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

Tapani YLI-MATTILA; Sari PAAVANEN-HUHTALA; Sergey A. BULAT; Irina A. ALEKHINA; Helgard I. NIRENBERG

doi:10.1017/S0953756202006020

Abstract

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 well-supported 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.

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GUO, YANG-DONG YLI-MATTILA, TAPANI and PULLI, SEPPO 2003. Assessment of genetic variation in timothy (Phleum pratense L.) using RAPD and UP-PCR. Hereditas, Vol. 138, Issue. 2, p. 101.

Torp, Mona and Nirenberg, Helgard I. 2004. Fusarium langsethiae sp. nov. on cereals in Europe. International Journal of Food Microbiology, Vol. 95, Issue. 3, p. 247.

Uhlig, S. Torp, M. Jarp, J. Parich, A. Gutleb §, A. C. and Krska, R. 2004. Moniliformin in Norwegian grain. Food Additives and Contaminants, Vol. 21, Issue. 6, p. 598.

Yli-Mattila, T. Mach, R.L. Alekhina, I.A. Bulat, S.A. Koskinen, S. Kullnig-Gradinger, C.M. Kubicek, C.P. and Klemsdal, S.S. 2004. Phylogenetic relationship of Fusarium langsethiae to Fusarium poae and Fusarium sporotrichioides as inferred by IGS, ITS, β-tubulin sequences and UP-PCR hybridization analysis. International Journal of Food Microbiology, Vol. 95, Issue. 3, p. 267.

Gagkaeva, T. Yu. and Yli-Mattila, T. 2004. Molecular Diversity and PCR-detection of Toxigenic Fusarium Species and Ochratoxigenic Fungi. p. 551.

Yli-Mattila, T. Paavanen-Huhtala, S. Parikka, P. Konstantinova, P. and Gagkaeva, T. Y. 2004. Molecular Diversity and PCR-detection of Toxigenic Fusarium Species and Ochratoxigenic Fungi. p. 573.

Konstantinova, Pavlina and Yli-Mattila, Tapani 2004. IGS–RFLP analysis and development of molecular markers for identification of Fusarium poae, Fusarium langsethiae, Fusarium sporotrichioides and Fusarium kyushuense. International Journal of Food Microbiology, Vol. 95, Issue. 3, p. 321.

Kerényi, Zoltán Moretti, Antonio Waalwijk, Cees Oláh, Brigitta and Hornok, László 2004. Mating Type Sequences in Asexually Reproducing Fusarium Species . Applied and Environmental Microbiology, Vol. 70, Issue. 8, p. 4419.

Nagaraian, Gopal Nam, Myeong-Hyeon Song, Jeong-Young Yoo, Sung-Joon and Kim, Hong-Gi 2004. Genetic Variation in Fusarium oxysporum f. sp. fagariae Populations Based RAPD and rDNA RFLP Analyses. The Plant Pathology Journal, Vol. 20, Issue. 4, p. 264.

Kosiak, Elzbieta Barbara Holst-Jensen, Arne Rundberget, Thomas Gonzalez Jaen, Maria Teresa and Torp, Mona 2005. Morphological, chemical and molecular differentiation of Fusarium equiseti isolated from Norwegian cereals. International Journal of Food Microbiology, Vol. 99, Issue. 2, p. 195.

Kang, Zhensheng Zingen-Sell, Irmgard and Buchenauer, Heinrich 2005. Infection of wheat spikes by Fusarium avenaceum and alterations of cell wall components in the infected tissue. European Journal of Plant Pathology, Vol. 111, Issue. 1, p. 19.

Pantou, Malena P. Strunnikova, Olga K. Shakhnazarova, Vlada Yu. Vishnevskaya, Nadezhda A. Papalouka, Vasiliki G. and Typas, Milton A. 2005. Molecular and immunochemical phylogeny of Verticillium species. Mycological Research, Vol. 109, Issue. 8, p. 889.

Nicolaisen, Mogens Justesen, Annemarie F. Thrane, Ulf Skouboe, Pernille and Holmstrøm, Kim 2005. An oligonucleotide microarray for the identification and differentiation of trichothecene producing and non-producing Fusarium species occurring on cereal grain. Journal of Microbiological Methods, Vol. 62, Issue. 1, p. 57.

Kristensen, Ralf Torp, Mona Kosiak, Barbara and Holst-Jensen, Arne 2005. Phylogeny and toxigenic potential is correlated in Fusarium species as revealed by partial translation elongation factor 1 alpha gene sequences. Mycological Research, Vol. 109, Issue. 2, p. 173.

Uhlig, Silvio Torp, Mona and Heier, Berit T. 2006. Beauvericin and enniatins A, A1, B and B1 in Norwegian grain: a survey. Food Chemistry, Vol. 94, Issue. 2, p. 193.

Yli-Mattila, T. Paavanen-Huhtala, S. Parikka, P. Jestoi, M. Klemsdal, S. S. and Rizzo, A. 2006. Genetic variation, real-time PCR, metabolites and mycotoxins ofFusarium avenaceum and related species. Mycotoxin Research, Vol. 22, Issue. 2, p. 79.

2006. The Fusarium Laboratory Manual. p. 280.

Jurado, M. Vázquez, C. Callejas, C. and González-Jaén, M. T. 2006. Occurrence and variability of mycotoxigenicFusarium species associated to wheat and maize in the South West of Spain. Mycotoxin Research, Vol. 22, Issue. 2, p. 87.

Mitina, G. V. Mikhailova, L. A. and Yli-Mattila, T. 2008. RAPD-PCR, UP-PCR and rDNA sequence analyses of the entomopathogenic fungusVerticillium lecaniiand its pathogenicity towards insects and phytopathogenic fungi. Archives Of Phytopathology And Plant Protection, Vol. 41, Issue. 2, p. 113.

Kouvelis, Vassili N. Sialakouma, Aphrodite and Typas, Milton A. 2008. Mitochondrial gene sequences alone or combined with ITS region sequences provide firm molecular criteria for the classification of Lecanicillium species. Mycological Research, Vol. 112, Issue. 7, p. 829.

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

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

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