Institute of Brain Science and Disease, School of Basic Medicine, Shandong Provincial Key Laboratory of Pathogenesis and Prevention of Neurological Disorders, Qingdao University, Qingdao, 266021, China.
Acta Pharmacol Sin. 2024 Jan;45(1):52-65. doi: 10.1038/s41401-023-01147-x. Epub 2023 Sep 6.
Gut microbiota disturbance and systemic inflammation have been implicated in the degeneration of dopaminergic neurons in Parkinson's disease (PD). How the alteration of gut microbiota results in neuropathological events in PD remains elusive. In this study, we explored whether and how environmental insults caused early neuropathological events in the substantia nigra (SN) of a PD mouse model. Aged (12-month-old) mice were orally administered rotenone (6.25 mg·kg·d) 5 days per week for 2 months. We demonstrated that oral administration of rotenone to ageing mice was sufficient to establish a PD mouse model and that microglial activation and iron deposition selectively appeared in the SN of the mice prior to loss of motor coordination and dopaminergic neurons, and these events could be fully blocked by microglial elimination with a PLX5622-formulated diet. 16 S rDNA sequencing analysis showed that the gut microbiota in rotenone-treated mice was altered, and mice receiving faecal microbial transplantation (FMT) from ageing mice treated with rotenone for 2 months exhibited the same pathology in the SN. We demonstrated that C-X-C motif chemokine ligand-1 (CXCL1) was an essential molecule, as intravenous injection of CXCL1 mimicked almost all the pathology in serum and SN induced by oral rotenone and FMT. Using metabolomics and transcriptomics analyses, we identified the PPAR pathway as a key pathway involved in rotenone-induced neuronal damage. Inhibition of the PPARγ pathway was consistent in the above models, whereas its activation by linoleic acid (60 mg·kg·d, i.g. for 1 week) could block these pathological events in mice intravenously injected with CXCL1. Altogether, these results reveal that the altered gut microbiota resulted in neuroinflammation and iron deposition occurring early in the SN of ageing mice with oral administration of rotenone, much earlier than motor symptoms and dopaminergic neuron loss. We found that CXCL1 plays a crucial role in this process, possibly via PPARγ signalling inhibition. This study may pave the way for understanding the "brain-gut-microbiota" molecular regulatory networks in PD pathogenesis. The aged C57BL/6 male mice with rotenone intragastric administration showed altered gut microbiota, which caused systemic inflammation, PPARγ signalling inhibition and neuroinflammation, brain iron deposition and ferroptosis, and eventually dopaminergic neurodegeneration in PD.
肠道微生物群紊乱和全身炎症与帕金森病 (PD) 中多巴胺能神经元的退化有关。肠道微生物群的改变如何导致 PD 中的神经病理事件仍然难以捉摸。在这项研究中,我们探讨了环境损伤是否以及如何导致 PD 小鼠模型中黑质 (SN) 的早期神经病理事件。将年老(12 个月大)的小鼠每周 5 天经口给予鱼藤酮(6.25mg·kg·d)2 个月。我们证明,向衰老小鼠口服给予鱼藤酮足以建立 PD 小鼠模型,并且在运动协调丧失和多巴胺能神经元丧失之前,小胶质细胞活化和铁沉积选择性地出现在小鼠的 SN 中,这些事件可以通过用 PLX5622 配方饮食消除小胶质细胞来完全阻断。16S rDNA 测序分析表明,鱼藤酮处理的小鼠的肠道微生物群发生了改变,并且接受来自接受 2 个月鱼藤酮治疗的衰老小鼠的粪便微生物移植(FMT)的小鼠在 SN 中表现出相同的病理学。我们证明,C-X-C 基序趋化因子配体 1(CXCL1)是一种必不可少的分子,因为静脉内注射 CXCL1 几乎模拟了口服鱼藤酮和 FMT 诱导的血清和 SN 中的所有病理学。通过代谢组学和转录组学分析,我们确定了过氧化物酶体增殖物激活受体 (PPAR) 途径是参与鱼藤酮诱导的神经元损伤的关键途径。上述模型中均观察到 PPARγ 途径的抑制,而通过亚油酸(60mg·kg·d,口服 1 周)激活该途径可阻断静脉内注射 CXCL1 的小鼠中的这些病理事件。总之,这些结果表明,在接受鱼藤酮口服给药的衰老小鼠的 SN 中,改变的肠道微生物群导致神经炎症和铁沉积发生得更早,远早于运动症状和多巴胺能神经元丧失。我们发现 CXCL1 在这个过程中起着至关重要的作用,可能是通过 PPARγ 信号抑制。这项研究可能为理解 PD 发病机制中的“脑-肠-微生物群”分子调节网络铺平道路。接受鱼藤酮胃内给药的年老 C57BL/6 雄性小鼠表现出改变的肠道微生物群,导致全身炎症、PPARγ 信号抑制和神经炎症、脑铁沉积和铁死亡,最终导致 PD 中的多巴胺能神经退行性变。
