracts using anti-dsRNA monoclonal antibodies in a pull-down assay. The extracted dsRNA can be amplified by reverse transcriptase-polymerase chain reaction and sequenced by next-generation sequencing. In our study, we have selected three distinct plant hosts: Māori potato (Solanum tuberosum), rengarenga (Arthropodium cirratum) and broadleaved dock (Rumex obtusifolius) representing a cultivated crop, a New Zealand-native ornamental plant and a weed, respectively. Of the sequence data obtained, 31-74% of the reads were of viral origin, and we identified five viruses including Potato virus Y and Potato virus S in potato; Turnip mosaic virus in rengarenga (a new host record); and in the dock sample Cherry leaf roll virus and a novel virus belonging to the genus Macluravirus. We believe that this new assay represents a significant opportunity to upscale virus ecology studies from environmental, primary industry and/or medical samples.

Development and validation of a multiplex reverse transcription quantitative PCR (RT-qPCR) assay for the rapid detection of Citrus tristeza virus, Citrus psorosis virus, and Citrus leaf blotch virus

A single real-time multiplex reverse transcription quantitative polymerase chain reaction (RT-qPCR) assay for the simultaneous detection of Citrus tristeza virus (CTV), Citrus psorosis virus (CPsV), and Citrus leaf blotch virus (CLBV) was developed and validated using three different fluorescently labeled minor groove binding qPCR probes. To increase the detection reliability, coat protein (CP) genes from large number of different isolates of CTV, CPsV and CLBV were sequenced and a multiple sequence alignment was generated with corresponding CP sequences from the GenBank and a robust multiplex RT-qPCR assay was designed. The capacity of the multiplex RT-qPCR assay in detecting the viruses was compared to singleplex RT-qPCR designed specifically for each virus and was assessed using multiple virus isolates from diverse geographical regions and citrus species as well as graft-inoculated citrus plants infected with various combination of the three viruses. No significant difference in detection limits was found and specificity was not affected by the inclusion of the three assays in a multiplex RT-qPCR reaction. Comparison of the viral load for each virus using singleplex and multiplex RT-qPCR assays, revealed no significant differences between the two assays in virus detection. No significant difference in Cq values was detected when using one-step and two-step multiplex RT-qPCR detection formats. Optimizing the RNA extraction technique for citrus tissues and testing the quality of the extracted RNA using RT-qPCR targeting the cytochrome oxidase citrus gene as an RNA specific internal control proved to generate better diagnostic assays. Results showed that the developed multiplex RT-qPCR can streamline viruses testing of citrus nursery stock by replacing three separate singleplex assays, thus reducing time and labor while retaining the same sensitivity and specificity. The three targeted RNA viruses are regulated pathogens for California's mandatory "Section 3701: Citrus Nursery Stock Pest Cleanliness Program". Adopting a compatible multiplex RT-qPCR testing protocol for these viruses as well as other RNA and DNA regulated pathogens will provide a valuable alternative tool for virus detection and efficient program implementation.

Genetic variability of blueberry scorch virus isolates from highbush blueberry in New York State

The genetic variability of blueberry scorch virus (BlScV) isolates from New York was determined within a portion of the RNA-dependent RNA polymerase gene and the triple gene block and coat protein (CP) genes. Phylogenetic analysis of 19 New York isolates and other isolates for which sequence information is available in GenBank revealed two distinct clades, regardless of the coding region analyzed, and limited variability within (0.029 ± 0.007) and between (0.183 ± 0.032) phylogroups. Recombination events were identified in the CP gene of three New York isolates, and codons of the five BlScV genes characterized were found to be under neutral or negative selective pressure.

Detection and Characterization of Viral Species/Subspecies Using Isothermal Recombinase Polymerase Amplification (RPA) Assays

Numerous molecular-based detection protocols include an amplification step of the targeted nucleic acids. This step is important to reach the expected sensitive detection of pathogens in diagnostic procedures. Amplifications of nucleic acid sequences are generally performed, in the presence of appropriate primers, using thermocyclers. However, the time requested to amplify molecular targets and the cost of the thermocycler machines could impair the use of these methods in routine diagnostics. Recombinase polymerase amplification (RPA) technique allows rapid (short-term incubation of sample and primers in an enzymatic mixture) and simple (isothermal) amplification of molecular targets. RPA protocol requires only basic molecular steps such as extraction procedures and agarose gel electrophoresis. Thus, RPA can be considered as an interesting alternative to standard molecular-based diagnostic tools. In this paper, the complete procedures to set up an RPA assay, applied to detection of RNA (Potato virus Y, Potyvirus) and DNA (Wheat dwarf virus, Mastrevirus) viruses, are described. The proposed procedure allows developing species- or subspecies-specific detection assay.

High-level production of active human TFPI-2 Kunitz domain in plant

Plants are an attractive production system alternative to cell bioreactor not only because of its lower production costs, but also due to its lack of mammalian pathogens and contaminants, plant capacity to generate appropriate eukaryotic folding and in many cases correct post-translational modifications. In recent years, several recombinant proteins and antibodies have been introduced in the biopharmaceutical market, in particular in cancer therapeutics. Kunitz domain 1 (KD1), a domain of Human Tissue Factor Pathway Inhibitor-2 (TFPI-2), has an outstanding potential in cancer treatment because it is a potent inhibitor of extracellular serine proteinases involved in tumor progression and angiogenesis. We present here the expression and purification of active human KD1 in different Nicotiana species as hosts and its stability during the infection process using a construct derived from a Tobacco mosaic virus (TMV) vector. Our purification protocol allows to recover over 100mg of active human KD1 per batch of 1 kg of plant tissue at about 97% purity. The yields are reproducible, being N. benthamiana the best system where higher levels of KD1 are obtained. Recombinant KD1 was also used to produce a high-sensitivity polyclonal antibody able to detect not only KD1 but also full-length TFPI-2. Finally, we show that this platform is a valuable alternative for the large scale production of KD1.

Calculation of diagnostic parameters of advanced serological and molecular tissue-print methods for detection of Citrus tristeza virus: a model for other plant pathogens

Citrus tristeza virus (CTV) is one of the most important virus diseases that affect citrus. Control of CTV is achieved by grafting selected virus-free citrus scions onto CTV-tolerant or -resistant rootstocks. Quarantine and certification programs are essential for avoiding the entry and propagation of severe strains of CTV. Citrus nurseries in Spain and central California (United States) maintain zero-tolerance policies for CTV that require sensitive, specific, and reliable pathogen-detection methods. Tissue-print (TP) real-time reverse-transcriptase polymerase chain reaction (RT-PCR) assay was compared with the validated TP enzyme-linked immunosorbent assay (ELISA), using the CTV-specific monoclonal antibodies 3DF1 and 3CA5, for CTV detection. In total, 1,395 samples from healthy and CTV-infected nursery and mature tree plants were analyzed with both methods. The total agreement between both detection methods was substantial (Cohen's kappa index of 0.77 ± 0.03). The diagnostic parameters of each technique (i.e., the sensitivity, specificity, and likelihood ratios) were evaluated in a second test involving 658 Citrus macrophylla nursery plants. Mexican lime indexing was used to evaluate samples with discrepant results in the analysis. For TP-ELISA, a sensitivity of 0.8015, a specificity of 0.9963, and a positive and negative likelihood ratio of 216.42 and 0.199, respectively, were estimated. For TP real-time RT-PCR, a sensitivity of 0.9820, a specificity of 0.8519, and a positive and negative likelihood ratio of 6.63 and 0.021, respectively, were estimated. These diagnostic parameters show that TP real-time RT-PCR was the most sensitive technique, whereas TP-ELISA showed the highest specificity, validating the use of the molecular technique for routine CTV-detection purposes. In addition, our results show that the combination of both techniques can accurately substitute for the conventional biological Mexican lime index for the detection of CTV. The calculation of diagnostic parameters is discussed, as a necessary tool, to validate detection or diagnostic methods in plant pathology. Furthermore, assessment of the post-test probability of disease after a diagnostic result and CTV prevalence allows selection of the best method for accurate and reliable diagnosis.

Tospoviruses in the Mediterranean area

Tospoviruses are among the most serious threats to vegetable crops in the Mediterranean basin. Tospovirus introduction, spread, and the diseases these viruses cause have been traced by epidemiological case studies. Recent research has centered on the close relationship between tospoviruses and their arthropod vectors (species of the Thripidae family). Here, we review several specific features of tospovirus-thrips associations in the Mediterranean. Since the introduction of Frankliniella occidentalis in Europe, Tomato spotted wilt virus (TSWV) has become one of the limiting factors for vegetable crops such as tomato, pepper, and lettuce. An increasing problem is the emergence of TSWV resistance-breaking strains that overcome the resistance genes in pepper and tomato. F. occidentalis is also a vector of Impatiens necrotic spot virus, which was first observed in the Mediterranean basin in the 1980s. Its importance as a cause of vegetable crop diseases is limited to occasional incidence in pepper and tomato fields. A recent introduction is Iris yellow spot virus, transmitted by the onion thrips Thrips tabaci, in onion and leek crops. Control measures in vegetable crops specific to Mediterranean conditions were examined in the context of their epidemiological features and tospovirus species which could pose a future potential risk for vegetable crops in the Mediterranean were discussed.

Chimeras between oilseed rape mosaic virus and tobacco mosaic virus highlight the relevant role of the tobamoviral RdRp as pathogenicity determinant in several hosts

Oilseed rape mosaic virus (ORMV) is a tobamovirus taxonomically distinct from the type member of the genus, Tobacco mosaic virus (TMV). Both viruses display a specific host range, although they share certain hosts, such as Arabidopsis thaliana, Nicotiana benthamiana and N. tabacum, on which they induce different symptoms. Using a gain-of-symptom approach, we generated chimeric viruses, starting from a TMV infectious clone, over which different regions of ORMV were exchanged with their corresponding regions in the TMV genome. This approach allowed the association of pathogenicity determinants to certain genes within the ORMV genome. A general trend was observed associating the viral origin of the RNA-dependent RNA-polymerase (RdRp) gene and the gain of symptoms. In A. thaliana and N. benthamiana, chimeric viruses were unable to reproduce the symptoms induced by the parental viruses, leading to disease states which could be described as intermediate, and variable in some cases. In contrast, a hypersensitive reaction caused by both of these viruses on N-gene-bearing tobaccos could be found in resistance reactions to all chimeric viruses, suggesting that the avirulence determinant maps similarly in both viruses. A systemic necrotic spotting typical of non-N-gene tobaccos infected with ORMV was associated with the polymerase domain of RdRp. To our knowledge, this is the first time that this controversial portion of the tobamovirus genome has been identified directly as a pathogenicity determinant. None of the reactions of the chimeric viruses could be correlated with increases or decreases in virus titres in the infections.

Immunocapture-PCR for plant virus detection

Immunocapture followed by the detection of viruses using polymerase chain reaction is a versatile, sensitive and robust diagnostic technique. The application of this hybrid method of virus detection in plants is particularly useful in species or tissues containing inhibitory substances. In addition, antibody-mediated virus purification is usually simpler than other methods of isolation.

Citrus tristeza virus: a pathogen that changed the course of the citrus industry

Citrus tristeza virus (CTV) (genus Closterovirus, family Closteroviridae) is the causal agent of devastating epidemics that changed the course of the citrus industry. Adapted to replicate in phloem cells of a few species within the family Rutaceae and to transmission by a few aphid species, CTV and citrus probably coevolved for centuries at the site of origin of citrus plants. CTV dispersal to other regions and its interaction with new scion varieties and rootstock combinations resulted in three distinct syndromes named tristeza, stem pitting and seedling yellows. The first, inciting decline of varieties propagated on sour orange, has forced the rebuilding of many citrus industries using tristeza-tolerant rootstocks. The second, inducing stunting, stem pitting and low bearing of some varieties, causes economic losses in an increasing number of countries. The third is usually observed by biological indexing, but rarely in the field. CTV polar virions are composed of two capsid proteins and a single-stranded, positive-sense genomic RNA (gRNA) of approximately 20 kb, containing 12 open reading frames (ORFs) and two untranslated regions (UTRs). ORFs 1a and 1b, encoding proteins of the replicase complex, are directly translated from the gRNA, and together with the 5' and 3'UTRs are the only regions required for RNA replication. The remaining ORFs, expressed via 3'-coterminal subgenomic RNAs, encode proteins required for virion assembly and movement (p6, p65, p61, p27 and p25), asymmetrical accumulation of positive and negative strands during RNA replication (p23), or suppression of post-transcriptional gene silencing (p25, p20 and p23), with the role of proteins p33, p18 and p13 as yet unknown. Analysis of genetic variation in CTV isolates revealed (1) conservation of genomes in distant geographical regions, with a limited repertoire of genotypes, (2) uneven distribution of variation along the gRNA, (3) frequent recombination events and (4) different selection pressures shaping CTV populations. Measures to control CTV damage include quarantine and budwood certification programmes, elimination of infected trees, use of tristeza-tolerant rootstocks, or cross protection with mild isolates, depending on CTV incidence and on the virus strains and host varieties predominant in each region. Incorporating resistance genes into commercial varieties by conventional breeding is presently unfeasible, whereas incorporation of pathogen-derived resistance by plant transformation has yielded variable results, indicating that the CTV-citrus interaction may be more specific and complex than initially thought. A deep understanding of the interactions between viral proteins and host and vector factors will be necessary to develop reliable and sound control measures.

A semi-automated and highly sensitive streptavidin magnetic capture-hybridization RT-PCR assay: Application to genus-wide or species-specific detection of several viruses of ornamental bulb crops

A semi-automated, rapid and sensitive method that combines magnetic capture-hybridization and reverse-transcription polymerase chain reaction (MCH/RT-PCR) for the detection of plant viruses is described. The assay uses a target specific biotin-labelled oligoprobe for RNA capture and streptavidin-coated magnetic beads for subsequent RNA-oligoprobe hybrid isolation from plant lysate. Detection and specific identification was accomplished by RT-PCR. This approach was investigated for the specific detection of Tobacco rattle virus and for the detection of viruses within the Potexvirus group in leaves, dormant bulbs and corms of flower bulbs of different species. Dilution series of TRV-infected tulip leaf sap showed that MCH/RT-PCR was 70,588 times more sensitive than enzyme-linked immunosorbent assay (ELISA) and was similar to that of RT-PCR. ELISA underestimated the infection levels of TRV in field samples compared to MCH/RT-PCR. The ability of MCH/RT-PCR to be performed in a microtiter plate on an automatic nucleic acid isolation station facilitates high throughput virus diagnostics. RNA isolation and purification was rapid, specific, sensitive, contamination-free and reproducible making this method amenable for routine indexing of stock plants as part of a management plan to reduce the propagation of virus-infected plants.

A real-time RT-PCR assay for detection and absolute quantitation of Citrus tristeza virus in different plant tissues

A real-time RT-PCR assay using SYBR Green was developed for specific and reliable quantitative detection of Citrus tristeza virus (CTV) in infected plants. A general primer set designed from conserved sequences in ORFs 1b and 2 enabled amplification of the genomic RNA (gRNA) while excluding most subgenomic and defective RNAs. Single RT-PCR products of 204 bp (isolate T36) or 186 bp (other isolates) were obtained with no primer-dimer or non-specific amplifications detected. Melting curve analysis revealed distinct melting temperature peaks (T(m)) for severe and mild isolates. External standard curves using RNA transcripts of the selected target allowed a reproducible quantitative assay, with a wide dynamic range of detection starting with 10(2) gRNA copies and with very low variation coefficient values. This protocol enabled reliable assessments of CTV accumulation in different tissues and from different citrus species, grown in the greenhouse or under field conditions, and infected with CTV isolates differing in their pathogenicity. CTV accumulation was higher in bark and fruits than in roots or leaves and showed minimal differences among several susceptible citrus species, but it was significantly lower in sour orange. This quantitative detection assay will be a valuable tool for diagnosis and molecular studies on CTV biology.

Improved Efficiency for Quantitative and Qualitative Indexing for Citrus tristeza virus and Citrus psorosis virus

Reverse transcription-polymerase chain reaction (RT-PCR) assays were developed for the detection of Citrus tristeza virus (CTV; genus Closterovirus) and Citrus psorosis virus (CPsV; genus Ophiovirus) in citrus trees. Real-time TaqMan RT-PCR was also developed for the detection of CTV. Three different sample preparation methods were compared. The total RNA extraction method by Qiagen was found to be more reliable than the other two methods consisting of crude plant sap extraction and total nucleic acid trapping on a silica bed. Of 287 samples tested for CTV, 210 samples tested positive by RT-PCR and 198 samples by enzyme-linked immunosorbent assay (ELISA). Furthermore, the results from monthly tests of a selected number of field-grown CTV-infected trees showed that RT-PCR detected the virus in 100% of the infected trees in winter and summer, whereas ELISA did not. The one-tube RT-PCR detection was developed for CPsV and was more sensitive than ELISA. Notably, three of 10 CPsV isolates were not detected by ELISA. As demonstrated here, our approach allows the efficacious detection of different viruses in citrus plants using a minimal amount of tissue during all seasons. The molecular methods described could be used in citrus certification programs and to test trees in nurseries and commercial orchards.

A sensitive one-step real-time RT-PCR method for detecting Grapevine leafroll-associated virus 2 variants in grapevine

Grapevine leafroll syndrome is caused by a complex of up to nine different Grapevine leafroll-associated viruses (GLRaV-1-9) with GLRaV-2 being reported as one of the most variable species of this group. Many methods, including indexing, serological and molecular procedures, have been developed for the detection of GLRaV-2. However, due to the low concentration of the virus in plants and the high variability of GLRaV-2, a method with improved sensitivity and with the capacity to detect of all known variants is required. Such improvement is essential for grapevine rootstocks, as these are suspected to harbour frequent GLRaV-2 infections difficult to detect, thus contributing to the spread of the leafroll disease. The development of new universal primers is described using a target sequence located in the 3' end of the virus genome. These primers were combined with a one-step SYBR Green real-time RT-PCR assay to achieve quantitative detection. All 43 GLRaV-2 isolates tested in this study were identified readily and reproducibly, regardless of their geographical origin or variety of grapevine. Using the procedure developed in this study, the sensitivity was increased 125 times compared to a conventional single-tube RT-PCR. This real-time method opens new perspectives for the sanitary selection of grapevine and in leafroll 2 disease monitoring.

A totivirus infecting the mutualistic fungal endophyte Epichloë festucae

Epichloë festucae (Ascomycota) infects the grass Festuca rubra. Infected plants may be more resistant to herbivores and obtain other benefits. The 5109bp dsRNA genome of a virus which infects E. festucae was sequenced, and its incidence in natural populations and transmission were studied. The viral genome has characteristics of the family Totiviridae. Its two ORFs are overlapped by four nucleotides; ORF1 codes a 765 amino acid putative coat protein (CP); ORF2 is in a -1 frameshift with respect to ORF1, and codes a 826 amino acid RNA dependent RNA polymerase (RdRp). This virus, denominated Epichloë festucae virus 1 (EfV1), is closely related to members of the genus Totivirus which infect filamentous fungi, as deduced from phylogenetic analyses of CPs and RdRps. In two natural populations of Epichloë festucae, 36.4% of the isolates were infected by EfV1. The virus was efficiently transmitted to asexual fungal spores. However, when ascospore progeny of matings between virus-free and infected strains was analyzed, it was found that the virus was not transmitted to progeny of sexual spores.

Physiological effects of constitutive expression of Oilseed Rape Mosaic Tobamovirus (ORMV) movement protein in Arabidopsis thaliana

Movement proteins (MPs) are non-cell autonomous viral-encoded proteins that assist viruses in their cell-to-cell movement. The MP encoded by Tobamoviruses is the best characterized example among MPs of non-tubule-inducing plant RNA viruses. The MP of Oilseed Rape Mosaic Tobamovirus (ORMV) was transgenically expressed in Arabidopsis thaliana, ecotype RLD, under the expression of the 35S promoter from Cauliflower Mosaic Virus. Transgenic lines were obtained in sense and antisense orientations. One of the sense transgenic lines was further characterized turning out to carry one copy of the transgene inserted in the terminal region of the right arm of chromosome 1. The constitutive expression of ORMV-MP induced mild physiological effects in Arabidopsis. Plants of the transgenic line allowed a faster systemic movement of the phloem tracer carboxyfluorescein. The tracer was unloaded differentially in different flower parts, revealing differential effects of ORMV-MP on phloem unloading in sink organs. On the other hand, transgenic Arabidopsis did not show any effect on biomass partitioning or sugar availability, effects reported for equivalent transgenic solanaceous plants expressing the MP of Tobacco Mosaic Virus, another Tobamovirus. Finally, the transgenic Arabidopsis plants were susceptible to ORMV infection, although showing milder overall symptoms than non-transgenic controls. The results highlight the relevance of the specific host-virus system, in the physiological outcome of the molecular interactions established by MPs.

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.

Application of a spotting sample preparation technique for the detection of pathogens in woody plants by RT-PCR and real-time PCR (TaqMan)

An extraction technique for reverse transcription-PCR (RT-PCR) detection of plant pathogens including viruses, bacteria and phytoplasma is described. The total nucleic acid of these plant pathogens was obtained by direct spotting of crude sap derived from infected leaf, petiole or cambial tissue onto two different types of membranes, positively charged Hybond N(+) Nylon and FTA membranes, and processed for use in PCR. Thirteen different plant viruses, Xylella fastidiosa (causal agent of Pierce's disease) and phytoplasmas were included in the experiment. A thermal treatment (95 degrees C for 10 min) of the Hybond N(+) Nylon discs in a buffered solution improved the detection, but for FTA membrane discs the thermal treatment was not required and the discs were directly placed in the PCR reaction cocktail. Specific amplification of genomic or ribosomal RNA fragments of these pathogens was obtained by one-step RT-PCR except for X. fastidiosa in which a fragment of the genomic DNA was used for amplification. The same sample preparation methods also worked well for real-time RT-PCR (TaqMan). The sample preparation techniques reported here could be used to store samples for future PCR test or for long distance shipment to a detection laboratory.

An alkaline solution simplifies nucleic acid preparation for RT-PCR and infectivity assays of viroids from crude sap and spotted membrane

Formats of a simple protocol for the preparation of nucleic acids for infectivity and RT-PCR detection of viroids from minute amounts of plant material are described. The method consists of preparing crude extracts in a NaOH-EDTA solution and then testing the supernatant. The NaOH-EDTA extract can be used at four distinct stages of preparation depending upon the accuracy desired, namely: (1) incubation of extract for 15 min at room temperature and the use of the supernatant for RT-PCR; (2) the supernatant can be spotted onto a nitrocellulose membrane (NCM) without vacuum, and the water-eluted liquid is used for RT-PCR; (3) centrifugation of the extract and use of supernatant in RT-PCR; (4) for quantitative accuracy, spotting the centrifuged supernatant on NCM using a vacuum device and then using the water-eluted liquid for RT-PCR. The protocols are rapid, inexpensive and applicable to large-scale epidemiological survey of ornamental plants or crops. The membranes are easily transported long distances and can be stored at room temperature for several months while retaining the ability to detect viroids by RT-PCR and by infectivity assays.

Development and assessment of a potato virus X-based expression system with improved biosafety

Over the last decade, plant virus-based vectors have been developed and successfully exploited for high-yield production of heterologous proteins in plants. However, widespread application of recombinant viruses raises concerns about possible risks to the environment. One of the primary safety issues that must be considered is the uncontrolled spread of the genetically engineered virus from experimental plants to susceptible weeds or crops. Using a movement-deficient Potato virus X (PVX)-based transient gene expression vector which harbors the beta-glucuronidase (gus) gene, we established a plant viral expression system that provides containment of the recombinant virus and allows for safe and efficient protein production. By deletion of the viral 25k movement protein gene, systemic spread of the modified virus in non-transgenic Nicotiana benthamiana plants was successfully inhibited. In transgenic N. benthamiana plants expressing the 25K viral movement protein, this deficiency was complemented, thus resulting in systemic infection with the movement-deficient virus. While no differences in virus spread and accumulation were observed compared to infection caused by wild-type PVX in non-transgenic plants, the movement protein transgenic plants exhibited none of the normal symptoms of viral infection. Several biosafety aspects were investigated including the potential for recombination between the defective virus and the movement protein transgene, as well as complementation effects in non-transgenic plants doubly infected with the defective and the wild-type virus. Furthermore, the applicability of the safety system for the production of heterologous proteins was evaluated with gus as a model gene. With respect to the stability of the gus insert and the expression level of the GUS protein, there were no differences between the novel system developed and the conventional PVX-based expression system.

Pathogen testing and certification of Vitis and Prunus species

Strategies to screen horticultural crops for graft-transmissible agents, particularly viruses and phytoplasmas, have advanced substantially over the past decade. Tests used for Vitis and Prunus are reviewed in detail, including both biological indexing procedures and laboratory-based assays. Despite advances in laboratory molecular-based detection techniques, a strong case is presented for the continued use of slower biological tests in programs requiring high levels of confidence in detection of pathogens that must be excluded from valuable germplasm.

Development of immunocapture reverse transcription loop-mediated isothermal amplification for the detection of tomato spotted wilt virus from chrysanthemum

An immunocapture reverse transcription loop-mediated isothermal amplification (IC/RT-LAMP) was developed for the detection of tomato spotted wilt virus (TSWV) from chrysanthemum. This method enabled sensitive, reproducible and specific detection of TSWV from chrysanthemum plants. In the RT-LAMP method, TSWV genomic RNA could be amplified under isothermal (65 degrees C) conditions within 1 h. The resulting amplicons were detected by the measurement or observation of the turbidity of the reaction mixture without gel electrophoresis. IC/RT-LAMP was 100 times more sensitive than IC/RT-PCR.

Immunopurification applied to the study of virus protein composition and encapsidation

A protocol for obtaining small amounts of highly pure virus preparations starting from reduced volumes (<5 ml) of infected tissue culture supernatants is described. This procedure was adapted to the study of transmissible gastroenteritis coronavirus (TGEV) protein composition and RNA encapsidation. This protocol relies on virion capture by monoclonal antibodies specific for a virion membrane protein. These antibodies were bound to protein A-coated ELISA wells armed with rabbit anti-mouse IgG antibodies. As an example, the purification of ³⁵S-labelled TGEV virions was performed. The quality of virus preparations was assessed by quantifying common contaminating RNAs by real-time RT-PCR. The most critical factors influencing the purity degree are analysed and discussed.

Ultra-sensitive detection of two garlic potyviruses using a real-time fluorescent (Taqman) RT-PCR assay

A method for the detection of Onion yellow dwarf virus (OYDV) and Leek yellow stripe virus (LYSV), the two most prevalent garlic potyviruses, has been developed that combines IC-RT-PCR/RT-PCR with the use of TaqMan probes. Comparisons with ELISA results obtained with identical OYDV and LYSV infected samples showed sensitivity in detecting these viruses increased up to 10(6)-fold. OYDV and LYSV were detected using different fluorochromes in the probe, thus allowing unequivocal diagnosis for each of them. The polyvalence of the designed virus-specific primers and probes was shown through their application to the detection of three isolates from very different geographical areas and from different hosts. A second version of the method avoids the need for an immunocapture step through the performance of a TaqMan RT-PCR assay directly on extracts of garlic cloves. This modification on the proposed basic method allows the analysis of bulb samples in 3-4h but did not give reproducible results with leaves. Both versions of the new diagnostic method bear great potential for their implementation in virus-free certification schemes in garlic, a vegetatively propagated crop for which such a certification is critical for a high-quality product.

Comparison of Detection Methods for a Novel Tobamovirus Isolated from Florida Hibiscus

A novel tobamovirus recently was isolated from hibiscus in Florida. Serological and molecular methods, including enzyme-linked immunosorbent assay (ELISA), dot-blot immunoassay (DBIA), tissue-blot immunoassay (TBIA), and immunocapture reverse-transcription poly-merase chain reaction (IC-RT-PCR) were compared to evaluate their usefulness for diagnosis of this virus. Each method was tested with partially purified virus preparations and tissue samples from infected hibiscus and Chenopodium quinoa plants. Indirect ELISA was more sensitive than double-antibody sandwich (DAS)-ELISA with all samples tested. The Florida hibiscus virus was detectable in hibiscus leaves and bark up to 1:12,800 and 1:6,400 dilutions, respectively, by indirect ELISA and up to 1:3,200 and 1:400 dilutions by DAS-ELISA. End-point dilutions of partially purified virus preparations from indirect and DAS-ELISA were 4 and 31 ng/ml, respectively. Florida hibiscus virus was detected by DBIA in sap from hibiscus bark and leaves at dilutions up to 1:400 and 1:800, respectively, showing that DBIA was less sensitive than either ELISA method. The virus also was detected reliably by TBIA from leaves and bark of hibiscus plants. The most sensitive method was IC-RT-PCR, which could detect as little as 500 pg/ml of virus in partially purified preparations and was 16- and 32-fold more sensitive than DAS-ELISA with hibiscus bark and leaf extracts, respectively. Over 600 hibiscus samples were tested by various combinations of these methods to validate their usefulness.

Innovative tools for detection of plant pathogenic viruses and bacteria

Detection of harmful viruses and bacteria in plant material, vectors or natural reservoirs is essential to ensure safe and sustainable agriculture. The techniques available have evolved significantly in the last few years to achieve rapid and reliable detection of pathogens, extraction of the target from the sample being important for optimising detection. For viruses, sample preparation has been simplified by imprinting or squashing plant material or insect vectors onto membranes. To improve the sensitivity of techniques for bacterial detection, a prior enrichment step in liquid or solid medium is advised. Serological and molecular techniques are currently the most appropriate when high numbers of samples need to be analysed. Specific monoclonal and/or recombinant antibodies are available for many plant pathogens and have contributed to the specificity of serological detection. Molecular detection can be optimised through the automatic purification of nucleic acids from pathogens by columns or robotics. New variants of PCR, such as simple or multiplex nested PCR in a single closed tube, co-operative-PCR and real-time monitoring of amplicons or quantitative PCR, allow high sensitivity in the detection of one or several pathogens in a single assay. The latest development in the analysis of nucleic acids is micro-array technology, but it requires generic DNA/RNA extraction and pre-amplification methods to increase detection sensitivity. The advances in research that will result from the sequencing of many plant pathogen genomes, especially now in the era of proteomics, represent a new source of information for the future development of sensitive and specific detection techniques for these microorganisms.

Strains of Turnip mosaic potyvirus as defined by the molecular analysis of the coat protein gene of the virus

Turnip mosaic virus (TuMV) is a member of the potyvirus genus with a wide host range and highly variable in its biological characteristics. Analysis of the CP gene sequences from databases, combined with the experimental analysis of the CP gene of further isolates, using data derived from sequence or restriction analysis, has allowed the genetic classification of 60 TuMV isolates or sequences. Two main genetic clusters MB (mostly Brassica isolates) and MR (mostly Radish isolates) were found, together with several apparently independent lineages. Isolates in the latter could be grouped as Intermediate between Brassica and Radish clusters (IBR) or outside Brassica and Radish clusters (OBR), according to their genetic distance to the main clusters. The genetic diversity of TuMV isolates deposited in the databases was increased with the sequences of the CP gene of seven selected isolates, mainly belonging to IBR or OBR groups. There was a correlation between the MR genetic cluster and JPN 1 serotype.

Incidence of Viruses and Virus like Diseases of Sweetpotato in Uganda

Sweetpotato plants were surveyed for viruslike diseases and viruses in the four major agroecological zones of Uganda. Testing of 1,260 sweetpotato plants, of which 634 had virus-like symptoms, showed that virus disease incidence ranged from 2.7% (Soroti district, short grassland-savannah zone) to 20% (Mukono district, tall grass-forest mosaic zone). Sweet potato chlorotic stunt virus (SPCSV), Sweet potato feathery mottle virus (SPFMV), Sweet potato mild mottle virus (SPMMV), and sweet potato chlorotic fleck virus (SPCFV) were serologically detected and positive results confirmed by immunocapture reverse transcriptase polymerase chain reaction (IC-RT-PCR) and subsequent sequence analyses of the amplified fragments, except SPCFV, which lacked sequence information. SPCSV and SPFMV were detected in all the 14 districts surveyed, whereas SPMMV and SPCFV were detected in 13 and 8 districts, respectively. Logistic regression analysis revealed that SPCSV and SPFMV, SPFMV and SPMMV, and SPFMV and SPCFV more frequently occurred together than any other virus combinations or as single virus infections. Co-infections of SPCSV with SPFMV and/or SPMMV were associated with more severe and persistent symptoms than infections with each of the viruses alone. Several plants (11%) displaying viruslike symptoms did not react with the virus antisera used, suggesting that more viruses or viruslike agents are infecting sweetpotatoes in Uganda.

Simultaneous and co-operational amplification (Co-PCR): a new concept for detection of plant viruses

A new and highly sensitive method for the amplification of viral RNA targets from plant material has been developed and patented. This technique called Co-operational amplification (Co-PCR) can be carried out easily in a simple tetraprimer reaction based on the simultaneous action of four primers. The reaction process consists of the simultaneous reverse transcription of two different fragments from the same target, one containing the other; the production of four amplicons by the combination of the two pair of primers, one pair external to other; and the co-operational action of amplicons for the production of the largest fragment. The technique was used successfully, both in metal block and capillary air thermal cyclers for the detection of plant RNA viruses (Cherry leaf roll virus, Strawberry latent ringspot virus, Cucumber mosaic virus, Plum pox virus and Citrus tristeza virus). The sensitivity observed is at least 100 times higher than that achieved with RT-PCR and similar to nested RT-PCR. Colorimetric detection was coupled with this methodology facilitating its introduction for routine indexing programs and for phytosanitary selection of virus-free plant material.

A fitness cost for Turnip mosaic virus to overcome host resistance

The relative fitness of the Turnip mosaic virus (TuMV) isolate UK 1 was compared with that of two other wildtype isolates CZE 1 and CDN 1. The isolates CZE 1 and CDN 1 are able to overcome the effect of the resistance gene TuRB01 and at least three other resistance sources that are effective against UK 1. Comparisons were also made between the fitness of UK 1 and a recombinant virus with a single nucleotide change (v35Tunos +5570 A>G) conferring the ability to overcome TuRB01 resistance. Co-inoculation experiments were carried out where pairs of isolates were serially passaged over 5 months in a plant line possessing no known resistance genes in order to examine the relative fitness of the isolates. In each case, UK 1 dominated the mixture in the susceptible host background. It out-competed CZE 1 and v35Tunos +5570 A>G within four passages, and CDN 1 after one passage. The greater fitness of UK 1 suggests that there may be a fitness cost to TuMV overcoming resistance genes of brassica crops. This may shed some light on the frequency of naturally occurring isolates, in that pathotype 1 isolates are found much more frequently than isolates of other pathotypes. Implications for the deployment of TuRB01 are discussed.

Functional genomics on potato virus A: virus genome-wide map of sites essential for virus propagation

Transposition-based in vitro insertional mutagenesis strategies provide promising new approaches for functional characterization of any cloned gene or genome region. We have extended the methodology and scope of such analysis to a complete viral genome. To map genome regions both essential and nonessential for Potato virus A propagation, we generated a genomic 15-bp insertion mutant library utilizing the efficient in vitro DNA transposition reaction of phage Mu. We then determined the proficiency of 1125 mutants to propagate in tobacco protoplasts by using a genetic footprinting strategy that simultaneously mapped the genomic insertion sites. Over 300 sites critical for virus propagation were identified, and many of them were located in positions previously not assigned to any viral functions. Many genome regions tolerated insertions indicating less important sites for virus propagation and thus pinpointed potential locations for further genome manipulation. The methodology described is applicable to a detailed functional analysis of any viral nucleic acid cloned as DNA and can be used to address many different processes during viral infection cycles.