The emergence of antifungal resistance calls for continued research efforts to better guide healthcare providers in treatment selection and outcomes. Unlike bacterial infections, treatment of superficial fungal infections is mainly limited to allylamines (terbinafine) and azoles (itraconazole). Here, we aim to update our current understanding of resistance mechanisms against allylamine and azole antifungals in the Trichophyton genus. Resistance development has been demonstrated in vitro by challenging Trichophyton isolates with allylamines or azoles at levels below the minimum inhibitory concentration (MIC), which corroborates the observation of clinical resistance. Frequently reported mechanisms of resistance include: (I) Alterations of the drug target by single-nucleotide variations (SNVs) of the SQLE/ERG1 and ERG11 genes
in particular, SQLE SNVs (Leu393Phe, Leu393Ser, and Phe397Leu) have been frequently reported in isolates with high terbinafine MICs
(II) overexpression of the target enzyme for azoles (ERG11) and downstream genes in the ergosterol biosynthesis pathway can decrease the effective drug concentration as well as prevent the depletion of ergosterol and the accumulation of toxic sterol intermediates
(III) the up-regulation of drug efflux channels-belonging to the ABC superfamily (PDR1, MDR2, MDR3, MDR4), MFS superfamily (MFS1), or Pma1 (plasma membrane ATPase 1)-can reduce the effective concentrations of terbinafine and azoles. The possibility of multidrug resistance has been shown in Trichophyton strains, of both human and animal origins, harboring multiple resistance mechanisms (e.g., target alteration/overexpression and drug efflux channels). Tackling the issue of antifungal resistance will require an integrated approach with multidisciplinary efforts including surveillance initiatives and antifungal stewardship programs. However, these efforts are hampered by the current limited accessibility of antifungal susceptibility testing as well as the limited choice of antifungals available in routine practice. A better understanding of resistance mechanisms could help develop targeted, molecular-based assays.