Gonzalez A S, Elguero M E, Finocchietto P, Holod S, Romorini L, Miriuka S G, Peralta J G, Poderoso J J, Carreras M C
Laboratory of Oxygen Metabolism, University of Buenos Aires, INIGEM-CONICET , Buenos Aires , Argentina.
Free Radic Res. 2014 Jul;48(7):769-83. doi: 10.3109/10715762.2014.906592. Epub 2014 Apr 10.
Sepsis-associated multiple organ failure is a major cause of mortality characterized by a massive increase of reactive oxygen and nitrogen species (ROS/RNS) and mitochondrial dysfunction. Despite intensive research, determining events in the progression or reversal of the disease are incompletely understood. Herein, we studied two prototype sepsis models: endotoxemia and cecal ligation and puncture (CLP)-which showed very different lethality rates (2.5% and 67%, respectively)-, evaluated iNOS, ROS and respiratory chain activity, and investigated mitochondrial biogenesis and dynamics, as possible processes involved in sepsis outcome. Endotoxemia and CLP showed different iNOS, ROS/RNS, and complex activities time-courses. Moreover, these alterations reverted after 24-h endotoxemia but not after CLP. Mitochondrial biogenesis was not elicited during the first 24 h in either model but instead, 50% mtDNA depletion was observed. Mitochondrial fusion and fission were evaluated using real-time PCR of mitofusin-2 (Mfn2), dynamin-related protein-1 (Drp1), and using electron microscopy. During endotoxemia, we observed a decrease of Mfn2-mRNA levels at 4-6 h, and an increase of mitochondrial fragmentation at 6 h. These parameters reverted at 24 h. In contrast, CLP showed not only decreased Mfn2-mRNA levels at 12-18 h but also increased Drp1-mRNA levels at 4 h, and enhanced and sustained mitochondrial fragmentation. The in vivo pretreatment with mdivi-1 (Drp1 inhibitor) significantly attenuated mitochondrial dysfunction and apoptosis in CLP. Therefore, abnormal fusion-to-fission balance, probably evoked by ROS/RNS secondary to iNOS induction, contributes to the progression of sepsis. Pharmacological targeting of Drp1 may be a potential novel therapeutic tool for sepsis.
脓毒症相关的多器官功能衰竭是死亡率的主要原因,其特征是活性氧和氮物种(ROS/RNS)大量增加以及线粒体功能障碍。尽管进行了深入研究,但对该疾病进展或逆转过程中的决定性事件仍未完全了解。在此,我们研究了两种典型的脓毒症模型:内毒素血症和盲肠结扎穿孔(CLP)——其显示出非常不同的致死率(分别为2.5%和67%)——评估了诱导型一氧化氮合酶(iNOS)、ROS和呼吸链活性,并研究了线粒体生物发生和动力学,将其作为可能参与脓毒症结局的过程。内毒素血症和CLP显示出不同的iNOS、ROS/RNS和复合物活性时间进程。此外,这些改变在内毒素血症24小时后恢复,但CLP后未恢复。在两种模型的最初24小时内均未引发线粒体生物发生,反而观察到50%的线粒体DNA耗竭。使用线粒体融合蛋白2(Mfn2)、动力相关蛋白1(Drp1)的实时聚合酶链反应(PCR)以及电子显微镜评估线粒体融合和裂变。在内毒素血症期间,我们观察到4 - 6小时时Mfn2 - mRNA水平降低,6小时时线粒体碎片化增加。这些参数在24小时时恢复。相比之下,CLP不仅在12 - 18小时时Mfn2 - mRNA水平降低,而且在4小时时Drp1 - mRNA水平升高,并增强且持续线粒体碎片化。用mdivi - 1(Drp1抑制剂)进行体内预处理可显著减轻CLP中的线粒体功能障碍和细胞凋亡。因此,可能由iNOS诱导继发的ROS/RNS引发的异常融合与裂变平衡,促成了脓毒症的进展。对Drp1进行药物靶向治疗可能是脓毒症一种潜在的新型治疗手段。
