Sari Paavanen-Huhtala

Molecular and morphological diversity of Fusarium species in Finland and northwestern Russia

In 2001 the range of the total Fusarium contamination percentage of infected seeds was between 0% and 44%, while in 2002 the contamination level was 2–25% in naturally infected Finnish samples and 5–14.5% in six samples from northwestern Russia. The most common Fusarium species in barley were F. avenaceum, F. arthrosporioides, F. sporotrichioides and F. culmorum, while in spring wheat the most common Fusarium species were F. avenaceum, F. arthrosporioides, F. culmorum, F. sporotrichioides and F. graminearum. In most cases, molecular identification with species-specific primers corresponded to the morphological analyses and allowed the identification of degenerated and otherwise morphologically difficult cultures. It was even possible to separate most of the F. arthrosporioides isolates from Finland from the closely-related F. avenaceum isolates. In the phylogenetic analysis of combined β-tubulin, IGS and ITS sequences most European F. arthrosporioides formed a separate clade from most isolates of F. avenaceum and from all isolates of F. tricinctum. Most of the species-specific primers also amplified DNA extracted from grain samples. It was, for instance, possible to detect F. avenaceum in all barley samples with contamination levels higher than 1% and in all spring wheat samples with contamination levels higher than 3%. The detection level for F. graminearum was at a contamination level of 3–5% and that for F. culmorum at a contamination level of 1–5%. In addition, the first Finnish F. langsethiae isolate was found by means of species-specific primers.

Real-time PCR detection and quantification of Fusarium poae, F. graminearum, F. sporotrichioides and F. langsethiae in cereal grains in Finland and Russia

Abstract TaqMan real-time quantitative PCR assays were developed for the accurate detection and quantification of DNA from Fusarium poae and F. graminearum species, which are able to produce trichothecenes. These and other PCR assays were used for the quantification of trichothecene-producing Fusarium fungi in cereal grains. A correlation was found between the levels of F. poae DNA and nivalenol and enniatins in barley and between the levels of F. graminearum DNA and deoxynivalenol in oats. The correlations between F. poae DNA and nivalenol and F. graminearum DNA and deoxynivalenol levels were higher than those between these mycotoxins and morphologically determined F. poae and F. graminearum/F. culmorum contamination levels. The use of F. poae specific primers and probe together with F. sporotrichioides/F. langsethiae specific primers and probe in a multiplex qPCR assay yielded results in accordance with those obtained using these primers and probes separately.

Real-time PCR for Quantification of Toxigenic Fusarium Species in Barley and Malt

A real-time PCR technique was applied for the quantification of trichothecene-producing Fusarium species (TMTRI assay) as well as the highly toxigenic Fusarium graminearum (TMFg12 assay) present in barley grain and malt. PCR results were compared to the amounts of trichothecenes detected in the samples to find out if the PCR assays can be used for trichothecene screening instead of expensive and laborious chemical analyses. DNA was extracted from ground kernels using a commercial DNA extraction kit and analysed in a LightCycler® system using specific primers and fluorogenic TaqMan probes. Both naturally and artificially contaminated grains were analysed. The TMTRI assay and the TMFg12 assay enabled the quantification of trichothecene-producing Fusarium DNA and F. graminearum DNA present in barley grain and malt samples, respectively. Both TaqMan assays were considered to be sensitive and reproducible. Linearity of the assays was 4–5 log units when pure Fusarium DNAs were tested. The amount of Fusarium DNA analysed with the TMTRI-trichothecene assay could be used for estimation of the deoxynivalenol (DON) content in barley grain. Furthermore, the TMFg12 assay for F. graminearum gave a good estimation of the DON content in north American barley and malt samples, whilst the correlation was poor among Finnish samples. DON content and the level of F. graminearum DNA were found to be naturally low in Finnish barleys.

Molecular, morphological and phylogenetic analysis of the Fusarium avenaceum/F. arthrosporioides/F. tricinctum species complex – a polyphasic approach

Differences in morphology, ITS, IGS, mtSSU and β-tubulin sequences and UP-PCR hybridization were compared between morphologically identified F. avenaceum, F. arthrosporioides, F. anguioides, F. tricinctum, F. graminum and F. acuminatum strains. According to the combined β-tubulin, IGS and ITS tree, the strains of the Fusarium avenaceum/F. arthrosporioides/F. tricinctum species complex species can be divided into seven clusters supported by bootstrap values higher than 50%. The two main groups of European F. avenaceum , which cannot be distinguished by morphology, were separated in the tree based on β-tubulin sequences and less clearly in trees based on IGS and ITS sequences. MtSSU sequences were identical in all F. avenaceum and F. tricinctum strains studied. The European F. avenaceum strains of main group II had identical β-tubulin sequences with one American F. avenaceum strain and four European F. arthrosporioides strains, while F. avenaceum strains of main group I were closely related to two European F. arthrosporioides strains and to one Japanese F. anguioides strain. According to the combined β-tubulin/IGS/ITS sequence tree, European F. arthrosporioides strains were divided into four groups; F. tricinctum strains formed a wellsupported cluster, in which two European clusters were separated from one African isolate. In the IGS sequence tree two European F. acuminatum strains together with one American F. acuminatum strain formed a cluster, which was separate from another American F. acuminatum strain. The F. acuminatum cluster was nested within the large F. tricinctum cluster together with one F. reticulatum strain in the combined IGS/β-tubulin tree. Several strains may be intermediates between the F. avenaceum/F. arthrosporioides/F. anguioides and F. tricinctum clusters and represent their own species. These results are partially supported by the results of UP-PCR hybridization analysis. Thus the molecular results may be helpful in future revision in the taxonomy of these species.

In vitro and in vivo mycotoxin production of Fusarium species isolated from Finnish grains

Abstract The capabilities of seven Finnish Fusarium species to produce mycotoxins under controlled laboratory (in vitro) conditions as well as on barley and wheat in the field (in vivo) were studied using mass spectrometric methods. In addition, the contaminating Fusarium species of the in vivo samples were identified and quantified with morphological and real-time polymerase chain reaction techniques. All investigated isolates (representing the species F. avenaceum, F. arthrosporioides, F. tricinctum, F. poae, F. culmorum, F. graminearum and F. sporotrichioides) produced mycotoxins on rice cultures and their production capabilities were generally in accordance with the available literature. The main mycotoxins produced were deoxynivalenol, 3-acetyldeoxynivalenol and zearalenone by F. culmorum and F. graminearum, beauvericin, diacetoxyscirpenol and HT-2/T-2 – toxins by F. sporotrichioides, beauvericin, enniatins, fusarenon-X, diacetoxyscirpenol and nivalenol by F. poae and enniatins and moniliformin by F. avenaceum/F. arthrosporioides and F. tricinctum. Most mycotoxins that were produced in vitro were also produced in vivo when concerning F. culmorum, F. graminearum and F. avenaceum. Statistical significance was recorded between the production of mycotoxins in vitro and in vivo for HT-2 and T-2 toxins in barley and for deoxynivalenol and T-2 toxin in wheat.

Development of Strain-specific Primers for a Strain of Gliocladium catenulatum Used in Biological Control

The randomly amplified polymorphic DNA (RAPD) technique was used to develop strain-specific primers for Gliocladium catenulatum strain J1446, which is promising in biological control. One of the primer pairs developed proved to be strain-specific; strain J1446 was differentiated from 16 G. catenulatum strains and six other strains of two Gliocladium species, as well as from Trichoderma virens, and isolates of Nectria spp. and Fusarium spp. Specific primers were also tested with DNA isolated from cucumber leaves, treated or untreated with a solution made from Gliocladium powder. The expected amplification product was produced only from treated leaves. DNA isolated from Gliocladium-treated potato tubers and fungi grown in peat was also used in amplification reactions. Strain-specific primers detected strain J1446 when the amount of DNA was 5 pg or more. Some variation between the Gliocladium strains was found by the random amplified microsatellites method (RAMS) and the universally primed polymerase chain reaction method (UP-PCR), but no clear fragments specific to strain J1446 were produced. Cross-blot hybridisation of UP-PCR products differentiated strain J1446 from T. virens, but not from the Gliocladium isolates. The 28S rDNA sequences and β-tubulin sequences were identical or very similar in all Gliocladium strains. Thus, it is possible that the Gliocladium strains of the present study are conspecific, which means that a revision in the taxonomy of Gliocladium species may be necessary.

RAPD-PCR, isozyme, rDNA RFLP and rDNA sequence analyses in identification of Finnish Fusarium oxysporum isolates

Twenty-seven Fusarium oxysporum isolates were studied by RAPD-PCR and isozyme analyses. Thirteen isolates were from barley and the rest from different hosts, most of which were dicotyledonous plants. All isolates could be distinguished from each other by RAPD-PCR analysis, and clustered into seven groups in NJ and parsimony consensus trees. Isozyme analysis detected polymorphism in five of the six enzymes and the isolates could be divided into 26 different electrophoretic groups. Five groups were supported by high branch support and bootstrap values in the approximate support tree of combined RAPD-PCR and isozyme data. These five groups were found also in NJ and parsimony consensus trees. The matrices from RAPD-PCR and isozyme data proved to be incongruent, but they did not totally disprove each other. Some correlation was found between geographical origin and phylogenetic relationships of isolates collected from barley. Representatives of the main clades of phylogenetic trees, were further studied by rDNA RFLP and rDNA sequence analyses, together with isolates of other Fusarium species. Isolates of F. oxysporum and F. avenaceum formed distinct groups in the phylogenetic analyses, except for two isolates of F. oxysporum which were grouped with isolates of F. redolens.

Species and strain identification of the predatory mite Euseius finlandicus by RAPD-PCR and ITS sequences.

The variation within and between Finnish Euseius finlandicus populations was investigated by RAPD-PCR and ITS sequence analyses. Resin DNA extraction was found to be a suitable method for samples of single mites used in PCR. The banding patterns from 24 RAPD primers and 10 primer pairs were very similar and reproducible in all specimens of the predatory mite studied. However, the E. finlandicus K-strain could be distinguished from organophosphate-resistant predatory mites (R-strain), since almost all of them produced a 1400 bp RAPD-PCR product, which was missing or very rare in other strains studied. Another RAPD band of ca. 680 bp was in turn much more common in other mites of E. finlandicus than in the K-strain mites. Mite specific primers were designed and used to follow the survival of the R-strain released on apple trees. The 680 bp band obtained with specific primers was specific to the species E. finlandicus mites studied, including those that had been negative with RAPD primers. The 1400 bp specific primers could be used as a marker for following the survival of R-strain mites on apple trees. At the species level it was possible to distinguish adults and eggs of E. finlandicus from Anthoseius rhenanus and Phytonemus pallidus by RAPD-PCR. In addition, a band at 480 bp was found to correspond to DNA of the predatory mite Phytoseius macropilis, when both specific primer pairs were used together. It was not possible to amplify the ITS region of E. finlandicus rDNA using several primer pairs that work in other mites and aphids. However, a basidiomycete rDNA sequence was amplified with one of these ITS primer pairs in K-strain mites. Finally, it was found that fungal rDNA-specific primers amplified an ITS region of ca. 650 bp in several strains of E. finlandicus. Internal primers, designed to amplify the central part of the 650 bp product, successfully amplified this product from all the mites.

Genetic variation, real-time PCR, metabolites and mycotoxins ofFusarium avenaceum and related species.

In this paper the latest studies dealing with genetic variation and mycotoxins ofF. avenaceum and related species are reviewed and compared to the data from chromatographic image analyses. Forty-three European strains ofFusarium avenaceum and related species were classified by chromatographic image analysis on full chromatographic matrices. The results were in most cases in agreement with those from morphological and molecular analyses and supported the separation betweenF. avenaceum, F. arthrosporioides andF. tricinctum and betweenF. avenaceum groups I and II. The mycotoxin profiles of the FinnishF. avenaceum, F. arthrosporioides andF tricinctum strains were very similar to each other. Moniliformin and enniatins were the main mycotoxins produced. A fluorogenic TaqMan PCR assay (qPCR) was used for the detection ofF. avenaceum/ F. arthrosporioides DNA in Finnish barley and wheat. The qPCR results obtained from grain samples were compared to mycotoxin levels. A correlation was found betweenF. avenaceum/F. arthrosporioides DNA and moniliformin (MON) and enniatin (ENNs) levels in barley. A correlation was also found between the combinedF. avenaceum/F. arthrosporioides/F. tricinctum contamination and MON and ENNs levels in barley in 2002, but not in 2003. This was probably due to the higher MON and ENNs levels in 2002 than in 2003. It was possible to use the DNA levels ofF. avenaceum/F. arthrosporioides to distinguish between most barley samples containing high amounts of MON and ENNs from those containing low levels of the mycotoxins.

Prevalence, species composition, genetic variation and pathogenicity of clover rot ( Sclerotinia trifoliorum ) and Fusarium spp. in red clover in Finland

The species composition of a total of 173 red clover root fungal isolates from red clover roots from two established organic fields, a field in a transitional phase to organic and from two conventional fields was investigated based on morphology and molecular methods. Fusarium avenaceum was the most common Fusarium species overall but it occurrred less frequently in older organic fields. Gliocladium spp., Trichoderma spp. and Rhizoctonia spp. isolates were more common in the established organic clover fields, which had been under organic management for more than ten years and in one conventional field, than in a field still in the transitional phase. The taxonomical status of certain Fusarium, Alternaria and Sclerotinia isolates difficult to identify by morphological traits alone could be confirmed by species-specific primers and by comparing their ITS (internal transcribed spacer region) sequences to known sequences. The fingerprinting patterns of RAPD-PCR products could be used for the identification of fungal isolates and for studying the genetic variation among the isolates. Only one of the Fusarium isolates originating from apparently healthy red clover roots was clearly pathogenic to germinated red clover seedlings. In detached leaf experiments, the cvs Jokioinen and Ilte were more susceptible to one of the Sclerotinia trifoliorum isolates than cvs Betty and Bjursele, while all of them were equally susceptible to two other S. trifoliorum isolates. In further greenhouse experiments with intact plants it was possible to slow down the development of clover rot to some extent by means of one of the biological agents tested (Bacillus subtilis 10-VIZR, commercial name Alirin B), and almost completely by chemical control.