Design, synthesis and antifungal activities of novel triazole derivatives with selenium-containing hydrophobic side chains.

In this work, a series of novel 1,2,4-triazole derivatives with selenium-containing hydrophobic side chains were designed and synthesized based on the structure of lanosterol 14α-demethylase (CYP51). All compounds were characterized by HRMS, 1H NMR and 13C NMR. Then, their antifungal activities against eight human pathogenic fungi were evaluated in vitro by testing the minimal inhibitory concentrations. The results showed that nearly all tested compounds were found to be more potent against all tested fungal strains than control drug fluconazole. Further mechanism study demonstrated that the target compounds had fungal CYP51 inhibitory activity. Meanwhile, representative compounds revealed low cytotoxic effects toward mammalian cell lines. In addition, the docking results showed that the target compounds bound to Candida albicans CYP51 in a better pattern than fluconazole, especially in the narrow hydrophobic cleft. Overall, the novel 1,2,4-triazole derivatives with selenium-containing hydrophobic side chains can be further developed for the potential treatment of invasive fungal infections.

Discovery of novel selenium-containing azole derivatives as antifungal agents by exploiting the hydrophobic cleft of CYP51.

Herein, we report the design, synthesis and evaluation of a novel series of diselenide and selenide derivatives as potent antifungal agents by exploiting the hydrophobic cleft of CYP51. Among all synthesized compounds, the most potent compound B01 with low cytotoxic and hemolysis effect exhibited excellent activity against C.alb., C.gla., C.par. and C.kru., as well as selected fluconazole-resistant strains. Moreover, compound B01 could reduce the biofilm formation of the FCZ-resistant C.alb. Subsequently, metabolic stability assays using liver microsomes demonstrated that compound B01 showed good profiles of metabolic stability. With superior pharmacological profile, compound B01 was advanced into in vivo bioactivity evaluation. In a murine model of systemic C.alb. infection, compound B01 significantly reduced fungal load of kidneys. Furthermore, compound B01 revealed relatively low acute toxicity and subacute toxicity in mice. In addition, docking study performed into C.alb. CYP51, showed the binding mode between C.alb. CYP51 and compound B01. Collectively, diselenides compound B01 can be further developed for the potential treatment of invasive fungal infections.

Lead optimization generates selenium-containing miconazole CYP51 inhibitors with improved pharmacological profile for the treatment of fungal infections.

A series of selenium-containing miconazole derivatives were identified as potent antifungal drugs in our previous study. Representative compound A03 (MIC = 0.01 µg/mL against C.alb. 5314) proved efficacious in inhibiting the growth of fungal pathogens. However, further study showed lead compound A03 exhibited potential hemolysis, significant cytotoxic effect and unfavorable metabolic stability and was therefore modified to overcome these drawbacks. In this article, the further optimization of selenium-containing miconazole derivatives resulted in the discovery of similarly potent compound B17 (MIC = 0.02 µg/mL against C.alb. 5314), exhibiting a superior pharmacological profile with decreased rate of metabolism, cytotoxic effect and hemolysis. Furthermore, compound B17 showed fungicidal activity against Candida albicans and significant effects on the treatment of resistant Candida albicans infections. Meanwhile, compound B17 not only could reduce the ergosterol biosynthesis pathway by inhibiting CYP51, but also inhibited biofilm formation. More importantly, compound B17 also shows promising in vivo efficacy after intraperitoneal injection and the PK study of compound B17 was evaluated. In addition, molecular docking studies provide a model for the interaction between the compound B17 and the CYP51 protein. Overall, we believe that these selenium-containing miconazole compounds can be further developed for the potential treatment of fungal infections.