Aspergillus terreus sectorization: a morphological phenomenon shedding light on amphotericin B resistance mechanism.

Prolonged cultivation of certain filamentous fungi, including Aspergillus terreus, on drug-free medium leads to degeneration and morphological heterogeneity, marked by the emergence of fluffy mycelium-type sectors. This phenomenon may indicate alterations in antifungal susceptibility profiles (particularly to amphotericin B (AmB) in A. terreus), as well as reductions or losses in conidiation, sexuality, secondary metabolite production, and/or virulence. In the present study, various characteristics of an AmB-resistant wild-type (WT) strain and its AmB-susceptible sectorized derivative (ATSec) were characterized. Compared to WT, ATSec exhibited increased susceptibility to AmB, reduced sporulation, and comparable sterol contents and virulence in Galleria mellonella. To elucidate the genes involved in AmB resistance, gene expression levels were compared between WT and ATSec with and without AmB treatment. The expression of P-type ATPase-related genes, which are implicated in membrane composition changes and consequently in AmB resistance, was significantly higher in the WT strain compared to ATSec. Moreover, the up-regulation of genes involved in the biosynthesis of polyketides-a diverse group of secondary metabolites-was higher in WT compared to ATSec, with a significant number of these genes also carrying at least one mutation. The findings of this study indicate that P-type ATPases may significantly be involved in AmB susceptibility and resistance observed in ATSec and WT strains. Additionally, mutations in polyketide synthase genes in ATSec may contribute to the phenotypic alterations associated with the sectorized phenotype.

Importance: Prolonged cultivation of certain filamentous fungi, including Aspergillus terreus, on drug-free medium leads to degeneration and morphological heterogeneity, marked by the emergence of fluffy mycelium-type sectors. This phenomenon may indicate alterations in antifungal susceptibility profiles (particularly to amphotericin B (AmB) in A. terreus), as well as reductions or losses in conidiation, sexuality, secondary metabolite production, and/or virulence. In the present study, various characteristics of an AmB-resistant wild-type strain (WT) and its AmB-susceptible sectorized derivative (ATSec) were characterized. Compared to WT, ATSec exhibited increased susceptibility to AmB, reduced sporulation, and comparable sterol contents and virulence in Galleria mellonella. To elucidate the genes involved in AmB resistance, gene expression levels were compared between WT and ATSec with and without AmB treatment. The expression of P-type ATPase-related genes, which are implicated in membrane composition changes and consequently in AmB resistance, was significantly higher in the WT strain compared to ATSec. Moreover, the up-regulation of genes involved in the biosynthesis of polyketides - a diverse group of secondary metabolites - was higher in WT compared to ATSec, with a significant number of these genes also carrying at least one mutation. The findings of this study indicate that P-type ATPases may significantly be involved in AmB susceptibility and resistance observed in ATSec and WT strains. Additionally, mutations in polyketide synthase genes in ATSec may contribute to the phenotypic alterations associated with the sectorized phenotype.