University of Notre Dame, Department of Biological Sciences, Notre Dame, Indiana, USA.
University of Notre Dame, Eck Institute for Global Health, Notre Dame, Indiana, USA.
Microbiol Spectr. 2022 Dec 21;10(6):e0265822. doi: 10.1128/spectrum.02658-22. Epub 2022 Nov 7.
Leishmaniasis, a category I neglected tropical disease, is a group of diseases caused by the protozoan parasite species with a wide range of clinical manifestations. Current treatment options can be highly toxic and expensive, with drug relapse and the emergence of resistance. Bacteriocins, antimicrobial peptides ribosomally produced by bacteria, are a relatively new avenue for potential antiprotozoal drugs. Particular interest has been focused on enterocin AS-48, with previously proven efficacy against protozoan species, including spp. Sequential characterization of enterocin AS-48 has illustrated that antibacterial bioactivity is preserved in linearized, truncated forms; however, minimal domains of AS-48 bacteriocins have not yet been explored against protozoans. Using rational design techniques to improve membrane penetration activity, we designed peptide libraries using the minimal bioactive domain of AS-48 homologs. Stepwise changes to the charge (), hydrophobicity (), and hydrophobic dipole moment (μ) were achieved through lysine and tryptophan substitutions and the inversion of residues within the helical wheel, respectively. A total of 480 synthetic peptide variants were assessed for antileishmanial activity against Leishmania donovani. One hundred seventy-two peptide variants exhibited 50% inhibitory concentration (IC) values below 20 μM against axenic amastigotes, with 60 peptide variants in the nanomolar range. Nine peptide variants exhibited potent activity against intracellular amastigotes with observed IC values of <4 μM and limited host cell toxicity, making them worthy of further drug development. Our work demonstrates that minimal bioactive domains of naturally existing bacteriocins can be synthetically engineered to increase membrane penetration against spp. with minimal host cytotoxicity, holding the promise of novel, potent antileishmanial therapies. Leishmaniasis is a neglected tropical disease caused by protozoan parasites of the genus . There are three primary clinical forms, cutaneous, mucocutaneous, and visceral, with visceral leishmaniasis being fatal if left untreated. Current drug treatments are less than ideal, especially in resource-limited areas, due to the difficult administration and treatment regimens as well as the high cost and the emergence of drug resistance. Identifying potent antileishmanial agents is of the utmost importance. We utilized rational design techniques to synthesize enterocin AS-48 and AS-48-like bacteriocin-based peptides and screened these peptides against L. donovani using a fluorescence-based phenotypic assay. Our results suggest that bacteriocins, specifically these rationally designed AS-48-like peptides, are promising leads for further development as antileishmanial drugs.
利什曼病是一种 I 类被忽视的热带病,是一组由原生动物寄生虫引起的疾病,临床表现广泛。目前的治疗选择可能具有高度的毒性和昂贵,药物复发和耐药性的出现。细菌素是细菌核糖体产生的抗微生物肽,是一种具有潜在抗原生动物药物作用的相对较新途径。人们特别关注肠菌素 AS-48,因为它以前已被证明对原生动物物种有效,包括 spp. 肠菌素 AS-48 的连续表征表明,线性化、截断形式保留了抗菌生物活性;然而,AS-48 细菌素的最小结构域尚未针对原生动物进行探索。我们使用合理的设计技术来提高膜穿透活性,使用 AS-48 同源物的最小生物活性结构域设计了肽文库。通过赖氨酸和色氨酸取代以及分别在螺旋轮内反转残基,实现了电荷()、疏水性()和疏水性偶极矩(μ)的逐步变化。总共评估了 480 种合成肽变体对利什曼原虫属的抗利什曼原虫活性。172 种肽变体对无细胞阿米巴虫的 50%抑制浓度(IC)值低于 20μM,60 种肽变体的 IC 值在纳摩尔范围内。9 种肽变体对细胞内阿米巴虫表现出很强的活性,观察到的 IC 值低于 4μM,宿主细胞毒性有限,值得进一步开发药物。我们的工作表明,天然存在的细菌素的最小生物活性结构域可以通过合成工程来增加对 spp. 的膜穿透性,同时对宿主细胞的毒性最小,为新型、有效的抗利什曼原虫疗法提供了希望。 利什曼病是一种由原生动物寄生虫引起的被忽视的热带病,属于 属。有三种主要的临床形式,皮肤、粘膜皮肤和内脏,内脏利什曼病如果不治疗是致命的。由于给药和治疗方案困难、成本高以及耐药性的出现,目前的药物治疗并不理想,尤其是在资源有限的地区。确定有效的抗利什曼原虫药物是最重要的。我们利用合理的设计技术合成肠菌素 AS-48 和 AS-48 类似的细菌素肽,并使用基于荧光的表型测定法对 L. donovani 进行了这些肽的筛选。我们的结果表明,细菌素,特别是这些经过合理设计的 AS-48 类似肽,是作为抗利什曼原虫药物进一步开发的有希望的先导物。
