RESUMO
Objective:To evaluate the effect of microevolution on phenotypes and drug resistance of the Trichosporon asahii biofilm. Methods:The standard strain of Trichosporon asahii was obtained from the Fungal Biodiversity Institute of the Royal Netherlands Academy of Arts and Sciences, the fluconazole-sensitive primary strain (TO) of Trichosporon asahii was isolated from a case of trichosporonosis diagnosed in the Department of Dermatology, the Seventh Medical Center of Chinese People′s Liberation Army General Hospital in 2000, and the fluconazole-resistant evolved strain (TEVO) of Trichosporon asahii was isolated from the above patient in 2014. Biofilms of the above-mentioned strains were formed in vitro, and tetrazolium salt XTT reduction assay was performed to evaluate growth kinetics of the Trichosporon asahii biofilm, and laser scanning confocal microscopy to determine the thickness of the biofilm; the sessile minimum inhibitory concentrations (SMICs) of fluconazole, itraconazole and voriconazole against the biofilms at different growth stages were determined in vitro for the evaluation of the resistance of the biofilms. One-way analysis of variance was used for comparisons among multiple groups, and Hartley test for testing homogeneity of variance. If the variance was homogeneous, least significant difference test was used for multiple comparisons; if the variance was heterogeneous, Tamhane′ T2 test was used for multiple comparisons. Results:In the adhesion (0 h) and formation stages (4- 24 hours) of the Trichosporon asahii biofilm, the metabolic activity of the evolved strain TEVO was the weakest (adhesion stage: F = 35.705, P < 0.001; formation stage: F = 15.042, P < 0.001) . At 48 hours after adhesion, the biofilms matured, and the TO strain showed the weakest metabolic activity ( F = 10.985, P < 0.001) . In the maturation stage, the biofilm thickness of the TEVO strain (26.1 ± 1.18 μm) was significantly higher than that of the TO strain (22.8 ± 1.73 μm, P = 0.001) , but significantly lower than that of the standard strain (29.5 ± 1.28 μm, P = 0.001) . As drug susceptibility testing showed, the SMICs of azole antifungal agents against the TEVO strain were higher than those against the TO strain in the adhesion and formation stages of the Trichosporon asahii biofilm, and the SMICs of azole antifungal agents against the biofilms of the 3 strains of Trichosporon asahii were all over 1 024 mg/L in the maturation stage of the biofilm. Conclusion:Under the dual pressure of host environment and antifungal drugs, adaptive changes took place in the phenotypes of the Trichosporon asahii biofilm with an increase in the resistance to azole antifungal drugs.
RESUMO
Recently, biochemical and genomic studies have specified new classification methods and renamed Propionibacterium acnes as Cutibacterium acnes ( C. acnes) to better study its phylotypes and distinguish it from other Propionibacterium species . C. acnes, an important commensal bacterium in human skin, is involved in maintaining skin health, and can also turn into an opportunistic pathogen causing acne vulgaris. Latest studies have showed that the balance between different phylotypes of C. acnes and its interaction with other microorganisms play a key role in the occurrence and development of acne vulgaris. This review summarizes correlations between C. acnes phylotypes and acne vulgaris, as well as antimicrobial susceptibility and interaction with other microorganism of C. acnes.