Abstract
Bacterial biofilms represent a survival strategy that enables microbial communities to withstand environmental stress. Stenotrophomonas maltophilia is an emerging, antibiotic-resistant, Gram-negative, opportunistic pathogen that frequently colonizes the lungs of individuals with cystic fibrosis. Its chaperone-usher pathway (CUP) pilus, SMF-1, is present in nearly all clinical isolates and is essential for biofilm development; however, its molecular architecture has remained unknown. Here, we present a 4.0 Å cryo-EM structure revealing that SMF-1 is an archaic, rather than a classic, CUP pilus. SMF-1 forms thin, zigzag filaments that assemble into defined antiparallel "pili-couples," which further aggregate into thick bundles. These bundles act as robust intercellular tethers, facilitating the rapid cell-to-cell aggregation required for biofilm initiation. Despite high sequence and structural similarity to classic CUP systems, SMF-1 lacks the interfaces required to form a rod-like architecture, suggesting it may represent an evolutionary intermediate between the CUP classes. Finally, we demonstrate that SMF-1 producing bacteria initiate biofilm formation within 24 hours and that flagella can further accelerate this process. Together, these findings uncover a conserved bundling mechanism that promotes bacterial colonization and may contribute to pathogenicity.