Characterization and PCR-based detection of benzimidazole-resistant isolates of Monilinia laxa in California

Monilinia laxa is a pathogen of brown rot of stone fruit and almond in California, causing blossom blights and fruit rots. In this study, low-level resistance to the benzimidazole fungicides benomyl and thiophanate-methyl was detected in field isolates of M laxa collected from stone fruits and almonds in California. Low-resistant (LR) isolates grew in potato dextrose agar (PDA) plates amended with benomyl and thiophanate-methyl at 1 and 5 microg ml(-1), respectively, but not in plates amended with benomyl at 5 microg ml(-1) or thiophanate-methyl at 50 microg ml(-1). The benzimidazole LR isolates were characterized by temperature sensitivity and the DNA sequence of the beta-tubulin gene. The LR isolates showed high-temperature sensitivity, being sensitive to 1 microg ml(-1) of benomyl at 28 degrees C but resistant at 8-24 degrees C. Analysis of the DNA sequence of the beta-tubulin gene showed that the LR isolates had a point mutation at the amino-acid position 240, causing substitution of leucine by phenylalanine. Based on the point mutation, a pair of allele-specific PCR primers was developed for rapid detection of LR isolates of M laxa. In addition, a pair of PCR primers specific to M laxa was developed on the basis of the differences in the DNA sequence of the intron 6 of beta-tubulin gene from M laxa, M fructicola and other fungal species. The primer pair amplified the expected 376-bp DNA fragment from all M laxa isolates tested, but not from 14 other fungal species isolated from stone fruit and almond crops. The restriction endonuclease BsmA I recognized the sequence GTCTCC in the PCR products from sensitive (S) isolates only, but not the GTTTCC sequence in the PCR products from LR isolates. The endonuclease digested the 376-bp PCR products from S isolates to produce two bands (111 and 265 bp) on agarose gels. Thus, both allele-specific PCR and the PCR-restriction fragment length polymorphism (PCR-RFLP) methods could be useful for rapidly detecting benzimidazole-resistant isolates of M laxa from stone fruit and almond crops in California.     

Population structure of rice blast isolates resistant to scytalone dehydratase inhibitors in Mie Prefecture and implications for their origin

In Mie Prefecture in Japan, rice blast isolates resistant to melanin biosynthesis inhibitors targeting scytalone dehydratase (SDH) were first observed in 2005. To analyze the distribution of the resistant isolates, 527 isolates were collected from wide areas in this prefecture during 2006 and 2007. Almost half of the isolates collected (233 of 527 isolates) carried a point mutation in the SDH gene conferring the resistant phenotype. To compare population structures of resistant and sensitive isolates, we analyzed the isolates with repetitive-element-based PCR DNA fingerprinting using a single primer complementary to a sequence in the terminal inverted repeat of transposable element Pot2. A majority of the resistant isolates were classified into a single DNA fingerprint haplotype, Mie1. Despite its prevalence in the resistant isolates, Mie1 was not found in the sensitive isolates. Furthermore, in a dendrogram constructed from the DNA fingerprint data, Mie1 and six other haplotypes formed a cluster composed of resistant isolates alone. These results suggest that the resistant isolates that belonged to the Mie1 haplotype had migrated from regions outside Mie Prefecture and selectively propagated in a short period in this prefecture.     

Comparison of scytalone dehydratase activities between scytalone dehydratase inhibitor-sensitive and inhibitor-resistant Magnaporthe oryzae isolates

Journal of Plant Diseases and Protection - Magnaporthe oryzae is the causal agent of blast disease of cereals such as rice. Recently, fungal isolates resistant to the melanin biosynthesis...     

Quantification of allele E198A in beta-tubulin conferring benzimidazole resistance in Monilinia fructicola using real-time PCR

BACKGROUND: Thiophanate-methyl, a member of the benzimidazole class of fungicides, is used in California to control brown rot of stone fruit caused by Monilinia fructicola (G. Wint.) Honey. The goal of this study was to develop a real-time polymerase chain reaction (PCR) assay as an efficient method to quantify the E198A allele of beta-tubulin that confers benzimidazole resistance. RESULTS: Using the real-time PCR assay, the frequency of allele E198A (FEA) in a population was determined from the quantities of DNA amplified with the E198A allele-specific primer pair HRF/HRR and the M. fructicola-specific primer pair MfF6/MfR6. The average proportions of highly resistant isolates determined with the conventional fungicide sensitivity method were within the range of average FEA values determined with the real-time PCR assay. We also determined the FEAs of M. fructicola populations sampled from 21 stone fruit orchards in California. Only one orchard showed a high FEA over 0.20, seven orchards had values between 0.01 and 0.1, and 13 orchards had values less than 0.01. CONCLUSION: The real-time PCR assay developed in this study provides a potentially useful tool to efficiently quantify benzimidazole resistance for large M. fructicola populations.     

Phenotypic and genetic characterization of Pseudomonas syringae strains associated with the recent citrus bacterial blast and bacterial black pit epidemics in Tunisia

In the spring of 2012, symptoms of a disease resembling citrus blast and citrus black pit were observed in some orchards in Tunisia. The epidemic spread rapidly in the following years. Twenty‐four commercial citrus orchards from four Tunisian regions showing characteristic symptoms of bacterial diseases were surveyed during a 3‐year study. Eighty‐eight Pseudomonas‐like bacterial isolates were successfully obtained from the northeast and west of Tunisia. No isolates were recovered from the central region. Overall, 46 isolates were identified as Pseudomonas syringae pv. syringae and most of them showed similar phenotypic and genetic profiles. The virulence of three selected isolates differed from one plant cultivar to another as well as from the type of plant organ used for the inoculation. In a bioassay test, all isolates produced syringomycin, which was confirmed by molecular detection based on the syrB and syrD genes. Only EC122 possessed syrD but not syrB. DNA fingerprints, based on repetitive sequence‐based polymerase chain reaction (rep‐PCR) and PCR melting profile (PCR MP), were used to determine the potential genetic diversity among strains. Clustering of PCR MP fingerprinting data matched with rep‐PCR fingerprinting data. The generated distribution tree showed that Tunisian isolates were closely related to the citrus reference strain LMG5496. In contrast, EC112, isolated from citrus, and the almond isolate EC122 were distantly related to the type strain LMG1247^T isolated from lilac. Such studies have not been reported until now for P. syringae from citrus.     

Quantification of potato common scab pathogens in soil by quantitative competitive PCR with fluorescent quenching‐based probes

Common scab of potato tubers caused by pathogenic Streptomyces spp. is a cause of serious economic loss worldwide. For the rapid and accurate quantification of pathogenic Streptomyces spp. residing in soil, a new competitive real‐time PCR method using fluorescent quenching‐based probes (quantitative competitive quenching probe PCR: QCQP‐PCR) was developed. The virulence gene of pathogenic Streptomyces spp., nec1, was selected as the target for QCQP‐PCR. A specific primer set to amplify the nec1 gene, and a fluorescently labelled probe that specifically hybridizes with the nec1 amplicon were designed. For QCQP‐PCR, an internal standard DNA (IS DNA) that is identical to the nec1 amplicon but has a 4‐base mismatch in the probe‐hybridizing region, and a fluorescently labelled probe IS, which specifically hybridizes with IS DNA at the mutagenized region, were PCR‐synthesized. The target nec1 gene was co‐amplified with the known copy number of IS DNA by PCR using the same primer set in the presence of the specific probes. The PCR products were monitored in real‐time by measuring the fluorescence intensity (quenching) of each probe. The initial amount of the nec1 gene was quantified based on the ratio of the PCR products of the same PCR cycle. The results revealed that QCQP‐PCR could be used to precisely quantify the nec1 gene, even in the presence of PCR inhibitors in the soil samples examined. The lower limit of quantification was 20 copies per tube, which corresponded to 1500 copies per g dry soil. The quantification achieved by this method was completed within 5 h, i.e. the duration of the entire analysis. These results demonstrate the usefulness of the present method for monitoring pathogenic Streptomyces species in soil.     

PCR assays for the sugarcane rust pathogens Puccinia kuehnii and P. melanocephala and detection of a SNP associated with geographical distribution in P. kuehnii

Puccinia kuehnii and P. melanocephala cause orange and brown rust of sugarcane, respectively. Puccinia kuehnii has been confirmed in Asia, Australia and recently, the Caribbean basin, whereas P. melanocephala is distributed among the majority of sugarcane growing regions. Differentiating these two economically significant pathogens visually is problematic and limited to material exhibiting mature disease symptoms or spores. Partial ITS1, ITS2 and complete 5·8S sequences were generated from P. kuehnii and P. melanocephala isolates from around the world. PCR primers and dual labelled hydrolysis probes were designed for each pathogen for use in real‐time PCR and optimized using locked nucleic acids (LNA). The primers amplified DNA from their target pathogens and not from other species of Puccinia or fungal species isolated from sugarcane leaves. Optimized real‐time PCR conditions allowed the detection of 0·19 pg of P. kuehnii or P. melanocephala genomic DNA and differentiated the pathogens on sugarcane leaves prior to observing typical symptoms in the field. Primer‐introduced restriction analysis‐PCR (PIRA‐PCR) was used to detect a single nucleotide polymorphism (Pk ITS1 183A>G) in ITS1 of P. kuehnii. Allele 183A was observed in all samples, whereas 183G was detected in 52% of samples from Asia and Australia yet absent from all Caribbean basin samples. Long distance spore dispersal, dispersal through an intermediate location or improper movement of contaminated material could explain the introduction of P. kuehnii to the Western hemisphere. However, the current proliferation of the pathogen in the Americas is limited to isolates which contain only the 183A allele.     

Application of cycleave PCR to the detection of a point mutation (F167Y) in the β2‐tubulin gene of Fusarium graminearum

BACKGROUND: Resistance of Fusarium graminearum to the benzimidazole fungicide carbendazim is caused by point mutations in the β₂‐tubulin gene (FGSG_06611.3). The point mutation at codon 167 (TTT → TAT, F167Y) occurs in more than 90% of field isolates in China. It is important to find a suitable method for rapid detection and quantification of this point mutation in the F. graminearum populations. RESULTS: A pair of primers, Codon167F/Codon167R, were designed to amplify a fragment containing the mutation site, and two cycling probes labelled with different fluorescent reporters were used to detect whether the mutation was present. A cycleave real‐time PCR method was developed for rapid determination of the frequency of this point mutation in 282 F. graminearum perithecia collected from different fields in Jiangsu Province, China. The mutation frequency in ascospores from the perithecia to carbendazim by a spore germination assay was 6.0%, while the frequency of the point mutation at codon 167 by the cycleave real‐time PCR assay was 3.9%. CONCLUSION: The cycleave real‐time PCR method is suitable for accurate detection of the codon 167 point mutation. The frequency of this mutation in the β₂‐tubulin gene represents the resistance frequency in F. graminearum populations to carbendazim. Copyright © 2011 Society of Chemical Industry     

Molecular characterization and inheritance of resistance to ACCase-inhibiting herbicides in Lolium rigidum

The molecular basis and mode of inheritance of resistance to ACCase-inhibiting herbicides were investigated in a biotype of Lolium rigidum Gaud that has been discovered in Israel. Dose-response experiments at the whole-plant level have revealed that the resistant biotype was more resistant (6.3- to 40-fold) than the susceptible wild-type to ACCase-inhibiting herbicides. A 276-bp genomic DNA encoding the carboxyltransferase domain within the chloroplastic ACCase from resistant and susceptible biotypes were amplified by PCR and analyzed. Sequence comparison revealed that a single isoleucine-to-leucine substitution differentiated ACCases from susceptible and resistant biotypes (corresponds to residue 1769 of wheat ACCase, Acc No AF029895). A PCR amplification of specific alleles (PASA) method was developed to detect the allele composition leading to isoleucine-leucine mutation. ACCase extracted from homozygote resistant, heterozygote and homozygote susceptible plants showed IC50 values of 25.8, 5.6 and 0.6 microM, respectively, suggesting that alteration in the ACCase is governed by a co-dominant gene. The inheritance studies confirmed that the resistance of L rigidum to ACCase-inhibiting herbicides is governed by a single, nuclear and co-dominant gene.     

Seasonal dynamics and virus translocation of Grapevine leafroll‐associated virus 3 in grapevine cultivars

Grapevine leafroll‐associated virus 3 (GLRaV‐3) is associated with grapevine leafroll disease, one of the most economically important viral diseases of grapevines. This disease impacts on both vine health and grape quality; reduction in yield, brix and wine colour are among its detrimental effects. Many methods, including serological and molecular procedures, have been developed for the detection of GLRaV‐3; however, there is no PCR‐based assay available to quantify virus populations within plant tissues. A real‐time RT‐PCR assay with TaqMan probe was developed for specific and reliable quantitative detection of GLRaV‐3 in infected tissues. The designed primers and probes target the conserved sequence in the RNA‐dependent RNA polymerase (RdRp) domain of the viral genome to prevent amplification of most subgenomic and defective RNAs. This protocol was used to examine the seasonal dynamics and translocation of GLRaV‐3 in field‐grown grapevines. The results showed that the virus spread quickly from trunks to new growing shoots and leaves early in the growing season, and most samples still harboured detectable virus during late summer and autumn. The seasonal progress of one GLRaV‐3 isolate was compared in four grapevine cultivars (Chardonnay, Cabernet Sauvignon, Italia and Thompson Seedless). Within cultivars there was little variability in the distribution and translocation of GLRaV‐3, except for in Thompson Seedless. This quantitative detection assay will be a valuable tool for GLRaV‐3 diagnosis, disease monitoring and population ecology studies.     

PCR-based detection of resistance to acetyl-CoA carboxylase-inhibiting herbicides in black-grass (Alopecurus myosuroides Huds) and ryegrass (Lolium rigidum gaud)

A simple method based upon allele-specific PCR was developed to detect an isoleucine-leucine substitution in the gene encoding chloroplastic acetyl-coenzyme A carboxylase (ACCase) in two gramineous weeds: Lolium rigidum Gaud and Alopecurus myosuroides Huds. Analysis of 1800 A myosuroides and 750 L rigidum seedlings showed that the presence of ACCase leucine allele(s) conferred cross-resistance to the cyclohexanedione herbicide cycloxydim and to the aryloxyphenoxypropionate herbicides fenoxaprop-P-ethyl and diclofop-methyl. Seedlings containing ACCase leucine allele(s) could be either sensitive or resistant to the aryloxyphenoxypropionate herbicides haloxyfop-P-methyl and clodinafop-propargyl. Successful detection of resistant plants in a field population of A myosuroides was achieved using this PCR assay. Using it with basic molecular biology laboratory equipment, the presence of resistant leucine ACCase allele(s) can be detected within one working day.     

Clonal populations of Clavibacter michiganensis subsp. michiganensis are responsible for the outbreaks of bacterial canker in greenhouse tomatoes in Italy

Clavibacter michiganensis subsp. michiganensis (Cmm) strains, collected in greenhouses from 17 farms during tomato bacterial canker outbreaks occurring between 2005 and 2008 in Sicily, were analysed by a multiphasic approach. Population studies were conducted to investigate the possible sources of inocula. Cmm strains were characterized by PCR assays targeting virulence genes, fingerprinting techniques, metabolic profiles and virulence. These strains were comparatively analysed with Cmm strains isolated in other parts of Italy over a period of 15 years. Chromosomal genes encoding virulence determinants tomA, ppaA, chpC, and the plasmid‐encoded genes pat‐1 and celA were detected by PCR in all tested strains, except for four Sicilian Cmm strains where the pat‐1 gene was not amplified. Using BOX‐PCR, Cmm strains were differentiated into 13 haplotypes and clonal populations were identified. Cmm strains isolated from different farms in 2008 showed the same BOX‐PCR haplotype. A distinct BOX‐PCR haplotype was obtained from atypical Cmm strains lacking pat‐1 and isolated in 2006/7 from three farms. Cmm strains with two different haplotypes were detected in one farm, whereas the other farms contained strains with only a single haplotype. A new fAFLP protocol based on the amplification of ApaI/MseI fragments was developed and was able to differentiate C. michiganensis subspecies. Different populations were delineated for the multiple outbreaks occurring in Sicily, whereas similar populations were recorded in other Italian regions over a period of 12 years. The results are consistent with previous studies that demonstrate that Cmm outbreaks are associated with propagation material.     

Grapevine virus A variants of group II associated with Shiraz disease in South Africa are present in plants affected by Australian Shiraz disease,and have also been detected in the USA

Primers were designed for RT‐nested PCR amplification of the highly variable 293‐nt fragment from the 5′ terminal part of the Grapevine virus A (GVA) replicase gene, specific to South African variants of molecular groups I and II. This new technique, along with RT‐PCR for simultaneous amplification of variants of groups I, II and III, as well as cloning of amplicons, single‐strand conformation polymorphism (SSCP) analysis of clones and sequencing, were used to investigate the populations of variants infecting 16 local Shiraz grapevines with different Shiraz disease (SD) status. The techniques were also used to study variants in GVA‐infected grapevines from Australia and the USA. The Australian grapevines included seven plants of cvs Shiraz and Merlot affected by Australian Shiraz disease (AuSD), and one plant of cv. Crimson Seedless with unknown AuSD status. Grapevines from the USA included plants of cvs Chardonnay, Thompson Seedless and an unknown cultivar. The results confirmed the association of certain genetic variants of group II with SD and showed the common presence of these variants in AuSD‐affected grapevines from Australia. Interestingly, a variant of this group was also detected in grapevine cv. Chardonnay from the USA, although the disease has not yet been reported from that country. The study also supports an earlier observation that members of group II, closely related to variant GTR1‐2, are not associated with the disease. The variants were found only in SD‐free grapevines. Results show that variants of the most divergent group III, which are common in South Africa, are also present in Australia and the USA. These variants are not associated with SD, but frequently occur in mixed infections with members of group II in plants affected by this disease in South Africa.     

High genetic and virulence diversity detected in Neofusicoccum luteum and N. australe populations in New Zealand vineyards

Genotypic and virulence diversity of Neofusicoccum luteum and N. australe isolates recovered from grapevines displaying symptoms of dieback and decline in New Zealand were investigated. The universally primed PCR (UP‐PCR) method was used to investigate the genetic diversity of 40 isolates of N. luteum and 33 isolates of N. australe. Five UP‐PCR primers produced a total of 51 loci from N. luteum and 57 from N. australe with a greater number of polymorphic loci produced in N. australe (86%) compared with N. luteum (69%). Analysis of UP‐PCR data showed both species found in New Zealand vineyards were genetically diverse at both the inter‐ and intra‐vineyard levels with only a single pair of clonal isolates in N. luteum. Cluster analysis of UP‐PCR data produced four genetic groups in N. luteum and 10 in N. australe (P < 0.05). For both species, there was no relationship between the genetic groups and the origin of isolates. The mean genetic diversity (H) of N. luteum was less than for N. australe, being 0.1791 and 0.2417, respectively. Pathogenicity assays of both species using isolates from either the same or different genetic groups inoculated onto either green shoots or grapevine trunks, showed virulence diversity within the population; however, no correlation was identified between genetic groups and virulence.     

Spread and interaction of Pepino mosaic virus (PepMV) and Pythium aphanidermatum in a closed nutrient solution recirculation system: effects on tomato growth and yield

Pepino mosaic virus (PepMV) was shown to be efficiently transmitted between tomato plants grown in a closed recirculating hydroponic system. PepMV was detected in all plant parts after transmission via contaminated nutrient solution using ELISA, immunocapture RT‐PCR, RT‐PCR, electron microscopy, and by inoculation to indicator plants. Detection of PepMV in nutrient solution was only possible after concentration by ultracentrifugation followed by RT‐PCR. Roots tested positive for PepMV 1–3 weeks after inoculation, and subsequently a rapid spread from the roots into the young leaves and developing fruits was found within 1 week. PepMV was only occasionally detected in the older leaves. None of the infected plants showed any symptoms on fruits, leaves or other organs. Pre‐infection of roots of tomato cv. Hildares with Pythium aphanidermatum significantly delayed PepMV root infections. When mechanically inoculated with PepMV at the 2–4 leaf stage, yield loss was observed in all plants. However, only plants of cv. Castle Rock recorded significant yield losses when infected via contaminated nutrient solution. Yield losses induced by infection with PepMV and/or P. aphanidermatum ranged from 0·4 up to 40% depending on experimental conditions.     

Use of next‐generation sequencing for the identification and characterization of Maize chlorotic mottle virus and Sugarcane mosaic virus causing maize lethal necrosis in Kenya

The diagnosis of novel unidentified viral plant diseases can be problematic, as the conventional methods such as real‐time PCR or ELISA may be too specific to a particular species or even strain of a virus, whilst alternatives such as electron microscopy (EM) or sap inoculation of indicator species do not usually give species level diagnosis. Next‐generation sequencing (NGS) offers an alternative solution where sequence is generated in a non‐specific fashion and identification is based on similarity searching against GenBank. The conventional and NGS techniques were applied to a damaging and apparently new disease of maize, which was first identified in Kenya in 2011. ELISA and TEM provided negative results, whilst inoculation of other cereal species identified the presence of an unidentified sap transmissible virus. RNA was purified from material showing symptoms and sequenced using a Roche 454 GS‐FLX+. Database searching of the resulting sequence identified the presence of Maize chlorotic mottle virus and Sugarcane mosaic virus, a combination previously reported to cause maize lethal necrosis disease. Over 90% of both viral genome sequences were obtained, allowing strain characterization and the development of specific real‐time PCR assays which were used to confirm the presence of the virus in material with symptoms from six different fields in two different regions of Kenya. The availability of these assays should aid the assessment of the disease and may be used for routine diagnosis. The work shows that next‐generation sequencing is a valuable investigational technique for rapidly identifying potential disease‐causing agents such as viruses.     

Detection of plant pathogens using real‐time PCR: how reliable are late Ct values?

Effective detection of pathogens from complex substrates is a challenging task. Molecular approaches such as real‐time PCR can detect pathogens present even in low quantities. However, weak real‐time PCR signals, as represented by high cycle threshold (C_t) values, may be questionable. Therefore, setting a reliable C_t threshold to declare a positive reaction is important for specific detection. In this study, five methods were assessed for their performance in determining a C_t cut‐off value. These methods were based on the widely used probability of detection (POD) or receiver‐operating characteristic (ROC) approaches. Two important forest pathogens, Hymenoscyphus fraxineus and Fusarium circinatum, were used to set up three experimental frameworks that combined two types of substrates (seed lots and spore traps) and different PCR machines. The ROC‐based method emerged as the most complete and flexible method under various experimental conditions. It was demonstrated that the ROC method leads to a cut‐off value below which late C_t results can reliably be considered indicative of positive test results. This cut‐off value must be determined for each experimental approach used. The method based on the distribution of a previously determined set of C_t values corresponding to false‐positives appeared to be better adapted to detecting false‐negative results, and thus useful for testing potentially invasive pathogens.