Thicket and mesh: Understanding turgor pressure resistance of outer membrane-cell wall system.

Abstract

The cell envelope of Gram-negative bacteria is composed of three layers: the outer membrane (OM), the peptidoglycan cell wall (PG), and the inner membrane. Together, the cell envelope provides a physical and chemical barrier that protects against the turgor pressure generated by the solute concentration difference between the inside and outside of bacteria, which can range from 0.2 atm to 5 atm. Previously, we measured the contribution of each component to see how it responds to different strains and determined that most of the cell envelope's strength comes from the OM and PG. However, the combined contribution from the OM and the PG, especially considering the Braun's lipoprotein (Lpp) that connects the two, remains to be elucidated. To address this, we constructed and simulated a combined OM-PG system that contains both OM and PG connected by Lpp. We also imposed different initial PG strain levels by stretching it by 2.0X and 2.5X its original size. The results showed that OM can resist imposed tensions by PG up to 2.0x its resting size. Moreover, we explored how the OM/PG-spanning protein TolC can affect the overall resistance to tension, through both enhancement of the connections between the layers and weakening them individually.