Isolation of fungal DNA from plant tissues and removal of DNA amplification inhibitors

A Genome-Wide Comparison of Rice False Smut Fungus Villosiclava virens Albino Strain LN02 Reveals the Genetic Diversity of Secondary Metabolites and the Cause of Albinism

Rice false smut (RFS) caused by Villosiclava virens (anamorph: Ustilaginoidea virens) has become one of the most destructive fungal diseases to decrease the yield and quality of rice grains. An albino strain LN02 was isolated from the white RFS balls collected in the Liaoning Province of China in 2019. The strain LN02 was considered as a natural albino mutant of V. virens by analyzing its phenotypes, internal transcribed spacer (ITS) conserved sequence, and biosynthesis gene clusters (BGCs) for secondary metabolites. The total assembled genome of strain LN02 was 38.81 Mb, which was comprised of seven nuclear chromosomes and one mitochondrial genome with an N50 value of 6,326,845 bp and 9339 protein-encoding genes. In addition, the genome of strain LN02 encoded 19 gene clusters for biosynthesis of secondary metabolites mainly including polyketides, terpenoids and non-ribosomal peptides (NRPs). Four sorbicillinoid metabolites were isolated from the cultures of strain LN02. It was found that the polyketide synthase (PKS)-encoding gene uspks1 for ustilaginoidin biosynthesis in strain LN02 was inactivated due to the deletion of four bases in the promoter sequence of uvpks1. The normal uvpks1 complementary mutant of strain LN02 could restore the ability to synthesize ustilaginoidins. It demonstrated that deficiency of ustilaginoidin biosynthesis is the cause of albinism for RFS albino strain LN02, and V. virens should be a non-melanin-producing fungus. This study further confirmed strain LN02 as a white phenotype mutant of V. virens. The albino strain LN02 will have a great potential in the development and application of secondary metabolites. The physiological and ecological functions of ustilaginoidins in RFS fungus are needed for further investigation.

Development and Application of a LAMP Assay for the Detection of the Latent Apple Tree Pathogen Valsa mali

Valsa mali, the causal agent of apple Valsa canker, produces cankers, resulting in the death of infected tissues and eventually the entire tree. Because of the long latent period of the disease, it is necessary to develop a rapid, sensitive, and reliable field-based assay to effectively diagnose apple Valsa canker when the plant is still symptomless. Loop-mediated isothermal amplification (LAMP) is a novel detection method that synthesizes a large amount of DNA and produces the visible byproduct (magnesium pyrophosphate) without conventional thermal cycling. Six LAMP primers were designed to target a species-specific region of the elongation factor-1α sequence, which can be completed at 61°C in 60 min. A positive result is indicated by color change after the intercalating dye SYBR Green I is added. The specificity of the LAMP was validated with DNA from 45 representative isolates of V. mali and closely related species V. malicola, V. leucostoma, and V. sordida. The sensitivity of the LAMP was determined to be 1 ng of DNA or as few as 10 spores. Because the assay does not require expensive equipment or specialized techniques, the LAMP-based diagnostic method can be applied under field conditions to more precisely and efficiently access disease pressure in apple orchards.

Latent Infection of Valsa mali in the Seeds, Seedlings and Twigs of Crabapple and Apple Trees is a Potential Inoculum Source of Valsa Canker

A real-time quantitative PCR assay using a species-specific primer pair was developed to rapidly and accurately quantify Valsa mali, the causative pathogen of apple Valsa canker (AVC), in crabapple seeds, crabapple seedlings, apple twigs and apple seeds. Surveys were conducted in different regions, and crabapple or apple seeds were collected for V. mali detection by qPCR assay. Our results showed that 12.87% to 49.01% of crabapple seeds collected from different regions were positive for V. mali. The exopleura and endopleura were the two major areas of V. mali infection in crabapple seeds. The presence of V. mali infection in crabapple seeds was also confirmed by a high-throughput sequencing approach. With the growth of crabapple seedlings, the concentration of V. mali gDNA in crabapple seedlings gradually increased until eight or more leaf blades emerged. One-year-old twigs from an apple scion nursery were infected with V. mali, and only apple seeds from infected apple trees showing evident Valsa canker symptoms carried V. mali. In conclusion, this study reports that crabapple seeds and apple seeds carried V. mali as latent inoculum sources. V. mali infected not only apple tissues but also crabapple seedlings, which are the rootstocks of apple trees. This study indicated that the inoculum sources for AVC vary. Application of a novel qPCR assay can potentially improve the accuracy of early diagnosis, and is helpful to reveal the epidemic regularity of AVC.

Multilaboratory Comparison of Quantitative PCR Assays for Detection and Quantification of Fusarium virguliforme from Soybean Roots and Soil

The ability to accurately detect and quantify Fusarium virguliforme, the cause of sudden death syndrome (SDS) in soybean, in samples such as plant root tissue and soil is extremely valuable for accurate disease diagnoses and to address research questions. Numerous quantitative real-time polymerase chain reaction (qPCR) assays have been developed for this pathogen but their sensitivity and specificity for F. virguliforme have not been compared. In this study, six qPCR assays were compared in five independent laboratories using the same set of DNA samples from fungi, plants, and soil. Multicopy gene-based assays targeting the ribosomal DNA intergenic spacer (IGS) or the mitochondrial small subunit (mtSSU) showed relatively high sensitivity (limit of detection [LOD] = 0.05 to 5 pg) compared with a single-copy gene (FvTox1)-based assay (LOD = 5 to 50 pg). Specificity varied greatly among assays, with the FvTox1 assay ranking the highest (100%) and two IGS assays being slightly less specific (95 to 96%). Another IGS assay targeting four SDS-causing fusaria showed lower specificity (70%), while the two mtSSU assays were lowest (41 and 47%). An IGS-based assay showed consistently highest sensitivity (LOD = 0.05 pg) and specificity and inclusivity above 94% and, thus, is suggested as the most useful qPCR assay for F. virguliforme diagnosis and quantification. However, specificity was also above 94% in two other assays and their selection for diagnostics and research will depend on objectives, samples, and materials used. These results will facilitate both fundamental and disease management research pertinent to SDS.

Improved Diagnoses and Quantification of Fusarium virguliforme, Causal Agent of Soybean Sudden Death Syndrome

Fusarium virguliforme (syn. F. solani f. sp. glycines) is the primary causal pathogen responsible for soybean sudden death syndrome (SDS) in North America. Diagnosis of SDS is difficult because symptoms can be inconsistent or similar to several soybean diseases and disorders. Additionally, quantification and identification of F. virguliforme by traditional dilution plating of soil or ground plant tissue is problematic due to the slow growth rate and plastic morphology of F. virguliforme. Although several real-time quantitative polymerase chain reaction (qPCR)-based assays have been developed for F. virguliforme, the performance of those assays does not allow for accurate quantification of F. virguliforme due to the reclassification of the F. solani species complex. In this study, we developed a TaqMan qPCR assay based on the ribosomal DNA (rDNA) intergenic spacer (IGS) region of F. virguliforme. Specificity of the assay was demonstrated by challenging it with genomic DNA of closely related Fusarium spp. and commonly encountered soilborne fungal pathogens. The detection limit of this assay was determined to be 100 fg of pure F. virguliforme genomic DNA or 100 macroconidia in 0.5 g of soil. An exogenous control was multiplexed with the assay to evaluate for PCR inhibition. Target locus copy number variation had minimal impact, with a range of rDNA copy number from 138 to 233 copies per haploid genome, resulting in a minor variation of up to 0.76 cycle threshold values between strains. The qPCR assay is transferable across platforms, as validated on the primary real-time PCR platform used in the Northcentral region of the National Plant Diagnostic Network. A conventional PCR assay for F. virguliforme detection was also developed and validated for use in situations where qPCR is not possible.

Contributions of Fusarium virguliforme and Heterodera glycines to the disease complex of sudden death syndrome of soybean

BACKGROUND

Sudden death syndrome (SDS) of soybean caused by Fusarium virguliforme spreads and reduces soybean yields through the North Central region of the U.S. The fungal pathogen and Heterodera glycines are difficult to manage.

METHODOLOGY/PRINCIPAL FINDINGS

The objective was to determine the contributions of H. glycines and F. virguliforme to SDS severity and effects on soybean yield. To quantify DNA of F. virguliforme in soybean roots and soil, a specific real time qPCR assay was developed. The assay was used on materials from soybean field microplots that contained in a four-factor factorial-design: (i) untreated or methyl bromide-fumigated; (ii) non-infested or infested with F. virguliforme; (iii) non-infested or infested with H. glycines; (iv) natural precipitation or additional weekly watering. In years 2 and 3 of the trial, soil and watering treatments were maintained. Roots of soybean 'Williams 82' were collected for necrosis ratings at the full seed growth stage R6. Foliar symptoms of SDS (area under the disease progress curve, AUDPC), root necrosis, and seed yield parameters were related to population densities of H. glycines and the relative DNA concentrations of F. virguliforme in the roots and soil. The specific and sensitive real time qPCR was used. Data from microplots were introduced into models of AUDPC, root necrosis, and seed yield parameters with the frequency of H. glycines and F. virguliforme, and among each other. The models confirmed the close interrelationship of H. glycines with the development of SDS, and allowed for predictions of disease risk based on populations of these two pathogens in soil.

CONCLUSIONS/SIGNIFICANCE

The results modeled the synergistic interaction between H. glycines and F. virguliforme quantitatively in previously infested field plots and explained previous findings of their interaction. Under these conditions, F. virguliforme was mildly aggressive and depended on infection of H. glycines to cause highly severe SDS.

Fungal endophyte diversity in soybean

AIM

To determine the identity and diversity of endophytes in soybean plants using culture-dependent (CD) and culture-independent (CI) methods.

METHODS AND RESULTS

Stem samples were collected from three field-grown soybean cultivars grown to a reproductive stage in Minnesota, USA. Samples were surface disinfested, and CD and CI methods were used to assess the endophytes. For the CD method, fungi were isolated and grouped based on colony morphology, and the rDNA ITS region was sequenced to identify the cultures. The most frequently isolated genera were Cladosporium (36%), Alternaria (13%), Diaporthe (9%) and Epicoccum (9%). For the CI method, DNA was extracted from the stems, and the ITS region was amplified, cloned and sequenced for identification. The most prevalent genus detected using CI method was Cladosporium (85%).

CONCLUSIONS

Soybean contains a diverse array of endophytic fungi that were identified in this study. The CD method detected greater endophyte diversity (H' = 2·12) than the CI method (H' = 0·66).

SIGNIFICANCE AND IMPACT OF THE STUDY

The results improve our understanding of the identity and diversity of endophytic fungi that likely have different kinds of interactions with soybean plants. The results suggest that CD and CI methods should be used to study endophytes in soybean and perhaps other annual crop plants.

Engineered DNA polymerase improves PCR results for plastid DNA

PREMISE OF THE STUDY

Secondary metabolites often inhibit PCR and sequencing reactions in extractions from plant material, especially from silica-dried and herbarium material. A DNA polymerase that is tolerant to inhibitors improves PCR results. •

METHODS AND RESULTS

A novel DNA amplification system, including a DNA polymerase engineered via directed evolution for improved tolerance to common plant-derived PCR inhibitors, was evaluated and PCR parameters optimized for three species. An additional 31 species were then tested with the engineered enzyme and optimized protocol, as well as with regular Taq polymerase. •

CONCLUSIONS

PCR products and high-quality sequence data were obtained for 96% of samples for rbcL and 79% for matK, compared to 29% and 21% with regular Taq polymerase.

A Nested PCR Assay for Detecting Valsa mali var. mali in Different Tissues of Apple Trees

A nested polymerase chain reaction (PCR) assay for detecting Valsa mali var. mali, the causal agent of apple tree Valsa canker, was developed. One pair of genus-specific primers was designed based on the ribosomal DNA internal transcribed spacer conservative sequence of the Valsa genus and one pair of species-specific primers was designed based on the specific sequence of V. mali var. mali. The specificity of the genus-specific and species-specific primers was evaluated against 10 V. mali var. mali isolates, 10 V. mali var. pyri isolates, 4 isolates from closely related Valsa spp., and 8 isolates from fungal species that are commonly isolated from naturally infected apple bark tissue. A distinct band of 348 bp in length was detected in all V. mali var. mali isolates but not in other tested species and the V. mali var. pyri variety. The sensitivity of this assay was evaluated by serial dilutions of DNA extracted from V. mali var. mali pure cultures and apple bark tissues with or without visible symptoms. The results showed that the assay was able to detect as little as 100 fg of DNA in mycelial samples and apple bark tissues with visible symptoms, whereas the lowest detectable concentration was 10 pg of DNA in symptomless apple bark tissues. The efficiency of the nested PCR assay was compared with that of fungal isolation assays. All symptomless and symptomatic samples from which the pathogen was successfully isolated yielded a PCR product of the expected size. The detection rate of nested PCR for symptomless samples was 64.7%, which was much higher than the detection rate of 20.6% by fungal isolation. The PCR analysis of different symptomless tissues showed that the incidence of V. mali var. mali was different in different tissues of apple trees. The average incidence of V. mali var. mali was 89% in terminal buds, 71% in internodes, and 48% in bud scale scars. Moreover, the incidence of V. mali var. mali in nonsymptomatic tissues was higher in orchards where more trees were infected. Taken together, the assay developed in this study can be used for rapid and reliable detection of V. mali var. mali in tissues of apple trees with or without symptoms and also for monitoring the presence of the pathogen at an early stage of disease development.

Evaluation of Cultivar Resistance to Soybean Cyst Nematode with a Quantitative Polymerase Chain Reaction Assay

Heterodera glycines, the soybean cyst nematode, is a major pathogen of soybean. Effective management of this pathogen is contingent on the use of resistant cultivars; thus, screening for resistant cultivars is essential. The purpose of this research was to develop a method to assess infection of soybean roots by H. glycines with real-time quantitative polymerase chain reaction (qPCR). This method will serve as a prelude to differentiation of resistance levels in soybean cultivars. A reproducible inoculation method was developed by means of a sand column to provide active second-stage juveniles (J2). Two-day-old soybean roots were infested with 0 or 1,000 J2/ml distilled water per seedling. Twenty-four hours after infestation, the roots were surface-sterilized and genomic DNA (gDNA) was extracted. For the qPCR assay, a primer pair for the single copy gene HgSNO, which codes for a protein involved in the production of vitamin B6, was selected for H. glycines gDNA amplification within soybean roots. Compatible 'Lee 74', incompatible 'Peking', and cultivars with different levels of resistance to H. glycines were infested with 0 or 1,000 J2/ml distilled water per seedling. Twenty-four hours postinfestation, infected seedlings were transplanted into pasteurized soil. Subsequently, they were harvested at 1, 7, 10, 14, and 21 days postinfestation for gDNA extraction. With the qPCR assay, the time needed to differentiate highly resistant cultivars from the rest was reduced. Quantification of H. glycines infection by traditional means (numbers of females produced in 30 days) is a time-consuming practice. This qPCR assay has the potential to replace the traditional Female Index-based screening and improve precision in determining infection levels.

Symptomatic and Asymptomatic Host Range of Fusarium virguliforme, the Causal Agent of Soybean Sudden Death Syndrome

Sudden death syndrome, caused by Fusarium virguliforme, is an important disease of soybean in the United States. Fifteen species of crops, weeds, or prairie plants were evaluated for their potential as hosts of F. virguliforme. Root and foliar symptoms and plant biomass were assessed following greenhouse inoculation studies. Root colonization of F. virguliforme was determined with isolations and with polymerase chain reaction assays. Soybean, alfalfa, pinto and navy bean, white and red clover, pea, and Canadian milk vetch developed root necrosis. Soybean, alfalfa, and red clover also developed foliar symptoms following inoculation. Sugar beet and canola did not develop symptoms but had significant reductions in biomass, suggesting that they are also hosts of F. virguliforme. Corn, wheat, ryegrass, pigweed, and lambsquarters did not develop symptoms. However, these species appeared to be asymptomatic hosts because quantities of pathogen DNA detected in inoculated roots were similar to quantities detected in inoculated soybean roots. These results suggest that the number and diversity of hosts for F. virguliforme are greater than previously reported. The likely broad host range limits the efficacy of crop rotation and indicates that crops other than soybean can be damaged by F. virguliforme and maintain or increase inoculum in soil.

A real-time PCR assay for detection and quantification of Verticillium dahliae in spinach seed

Verticillium dahliae is a soilborne fungus that causes Verticillium wilt on multiple crops in central coastal California. Although spinach crops grown in this region for fresh and processing commercial production do not display Verticillium wilt symptoms, spinach seeds produced in the United States or Europe are commonly infected with V. dahliae. Planting of the infected seed increases the soil inoculum density and may introduce exotic strains that contribute to Verticillium wilt epidemics on lettuce and other crops grown in rotation with spinach. A sensitive, rapid, and reliable method for quantification of V. dahliae in spinach seed may help identify highly infected lots, curtail their planting, and minimize the spread of exotic strains via spinach seed. In this study, a quantitative real-time polymerase chain reaction (qPCR) assay was optimized and employed for detection and quantification of V. dahliae in spinach germplasm and 15 commercial spinach seed lots. The assay used a previously reported V. dahliae-specific primer pair (VertBt-F and VertBt-R) and an analytical mill for grinding tough spinach seed for DNA extraction. The assay enabled reliable quantification of V. dahliae in spinach seed, with a sensitivity limit of ≈1 infected seed per 100 (1.3% infection in a seed lot). The quantification was highly reproducible between replicate samples of a seed lot and in different real-time PCR instruments. When tested on commercial seed lots, a pathogen DNA content corresponding to a quantification cycle value of ≥31 corresponded with a percent seed infection of ≤1.3%. The assay is useful in qualitatively assessing seed lots for V. dahliae infection levels, and the results of the assay can be helpful to guide decisions on whether to apply seed treatments.

Specific molecular detection of Phytophthora sojae using conventional and real-time PCR

Phytophthora rot, caused by Phytophthora sojae, is one of the most damaging diseases of soybean (Glycine max) worldwide. This disease can be difficult to diagnose and other Phytophthora species can infect soybean. Accurate diagnosis is important for management of Phytophthora rot. The objective of this study was to evaluate polymerase chain reaction (PCR) methods for rapid and specific detection of P. sojae and diagnosis of Phytophthora rot. PCR assays using two sets of primers (PS and PSOJ) that target the ITS region were evaluated for specificity and sensitivity to P. sojae. Genomic DNA extracted from 11 species of Phytophthora and 19 other species of fungal and oomycete pathogens were used to test the specificity of each primer set. The previously published PS primers amplified DNA from P. sojae and from four other Phytophthora species using conventional PCR, indicating they are not specific for P. sojae. The new PSOJ primers amplified DNA only from P. sojae using conventional and real-time PCR and not from Phytophthora sansomeana, which has been found in soybean production areas, indicating that they are specific for P. sojae. The PSOJ primers were also used to detect P. sojae in diseased soybean tissue and infested soil. The PCR assays based on the PSOJ primers are specific, rapid, and sensitive tools for the detection of P. sojae.

Exogenous Controls Increase Negative Call Veracity in Multiplexed, Quantitative PCR Assays for Phakopsora pachyrhizi

Quantitative polymerase chain reaction (Q-PCR) utilizing specific primer sequences and a fluorogenic, 5'-exonuclease linear hydrolysis probe is well established as a detection and identification method for Phakopsora pachyrhizi and P. meibomiae, two rust pathogens of soybean. Because of the extreme sensitivity of Q-PCR, the DNA of single urediniospores of these fungi can be detected from total DNA extracts of environmental samples. However, some DNA preparations unpredictably contain PCR inhibitors that increase the frequency of false negatives indistinguishable from true negatives. Three synthetic DNA molecules of arbitrary sequence were constructed as multiplexed internal controls (ICs) to cull false-negative results by producing a positive signal to validate the PCR process within each individual reaction. The first two, PpaIC and PmeIC, are a single-stranded oligonucleotide flanked by sequences complementary to the primers of either the P. pachyrhizi or P. meibomiae primary assay but hybridizing to a unique fluorogenic probe; the third contains unique primer- and probe-binding sequences, and was prepared as a cloned DNA fragment in a linearized plasmid. These ICs neither qualitatively nor quantitatively affected their primary assays. PpaIC and PmeIC were shown to successfully identify false-negative reactions resulting from endogenous or exogenous inhibitors, and can be readily adapted to function in a variety of diagnostic Q-PCR assays; the plasmid was found to successfully validate true negatives in similar Q-PCR assays for other soybean pathogens, as well as to function as a tracer molecule during DNA extraction and recovery.

DNA-Dependent Detection of the Grapevine Fungal Endophytes Aureobasidium pullulans and Epicoccum nigrum

Aureobasidium pullulans and Epicoccum nigrum are frequently reported as endophytes of various crops, including grapevine (Vitis vinifera). Because of their potential role as biological control agents against grapevine pathogens, we examined the occurrence of A. pullulans and E. nigrum in two grapevine varieties (Merlot and Prosecco) in Italian vineyards where spontaneous recovery from phytoplasma disease is recurrent. Species-specific primers for A. pullulans and two genetically distinct strains of E. nigrum were designed in variable regions of ITS1 and ITS2. Primer specificity was confirmed by polymerase chain reaction using purified DNA from other fungal endophytes that are usually encountered during isolation attempts from grapevine tissues and from several other strains of A. pullulans and E. nigrum isolated from other sources. In order to determine the occurrence of the two endophytes in grapevine plants, DNA was extracted from shoots of 44 grapevines collected in six vineyards from different localities of northeast Italy. Both endophytes were detected and their identity was confirmed by restriction fragment length polymorphism (RFLP) patterns obtained from reference strains. RFLP analyses confirmed the presence of two E. nigrum strains belonging to different RFLP groups in grapevine. The molecular methods described allowed a sensitive, specific, and reliable identification of the two endophytes in grapevine.

Characterizing Reaction of Soybean to Phialophora gregata Using Pathogen Population Density and DNA Quantity in Stems

Evaluation of soybean germplasm for resistance to brown stem rot (BSR) is typically based on symptom severity. However, this approach may not reflect the level of colonization of soybean by the casual agent, Phialophora gregata. A potentially more accurate method to characterize resistance to BSR is to estimate pathogen quantity. The primary goal of this study was to evaluate soybean accessions for resistance to BSR based on the quantity of pathogen in stems. Plants were collected from experiments in field and controlled environments, and CFU and pathogen DNA quantity were determined using dilution plating techniques and real-time quantitative PCR (qPCR), respectively. In the field, the BSR-susceptible cultivars Corsoy 79 and Century 84 expressed greater than 73% foliar and stem symptom severity and had the highest pathogen population density, with a range from log₁₀ 4.3 to 4.7 CFU per gram of stem tissue. The resistant cultivar Bell expressed less than 10% foliar symptom severity, but had a pathogen population density that was not statistically different from the susceptible accessions. CFU measured in Dwight and L84-5873 were consistently lower than CFU in susceptible accessions and several resistant accessions. The amount of pathogen DNA differed among accessions in controlled environments. For example, Corsoy 79 and Century 84 had the highest pathogen DNA quantity, ranging from log₁₀ 6.19 to 6.65 copies, whereas the resistant cultivars Bell, Dwight, and L84-5873 had significantly lower DNA quantities, ranging from log₁₀ 2.04 to 2.91 copies. PI 437833 and IA2008R expressed low symptom severity but contained high DNA quantities. Pella 86, a highly symptomatic cultivar, had fewer CFU and lower DNA quantity in comparison to two other highly symptomatic cultivars and some cultivars with low symptom severity. These results suggest that some accessions express resistance to both pathogen colonization and symptom development, while others are resistant to symptom development but not to pathogen colonization. Results also indicate that resistant and susceptible accessions can be distinguished based on DNA quantity in controlled environments. In the field, differences between the pathogen population in resistant and susceptible cultivars were less distinct, possibly due to when plants were assayed.

Molecular detection of Puccinia horiana in Chrysanthemum x morifolium through conventional and real-time PCR

Puccinia horiana Henn. is a quarantine organism and one of the most important fungal pathogens of Chrysanthemum x morifolium cultivars grown for cut flower or potted plant production (florist's chrysanthemum) in several regions of the world. Highly specific primer pairs were identified for conventional, nested, and real-time PCR detection of P. horiana based on the specific and sensitive PCR amplification of selected regions in the internal transcribed spacers (ITS1 and ITS2) of the nuclear ribosomal DNA (rDNA). Using these different PCR versions, 10 pg, 10 fg, and 5 fg genomic DNA could be detected, respectively. When using cloned target DNA as template, the detection limits were 5000, 50, and 5 target copies, respectively. These detection limits were not affected by a background of chrysanthemum plant DNA. The DNA extraction method was optimized to maximize the recoverability of the pathogen from infected plant tissue. A CTAB extraction protocol or a selection of commercial DNA extraction methods allowed the use of 10 ng total (plant+pathogen) DNA without interference of PCR inhibitors. Due to the specificity of the primers, SYBR Green I technology enabled reliable real time PCR signal detection. However, an efficient TaqMan probe is available. The lowest proportion of infected plant material that could still be detected when mixed with healthy plant material was 0.001%. The real-time PCR assay could detect as few as eight pure P. horiana basidiospores, demonstrating the potential of the technique for aerial detection of the pathogen. The amount of P. horiana DNA in plant tissue was determined at various time points after basidiospore inoculation. Using the real-time PCR protocol, it was possible to detect the pathogen immediately after the inoculation period, even though the accumulation of pathogen DNA was most pronounced near the end of the latent period. The detection system proved to be accurate and sensitive and could help not only in pathogen diagnosis but also in pathogen monitoring and disease forecasting systems.

Novel approaches to mitigate primer interaction and eliminate inhibitors in multiplex PCR, demonstrated using an assay for detection of three strawberry viruses

Multiplex PCR is an important technique for detecting a variety of pathogens simultaneously in a single assay. Previous research has focused on optimising the factors affecting reliable multiplex PCR, including primer design, PCR components and conditions, and inhibitors in samples. In this study, the interaction of primers to form complex secondary structures including visible dimers and invisible "primer clusters", a novel form of primer secondary structure found during this research, were shown to be the most important factors affecting successful multiplex PCR. Approaches to mitigate primer interaction and eliminate inhibitors were tested, including: reduction of primer concentrations especially those with preferential amplification; decrease of PCR extension temperature; increase of extension time and PCR cycles; and addition of bovine serum albumin. Based on these approaches, a multiplex RT-PCR with sensitivity comparable to the simplex PCR for individual viruses was developed for the detection of Raspberry ringspot virus, Strawberry latent ringspot virus and Tomato bushy stunt virus. A plant internal amplification control was also included. These approaches may be useful as a guideline for the development of multiplex PCR protocols for the detection of other pathogens or organisms associated with plants, humans, animals and the environment.

Quantification of Phytophthora capsici Oospores in Soil by Sieving-Centrifugation and Real-Time Polymerase Chain Reaction

A procedure was developed to quantify Phytophthora capsici oospores in soil by combining a sieving-centrifugation method and a real-time quantitative polymerase chain reaction (QPCR) assay. Five soil samples representing three different soil textures were infested with oospores of P. capsici to produce 10¹, 10², 10³, 10⁴, or 10⁵ spores per 10 g of air-dried soil. Each 10-g sample of infested soil was suspended in 400 ml of water and then passed through 106-, 63-, and 38-μm metal sieves. The filtrate was then passed through a 20-μm mesh filter. Materials caught on the filter were washed with water into two 50-ml centrifuge tubes and spun for 4 min (900 × g). The pellet was suspended in 30 ml of 1.6 M sucrose solution and centrifuged for 45 s (190 × g). The supernatant was passed through the 20-μm mesh filter. The sucrose extraction process of oospores was repeated five times to maximize oospore extraction. Materials caught on the 20-μm mesh filter were washed with water into a 50-ml tube and spun for 4 min (900 × g). The pellet was suspended in 1 ml of water, and the number of oospores was determined with a haemocytometer. The relationship between number of oospores recovered from the soil and number of oospores incorporated into the soil was Ŷ = -0.95 + 1.31X - 0.03X² (R² = 0.98), in which Ŷ = log₁₀ of number of oospores recovered from the soil and X = log₁₀ of number of oospores incorporated into the soil. The oospores were germinated after treatment with 0.1% KMnO₄ solution for 10 min to induce germination. On the basis of the detection of ribosomal DNA, a QPCR method for P. capsici oospores was developed. PCR inhibitors were eliminated by extracting oospores from the soil by sieving-centrifugation. DNA was extracted and quantified from P. capsici oospores with suspensions of 10¹, 10^1.5, 10², 10^2.5, 10³, 10^3.5, 10⁴, 10^4.5, and 10⁵ oospores per ml of water. The relationship between the DNA quantities and number of P. capsici oospores was Ŷ = -3.57 - 0.54X + 0.30X² (R² = 0.93), in which Ŷ = log₁₀ (nanogram of P. capsici DNA) and X = log₁₀ (number of oospores). The relationship between the quantity of DNA of P. capsici oospores recovered from the soil and the number of oospores incorporated into the soil was determined by Ŷ = -3.53 - 0.73X + 0.32X² (R² = 0.955, P < 0.05), in which Ŷ = log₁₀ (DNA quantity of P. capsici oospores recovered from the soil) and X = log₁₀ (number of P. capsici oospores incorporated into the soil). Utilizing the sieving-centrifugation and QPCR methods, oospores of P. capsici were quantified in soil samples collected from commercial fields.

Species-Specific Primers for Eutypella parasitica, the Causal Agent of Eutypella Canker of Maple

Eutypella parasitica was recently reported in Europe for the first time, and this study reports the molecular evaluation of the internal transcribed spacer (ITS)1/5.8S/ITS2 regions of 68 isolates of the fungus obtained in pure culture with polymerase chain reaction restriction fragment length polymorphism (RFLP). The RFLP patterns of all isolates proved identical and the restriction profiles served to differentiate E. parasitica from Eutypa lata, another pathogenic member of the family Diatrypaceae. Low intraspecific variability was detected in the sequenced ITS1/5.8S/ITS2 regions of eight Eutypella parasitica isolates originating from different hosts and geographical locations. Based on this ITS region, EpR/F primers specific to E. parasitica were constructed and tested with a wide range of fungal isolates. The EpR/F primer pair successfully amplified the expected fragment size of 341 bp from isolates of E. parasitica and also directly from infected maple wood shavings. The RFLP patterns and species-specific primers represent a step toward routine, large-scale, and rapid molecular diagnostics and identification of E. parasitica.

Detection and Quantification of Phialophora gregata in Soybean and Soil Samples with a Quantitative, Real-Time PCR Assay

Brown stem rot of soybean, caused by the soilborne fungus Phialophora gregata, is a common and widespread disease of soybean (Glycine max) in the midwestern United States. This pathogen is challenging to study due to a long latent period and slow growth. A TaqMan probe-based quantitative, real-time polymerase chain reaction (qPCR) assay was developed for sensitive and specific detection and quantification of genotypes A and B of P. gregata in plant and soil samples. It is sensitive with detection limits of 50 fg of pure genomic DNA, 100 copies of the target DNA sequence, and approximately 400 conidia. The qPCR assay is approximately 1,000 times more sensitive in detecting DNA and conidia of P. gregata, and is more rapid and less sensitive to PCR inhibitors from soybean stems than a standard PCR (sPCR) assay. Using this single-step qPCR assay, low levels of infection were detected in soybean stems at least 1 to 2 weeks prior to symptom development and before P. gregata was detected with sPCR. This assay also was used to detect the pathogen in field-grown plants and in naturally infested field soils. This new qPCR assay is a powerful tool for rapid, specific, and sensitive detection, diagnosis, and quantification of P. gregata in plants and soil, and for advancing studies of the ecology of P. gregata and its interactions with host plants.

Interactions Between the Soybean Cyst Nematode and Fusarium solani f. sp. glycines Based on Greenhouse Factorial Experiments

ABSTRACT The soybean cyst nematode, Heterodera glycines, and the fungus that causes sudden death syndrome (SDS) of soybean, Fusarium solani f. sp. glycines, frequently co-infest soybean (Glycine max) fields. The interactions between H. glycines and F. solani f. sp. glycines were investigated in factorial greenhouse experiments with different inoculum levels of both organisms on a soybean cultivar susceptible to both pathogens. Measured responses included root and shoot dry weights, H. glycines reproduction, area under the SDS disease progress curve, and fungal colonization of roots. Both H. glycines and F. solani f. sp. glycines reduced the growth of soybeans. Reproduction of H. glycines was suppressed by high inoculum levels but not by low levels of F. solani f. sp. glycines. The infection of soybean roots by H. glycines did not affect root colonization by the fungus, as determined by real-time polymerase chain reaction. Although both pathogens reduced the growth of soybeans, H. glycines did not increase SDS foliar symptoms, and statistical interactions between the two pathogens were seldom significant.

Population Dynamics of Phialophora gregata in Stem Residue of a Resistant and a Susceptible Soybean Cultivar

Previous studies on the saprophytic survival of Phialophora gregata were conducted with soybean residue derived from a susceptible cultivar and did not address genotypes of P. gregata. This current study monitored the saprophytic population density of P. gregata in stem residue derived from a susceptible and a resistant soybean cultivar placed in the field. A second phase of the study followed the frequencies of genotypes A and B of P. gregata in stem residue derived from a susceptible cultivar. The population density of P. gregata declined 10-fold in stem residue from the initiation of sampling to the end of this 16-month study, regardless of cultivar or whether residue was positioned on the soil surface or buried. The population density of P. gregata was greater in buried residue of the resistant cultivar compared with the susceptible cultivar after 12 to 14 months, but equalized after 16 months. The population density of P. gregata was similar in residue derived from the susceptible and resistant cultivars if positioned on the soil surface. Genotype B was detected more frequently than genotype A of P. gregata at each sampling date regardless of residue placement.