A Rapid qPCR for the Detection of Verticillium nonalfalfae MLST2 - A Highly Pathogenic Fungus on Kiwifruit.

A highly pathogenic fungus characterized as Verticillium nonalfalfae multilocus sequence type 2 (MLST2) is an emerging fungal pathogen causing Verticillium wilt on kiwifruit. Although V. nonalfalfae MLST2 has not been reported outside Chile, there is a risk that this pathogen could spread through the global movement of germplasms to other countries. Current diagnostic methods for this fungus rely on a laborious and time-consuming plating assay for morphological identification and DNA sequence analysis. In this study, we describe the development and validation of a novel quantitative polymerase chain reaction (qPCR) assay for rapid and specific detection of V. nonalfalfae MLST2 in plant tissues. The assay targets the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) gene and was shown to detect all tested isolates of V. nonalfalfae MLST2 with a detection limit of approximately 2 pg of pathogen genomic DNA. There was no cross-reaction with V. nonalfalfae MLST1, other Verticillium species, or non-target fungal species found on kiwifruit. This assay was duplexed with a plant internal control for simultaneous detection of the pathogen and cytochrome oxidase gene from the host plant. This new specific and sensitive qPCR assay is a valuable molecular diagnostic tool for rapid screening of imported plant material and would also be useful for testing samples collected from field surveillance activities to monitor the presence of V. nonalfalfae MLST2.

Transferability of PCR-based diagnostic protocols: An international collaborative case study assessing protocols targeting the quarantine pine pathogen Fusarium circinatum.

Fusarium circinatum is a harmful pathogenic fungus mostly attacking Pinus species and also Pseudotsuga menziesii, causing cankers in trees of all ages, damping-off in seedlings, and mortality in cuttings and mother plants for clonal production. This fungus is listed as a quarantine pest in several parts of the world and the trade of potentially contaminated pine material such as cuttings, seedlings or seeds is restricted in order to prevent its spread to disease-free areas. Inspection of plant material often relies on DNA testing and several conventional or real-time PCR based tests targeting F. circinatum are available in the literature. In this work, an international collaborative study joined 23 partners to assess the transferability and the performance of nine molecular protocols, using a wide panel of DNA from 71 representative strains of F. circinatum and related Fusarium species. Diagnostic sensitivity, specificity and accuracy of the nine protocols all reached values >80%, and the diagnostic specificity was the only parameter differing significantly between protocols. The rates of false positives and of false negatives were computed and only the false positive rates differed significantly, ranging from 3.0% to 17.3%. The difference between protocols for some of the performance values were mainly due to cross-reactions with DNA from non-target species, which were either not tested or documented in the original articles. Considering that participating laboratories were free to use their own reagents and equipment, this study demonstrated that the diagnostic protocols for F. circinatum were not easily transferable to end-users. More generally, our results suggest that the use of protocols using conventional or real-time PCR outside their initial development and validation conditions should require careful characterization of the performance data prior to use under modified conditions (i.e. reagents and equipment). Suggestions to improve the transfer are proposed.

Genetic and pathogenic diversity of Neofusicoccum parvum in New Zealand vineyards.

Genetic diversity of 50 isolates of Neofusicoccum parvum, the predominant species of the Botryosphaeriaceae recovered from grapevines displaying symptoms of dieback and decline in New Zealand, was compared to that of isolates from Australia, South Africa, and California. The eight universally primed polymerase chain reaction (UP-PCR) primers distinguished 56 genotypes, with only four clonal pairs found. Seven main groups were identified in a neighbour-joining (NJ) tree with isolates from different regions and vineyards of New Zealand, Australia, and California distributed in different groups, indicating a high level of intra and intervineyard genetic variation. All of the South African isolates were positioned in a separate UP-PCR group, indicating that these isolates were less related to the other N. parvum isolates. When compared to fungi that reproduce sexually the genetic diversity and Shannon diversity indices were low (0.076-0.249; 0.109-0.367, respectively), genetic identity levels were high (0.76-0.95), and genetic distance levels were low (0.04-0.27). The large number of genotypes and the low number of clones in the New Zealand N. parvum populations may be explained by parasexual recombination as anastomosis was observed between nonself pairings. Pathogenicity tests using isolates from different UP-PCR groups inoculated onto either green shoots or 1-y-old grapevines detected virulence diversity, indicating intra and intervineyard variation between isolates, however, no correlation was detected between UP-PCR group and virulence.