生物
失调
肠道菌群
微生物群
平衡
细胞生物学
代谢途径
代谢组学
转录组
干细胞
能量稳态
免疫学
微生物学
下调和上调
肠-脑轴
调解人
再生(生物学)
营养感应
代谢综合征
营养基因学
寄主(生物学)
LGR5型
机制(生物学)
信号转导
微生物代谢
新陈代谢
氧化应激
免疫系统
脂质代谢
肠粘膜
作者
Yimin Zhuang,Zhiyu Huang,S Liu,Yiming Xu,Guobin Hou,Duo Gao,Tianyu Chen,Boyan Ma,Wen Jiang,Jingtao You,Li M,Wei Wang,Shengli Li,Zhijun Cao
标识
DOI:10.1093/ismejo/wrag135
摘要
Childhood malnutrition represents a major global health burden that extends beyond caloric deficiency to include dietary imbalance. The early-life gut microbiome functions as a dynamic ecosystem whose structure and metabolic output are intimately linked to host development, yet how nutritional imbalance disrupts this ecosystem and its integration with the host remains poorly understood. Using an isocaloric but nutrient-imbalanced diet in a mouse model, we recapitulated chronic growth stunting and identified a systemic syndrome comprising growth retardation, oxidative stress, and immunosuppression. Gut microbiota dysbiosis was established as the central mediator of these pathological manifestations. Integrated multi-omics analyses revealed that nutritional imbalance compromised microbial community structure and function, reducing diversity and ecological stability whereas disrupting metabolic activity-particularly short-chain fatty acid (SCFA) production. Through single-cell RNA sequencing of colonic epithelium, we demonstrated that these microbial perturbations suppressed host energy metabolism and inhibited the Wnt/β-catenin signaling pathway in regenerative epithelial cells. This resulted in the downregulation of key stem cell regulators LGR5 and ASCL2, ultimately impairing epithelial renewal and manifesting as reduced crypt depth. Our findings reveal a microbiota-dependent mechanism linking dietary imbalance to impaired host development, demonstrating how nutritional stress disrupts gut microbial structure and metabolic output, ultimately compromising epithelial regeneration. This work highlights the importance of considering the gut microbiome as an ecosystem whose homeostasis is fundamental to early-life health.
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