Butyric acid and valeric acid attenuate stress-induced ferroptosis and depressive-like behaviors by suppressing hippocampal neuroinflammation.

IF 7.5 2区医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL

Journal of Translational Medicine Pub Date : 2025-09-02 DOI:10.1186/s12967-025-06950-0

Xiaoying Ma, Weibo Shi, Zhen Wang, Shujin Li, Rufei Ma, Weihao Zhu, Lin Wu, Xiaowei Feng, Bin Cong, Yingmin Li

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引用次数: 0

Abstract

Background: Depression is closely associated with stress-induced hippocampal damage and dysfunction. Emerging evidence demonstrates that the gut microbiota and its metabolites, acting as probiotics or prebiotics, can modulate brain structure and function via the gut-brain axis, thereby offering therapeutic potential for ameliorating related neurological and psychiatric disorders. This study delves into the contribution of the gut microbiota and its metabolites to stress-induced ferroptosis of hippocampal neurons and the associated molecular pathways.

Methods: This study used time-course stress paradigms combined with ferroptosis inhibitors to identify hippocampal neuronal ferroptosis. Fecal microbiota transplantation were conducted to analyze the role of gut microbiota in this process. Subsequently, 16 S rDNA sequencing and metabolomics techniques were applied to identify key gut microbiota and metabolites. Metabolites intervention were performed to examine their causal relationship with neuronal ferroptosis. Finally, we used histochemical and molecular assays to assess both intestinal and blood-brain barrier integrity as well as inflammation in peripheral blood and hippocampal tissue, along with GPR41/RhoA/Rock1 pathway changes, to preliminarily investigate the molecular mechanisms underlying stress-induced hippocampal neuronal ferroptosis.

Results: We demonstrated that stress triggered hippocampal neuronal ferroptosis and subsequent depressive-like behaviors in mice. Fecal microbiota transplantation successfully replicated the ferroptosis phenotype. Butyric acid and valeric acid were identified as key metabolites significantly reduced in the serum of acutely and chronically stressed mice, respectively. Intervention with these metabolites markedly alleviated ferroptosis. Furthermore, valerate intervention increased hippocampal GPR41 expression and significantly suppressed the pro-inflammatory RhoA/Rock1 pathway in chronically stressed mice, thereby reducing neuroinflammation and ameliorating neuronal ferroptosis. However, butyrate intervention showed no significant effect on the GPR41/RhoA/Rock1 pathway.

Conclusion: Stress induces ferroptosis in hippocampal neurons, where reduced abundance of short-chain fatty acid-producing bacteria plays a key role. Key metabolites butyric acid and valeric acid alleviate neuroinflammation to improve ferroptosis via the gut-brain axis in acute and chronic stress, respectively. Specifically, valeric acid exerts neuroprotective effect through the GPR41/RhoA/Rock1 pathway, whereas butyric acid-mediated protection likely operates through alternative mechanisms.

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丁酸和戊酸通过抑制海马神经炎症减轻应激诱导的铁下垂和抑郁样行为。

背景：抑郁症与应激性海马损伤和功能障碍密切相关。新出现的证据表明，肠道微生物群及其代谢物，作为益生菌或益生元，可以通过肠-脑轴调节大脑结构和功能，从而为改善相关的神经和精神疾病提供治疗潜力。本研究探讨了肠道微生物群及其代谢物在应激诱导的海马神经元铁下垂中的作用及其相关的分子途径。方法：本研究采用时程应激模式联合铁下垂抑制剂对海马神经元铁下垂进行鉴定。通过粪便菌群移植来分析肠道菌群在这一过程中的作用。随后，应用16s rDNA测序和代谢组学技术鉴定关键肠道微生物群和代谢物。进行代谢物干预以检查其与神经元铁下垂的因果关系。最后，我们通过组织化学和分子分析评估肠道和血脑屏障的完整性，以及外周血和海马组织的炎症，以及GPR41/RhoA/Rock1通路的变化，初步探讨应激诱导海马神经元铁质凋亡的分子机制。结果：我们证明了应激触发小鼠海马神经元铁下垂和随后的抑郁样行为。粪便菌群移植成功复制了铁下垂表型。急性和慢性应激小鼠血清中丁酸和戊酸分别被鉴定为显著降低的关键代谢物。用这些代谢物干预可显著减轻铁下垂。此外，戊酸干预增加了慢性应激小鼠海马GPR41的表达，显著抑制了促炎RhoA/Rock1通路，从而减少了神经炎症，改善了神经元铁下垂。然而，丁酸盐干预对GPR41/RhoA/Rock1通路无显著影响。结论：应激诱导海马神经元铁下垂，其中短链脂肪酸生成菌丰度降低起关键作用。关键代谢物丁酸和戊酸分别在急性和慢性应激下通过肠-脑轴减轻神经炎症，改善铁下垂。具体来说，戊酸通过GPR41/RhoA/Rock1通路发挥神经保护作用，而丁酸介导的保护可能通过其他机制起作用。

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来源期刊

Journal of Translational Medicine 医学-医学：研究与实验

CiteScore

10.00

自引率

1.40%

发文量

537

审稿时长

1 months

期刊介绍： The Journal of Translational Medicine is an open-access journal that publishes articles focusing on information derived from human experimentation to enhance communication between basic and clinical science. It covers all areas of translational medicine.