Detection of paralogous polyketide synthase genes in Parmeliaceae by specific primers

Magdalena OPANOWICZ; Juliane BLAHA; Martin GRUBE

doi:10.1017/S0024282905005529

Abstract

A first assessment of paralogy in non-reducing polyketide synthases of Parmeliaceae is presented. Primers which are specific to the keto-acyl synthase domain were used to amplify gene fragments of putative non-reducing polyketide synthases from various representatives of the family. The corresponding sequences were analysed together with a selection of known polyketide synthase genes from other fungi, including lichenized fungi. The results suggest that genes from Parmeliaceae represent at least 6 paralogs. Their different positions in the tree partly correlate with the variable presence of spliceosomal introns at particular positions in the gene fragments. Because only one paralog could be unambiguously detected in each species by direct sequencing of PCR products with this approach, we tested the applicability of clade-specific primers, designed by using orthologous signature sequences. With these primers more paralogs could be detected from the same DNA extract in a number of species, but certain paralogs were consistently not amplified in these species. The paralog-specific primer approach can potentially be used for a rapid screening of PKS genes from a broader range of lichen fungi.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Muggia, Lucia Schmitt, Imke and Grube, Martin 2008. Purifying selection is a prevailing motif in the evolution of ketoacyl synthase domains of polyketide synthases from lichenized fungi. Mycological Research, Vol. 112, Issue. 2, p. 277.

Chooi, Yit-Heng Stalker, David M. Davis, Meryl A. Fujii, Isao Elix, John A. Louwhoff, Simone H.J.J. and Lawrie, Ann C. 2008. Cloning and sequence characterization of a non-reducing polyketide synthase gene from the lichen Xanthoparmelia semiviridis. Mycological Research, Vol. 112, Issue. 2, p. 147.

Stocker-Wörgötter, Elfie 2008. Metabolic diversity of lichen-forming ascomycetous fungi: culturing, polyketide and shikimatemetabolite production, and PKS genes. Nat. Prod. Rep., Vol. 25, Issue. 1, p. 188.

Brunauer, Georg Muggia, Lucia Stocker-Wörgötter, Elfie and Grube, Martin 2009. A transcribed polyketide synthase gene from Xanthoria elegans. Mycological Research, Vol. 113, Issue. 1, p. 82.

Honegger, Rosmarie 2009. The Mycota. Vol. 5, Issue. , p. 307.

Nelsen, Matthew P. and Gargas, Andrea 2009. Assessing clonality and chemotype monophyly in Thamnolia (Icmadophilaceae). The Bryologist, Vol. 112, Issue. 1, p. 42.

Printzen, Christian 2010. Progress in Botany, Vol. 71. Vol. 71, Issue. , p. 233.

FONTAINE, Kyle M. AHTI, Teuvo and PIERCEY-NORMORE, Michele D. 2010. Convergent evolution in Cladonia gracilis and allies. The Lichenologist, Vol. 42, Issue. 3, p. 323.

Lucia, Muggia and Martin, Grube 2010. Type III polyketide synthases in lichen mycobionts. Fungal Biology, Vol. 114, Issue. 4, p. 379.

Lumbsch, H. Thorsten and Leavitt, Steven D. 2011. Goodbye morphology? A paradigm shift in the delimitation of species in lichenized fungi. Fungal Diversity, Vol. 50, Issue. 1, p. 59.

Armaleo, Daniele Sun, Xiameng and Culberson, Chicita 2011. Insights from the first putative biosynthetic gene cluster for a lichen depside and depsidone. Mycologia, Vol. 103, Issue. 4, p. 741.

Timsina, Brinda A. Stocker-Wörgötter, E. and Piercey-Normore, Michele D. 2012. Monophyly of some North American species ofRamalinaand inferred polyketide synthase gene function. Botany, Vol. 90, Issue. 12, p. 1295.

Timsina, Brinda A. Sorensen, John L. Weihrauch, Dirk and Piercey-Normore, Michele D. 2013. Effect of aposymbiotic conditions on colony growth and secondary metabolite production in the lichen-forming fungus Ramalina dilacerata. Fungal Biology, Vol. 117, Issue. 11-12, p. 731.

Timsina, Brinda A. Hausner, Georg and Piercey-Normore, Michele D. 2014. Evolution of ketosynthase domains of polyketide synthase genes in the Cladonia chlorophaea species complex (Cladoniaceae). Fungal Biology, Vol. 118, Issue. 11, p. 896.

Van de Putte, Kobeke Nuytinck, Jorinde De Crop, Eske and Verbeken, Annemieke 2016. Lactifluus volemus in Europe: Three species in one – Revealed by a multilocus genealogical approach, Bayesian species delimitation and morphology. Fungal Biology, Vol. 120, Issue. 1, p. 1.

Xu, Maonian Heidmarsson, Starri Olafsdottir, Elin Soffia Buonfiglio, Rosa Kogej, Thierry and Omarsdottir, Sesselja 2016. Secondary metabolites from cetrarioid lichens: Chemotaxonomy, biological activities and pharmaceutical potential. Phytomedicine, Vol. 23, Issue. 5, p. 441.

Fortuna, Lorenzo Baracchini, Elena Adami, Gianpiero and Tretiach, Mauro 2017. Melanization Affects the Content of Selected Elements in Parmelioid Lichens. Journal of Chemical Ecology, Vol. 43, Issue. 11-12, p. 1086.

Bhattacharya, Amitav 2019. Effect of High Temperature on Crop Productivity and Metabolism of Macro Molecules. p. 391.

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Detection of paralogous polyketide synthase genes in Parmeliaceae by specific primers

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Detection of paralogous polyketide synthase genes in Parmeliaceae by specific primers

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