Department of Biology, The Catholic University of America, Washington, DC, USA.
Microbial Pathogenesis Section, Laboratory of Parasitic Diseases, NIAID, NIH, Bethesda, Maryland, USA.
mBio. 2018 Oct 16;9(5):e01926-18. doi: 10.1128/mBio.01926-18.
and , the causative agents of anthrax and plague, respectively, are two of the deadliest pathogenic bacteria that have been used as biological warfare agents. Although Biothrax is a licensed vaccine against anthrax, no Food and Drug Administration-approved vaccine exists for plague. Here, we report the development of a dual anthrax-plague nanoparticle vaccine employing bacteriophage (phage) T4 as a platform. Using an assembly system, the 120- by 86-nm heads (capsids) of phage T4 were arrayed with anthrax and plague antigens fused to the small outer capsid protein Soc (9 kDa). The antigens included the anthrax protective antigen (PA) (83 kDa) and the mutated (mut) capsular antigen F1 and the low-calcium-response V antigen of the type 3 secretion system from (F1mutV) (56 kDa). These viral nanoparticles elicited robust anthrax- and plague-specific immune responses and provided complete protection against inhalational anthrax and/or pneumonic plague in three animal challenge models, namely, mice, rats, and rabbits. Protection was demonstrated even when the animals were simultaneously challenged with lethal doses of both anthrax lethal toxin and CO92 bacteria. Unlike the traditional subunit vaccines, the phage T4 vaccine uses a highly stable nanoparticle scaffold, provides multivalency, requires no adjuvant, and elicits broad T-helper 1 and 2 immune responses that are essential for complete clearance of bacteria during infection. Therefore, phage T4 is a unique nanoparticle platform to formulate multivalent vaccines against high-risk pathogens for national preparedness against potential bioterror attacks and emerging infections. Following the deadly anthrax attacks of 2001, the Centers for Disease Control and Prevention (CDC) determined that and that cause anthrax and plague, respectively, are two Tier 1 select agents that pose the greatest threat to the national security of the United States. Both cause rapid death, in 3 to 6 days, of exposed individuals. We engineered a virus nanoparticle vaccine using bacteriophage T4 by incorporating key antigens of both and into one formulation. Two doses of this vaccine provided complete protection against both inhalational anthrax and pneumonic plague in animal models. This dual anthrax-plague vaccine is a strong candidate for stockpiling against a potential bioterror attack involving either one or both of these biothreat agents. Further, our results establish the T4 nanoparticle as a novel platform to develop multivalent vaccines against pathogens of high public health significance.
炭疽和鼠疫分别是炭疽杆菌和鼠疫耶尔森菌这两种致命病原体的病原体,曾被用作生物战剂。虽然 Biothrax 是一种炭疽疫苗,但尚无经食品和药物管理局批准的鼠疫疫苗。在这里,我们报告了一种双重炭疽-鼠疫纳米颗粒疫苗的开发,该疫苗使用噬菌体(噬菌体)T4 作为平台。使用 组装系统,噬菌体 T4 的 120×86nm 头部(衣壳)排列有与炭疽和鼠疫抗原融合的小外壳蛋白 Soc(9kDa)。抗原包括炭疽保护性抗原(PA)(83kDa)和突变(mut)荚膜抗原 F1 和来自 (F1mutV)(56kDa)的 3 型分泌系统的低钙反应 V 抗原。这些病毒纳米颗粒引起了强烈的炭疽和鼠疫特异性免疫反应,并在三种动物挑战模型(即小鼠、大鼠和兔子)中提供了针对吸入性炭疽和/或肺鼠疫的完全保护。即使在同时用炭疽致死毒素和 CO92 细菌的致死剂量对动物进行挑战时,也证明了保护作用。与传统的亚单位疫苗不同,噬菌体 T4 疫苗使用高度稳定的纳米颗粒支架,提供多价性,不需要佐剂,并引发广泛的 T 辅助 1 和 2 免疫反应,这对于在感染期间完全清除细菌至关重要。因此,噬菌体 T4 是一种独特的纳米颗粒平台,可用于针对高风险病原体制定多价疫苗,以应对潜在的生物恐怖袭击和新发感染的国家准备工作。2001 年炭疽袭击事件发生后,疾病控制与预防中心(CDC)确定,分别导致炭疽和鼠疫的炭疽芽孢杆菌和鼠疫耶尔森菌是对美国国家安全构成最大威胁的两个一级选择剂。两者都会导致暴露个体在 3 至 6 天内迅速死亡。我们通过将两种病原体的关键抗原纳入一种制剂,使用噬菌体 T4 工程化了一种病毒纳米颗粒疫苗。该疫苗的两剂剂量在动物模型中提供了对吸入性炭疽和肺鼠疫的完全保护。这种双重炭疽-鼠疫疫苗是针对涉及这两种生物威胁剂之一或两者的潜在生物恐怖袭击进行储备的有力候选者。此外,我们的结果确立了 T4 纳米颗粒作为开发针对高公共卫生重要性病原体的多价疫苗的新型平台。
