School of Chemistry and Molecular Biosciences, The University of Queensland, St Lucia, Queensland 4072, Australia.
Institute for Molecular Biosciences, The University of Queensland, St Lucia, Queensland 4072, Australia.
ACS Infect Dis. 2023 Aug 11;9(8):1570-1581. doi: 10.1021/acsinfecdis.3c00159. Epub 2023 Jul 24.
Untreated group A (GAS) can lead to a range of life-threatening diseases, including rheumatic heart disease. To date, no therapeutic or prophylactic vaccines are commercially available to treat or prevent GAS infection. Development of a peptide-based subunit vaccine offers a promising solution, negating the safety issues of live-attenuated or inactive vaccines. Subunit vaccines administer small peptide fragments (antigens), which are typically poorly immunogenic. Therefore, these peptide antigens require formulation with an immune stimulant and/or vaccine delivery platform to improve their immunogenicity. We investigated polyelectrolyte complexes (PECs) and polymer-coated liposomes as self-adjuvanting delivery vehicles for a GAS B cell peptide epitope conjugated to a universal T-helper epitope and a synthetic toll-like receptor 2-targeting moiety lipid core peptide-1 (LCP-1). A structure-activity relationship of cationic PEC vaccines containing different external PEI-coatings (poly(ethylenimine); 10 kDa PEI, 25 kDa PEI, and a synthetic mannose-functionalized 25 kDa PEI) formed vaccines PEC-1, PEC-2, and PEC-3, respectively. All three PEC vaccines induced J8-specific systemic immunoglobulin G (IgG) antibodies when administered intranasally to female BALB/c mice without the use of additional adjuvants. Interestingly, PEC-3 induced the highest antibody titers among all tested vaccines, with the ability to effectively opsonize two clinically isolated GAS strains. A comparative study of PEC-2 and PEC-3 with liposome-based delivery systems was performed subcutaneously. LCP-1 was incorporated into a liposome formulation (DPPC, DPPG and cholesterol), and the liposomes were externally coated with PEI (25 kDa; Lip-2) or mannosylated PEI (25 kDa; Lip-3). All liposome vaccines induced stronger humoral immune responses compared to their PEC counterparts. Notably, sera of mice immunized with Lip-2 and Lip-3 produced significantly higher opsonic activity against clinically isolated GAS strains compared to the positive control, P25-J8 emulsified with the commercial adjuvant, complete Freund's adjuvant (CFA). This study highlights the capability of a PEI-liposome system to act as a self-adjuvanting vehicle for the delivery of GAS peptide antigens and protection against GAS infection.
未经治疗的 A 组链球菌(GAS)可导致一系列危及生命的疾病,包括风湿性心脏病。迄今为止,尚无治疗或预防 GAS 感染的商业性治疗或预防性疫苗。开发基于肽的亚单位疫苗提供了一个有前途的解决方案,可以规避减毒活疫苗或非活性疫苗的安全性问题。亚单位疫苗给予小肽片段(抗原),这些抗原通常免疫原性差。因此,这些肽抗原需要与免疫刺激剂和/或疫苗传递平台联合使用,以提高其免疫原性。我们研究了聚电解质复合物(PEC)和聚合物包被的脂质体作为自佐剂的传递载体,用于将 GAS B 细胞肽表位与通用 T 辅助表位和合成的 Toll 样受体 2 靶向部分脂质核心肽-1(LCP-1)缀合。含有不同外部 PEI 涂层(聚(乙二胺);10 kDa PEI、25 kDa PEI 和合成的甘露糖功能化 25 kDa PEI)的阳离子 PEC 疫苗的构效关系分别形成疫苗 PEC-1、PEC-2 和 PEC-3。当以鼻腔内途径给予雌性 BALB/c 小鼠时,所有三种 PEC 疫苗均无需使用额外佐剂即可诱导 J8 特异性系统性免疫球蛋白 G(IgG)抗体。有趣的是,与所有测试的疫苗相比,PEC-3 诱导的抗体滴度最高,能够有效地调理两种临床分离的 GAS 菌株。对 PEC-2 和 PEC-3 与基于脂质体的传递系统的比较研究是皮下进行的。LCP-1 被掺入脂质体配方(DPPC、DPPG 和胆固醇)中,并且脂质体被外部涂覆有 PEI(25 kDa;Lip-2)或甘露糖化的 PEI(25 kDa;Lip-3)。与它们的 PEC 对应物相比,所有脂质体疫苗均诱导更强的体液免疫反应。值得注意的是,用 Lip-2 和 Lip-3 免疫的小鼠的血清对临床分离的 GAS 菌株产生的调理活性明显高于阳性对照,即用商业佐剂完全弗氏佐剂(CFA)乳化的 P25-J8。这项研究强调了 PEI-脂质体系统作为 GAS 肽抗原传递的自佐剂载体的能力,并提供了针对 GAS 感染的保护。
