GP-fatty acid axis regulating the adaptive morphogenesis of VBNC bacteria in response to chlorine stress in the process of chlorination disinfection

Abstract

Investigating the specific metabolic regulatory strategy of viable but non-culturable (VBNC) bacteria is crucial for understanding adaptive morphogenesis, processes of shrinking body size and maintaining cell membrane integrity. Metabolomic studies have revealed an upregulation in the metabolic competence of glycerophospholipids (GP) and fatty acid catabolism in VBNC bacteria. Disruption of the GP-fatty acid axis, as evidenced by scanning electron microscopy, hinders the maintenance of adaptive morphology. VBNC bacteria minimize cell size by consuming fatty acids to sustain intracellular energy metabolism. Concurrently, GP metabolism replenishes fatty acid consumption and upholds cell membrane integrity, preventing HClO intrusion. Regulation of the GP-fatty acid axis also sustains intracellular antioxidants (e.g. glutathione and ubiquinone), preventing lipid peroxidation. Moreover, disruption of the GP-fatty acid axis impedes biofilm formation (reduced by 94.77 %) and reactivation (reduced by 95.73 %) of VBNC bacteria, with negligible effects on culturable bacteria. The study underscores the GP-fatty acid axis regulation to form adaptive morphology is a fundamental survival strategy for VBNC bacteria. Developing an efficient disinfection method targeting the GP-fatty acid axis emerges as a promising strategy to mitigate the health risk of VBNC bacteria.