Amity Institute of Biotechnology, Amity University Haryana, Gurugram, Manesar, 122413, India.
Amity Institute of Biotechnology, Amity University Haryana, Gurugram, Manesar, 122413, India.
J Mycol Med. 2019 Sep;29(3):210-218. doi: 10.1016/j.mycmed.2019.07.003. Epub 2019 Jul 26.
The rise in fungal infections is alarming due to emergence of multidrug drug resistance (MDR). Hence elucidating novel drug targets to circumvent the problem of MDR warrants immediate attention. This study analyzes the effect of retrograde (RTG) signaling disruption on major MDR mechanisms and virulence of the human pathogenic fungal species Candida albicans.
Drug transporter activity was measured by rhodamine 6G (R6G) efflux. Membrane damage was studied by propidium iodide intake and ergosterol level determination. Cell wall effect was estimated by quantifying chitin levels and cell sedimentation rate. Biofilm formation was visualized by calcoflour white and crystal violet staining and measured by dry mass and MTT assay. Cell adherence to buccal epithelial cell was determined by trypan blue staining and MTT assay. Virulence was studied using nematode model Caenorhabditis elegans.
We demonstrated that mutant of transcription factor CaRTG3 leads to impaired efflux activity of ATP Binding Cassette (ABC) superfamily multidrug transporters. We further uncover that rtg3 mutant exhibited a disrupted membrane, decreased ergosterol levels and increased chitin content. Furthermore, RTG signaling disruption leads to inhibited biofilm formation and cell adherence to buccal epithelial cells. Lastly, rtg3 mutant displayed a reduced infectivity in C. elegans illustrating its vulnerability as antifungal target. Interestingly, all the abrogated phenotypes could be rescued in the revertant strain of rtg3 mutant.
Present study establishes a link between RTG signaling, drug efflux and biofilm formation and validates CaRTG3 as antifungal target. Intricate studies are needed to further understand and exploit this therapeutic opportunity.
由于多药耐药性(MDR)的出现,真菌感染的上升令人震惊。因此,阐明新的药物靶点以规避 MDR 问题需要立即引起关注。本研究分析了逆行(RTG)信号中断对主要 MDR 机制和人类致病性真菌白色念珠菌毒力的影响。
通过罗丹明 6G(R6G)外排测量药物转运体活性。通过摄取碘化丙啶和测定麦角固醇水平研究膜损伤。通过定量壳聚糖水平和细胞沉降率估计细胞壁效应。通过钙荧光白和结晶紫染色可视化生物膜形成,并通过干重和 MTT 测定测量。通过台盼蓝染色和 MTT 测定测定细胞对口腔上皮细胞的粘附。使用秀丽隐杆线虫 Caenorhabditis elegans 模型研究了毒力。
我们证明转录因子 CaRTG3 的突变导致 ATP 结合盒(ABC)超家族多药转运蛋白的外排活性受损。我们进一步发现 rtg3 突变体表现出膜破坏、麦角固醇水平降低和壳聚糖含量增加。此外,RTG 信号中断导致生物膜形成和细胞对口腔上皮细胞的粘附受到抑制。最后,rtg3 突变体在秀丽隐杆线虫中显示出降低的感染性,表明其作为抗真菌靶标易感性。有趣的是,rtg3 突变体的所有破坏表型都可以在回复突变株中得到挽救。
本研究建立了 RTG 信号、药物外排和生物膜形成之间的联系,并验证了 CaRTG3 作为抗真菌靶标。需要进行深入研究以进一步了解和利用这一治疗机会。
