The cyclic lipopeptide micafungin induces rupture of isolated mitochondria by reprograming the mitochondrial inner membrane anion channel.

The antifungal activity of the drug micafungin, a cyclic lipopeptide that interacts with membrane proteins, may involve inhibition of fungal mitochondria. In humans, mitochondria are spared by the inability of micafungin to cross the cytoplasmic membrane. Using isolated mitochondria, we find that micafungin initiates the uptake of salts, causing rapid swelling and rupture of mitochondria with release of cytochrome c. The inner membrane anion channel (IMAC) is altered by micafungin to transfer both cations and anions. We propose that binding of anionic micafungin to IMAC attracts cations into the ion pore for the rapid transfer of ion pairs.

Biological Properties and Analytical Methods for Micafungin: A Critical Review.

Micafungin is characterized as one of the most active available drugs for candidemia treatment; however, their use is also associated in prophylaxis protocols in cases of invasive fungal infections. The use of this drug is widely appreciated in the medical field due to be the most active echinocandin available for invasive fungal infections. In order to provide important parameters related to the chemical, physical, biological and therapeutic characteristics, this review article gathers important research results that demonstrate the biological potential of this drug, as well as to present analytical methods that can be used to determine the antifungal potential and a monitoring of administered dosages. Important studies about the methods most commonly used in biological activity evaluation and determination/quantification by analytical methods are provided in this review article. With the data provided, the scientific community will have the possibility to choose the analytical methods and biological that can be employed in clinical and scientific research to provide greater safety and reliability of the results to be found.

Cutibacterium acnes protects Candida albicans from the effect of micafungin in biofilms.

The aim of this study was to investigate the ability of Candida albicans and Cutibacterium acnes to grow together as a polymicrobial biofilm in vitro and to examine the influence of C. acnes on C. albicans susceptibility to micafungin. Mature 72-h-old single-species biofilms of C. albicans and polymicrobial biofilms involving both C. albicans and C. acnes were formed in brain-heart infusion and were observed by scanning electronic microscopy. Moreover, 24-h-old single-species and polymicrobial biofilms were treated for 24 h with micafungin (concentrations ranging from 0.75 mg/L to 12 mg/L) and the antibiofilm activity of micafungin was evaluated on fungal cells by flow cytometry following addition of propidium iodide. The results showed that C. albicans and C. acnes formed a polymicrobial biofilm in the tested conditions and that bacterial presence did not modify fungal viability. Micafungin induced a fungal mortality rate ranging from 70-95% in C. albicans single-species biofilms and from 35-40% in C. acnes-C. albicans polymicrobial biofilms. Mortality induced by micafungin was significantly reduced (P < 0.05 for micafungin at 6 mg/L and P < 0.001 for other micafungin concentrations) in polymicrobial conditions compared with single-species biofilms. In conclusion, this study showed that C. albicans and C. acnes are able to form polymicrobial biofilms together in a synergistic way and that this organisation increases yeast resistance to micafungin.