Catch Bond-mediated Adhesion without a Shear Threshold

Abstract: The FimH protein is the adhesive subunit of Escherichia coli type 1 fimbriae. It mediates shear-dependent bacterial binding to monomannose (1M)-coated surfaces manifested by the existence of a shear threshold for binding, below which bacteria do not adhere. The 1M-specific shear-dependent binding of FimH is consistent with so-called catch bond interactions, whose lifetime is increased by tensile force. We show here that the oligosaccharide-specific interaction of FimH with another of its ligands, trimannose (3… Show more

“…In contrast to 3M-RB-coated surfaces, where E. coli slowly rolls along the surface without detaching at shear stress levels below about 10 dynes/cm 2 , E. coli cannot stably adhere to 1M-BSAcoated surfaces below about 0.5 dynes/cm 2 . The cells roll rapidly on FimH-1M bonds, lasting less than 1 s at shear stress levels between roughly 0.5 and 10 dynes/cm 2 , with rolling velocities averaging 5 to 20 m/s compared to averages of 0.1 to 0.4 m/s on 3M-RB at 3.7 dynes/cm 2 (even in spite of the use of a 100-fold lower 3M-RB incubation concentration), consistent with a longer FimH-3M than FimH-1M bond lifetime (23). In 1M-mediated adhesion, bacteria switch to a shearactivated stationary state at shear stress levels above 10 dynes/ cm 2 , similar to what is seen with adhesion to 3M but resulting in bacteria remaining stationary for only about a minute, a time considerably shorter than the 3M-mediated adhesion time (32) (Fig.…”

“…This shear stress-induced enhancement of binding strength correlates with shear stress (and therefore dragging force) rather than shear rate (and transport) (34) and occurs only if the bacteria bind to surfaces coated with mannose but not to surfaces presenting FimH antibodies (33). Furthermore, the shear regime in which maximum adhesion occurs can be tuned by point mutations in the lectin domain of FimH, which gives further structural proof that shear stress-enhanced adhesion is specific to the FimHmannose bond (23,33,34). Finally, while cells are deformable objects, shear stress-enhanced adhesion also occurs for rigid monomannose (1M)-coated beads binding to surfaces coated with purified type 1 fimbriae (8).…”

“…These long-lived bonds mediate firm stationary bacterial adhesion for periods on the order of 1 min on 1M-coated surfaces and for over 30 min on 3M-coated surfaces. The longer lifetime of FimH binding to 3M compared to 1M is likely due to additional FimH-ligand contact points outside the 1M-binding pocket of FimH (23).…”

Elevated Shear Stress Protects Escherichia coli Cells Adhering to Surfaces via Catch Bonds from Detachment by Soluble Inhibitors

“…In contrast to 3M-RB-coated surfaces, where E. coli slowly rolls along the surface without detaching at shear stress levels below about 10 dynes/cm 2 , E. coli cannot stably adhere to 1M-BSAcoated surfaces below about 0.5 dynes/cm 2 . The cells roll rapidly on FimH-1M bonds, lasting less than 1 s at shear stress levels between roughly 0.5 and 10 dynes/cm 2 , with rolling velocities averaging 5 to 20 m/s compared to averages of 0.1 to 0.4 m/s on 3M-RB at 3.7 dynes/cm 2 (even in spite of the use of a 100-fold lower 3M-RB incubation concentration), consistent with a longer FimH-3M than FimH-1M bond lifetime (23). In 1M-mediated adhesion, bacteria switch to a shearactivated stationary state at shear stress levels above 10 dynes/ cm 2 , similar to what is seen with adhesion to 3M but resulting in bacteria remaining stationary for only about a minute, a time considerably shorter than the 3M-mediated adhesion time (32) (Fig.…”

“…This shear stress-induced enhancement of binding strength correlates with shear stress (and therefore dragging force) rather than shear rate (and transport) (34) and occurs only if the bacteria bind to surfaces coated with mannose but not to surfaces presenting FimH antibodies (33). Furthermore, the shear regime in which maximum adhesion occurs can be tuned by point mutations in the lectin domain of FimH, which gives further structural proof that shear stress-enhanced adhesion is specific to the FimHmannose bond (23,33,34). Finally, while cells are deformable objects, shear stress-enhanced adhesion also occurs for rigid monomannose (1M)-coated beads binding to surfaces coated with purified type 1 fimbriae (8).…”

“…These long-lived bonds mediate firm stationary bacterial adhesion for periods on the order of 1 min on 1M-coated surfaces and for over 30 min on 3M-coated surfaces. The longer lifetime of FimH binding to 3M compared to 1M is likely due to additional FimH-ligand contact points outside the 1M-binding pocket of FimH (23).…”

Elevated Shear Stress Protects Escherichia coli Cells Adhering to Surfaces via Catch Bonds from Detachment by Soluble Inhibitors

“…Ten percent of protein domains have a β ‐sandwich structure, including the binding domains in catch‐bond forming cadherins,42, 43 and many bacterial adhesins that mediate a shear‐enhanced adhesion that strongly suggests catch bonds 44, 45, 46, 47, 48, 49. It is possible that backbone fluctuations in β ‐sandwich folds are common in catch‐bond forming proteins because the β sandwich would confer the mechanical stability needed to withstand force, while the twisting fluctuations would allow the allostery that provides a mechanism for catch bonds.…”

Mechanism of allosteric propagation across a β‐sheet structure investigated by molecular dynamics simulations

“…The untreated glass surface used in those experiments sets this process apart from the surface-specific phenomenon of catch bonds, whereby bacteria, such as Escherichia coli, possess specific adhesins that attach to mannose-coated surfaces in a shear-dependent manner. In these species-specific cases, increasing shear rate strengthens attachment (31). Whereas catch bonds strengthen adhesion after a cell has landed on a surface, shear trapping increases the flux of cells toward the surface.…”

Microfluidic Studies of Biofilm Formation in Dynamic Environments