{"title":"Phagolysosomal resistance hypothesized to be a danger signal.","authors":"Christopher A Forden","doi":"10.1111/sji.13400","DOIUrl":null,"url":null,"abstract":"<p><p>Antigen presenting cells sometimes require T cell \"help\" to kill and decompose microbes they capture, especially when those microbes resist effector molecules including nitric oxide and reactive oxygen species. Pathogens are more likely to resist those effectors, shared by the innate and adaptive immune systems, than are commensals. Does such resistance alert the immune system to the danger posed by those pathogens? Several lines of evidence suggest this occurs. Mouse studies showed a surprising exacerbation, not alleviation of experimental autoimmune encephalomyelitis, by suppression of nitric oxide production, but only when the suppression was applied to animals undergoing vaccination with myelin. In contrast, animals receiving T cells activated by vaccination without suppression of nitric oxide benefitted from reduced autoimmune cytotoxicity when nitric oxide production was suppressed after adoptive transfer. Vaccinia and adenovirus suppress nitric oxide production and have been successful vaccine platforms, also consistent with the above phagolysosomal resistance hypothesis. The hypothesis solves a long-standing quandary-how can nitric oxide protect against both infection and autoimmunity, especially autoimmune diseases for which it seems a major effector? The importance of physical linkage between epitopes, first proposed in Bretscher's Two-Step, Two-Signal theory dependent on B cells, is extended to include phagolysosomal resistance in general, plus a corollary proposition that the immune system detects resistance to dissociation of high-affinity pathogenic ligands from host binding sites to make neutralizing antibodies.</p>","PeriodicalId":21493,"journal":{"name":"Scandinavian Journal of Immunology","volume":" ","pages":"e13400"},"PeriodicalIF":4.1000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Scandinavian Journal of Immunology","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.1111/sji.13400","RegionNum":4,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"2024/8/13 0:00:00","PubModel":"Epub","JCR":"Q2","JCRName":"IMMUNOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
Antigen presenting cells sometimes require T cell "help" to kill and decompose microbes they capture, especially when those microbes resist effector molecules including nitric oxide and reactive oxygen species. Pathogens are more likely to resist those effectors, shared by the innate and adaptive immune systems, than are commensals. Does such resistance alert the immune system to the danger posed by those pathogens? Several lines of evidence suggest this occurs. Mouse studies showed a surprising exacerbation, not alleviation of experimental autoimmune encephalomyelitis, by suppression of nitric oxide production, but only when the suppression was applied to animals undergoing vaccination with myelin. In contrast, animals receiving T cells activated by vaccination without suppression of nitric oxide benefitted from reduced autoimmune cytotoxicity when nitric oxide production was suppressed after adoptive transfer. Vaccinia and adenovirus suppress nitric oxide production and have been successful vaccine platforms, also consistent with the above phagolysosomal resistance hypothesis. The hypothesis solves a long-standing quandary-how can nitric oxide protect against both infection and autoimmunity, especially autoimmune diseases for which it seems a major effector? The importance of physical linkage between epitopes, first proposed in Bretscher's Two-Step, Two-Signal theory dependent on B cells, is extended to include phagolysosomal resistance in general, plus a corollary proposition that the immune system detects resistance to dissociation of high-affinity pathogenic ligands from host binding sites to make neutralizing antibodies.
抗原递呈细胞有时需要 T 细胞的 "帮助 "来杀死和分解它们捕获的微生物,尤其是当这些微生物抵制一氧化氮和活性氧等效应分子时。病原体比共生体更有可能抵抗先天性免疫系统和适应性免疫系统共有的这些效应分子。这种抵抗是否会提醒免疫系统注意这些病原体带来的危险?一些证据表明会出现这种情况。小鼠研究显示,抑制一氧化氮的产生会令人惊讶地加剧而非缓解实验性自身免疫性脑脊髓炎,但只有在动物接种髓鞘疫苗时才会出现这种情况。与此相反,当一氧化氮的产生在采用性转移后受到抑制时,接受疫苗激活的 T 细胞的动物会从自身免疫细胞毒性的降低中获益,而不抑制一氧化氮的产生。疫苗素和腺病毒抑制一氧化氮的产生,并已成为成功的疫苗平台,这也与上述吞噬体抗性假说相一致。该假说解决了一个长期存在的难题--一氧化氮如何既能抵御感染,又能抵御自身免疫,尤其是自身免疫疾病,而一氧化氮似乎是自身免疫疾病的主要效应因子?布雷舍尔(Bretscher)的 "两步双信号理论"(Two-Step, Two-Signal theory)首次提出了表位间物理联系的重要性,并将其扩展到一般的吞噬体抗性,以及免疫系统检测高亲和性致病配体与宿主结合位点解离的抗性以产生中和抗体的必然命题。
期刊介绍:
This peer-reviewed international journal publishes original articles and reviews on all aspects of basic, translational and clinical immunology. The journal aims to provide high quality service to authors, and high quality articles for readers.
The journal accepts for publication material from investigators all over the world, which makes a significant contribution to basic, translational and clinical immunology.