This review explores how antimicrobial peptides (AMPs), antibiotic use, and gut bacteria interact in inflammatory bowel disease (IBD). In Crohn's disease and colitis, key defensive peptides like defensins and LL-37 are reduced in affected areas, weakening the gut's natural barrier, while antibiotic overuse further disrupts the balance of gut bacteria and AMP production. The authors propose viewing these three factors as an interconnected system and suggest that therapies targeting AMP restoration, microbiome-friendly antibiotics, and fecal transplants could help restore gut health in IBD patients.
Abstract
Inflammatory bowel disease (IBD) represents a chronic relapsing disorder driven by a loss of homeostatic balance between the host immune system and the intestinal microbiota. Endogenous antimicrobial peptides (AMPs), produced primarily by epithelial and immune cells, function in concert with commensal microorganisms to preserve mucosal integrity and barrier function. Disruption of this antimicrobial equilibrium-through genetic susceptibility such as NOD2 mutations or environmental perturbations including antibiotic overuse-can impair antimicrobial defense, distort microbial composition, and initiate chronic inflammation. Recent investigations have revealed distinct alterations in AMP expression across IBD subtypes. In Crohn's disease, Paneth cell-derived α-defensins (HD5 and HD6) are markedly diminished in the ileal mucosa, whereas colonic, segmental IBD exhibits inadequate induction of β-defensins and LL-37. Conversely, in actively inflamed regions, certain AMPs such as human β-defensin-2 (HBD2) and lysozyme are strongly upregulated, reflecting a compensatory response to inflammatory cell infiltration and microbial invasion. Beyond host-derived peptides, broad-spectrum antibiotic exposure profoundly reshapes commensal communities, attenuates basal pattern-recognition receptor signaling, and secondarily perturbs AMP regulation-creating a feedback loop that amplifies dysbiosis. Here, we conceptualize these interactions as an integrated AMP-antibiotic-microbiota triad, in which endogenous antimicrobial regulation, exogenous antimicrobial pressure, and microbial ecological resilience dynamically co-determine mucosal stability. By positioning AMPs within this tripartite regulatory framework, this review delineates how antimicrobial imbalance arises across IBD subtypes, compares emerging therapeutic strategies-including AMP enhancement, microbiota-sparing antibiotic regimens, fecal microbiota transplantation, and metabolite-guided interventions-and highlights implications for precision recalibration of antimicrobial homeostasis in IBD.