Jelena Baćanović-Šišić scite author profile

Schmidt

et al. 2017

Eur J Plant Pathol

The ‘forma specialis’ issue in Fusarium: A case study in Fusarium solani f. sp. pisi

Al‐Hatmi

et al. 2018

Sci Rep

The Fusarium solani species complex (FSSC) has been studied intensively but its association with legumes, particularly under European agro-climatic conditions, is still poorly understood. In the present study, we investigated phylogenetic relationships and aggressiveness of 79 isolates of the FSSC collected from pea, subterranean clover, white clover and winter vetch grown under diverse agro-climatic and soil conditions within Temperate and Mediterranean Europe. The isolates were characterized by sequencing tef1 and rpb2 loci and by greenhouse aggressiveness assays. The majority of the isolates belonged to two lineages: the F. pisi comb. nov. lineage (formerly F. solani f. sp. pisi) mainly accommodating German and Swiss isolates, and the Fusisporium (Fusarium) solani lineage accommodating mainly Italian isolates. Based on the results of aggressiveness tests on pea, most of the isolates were classified as weakly to moderately aggressive. In addition, using one model strain, 62 accessions of 10 legume genera were evaluated for their potential to host F. pisi, the species known mainly as a pathogen of pea. A total of 58 accessions were colonized, with 25 of these being asymptomatic hosts. These results suggest a broad host range for F. pisi and challenge the forma specialis naming system in Fusarium.Fusarium solani (sexual morph Nectria haematococca; syn. Haematonectria haematococca) is a filamentous fungus of significant agricultural importance that has been accommodated as a single species in the section Martiella within the genus Fusarium 1 . Re-evaluation of species taxonomy based on molecular phylogenetic analyses has revealed that F. solani is a species complex (FSSC) which includes at least 60 distinct phylogenetic species 2,3 . Members of the complex are globally distributed and of considerable ecological plasticity, causing infections in both plants and humans 4,5 . Phytopathogenic species within the FSSC include some of the most economically important plant pathogens associated with vascular wilts and root rots in over 100 crops 6 . Despite the broad host range of the complex as a whole, individual species are often associated with only one or a few plant hosts. Consequently, populations of F. solani pathogenic on plants have been divided into 12 formae speciales and two races [7][8][9][10] . Early studies on sexual compatibility of special forms and races has already shown that F. solani represents at least seven biological species classified as mating populations (MPs) I-VII, with Nectria haematococca as the most commonly referred sexual morph. Biological species correlated with a host range, as successful sexual crosses were found only among heterothallic isolates within each special form or race 11 . However, the designation forma specialis may lead to incorrect assumptions concerning the aggressiveness and host specificity of individual isolates. For example, studies on the host range of F. solani f. sp. pisi (MP VI), named by its specific pathogenicity on pea (Pisum sativum), revealed that the speci...

show abstract

A Novel Real Time PCR Method for the Detection and Quantification of Didymella pinodella in Symptomatic and Asymptomatic Plant Hosts

Oberhänsli

et al. 2021

JoF

Didymella pinodella is the major pathogen of the pea root rot complex in Europe. This wide host range pathogen often asymptomatically colonizes its hosts, making the control strategies challenging. We developed a real-time PCR assay for the detection and quantification of D. pinodella based on the TEF-1 alpha gene sequence alignments. The assay was tested for specificity on a 54-isolate panel representing 35 fungal species and further validated in symptomatic and asymptomatic pea and wheat roots from greenhouse tests. The assay was highly consistent across separate qPCR reactions and had a quantification/detection limit of 3.1 pg of target DNA per reaction in plant tissue. Cross-reactions were observed with DNA extracts of five Didymella species. The risk of cross contamination, however, is low as the non-targets have not been associated with pea previously and they were amplified with at least 1000-fold lower sensitivity. Greenhouse inoculation tests revealed a high correlation between the pathogen DNA quantities in pea roots and pea root rot severity and biomass reduction. The assay also detected D. pinodella in asymptomatic wheat roots, which, despite the absence of visible root rot symptoms, caused wheat biomass reduction. This study provides new insights into the complex life style of D. pinodella and can assist in better understanding the pathogen survival and spread in the environment.

show abstract

Root Pathogens Occurring on Pea (Pisum sativum) and Faba Bean (Vicia faba) in Germany

Schmidt³

et al. 2020