Department of Genetics, University of Georgia, Athens, Georgia, USA.
Department of Microbiology, University of Georgia, Athens, Georgia, USA.
mSphere. 2019 Feb 13;4(1):e00025-19. doi: 10.1128/mSphere.00025-19.
species cause pulmonary invasive aspergillosis resulting in nearly 100,000 deaths each year. Patients at the greatest risk of developing life-threatening aspergillosis have weakened immune systems and/or various lung disorders. Patients are treated with antifungals such as amphotericin B (AmB), caspofungin acetate, or triazoles (itraconazole, voriconazole, etc.), but these antifungal agents have serious limitations due to lack of sufficient fungicidal effect and human toxicity. Liposomes with AmB intercalated into the lipid membrane (AmB-LLs; available commercially as AmBisome) have severalfold-reduced toxicity compared to that of detergent-solubilized drug. However, even with the current antifungal therapies, 1-year survival among patients is only 25 to 60%. Hence, there is a critical need for improved antifungal therapeutics. Dectin-1 is a mammalian innate immune receptor in the membrane of some leukocytes that binds as a dimer to beta-glucans found in fungal cell walls, signaling fungal infection. Using a novel protocol, we coated AmB-LLs with Dectin-1's beta-glucan binding domain to make DEC-AmB-LLs. DEC-AmB-LLs bound rapidly, efficiently, and with great strength to and to and , highly divergent fungal pathogens of global importance. In contrast, untargeted AmB-LLs and bovine serum albumin (BSA)-coated BSA-AmB-LLs showed 200-fold-lower affinity for fungal cells. DEC-AmB-LLs reduced the growth and viability of an order of magnitude more efficiently than untargeted control liposomes delivering the same concentrations of AmB, in essence decreasing the effective dose of AmB. Future efforts will focus on examining pan-antifungal targeted liposomal drugs in animal models of disease. The fungus causes pulmonary invasive aspergillosis resulting in nearly 100,000 deaths each year. Patients are often treated with antifungal drugs such as amphotericin B (AmB) loaded into liposomes (AmB-LLs), but all antifungal drugs, including AmB-LLs, have serious limitations due to human toxicity and insufficient fungal cell killing. Even with the best current therapies, 1-year survival among patients with invasive aspergillosis is only 25 to 60%. Hence, there is a critical need for improved antifungal therapeutics. Dectin-1 is a mammalian protein that binds to beta-glucan polysaccharides found in nearly all fungal cell walls. We coated AmB-LLs with Dectin-1 to make DEC-AmB-LLs. DEC-AmB-LLs bound strongly to fungal cells, while AmB-LLs had little affinity. DEC-AmB-LLs killed or inhibited 10 times more efficiently than untargeted liposomes, decreasing the effective dose of AmB. Dectin-1-coated drug-loaded liposomes targeting fungal pathogens have the potential to greatly enhance antifungal therapeutics.
种类导致肺部侵袭性曲霉菌病,导致每年近 10 万人死亡。患有生命威胁性曲霉菌病风险最高的患者免疫系统较弱和/或患有各种肺部疾病。患者接受抗真菌药物治疗,如两性霉素 B(AmB)、卡泊芬净醋酸酯或三唑类(伊曲康唑、伏立康唑等),但由于缺乏足够的杀菌作用和人体毒性,这些抗真菌药物存在严重的局限性。两性霉素 B 插入脂质膜的脂质体(AmB-LL;市售的 AmBisome)与去污剂溶解的药物相比,毒性降低了几倍。然而,即使采用目前的抗真菌疗法,患者的 1 年生存率也只有 25%至 60%。因此,迫切需要改进的抗真菌治疗方法。Dectin-1 是一种存在于某些白细胞膜中的哺乳动物先天免疫受体,它以二聚体的形式与真菌细胞壁中的β-葡聚糖结合,从而发出真菌感染的信号。我们使用一种新的方案,用 Dectin-1 的β-葡聚糖结合域包被 AmB-LL,制成 DEC-AmB-LL。DEC-AmB-LL 快速、高效、强度极大地与 和 以及高度分化的真菌病原体结合,这些真菌病原体是具有全球重要性的病原体。相比之下,未靶向的 AmB-LL 和牛血清白蛋白(BSA)包被的 BSA-AmB-LL 对真菌细胞的亲和力低 200 倍。与未靶向的对照脂质体相比,DEC-AmB-LL 更有效地降低了 的生长和活力,实质上降低了 AmB 的有效剂量。未来的研究将集中在疾病动物模型中研究泛抗真菌靶向脂质体药物。 真菌 导致肺部侵袭性曲霉菌病,导致每年近 10 万人死亡。患者通常接受两性霉素 B(AmB)负载的脂质体(AmB-LL)等抗真菌药物治疗,但由于人体毒性和对真菌细胞杀伤不足,所有抗真菌药物,包括 AmB-LL,都存在严重的局限性。即使采用目前最好的治疗方法,侵袭性曲霉菌病患者的 1 年生存率也只有 25%至 60%。因此,迫切需要改进的抗真菌治疗方法。Dectin-1 是一种哺乳动物蛋白,与几乎所有真菌细胞壁中的β-葡聚糖多糖结合。我们用 Dectin-1 包被 AmB-LL,制成 DEC-AmB-LL。DEC-AmB-LL 与真菌细胞紧密结合,而 AmB-LL 则没有亲和力。与未靶向的脂质体相比,DEC-AmB-LL 杀死或抑制 的效率高 10 倍,降低了 AmB 的有效剂量。针对真菌病原体的 Dectin-1 包被载药脂质体有可能极大地增强抗真菌治疗。
