EA 1069 Laboratoire de Chimie des Substances Naturelles, Faculté de Pharmacie, Université de Limoges, 2 rue du Dr Marcland, 87025 Limoges Cedex, France.
UMR5174 UPS-CNRS-IRD Laboratoire Evolution et Diversité Biologique, EDB, Université Toulouse, 3, Bât 4R1, 118 route de Narbonne, 31062 Toulouse, France.
Microbiol Res. 2018 Jun;211:1-12. doi: 10.1016/j.micres.2018.03.006. Epub 2018 Mar 21.
Fungal communities associated to three epiphytic lichens active against Candida, were investigated using culture-based methods We hypothetized that associated fungi would contribute to lichens activities. The ability of specific fungi to grow inside or outside lichens was investigated. To detect biogenesis pathways involved in the production of secondary metabolites, genes coding for nonribosomal peptide synthetase (NRPS) and polyketide synthase I (PKS I) were screened by PCR from fungal DNA extracts. Both endo and epilichenic communities were isolated from two fructicose (Evernia prunastri and Ramalina fastigiata) and one foliose (Pleurosticta acetabulum) lichens. A total of 86 endolichenic and 114 epilichenic isolates were obtained, corresponding to 18 and 24 phylogenetic groups respectively suggesting a wide diversity of fungi. The communities and the species richness were distinct between the three lichens which hosted potentially new fungal species. Additionally, the endo- and epilichenic communities differed in their composition: Sordariomycetes were particularly abundant among endolichenic fungi and Dothideomycetes among epilichenic fungi. Only a few fungi colonized both habitats, such as S. fimicola, Cladosporium sp1 and Botrytis cinerea. Interestingly, Nemania serpens (with several genotypes) was the most abundant endolichenic fungus (53% of isolates) and was shared by the three lichens. Finally, 12 out of 36 phylogenetic groups revealed the presence of genes coding for nonribosomal peptide synthetase (NRPs) and polyketide synthase I (PKS I). This study shows that common lichens are reservoirs of diverse fungal communities, which could potentially contribute to global activity of the lichen and, therefore, deserve to be isolated for further chemical studies.
采用基于培养的方法研究了与三种对念珠菌有活性的附生地衣相关的真菌群落。我们假设相关真菌将有助于地衣的活动。研究了特定真菌在内部或外部地衣中生长的能力。为了检测参与次生代谢物产生的生物发生途径,从真菌 DNA 提取物中通过 PCR 筛选了非核糖体肽合成酶(NRPS)和聚酮合酶 I(PKS I)的编码基因。从两种果糖(Evernia prunastri 和 Ramalina fastigiata)和一种叶状(Pleurosticta acetabulum)地衣中分离出内生和外生地衣群落。共获得 86 个内生和 114 个外生地衣分离物,分别对应于 18 和 24 个系统发育群,表明真菌多样性广泛。三种地衣中的群落和物种丰富度存在差异,这些地衣中可能含有新的真菌物种。此外,内生和外生地衣群落的组成也不同:Sordariomycetes 在内生真菌中特别丰富,而 Dothideomycetes 在外生地衣真菌中丰富。只有少数真菌同时定植于两种生境,如 S. fimicola、Cladosporium sp1 和 Botrytis cinerea。有趣的是,Nemania serpens(有几个基因型)是最丰富的内生真菌(占分离物的 53%),存在于三种地衣中。最后,36 个系统发育群中有 12 个显示出存在非核糖体肽合成酶(NRPS)和聚酮合酶 I(PKS I)编码基因。本研究表明,常见地衣是多种真菌群落的储存库,这些真菌可能有助于地衣的整体活性,因此值得进一步进行化学研究。
