Lactobacillus murinus Mediates Multi-Target Protection to Alleviate Cyclophosphamide-Induced Intestinal Injury and Immune Suppression Through the Gut–Metabolism–Immune Axis
Jingna Wu, Nan Pan, Xiaoting Chen, Lexuan Qi, Hui Huang, Xiaoya Qu, Zhiyu LiuThe protective effects of Lactobacillus murinus on chemotherapy-related intestinal injury and immune imbalances were explored by establishing a cyclophosphamide (CTX)-induced mouse model of immunosuppression. CTX treatment led to intestinal barrier destruction, exacerbated local inflammation, and significantly reduced short-chain fatty acid levels (especially butyrate), accompanied by systemic immune suppression. Lactobacillus murinus intervention, especially at medium and high doses, dose-dependently repaired the intestinal barrier, inhibited inflammatory responses, restored levels of metabolites such as butyrate, and systematically regulated splenic immune cell proportions, restoring the CD4+/CD8+ balance. Metabolomic analysis further revealed that, at different doses, this regulation affected distinct metabolic pathways: low doses enhanced glutathione and purine metabolism, medium doses restored folate and steroid hormone metabolism, and high doses promoted fatty acid β-oxidation and galactose metabolism, forming a multi-level metabolic protective network. This suggests that L. murinus can alleviate chemotherapy-induced intestinal mucositis and mitigate systemic immune suppression through a dual local anti-inflammatory and systemic immune-regulatory effect, with potential mechanisms related to butyrate-mediated regulation of the “metabolism–immune axis,” providing evidence for probiotic-assisted chemotherapy.