Laboratório de Estudos Avançados de Microrganismos Emergentes E Resistentes (LEAMER), Departamento de Microbiologia Geral, Instituto de Microbiologia Paulo de Góes (IMPG), Universidade Federal Do Rio de Janeiro (UFRJ), Rio de Janeiro, RJ, 21941-902, Brazil.
Programa de Pós-Graduação Em Bioquímica (PPGBq), Instituto de Química, Universidade Federal Do Rio de Janeiro (UFRJ), Rio de Janeiro, RJ, 21941-909, Brazil.
Biometals. 2024 Oct;37(5):1237-1253. doi: 10.1007/s10534-024-00605-1. Epub 2024 Jun 14.
Candida species undeniably rank as the most prevalent opportunistic human fungal pathogens worldwide, with Candida albicans as the predominant representative. However, the emergence of non-albicans Candida species (NACs) has marked a significant shift, accompanied by rising incidence rates and concerning trends of antifungal resistance. The search for new strategies to combat antifungal-resistant Candida strains is of paramount importance. Recently, our research group reported the anti-Candida activity of a coordination compound containing copper(II) complexed with theophylline (theo) and 1,10-phenanthroline (phen), known as "CTP" - Cu(theo)phen(HO).5HO. In the present work, we investigated the mechanisms of action of CTP against six medically relevant, antifungal-resistant NACs, including C. auris, C. glabrata, C. haemulonii, C. krusei, C. parapsilosis and C. tropicalis. CTP demonstrated significant efficacy in inhibiting mitochondrial dehydrogenases, leading to heightened intracellular reactive oxygen species production. CTP treatment resulted in substantial damage to the plasma membrane, as evidenced by the passive incorporation of propidium iodide, and induced DNA fragmentation as revealed by the TUNEL assay. Scanning electron microscopy images of post-CTP treatment NACs further illustrated profound alterations in the fungal surface morphology, including invaginations, cavitations and lysis. These surface modifications significantly impacted the ability of Candida cells to adhere to a polystyrene surface and to form robust biofilm structures. Moreover, CTP was effective in disassembling mature biofilms formed by these NACs. In conclusion, CTP represents a promising avenue for the development of novel antifungals with innovative mechanisms of action against clinically relevant NACs that are resistant to antifungals commonly used in clinical settings.
念珠菌属无疑是全球最普遍的机会性人类真菌病原体,其中白色念珠菌是主要代表。然而,非白念珠菌属念珠菌(NAC)的出现标志着一个重大转变,伴随着发病率的上升和令人担忧的抗真菌耐药趋势。寻找新的策略来对抗抗真菌耐药的念珠菌菌株至关重要。最近,我们的研究小组报道了一种含有铜(II)与茶碱(theo)和 1,10-菲啰啉(phen)配位的配合物的抗念珠菌活性,称为“CTP”-Cu(theo)phen(HO)。5HO。在本工作中,我们研究了 CTP 对六种与医学相关的抗真菌耐药 NAC 的作用机制,包括 C. auris、C. glabrata、C. haemulonii、C. krusei、C. parapsilosis 和 C. tropicalis。CTP 对线粒体脱氢酶具有显著的抑制作用,导致细胞内活性氧的产生增加。CTP 处理导致质膜严重损伤,如碘化丙啶的被动掺入所证明的,并且如 TUNEL 测定所揭示的诱导 DNA 片段化。经 CTP 处理后的 NAC 的扫描电子显微镜图像进一步说明了真菌表面形态的深刻变化,包括内陷、空化和溶解。这些表面修饰显著影响了念珠菌细胞粘附到聚苯乙烯表面和形成坚固生物膜结构的能力。此外,CTP 有效地分解了这些 NAC 形成的成熟生物膜。总之,CTP 代表了开发具有创新作用机制的新型抗真菌药物的有前途的途径,这些药物针对临床上相关的、对临床常用抗真菌药物耐药的 NAC。
