Targeted regulation of sterol biosynthesis genes according to perturbations in ergosterol biosynthesis in fungi.

INTRODUCTION: The synthesis and regulation of ergosterol are vital for fungal growth and stress adaptation. While ergosterol-mediated feedback regulation is a recognized mechanism controlling sterol biosynthesis in fungi, prior research suggests the presence of additional regulatory mechanisms. However, the specifics of the alternative regulatory mechanisms have not been systematically investigated. OBJECTIVES: We proposed that a regulatory network is likely to discern disturbances in sterol biosynthesis and trigger responses accordingly. This study aimed to validate the hypothesis and investigate the regulatory mechanisms. METHODS: Quantitative Real-time PCR and HPLC-MS/MS were used to explore and compare the regulation of sterol biosynthesis in different fungi. Key transcription factors involved in the alternative regulatory mechanism in Neurospora crassa were identified by phenotypic profiling of a transcription factor mutant library. ChIP-qPCR, fluorescence confocal imaging, RNA sequencing, and gene set enrichment analysis (GSEA) were used to reveal the mechanism of each transcription factor. RESULTS: Unlike the canonical ergosterol-mediated feedback regulation in fungi like C. neoformans, our study demonstrated that the inhibitions of ergosterol biosynthesis at specific steps triggered distinct transcriptional responses of erg genes in fungi, including N. crassa and Aspergillus fumigatus. In N. crassa, the responses were orchestrated by different transcription factors. Specifically, the inhibition of ERG24 and ERG2 activated transcription factors SAH-2 and AtrR, resulting in the upregulation of erg24, erg2, erg25, and erg3. Furthermore, the inhibition of ERG11/CYP51 activated transcription factor NcSR, leading to the upregulation of erg11 and erg6. Phenotypic profiles of mutants of various N. crassa erg genes and the aforementioned transcription factors implied that the targeted regulation of ergosterol biosynthesis could fortify fungal viability within complex habitats. CONCLUSION: Our study reveals a novel regulatory mechanism in fungi: targeted upregulation of specific sterol biosynthesis genes in response to given perturbations in ergosterol biosynthesis, exhibiting a higher degree of precision and sophistication in sterol biosynthesis regulation.