P068 Inhibition of Candida glabrata biofilm using the combination of a novel antifungal cyclic lipopeptide and azole: An in vitro synergistic approach

Abstract

Poster session 1, September 21, 2022, 12:30 PM - 1:30 PMThe general feature of the biofilm is a densely packed microbial community with an extracellular matrix composed of polysaccharides and proteins. Candida glabrata was reported as the most biofilm-forming species responsible for causing virulent Candida infections among Candida non-albicans (CNA). Candida glabrata is the most azole-resistant species of all Candida species. The early and maturing biofilms enable the Candida cells to overcome the effects of azoles and exhibit higher drug resistance. Since simple azole mono-therapy rarely eradicates recalcitrant Candida biofilms, removal of the infected device becomes necessary for curing the infection.ObjectiveThe objective was to assess the biofilm inhibition effect of antifungal cyclic lipopeptide which has been purified by a multi-step process from the cell-free supernatant of Bacillus subtilis, and to analyze the synergistic activity of the purified lipopeptide lead compound designated as AF4 with the standard antifungal fluconazole using different concentrations.MethodsBriefly, cell-free supernatant was extracted using a solvent mixture and silica gel-based adsorption chromatography. The potential antifungal cyclic lipopeptide variant AF4 was extracted from the soil isolate B. subtilis by a multi-step purification process that involves reversed-phase HPLC and exhibited a wide-spectrum of anti-Candida activity. The XTT reduction assay was used for metabolically active cells after treatment with a combination of drugs, and crystal violet (CV) assay was performed to quantify the cell biomass. Scanning electron microscopy (SEM) and confocal laser scanning microscopy (CLSM) were used to analyze the biofilm morphology and architecture of the AF4 lipopeptide at (2xMIC) and fluconazole (8x-16xMIC)-treated biofilms. For confocal microscopy-based biofilm visualization, a combination of two different dyes was used. Extracellular polymeric substances were stained by concanavalin A-Alexa Fluor 488 conjugate and, the FUN- 1 fluorescent dye was used for staining the live biofilm-forming Candida cells. After capturing the Z-stack images in CLSM, the biomass (μm3/μm2), average thickness (μm), and roughness of the biofilm were analyzed by Comstat 2.1 software.ResultsThe AFST analysis showed that the MIC of the lead antifungal lipopeptide was 8 μg/mL against the C. glabrata planktonic cells. Adding the antifungal compound at higher MICs such as by 2-folds exhibited strong antibiofilm effect that significantly enhanced the synergistic antifungal activity of the fluconazole against C. glabrata biofilm formation. Synergistic effect of fluconazole at 8x-16xMIC with 2xMIC of the lead compound AF4 on C. glabrata 24 h maturing biofilm had increased significantly as revealed by the XTT and CV assays. The results confirmed ˃ 50% inhibition of the biofilm in both 6 h developmental and 24 h maturing biofilms in 8xMIC fluconazole plus 2xMIC AF4 while compared with fluconazole alone at the same concentration. The results from the XTT and, CV assays and SEM and CLSM (Fig. 1) suggest that the combinatorial treatments of the lead antifungal lipopeptide and fluconazole at varying concentrations have the potential of eradicating or nearly eradicating the maturing biofilm of CAN.ConclusionsThe combinatorial study was found effective in combating the biofilm formation. A correlation between metabolic activity and antifungal resistance in maturing biofilms has been found.