Abstract
Rapid responses to environmental changes are essential for maintaining fitness. In pathogenic fungi such as the dermatophyte Trichophyton interdigitale, appropriate responses to environmental shifts determine successful infection. Transcriptional regulation and alternative splicing (AS) are key modulators of fungal adaptation and pathogenesis. Here, we validated the role of the transcription factor PacC in coordinating AS in T. interdigitale grown in infection-mimicking medium. RNA-seq analysis of a ΔpacC mutant revealed a predominance of intron retention events, mainly involving introns 1 and 2, indicating defective splicing and potential nonsense-mediated decay of genes related to ion transport, metabolism, and genome maintenance. These alterations compromised energy balance, ergosterol biosynthesis, and cellular homeostasis. PacC-dependent AS generated alternative isoforms of cytoskeletal and metabolic proteins, including myosin-1 and a GH3 β-glucosidase, potentially modulating enzymatic activity, metabolic burden, and cell wall remodeling during infection. Exon-skipping in the chromatin remodeler RSC1 suggests PacC involvement in epigenetic regulation under host-mimicking conditions. Transmission electron microscopy revealed possible Woronin bodies, cytoplasmic disruption, and cell wall thinning in the mutant. Overall, PacC integrates transcriptional and post-transcriptional regulation to promote adaptation, survival, and virulence, highlighting AS as a regulatory layer linking environmental sensing to metabolic and epigenetic plasticity in pathogenic fungi.