Evolutionary Genomics of Human Gut Bacteria: Ecological Plasticity Across the Mutualism–Pathogenicity Spectrum

The human gut microbiome comprises a diverse community of bacteria whose interactions with the host range from beneficial mutualism to opportunistic pathogenicity. These interactions are shaped by genomic plasticity and ecological pressures that influence whether microbes support host health, remain conditionally harmless, or contribute to disease. Understanding the mechanisms underlying these shifts is essential for clarifying the balance between cooperation and pathogenicity within the gut ecosystem. This review explores the genomic and evolutionary mechanisms that shape microbial adaptation across the mutualism–pathogenicity spectrum in the human gut. Key processes, including horizontal gene transfer (HGT), host-mediated selection, and niche specialization, enable microbes to acquire, regulate, or retain traits that influence colonization, metabolic function, and virulence. These adaptive mechanisms allow gut bacteria to respond dynamically to ecological pressures such as inflammation, antibiotic exposure, and dietary change, resulting in context-dependent microbial behaviors. The review also considers how concepts from insect endosymbiosis may provide insight into gut microbial adaptation. While both systems exhibit host specialization, major differences in transmission mode, ecological flexibility, and genome evolution limit direct comparisons. Rather than following a fixed progression toward parasitism, gut microbes exhibit flexible adaptive strategies shaped by host and environmental conditions. By integrating ecological and evolutionary perspectives, this review presents a balanced framework for understanding how genomic adaptation influences microbial behavior in the gut. This perspective improves our understanding of dysbiosis and microbial pathogenesis and may support the development of microbiome-informed therapeutic strategies for maintaining host health.