Swashing motility: A novel propulsion-independent mechanism for surface migration inSalmonellaandE. coli

Abstract

AbstractBacterial motility over surfaces is crucial for colonization, biofilm formation, and pathogenicity. Surface motility inEscherichia coliandSalmonella entericais traditionally believed to rely on flagellar propulsion. Here, we report a novel mode of motility, termed “swashing,” where these bacteria migrate on agar surfaces without functional flagella. Mutants lacking flagellar filaments and motility proteins exhibit rapid surface migration comparable to wild-type strains. Unlike previously described sliding motility, swashing is inhibited by surfactants and requires fermentable sugars. We propose that the fermentation of sugars at the colony edge produces osmolytes, creating local osmotic gradients that draw water from the agar, forming a fluid bulge that propels the colony forward. Our findings challenge the established view that flagellar propulsion is required for surface motility inE. coliandSalmonella, and highlight the role of a fermentation in facilitating bacterial spreading. This discovery expands our understanding of bacterial motility, offering new insights into bacterial adaptive strategies in diverse environments.Significance StatementBacteria move on surfaces using a variety of mechanisms, with important implications for their growth and survival in both the clinical setting (such as on the surface of medical devices) and in the wild. Surface motility in the medically important model speciesS. entericaandE. colihas been extensively studied and is thought to require flagellar propulsion. Here, we show surface expansion in these species even in the absence of propulsion by the flagella. Instead, movement is tied to fermentation and surface tension: As cells ferment sugars, they create local osmolarity gradients, which generate a wave of fluid on which the cells “swash.”