Extreme envelope plasticity drives temperature-dependent morphogenesis in the LPS-free bacterium Sphingobium yanoikuyae

Bacterial growth patterns are generally considered to be constrained and species-specific. Here, we show that Sphingobium yanoikuyae exhibits exceptional plasticity in envelope architecture and morphogenesis driven by a glycosphingolipid (GSL)-based outer membrane and an atypical peptidoglycan structure. At 30{degrees}C, cells expand asymmetrically via a rare bipolar envelope synthesis mode, whereas growth at 37{degrees}C triggers a transition toward longitudinal elongation accompanied by increased outer membrane vesiculation, indicating a reversible reprogramming of morphogenesis under host-like conditions. This switch is supported by rapid outer membrane dynamics, including high membrane fluidity and fast redistribution of envelope components. Despite these pronounced morphological changes, peptidoglycan composition remains conserved and unusually short, suggesting that growth plasticity is governed primarily by spatial regulation rather than changes in cell wall chemistry. Genetic analyses further identify essential roles for proteins involved in outer membrane - peptidoglycan and outer membrane - inner membrane coupling, as well as GSL transport systems, and core cell wall synthesis machinery, while revealing extensive redundancy in envelope remodeling enzymes. Together, these results establish S. yanoikuyae as a model for extreme envelope adaptability, where a highly fluid outer membrane and structurally unconventional peptidoglycan enable reversible transitions between distinct growth programs, potentially shaping environmental fitness and host-associated interactions.