<p>Bacterial diarrheal diseases continue to constitute a major burden on global public health, particularly within pediatric populations in low-resource settings. While clinically unified by the symptomology of diarrhea, the primary causative agents; Enterotoxigenic <i>Escherichia coli</i> (ETEC), <i>Shigella</i> species, <i>Salmonella enterica</i>, and <i>Clostridioides difficile</i> employ fundamentally distinct molecular strategies to subvert intestinal homeostasis. This review presents a comparative analysis of these ecosystem engineers, proposing that their pathogenicity is defined by their unique management of the host-microbiota metabolic and signaling conflict. We advance beyond the traditional host-pathogen dyad to explore a mechanistic triangle, integrating recent findings that the microbiota acts as a dynamic third player imposing colonization resistance via secondary bile acids and nutrient competition (proline), or conversely, providing metabolic fuel (formate, tetrathionate) for pathogen expansion. We synthesize advanced molecular insights from including the energetics of the <i>Shigella</i> T3SS sorting platform (Spa47); the multilayered “effector-immunity arms race” involving the <i>Shigella</i> effectors OspC1 and OspD3 in manipulating necroptosis; novel <i>Salmonella</i> T3SS-2 targets such as LMO4 and SteA-mediated ER contact sites; and the receptor diversity of <i>C. difficile</i> TcdB variants. Finally, we map these mechanisms to next-generation therapeutic vulnerabilities, highlighting the transition from broad-spectrum antibiotics to precision bacteriophage biocontrol (LPEK22, LPST94) and AI-discovered lysins (DeepLysin) as the future of intervention.</p><p></p>

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Divergent mechanistic pathways of diarrheagenic bacterial infections at the host-microbiota interface: a review

  • Michael Tosin Bayode¹,
  • Oluwatoyosi Ezekiel Olawale,
  • Olubukola Olayemi Olusola-Makinde

摘要

Bacterial diarrheal diseases continue to constitute a major burden on global public health, particularly within pediatric populations in low-resource settings. While clinically unified by the symptomology of diarrhea, the primary causative agents; Enterotoxigenic Escherichia coli (ETEC), Shigella species, Salmonella enterica, and Clostridioides difficile employ fundamentally distinct molecular strategies to subvert intestinal homeostasis. This review presents a comparative analysis of these ecosystem engineers, proposing that their pathogenicity is defined by their unique management of the host-microbiota metabolic and signaling conflict. We advance beyond the traditional host-pathogen dyad to explore a mechanistic triangle, integrating recent findings that the microbiota acts as a dynamic third player imposing colonization resistance via secondary bile acids and nutrient competition (proline), or conversely, providing metabolic fuel (formate, tetrathionate) for pathogen expansion. We synthesize advanced molecular insights from including the energetics of the Shigella T3SS sorting platform (Spa47); the multilayered “effector-immunity arms race” involving the Shigella effectors OspC1 and OspD3 in manipulating necroptosis; novel Salmonella T3SS-2 targets such as LMO4 and SteA-mediated ER contact sites; and the receptor diversity of C. difficile TcdB variants. Finally, we map these mechanisms to next-generation therapeutic vulnerabilities, highlighting the transition from broad-spectrum antibiotics to precision bacteriophage biocontrol (LPEK22, LPST94) and AI-discovered lysins (DeepLysin) as the future of intervention.