Duplex real-time PCR assay for the simultaneous detection of Caliciopsis pinea and Fusarium circinatum in pine samples.

Fusarium circinatum and Caliciopsis pinea are the causal agents of Pitch canker and Caliciopsis canker, respectively. These diseases affect pines and other conifers both in Europe and North America. The two pathogens cause similar bleeding cankers, especially at the early stage of colonization. Symptoms closely resembling those due to F. circinatum can be instead associated with C. pinea. Since F. circinatum is a quarantine organism, subjected to provisional emergency measures, its report immediately causes serious economic implications, while C. pinea, even if now emerging, is not regulated in the EU nor in the USA. For this reason, a reliable and accurate diagnostic tool able to distinguish between the two organisms was considered a priority. In this study, we developed and standardized a duplex real-time PCR assay allowing the simultaneous recognition of C. pinea and F. circinatum DNA in pine tissue in a reasonably short time and for amounts as small as 0.06 pg/µl. The molecular assay is, therefore, able to detect the infection even before symptoms have fully developed. The test was challenged with a very large set of strains (110 different isolates) collected in different regions of the world and host trees, and gave reliable results. The high efficiency of this method suggests its use as a standard diagnostic tool during phytosanitary controls. In addition, the duplex real-time PCR assay presented here is the first DNA-based method designed to detect C. pinea, which is becoming an increasing threat to pine stands both in North America and in Europe.

Genetic and genomic evidence of niche partitioning and adaptive radiation in mountain pine beetle fungal symbionts.

Bark beetles form multipartite symbiotic associations with blue stain fungi (Ophiostomatales, Ascomycota). These fungal symbionts play an important role during the beetle's life cycle by providing nutritional supplementation, overcoming tree defences and modifying host tissues to favour brood development. The maintenance of stable multipartite symbioses with seemingly less competitive symbionts in similar habitats is of fundamental interest to ecology and evolution. We tested the hypothesis that the coexistence of three fungal species associated with the mountain pine beetle is the result of niche partitioning and adaptive radiation using SNP genotyping coupled with genotype-environment association analysis and phenotypic characterization of growth rate under different temperatures. We found that genetic variation and population structure within each species is best explained by distinct spatial and environmental variables. We observed both common (temperature seasonality and the host species) and distinct (drought, cold stress, precipitation) environmental and spatial factors that shaped the genomes of these fungi resulting in contrasting outcomes. Phenotypic intraspecific variations in Grosmannia clavigera and Leptographium longiclavatum, together with high heritability, suggest potential for adaptive selection in these species. By contrast, Ophiostoma montium displayed narrower intraspecific variation but greater tolerance to extreme high temperatures. Our study highlights unique phenotypic and genotypic characteristics in these symbionts that are consistent with our hypothesis. By maintaining this multipartite relationship, the bark beetles have a greater likelihood of obtaining the benefits afforded by the fungi and reduce the risk of being left aposymbiotic. Complementarity among species could facilitate colonization of new habitats and survival under adverse conditions.