Identification of a copper-transporting ATPase involved in biosynthesis of A. flavus conidial pigment.

Conidia are asexual spores and play a crucial role in fungal dissemination. Conidial pigmentation is important for tolerance against UV radiation and contributes to survival of fungi. The molecular basis of conidial pigmentation has been studied in several fungal species. In spite of sharing the initial common step of polyketide formation, other steps for pigment biosynthesis appear to be species-dependent. In this study, we isolated an Aspergillus flavus spontaneous mutant that produced yellow conidia. The underlying genetic defect, a three-nucleotide in-frame deletion in the gene, AFLA_051390, that encodes a copper-transporting ATPase, was identified by a comparative genomics approach. This genetic association was confirmed by disruption of the wild-type gene. When yellow mutants were grown on medium supplemented with copper ions or chloride ions, green conidial color was partially and nearly completely restored, respectively. Further disruption of AFLA_045660, an orthologue of Aspergillus nidulans yA (yellow pigment) that encodes a multicopper oxidase, in wild type and a derived strain producing dark green conidia showed that it yielded mutants that produced gold conidia. The results placed formation of the gold pigment after that of the yellow pigment and before that of the dark green pigment. Using reported inhibitors of DHN-melanin (tricyclazole and phthalide) and DOPA-melanin (tropolone and kojic acid) pathways on a set of conidial color mutants, we investigated the involvement of melanin biosynthesis in A. flavus conidial pigment formation. Results imply that both pathways have no bearing on conidial pigment biosynthesis of A. flavus.

Transcriptomic profiles of Aspergillus flavus CA42, a strain that produces small sclerotia, by decanal treatment and after recovery.

Aspergillus flavus is a ubiquitous saprophyte and is capable of producing many secondary metabolites including the carcinogenic aflatoxins. The A. flavus population that produces small sclerotia (S strain) has been implicated as the culprit for persistent aflatoxin contamination in field crops. We investigated how the plant volatile decanal, a C10 fatty aldehyde, affected the growth and development of the S strain A. flavus. Decanal treatment yielded fluffy variants lacking sclerotia and conidia and exhibiting a dosage-dependent radial colony growth. We used RNA-Seq analysis to examine transcriptomic changes caused by decanal and after removal of decanal. Mature sclerotia contained only 80% of the total transcripts detected in all samples in comparison to 94% for the decanal treated culture. Gene ontology (GO) analysis showed that decanal treatment increased expression of genes involved in oxidoreductase activity, cellular carbohydrate metabolism, alcohol metabolism and aflatoxin biosynthesis. The treatment affected cellular components associated with cell wall, and gene expression of glucanases, α-amylases, pectinesterase and peptidase required for its biosynthesis was increased. After decanal was removed, the culture resumed sclerotial production. Moreover, its GO terms significantly overlapped with those of the untreated culture; five of the enriched molecular functions, oxidoreductase activity, monooxygenase activity, electron carrier activity, heme binding, and iron binding were found in the untreated culture. The GO term of cellular component enriched was mainly integral protein constituents of the membrane. The results suggested that decanal halted development at the vegetative state rendering the fungus unable to produce conidia and sclerotia. The induced fluffy phenotype could be related to lower transcript abundance of flbB, flbD, and flbE but not to veA expression. Increased abundance of the laeA transcript in the treated culture correlated with early transcriptional activation of aflatoxin and kojic acid biosynthesis gene clusters. Expression profiles revealed subtle differences in timing of activation of the respective 55 secondary metabolite gene clusters.