凝血系统与免疫系统的协同进化。

Coevolution of the coagulation and immune systems.

机构信息

Institute of Laboratory Medicine and Pathobiochemistry, Molecular Diagnostics, University Hospital of the Universities of Marburg and Giessen UKGM, Justus Liebig University Giessen, Feulgenstr. 12, 35392, Giessen, Germany.

出版信息

Inflamm Res. 2019 Feb;68(2):117-123. doi: 10.1007/s00011-018-01210-y. Epub 2019 Jan 2.

DOI:10.1007/s00011-018-01210-y

PMID:30604212

Abstract

BACKGROUND

Higher organisms rely on the coagulation and immune systems to fight disease-causing pathogens and other foreign invaders in the body. Coagulation has an important role as a barrier against foreign bodies, including bacteria, viruses, and protozoa. The protective responses associated with the coagulation and immune systems can protect the host organism from a wide range of pathogens, such as viruses, parasites, fungi, and even bacteria.

AIM

The purpose of this paper was to review available research on the evolution of the coagulation and immune systems.

MATERIALS AND METHODS

The study analyzed evidence from studies that have examined the coagulation and immune systems in the context of evolutionary processes. The articles used in the review were identified from the PsycINFO, CIHAHL, PubMed, Web of Science, and CIHAHL databases.

RESULTS

Studies have shown that both the coagulation system and the early immune system originated from the same initial system in early organisms. Some researchers argue that hemocytes from lower organisms are the common link from which the immune system and coagulation system developed.

DISCUSSION AND CONCLUSION

Simple organisms have hemocytes that can carry out both immune response and coagulation processes. Evolution led to the separation of these processes in higher organisms. Furthermore, this divergence resulted in the emergence of thrombocytes and plasmatic coagulation subsystems. These observations explain why there is some form of overlap between immunity and hemostasis, even in advanced organisms such as vertebrates. Several phenomena in clinical medicine related to coagulation and immunity can be explained by this overlap and are consistent with the hypothesis of the coevolution of coagulation and the immune system.

摘要

背景

高等生物依赖于凝血和免疫系统来抵抗体内的致病病原体和其他外来入侵者。凝血作为一种抵御包括细菌、病毒和原生动物在内的异物的屏障具有重要作用。与凝血和免疫系统相关的保护反应可以使宿主免受多种病原体的侵害，如病毒、寄生虫、真菌，甚至细菌。

目的

本文旨在回顾有关凝血和免疫系统进化的现有研究。

材料和方法

该研究分析了在进化过程背景下检查凝血和免疫系统的研究中的证据。综述中使用的文章是从 PsycINFO、CIHAHL、PubMed、Web of Science 和 CIHAHL 数据库中确定的。

结果

研究表明，凝血系统和早期免疫系统都起源于早期生物中相同的初始系统。一些研究人员认为，较低等生物的血细胞是免疫系统和凝血系统共同发展的共同联系。

讨论和结论

简单的生物体具有可以同时进行免疫反应和凝血过程的血细胞。进化导致这些过程在高等生物中分离。此外，这种分化导致了血小板和血浆凝血子系统的出现。这些观察结果解释了为什么即使在高级生物（如脊椎动物）中，免疫和止血之间也存在某种形式的重叠。与凝血和免疫相关的一些临床医学现象可以通过这种重叠来解释，并且与凝血和免疫系统的共同进化假说一致。

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凝血系统与免疫系统的协同进化。

Coevolution of the coagulation and immune systems.

机构信息

出版信息

BACKGROUND

AIM

MATERIALS AND METHODS

RESULTS

DISCUSSION AND CONCLUSION

背景

目的

材料和方法

结果

讨论和结论

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