Gram-Negative Bacteria and Lipopolysaccharides as Risk Factors for the Occurrence of Diabetic Foot

Abstract Context Imbalance of the skin microbial community could impair skin immune homeostasis and thus trigger skin lesions. Dysbiosis of skin microbiome may be involved in the early pathogenesis of diabetic foot (DF). However, the potential mechanism remains unclear. Objective To investigate the...

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Published in:The journal of clinical endocrinology and metabolism 2023-09, Vol.108 (10), p.2604-2614
Main Authors: Zhang, Shili, Li, Shuxian, Huang, Jiali, Ding, Xinyi, Qiu, Yan, Luo, Xiangrong, Meng, Jianfu, Hu, YanJun, Zhou, Hao, Fan, Hongying, Cao, Ying, Gao, Fang, Xue, Yaoming, Zou, Mengchen
Format: Article
Language:English
Subjects:
Amino acids
Antibiotic resistance
Bacteria
Clinical
Diabetes
Diabetes mellitus
Dysbacteriosis
Feet
Foot diseases
Gram-negative bacteria
Homeostasis
Inflammation
Lipopolysaccharides
Metabolites
Metagenomics
Microbiomes
Microbiota
Risk factors
Risk groups
rRNA 16S
Signal transduction
Skin diseases
Skin lesions
TLR4 protein
Toll-like receptors
Ulcers
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Summary:Abstract Context Imbalance of the skin microbial community could impair skin immune homeostasis and thus trigger skin lesions. Dysbiosis of skin microbiome may be involved in the early pathogenesis of diabetic foot (DF). However, the potential mechanism remains unclear. Objective To investigate the dynamic composition and function of the foot skin microbiome with risk stratification for DF and assess whether dysbiosis of the skin microbiome induces diabetic skin lesions. Methods We enrolled 90 consecutive subjects who were divided into 5 groups based on DF risk stratification: very low, low, moderate, and high risk for ulcers and a healthy control group. Integrated analysis of 16S ribosomal RNA and metagenomic sequencing of cotton swab samples was applied to identify the foot skin microbiome composition and functions in subjects. Then a mouse model of microbiota transplantation was used to evaluate the effects of the skin microbiome on diabetic skin lesions. Results The results demonstrated that, with the progression of diabetic complications, the proportion of gram-negative bacteria in plantar skin increased. At the species level, metagenome sequencing analyses showed Moraxella osloensis to be a representative core strain in the high-risk group. The major microbial metabolites affecting diabetic skin lesions were increased amino acid metabolites, and antibiotic resistance genes in microorganisms were abundant. Skin microbiota from high-risk patients induced more inflammatory cell infiltration, similar to the lipopolysaccharide (LPS)-stimulated response, which was inhibited by Toll-like receptor 4 (TLR4) antagonists. Conclusions The skin microbiome in patients with diabetes undergoes dynamic changes at taxonomic and functional levels with the progression of diabetic complications. The increase in gram-negative bacteria on the skin surface through LPS-TLR4 signal transduction could induce inflammatory response in early diabetic skin lesions.
ISSN:0021-972X
1945-7197
DOI:10.1210/clinem/dgad178