Deciphering the Acetaldehyde Signaling Network Underlying Bacterial Escape from Protozoan Predators

Entamoeba histolytica (Eh) is a formidable intestinal pathogen, yet the ecological principles governing its invasion of the gut microbiome remain elusive. Upon colonization, Eh encounters resident bacteria typically sequestered within aggregates and biofilms. While Eh utilizes cysteine proteinases to degrade biofilm matrices and access bacterial prey, the strategies bacteria employ to sense and evade this predation are largely unknown. Here, we identify a metabolic signalling axis that allows the probiotic bacterium Bacillus subtilis to perceive and respond to predatory Eh. In the absence of mitochondria, Eh relies on fermentative glycolysis, using alcohol dehydrogenase to produce distinct metabolic byproducts. Using quantitative proteomics and single-cell imaging, we demonstrate that B. subtilis detects the Eh-derived metabolite acetaldehyde as a proxy for predator presence. By mapping the acetaldehyde-responsive regulatory network, we show how this metabolic input is transduced to control the motility machinery, while our data suggest that the broader predatory secretome acts as a multi-modal signal influencing multiple bacterial physiological programs. This chemical cue triggers a rapid phenotypic switch in B. subtilis, driving a transition towards a motile, planktonic "flight" response. Our findings reveal that commensal bacteria exploit the unique metabolic signature of anaerobic parasites to coordinate defensive behaviours, highlighting how inter-kingdom signalling shapes microbiome architecture during infection.