Precision Vaccines Program, Boston Children's Hospital, Boston, MA, USA; Harvard Medical School, Boston, MA, USA.
Institute of Clinical Research, University of Southern Denmark and Odense University Hospital, Odense, Denmark; Bandim Health Project, INDEPTH Network, Bissau, Guinea-Bissau.
Vaccine. 2022 Mar 8;40(11):1534-1539. doi: 10.1016/j.vaccine.2021.03.092. Epub 2021 Apr 15.
The BCG vaccine has long been recognized for reducing the risk to suffer from infectious diseases unrelated to its target disease, tuberculosis. Evidence from human trials demonstrate substantial reductions in all-cause mortality, especially in the first week of life. Observational studies have identified an association between BCG vaccination and reduced risk of respiratory infectious disease and clinical malaria later in childhood. The mechanistic basis for these pathogen-agnostic benefits, also known as beneficial non-specific effects (NSE) of BCG have been attributed to trained immunity, or epigenetic reprogramming of hematopoietic cells that give rise to innate immune cells responding more efficiently to a broad range of pathogens. Furthermore, within trained immunity, the focus so far has been on enhanced monocyte function. However, polymorphonuclear cells, namely neutrophils, are not only major constituents of the hematopoietic compartment but functionally as well as numerically represent a prominent component of the immune system. The beneficial NSEs of the BCG vaccine on newborn sepsis was recently demonstrated to be driven by a BCG-mediated numeric increase of neutrophils (emergency granulopoiesis (EG)). And experimental evidence in animal models suggest that BCG can modulate neutrophil function as well. Together, these findings suggest that neutrophils are crucial to at least the immediate beneficial NSE of the BCG vaccine. Efforts to uncover the full gamut of mechanisms underpinning the broad beneficial effects of BCG should therefore include neutrophils at the forefront.
卡介苗疫苗长期以来被认为可以降低感染与其目标疾病无关的传染病的风险。人体试验的证据表明,卡介苗疫苗可显著降低全因死亡率,尤其是在生命的第一周。观察性研究表明,卡介苗接种与降低儿童期呼吸道传染病和临床疟疾的风险之间存在关联。这些针对病原体的益处的机制基础,也称为卡介苗的有益非特异性效应(NSE),归因于训练有素的免疫,或造血细胞的表观遗传重编程,导致先天免疫细胞更有效地对广泛的病原体做出反应。此外,在训练有素的免疫中,迄今为止的重点一直是增强单核细胞功能。然而,多形核细胞,即中性粒细胞,不仅是造血细胞的主要组成部分,而且在功能和数量上也是免疫系统的重要组成部分。最近的研究表明,卡介苗疫苗对新生儿败血症的有益 NSE 是由卡介苗介导的中性粒细胞数量增加(紧急粒细胞生成(EG))驱动的。动物模型中的实验证据表明,卡介苗也可以调节中性粒细胞的功能。这些发现表明,中性粒细胞对于卡介苗疫苗的立即有益的 NSE 至少是至关重要的。因此,揭示卡介苗广泛有益效应的全部机制应该将中性粒细胞置于最前沿。
