Division of Transplant Immunology and Mucosal Biology, MRC Centre for Transplantation, King's College London, Guy's Hospital, London SE1 9RT, UK.
Semin Immunol. 2013 Feb;25(1):12-9. doi: 10.1016/j.smim.2013.04.012. Epub 2013 May 29.
The complement system is among the evolutionary oldest 'players' of the immune system. It was discovered in 1896 by Jules Bordet as a heat-labile fraction of the serum responsible for the opsonisation and subsequent killing of bacteria. The decades between the 1920s and 1990s then marked the discovery and biochemical characterization of the proteins comprising the complement system. Today, complement is defined as a complex system consisting of more than 30 membrane-bound and soluble plasma proteins, which are activated in a cascade-like manner, very similarly to the caspase proteases and blood coagulation systems. Complement is engrained in the immunologist's mind as a serum-effective, quintessential part of innate immunity, vitally required for the detection and removal of pathogens or other dangerous entities. Three decades ago, this rather confined definition was challenged and then refined when it was shown that complement participates vitally in the induction and regulation of B cell responses, thus adaptive immunity. Similarly, research work published in more recent years supports an equally important role for the complement system in shaping T cell responses. Today, we are again facing paradigm shifts in the field: complement is actively involved in the negative control of T cell effector immune responses, and thus, by definition in immune homeostasis. Further, while serum complement activity is without doubt fundamental in the defence against invading pathogens, local immune cell-derived production of complement emerges as key mediator of complement's impact on adaptive immune responses. And finally, the impact of complement on metabolic pathways and the crosstalk between complement and other immune effector systems is likely more extensive than previously anticipated and is fertile ground for future discoveries. In this review, we will discuss these emerging new roles of complement, with a focus on Th1 cell biology.
补体系统是免疫系统中最古老的“参与者”之一。它于 1896 年由朱尔斯·博尔德特(Jules Bordet)发现,是血清中一种对细菌具有调理和随后杀伤作用的热不稳定成分。在 20 世纪 20 年代到 90 年代的几十年里,人们发现并对构成补体系统的蛋白质进行了生化特性鉴定。如今,补体被定义为一个由 30 多种膜结合和可溶性血浆蛋白组成的复杂系统,这些蛋白以级联方式激活,与半胱天冬酶蛋白酶和血液凝固系统非常相似。补体被免疫学家视为血清有效、先天免疫的典型部分,对于检测和清除病原体或其他危险实体至关重要。三十年前,当人们发现补体在诱导和调节 B 细胞反应(即适应性免疫)方面发挥着至关重要的作用时,这种相当局限的定义受到了挑战并得到了改进。同样,近年来发表的研究工作支持补体系统在塑造 T 细胞反应方面同样重要的作用。如今,我们再次面临该领域的范式转变:补体积极参与 T 细胞效应免疫反应的负调控,因此,根据定义,它参与免疫稳态。此外,虽然血清补体活性无疑是抵御入侵病原体的基础,但局部免疫细胞产生的补体作为补体对适应性免疫反应影响的关键介质而出现。最后,补体对代谢途径的影响以及补体与其他免疫效应系统的串扰可能比以前预期的更为广泛,这为未来的发现提供了肥沃的土壤。在这篇综述中,我们将讨论补体的这些新出现的作用,重点是 Th1 细胞生物学。
