Clade A consisted of proteins annotated as sesquiterpene synthases with the greatest similarity to Cop6 from Coprinopsis cinereus, including two proteins from EF0021 and eight from Taxomyces andreanae, whereas selleck screening library all other sequences formerly annotated as sesquiterpene synthases clustered in clade C along with Cop1–Cop5 from Coprinopsis cinereus and protoilludene synthase from Armillaria gallica (Agger et al. 2009; Engels et al. 2011). Because Cop1–5 differ from Cop6 mechanistically, using all-trans-farnesyl diphosphate (FPP) or cis-FPP as a substrate to form trichodiene-like or germancrene-like cyclization products, the new terpene synthases clustering in clades A and C are probably grouped on the basis
of conserved functionally-relevant motifs as well as their fungal origin. Only two sequences, one each from EF0021 and Taxomyces andreanae, were similar to proteins in clade B, which contained all plant and fungal sequences related to diterpene biosynthesis. Clade B comprised three sub-clades, Defactinib cost based either on origin (fungi vs. plants) or specific function (e.g. their role in gibberellin biosynthesis). The abovementioned diterpene synthase from EF0021 and prenyltransferase from T. andreanae clustered with the fungal prenyltransferases and fusicoccadiene synthases. However, since these special chimeric synthases contain a prenyltransferase domain, clustering
probably Selleck MDV3100 reflected the stronger conservation of this domain which sets these proteins aside from the other terpene synthases. The presence of this domain also confers greater similarity e.g. to plant geranylgeranyl diphosphate and copalyl diphosphate synthases than other fungal sesquiterpene synthases in clades A and C. Our data clearly showed no evidence for homology to plant terpene synthases, and thus for trans-kingdom gene Silibinin transfer, as initially proposed as a possible explanation for the evolution of Taxol biosynthesis in plants and fungi. Furthermore, we found no evidence for similarities between the terpene synthases in the two endophytes we investigated. Terpene synthase 0021_TS_1762 remains
the only candidate for an enzyme that might be involved in diterpenoid metabolism, although the absence of a Taxomyces andreanae ortholog argues against the hypothesis that this enzyme is a fungal taxadiene synthase. Even if the pathway evolved independently in fungi and plants, as is thought to be the case for gibberellin biosynthesis (Bömke and Tudzynski 2009), enzymes that catalyze the complex synthesis of taxadiene should have a common evolutionary origin and should therefore show evidence of significant sequence similarity. Excluding any evolutionary scenario discussed above, the detection of minute amounts of taxanes in our fungal isolates is best explained by residual taxanes synthesized by the host yew tree. Taxol and related taxanes are highly lipophilic compounds that accumulate in endophyte cell wall structures.