Twists and turns of the salicylate catabolism in Aspergillus terreus

ABSTRACT In fungi, salicylate catabolism was believed to proceed only through the catechol branch of the 3-oxoadipate pathway, as shown e.g. in Aspergillus nidulans . However, the observation of a transient accumulation of gentisate upon cultivation of Aspergillus terreus in salicylate media questions this concept. To address this we have run a comparative analysis of the transcriptome of these two species after growth in salicylate using acetate as a control condition. The results revealed the high complexity of the salicylate metabolism in A. terreus with the concomitant positive regulation of several pathways for the catabolism of aromatic compounds. This included the unexpected joint action of two pathways: the nicotinate and the 3-hydroxyanthranilate, possibly crucial for the catabolism of aromatics in this fungus. New genes participating in the nicotinate metabolism are here proposed, whereas the 3-hydroxyanthranilate catabolic pathway in fungi is described for the first time. The transcriptome analysis showed also for the two species an intimate relationship between salicylate catabolism and secondary metabolism. This study emphasizes that the central pathways for the catabolism of aromatic hydrocarbons in fungi hold many mysteries yet to be discovered. IMPORTANCE Aspergilli are versatile cell factories used in industry for production of organic acids, enzymes and pharmaceutical drugs. To date, organic acids bio-based production relies on food substrates. These processes are currently being challenged to switch to renewable non-food raw materials; a reality that should inspire the use of lignin derived aromatic monomers. In this context, Aspergilli emerge at the forefront of future bio-based approaches due to their industrial relevance and recognized prolific catabolism of aromatic compounds. Notwithstanding considerable advances in the field, there are still important knowledge gaps in the central catabolism of aromatic hydrocarbons in fungi. Here, we disclosed a novel central pathway, defying previous established ideas on the central metabolism of the aromatic amino acid tryptophan in Ascomycota. We also observed that the catabolism of the aromatic salicylate greatly activated the secondary metabolism, furthering the significance of using lignin derived aromatic hydrocarbons as a distinctive biomass source.