Forlenza Maria, Scharsack Joern P, Kachamakova Neli M, Taverne-Thiele Anja J, Rombout Jan H W M, Wiegertjes Geert F
Department of Animal Sciences, Cell Biology and Immunology Group, Wageningen Institute of Animal Sciences, Wageningen University, P.O. Box 338, 6700 AH Wageningen, The Netherlands.
Mol Immunol. 2008 Jun;45(11):3178-89. doi: 10.1016/j.molimm.2008.02.025. Epub 2008 Apr 14.
Tyrosine nitration is a hallmark for nitrosative stress caused by the release of reactive oxygen and nitrogen species by activated macrophages and neutrophilic granulocytes at sites of inflammation and infection. In the first part of the study, we used an informative host-parasite animal model to describe the differential contribution of macrophages and neutrophilic granulocytes to in vivo tissue nitration. To this purpose common carp (Cyprinus carpio) were infected with the extracellular blood parasite Trypanoplasma borreli (Kinetoplastida). After infection, serum nitrite levels significantly increased concurrently to the upregulation of inducible nitric oxide synthase (iNOS) gene expression. Tyrosine nitration, as measured by immunohistochemistry using an anti-nitrotyrosine antibody, dramatically increased in tissues from parasite-infected fish, demonstrating that elevated NO production during T. borreli infection coincides with nitrosative stress in immunologically active tissues. The combined use of an anti-nitrotyrosine antibody with a panel of monoclonal antibodies specific for several carp leukocytes, revealed that fish neutrophilic granulocytes strongly contribute to in vivo tissue nitration most likely through both, a peroxynitrite- and an MPO-mediated mechanism. Conversely, fish macrophages, by restricting the presence of radicals and enzymes to their intraphagosomal compartment, contribute to a much lesser extent to in vivo tissue nitration. In the second part of the study, we examined the effects of nitrosative stress on the parasite itself. Peroxynitrite, but not NO donor substances, exerted strong cytotoxicity on the parasite in vitro. In vivo, however, nitration of T. borreli was limited if not absent despite the presence of parasites in highly nitrated tissue areas. Further, we investigated parasite susceptibility to the human anti-trypanosome drug Melarsoprol (Arsobal), which directly interferes with the parasite-specific trypanothione anti-oxidant system. Arsobal treatment strongly decreased T. borreli viability both, in vitro and in vivo. All together, our data suggest an evolutionary conservation in modern bony fish of the function of neutrophilic granulocytes and macrophages in the nitration process and support the common carp as a suitable animal model for investigations on nitrosative stress in host-parasite interactions. The potential of T. borreli to serve as an alternative tool for pharmacological studies on human anti-trypanosome drugs is discussed.
酪氨酸硝化是炎症和感染部位活化的巨噬细胞和嗜中性粒细胞释放活性氧和氮物种所引起的亚硝化应激的标志。在研究的第一部分,我们使用了一个信息丰富的宿主 - 寄生虫动物模型来描述巨噬细胞和嗜中性粒细胞对体内组织硝化的不同贡献。为此,将鲤鱼(Cyprinus carpio)感染细胞外血液寄生虫博氏锥虫(动质体纲)。感染后,血清亚硝酸盐水平显著升高,同时诱导型一氧化氮合酶(iNOS)基因表达上调。通过使用抗硝基酪氨酸抗体的免疫组织化学测定,寄生虫感染鱼的组织中酪氨酸硝化显著增加,表明博氏锥虫感染期间一氧化氮产量升高与免疫活性组织中的亚硝化应激同时出现。抗硝基酪氨酸抗体与一组针对几种鲤鱼白细胞的单克隆抗体联合使用,表明鱼类嗜中性粒细胞很可能通过过氧亚硝酸盐和髓过氧化物酶介导的机制对体内组织硝化有强烈贡献。相反,鱼类巨噬细胞通过将自由基和酶限制在其吞噬体内隔室,对体内组织硝化的贡献要小得多。在研究的第二部分,我们研究了亚硝化应激对寄生虫本身的影响。过氧亚硝酸盐而非一氧化氮供体物质在体外对寄生虫具有强烈的细胞毒性。然而,在体内,尽管在高度硝化的组织区域存在寄生虫,但博氏锥虫的硝化作用即使有也是有限的。此外,我们研究了寄生虫对人类抗锥虫药物美拉胂醇(Arsobal)的敏感性,该药物直接干扰寄生虫特异性的锥虫硫醇抗氧化系统。Arsobal治疗在体外和体内均强烈降低了博氏锥虫的活力。总之,我们的数据表明现代硬骨鱼中嗜中性粒细胞和巨噬细胞在硝化过程中的功能具有进化保守性,并支持鲤鱼作为研究宿主 - 寄生虫相互作用中亚硝化应激的合适动物模型。还讨论了博氏锥虫作为人类抗锥虫药物药理学研究替代工具的潜力。
