Abstract
Bacteria must withstand large mechanical shear forces when adhering to and colonizing hosts. Recent structural studies on a class of Gram-positive bacterial adhesins have revealed an intramolecular Cys-Gln thioester bond that can react with surface-associated ligands to covalently anchor to host surfaces. Two other examples of such internal thioester bonds occur in certain anti-proteases and in the immune complement system, both of which react with the ligand only after the thioester bond is exposed by a proteolytic cleavage. We hypothesized that mechanical forces in bacterial adhesion could regulate thioester reactivity to ligand analogously to such proteolytic gating. Studying the pilus tip adhesin Spy0125 of Streptococcus pyogenes, we developed a single molecule assay to unambiguously resolve the state of the thioester bond. We found that when Spy0125 was in a folded state, its thioester bond could be cleaved with the small-molecule nucleophiles methylamine and histamine, but when Spy0125 was mechanically unfolded and subjected to forces of 50-350 piconewtons, thioester cleavage was no longer observed. For folded Spy0125 without mechanical force exposure, thioester cleavage was in equilibrium with spontaneous thioester reformation, which occurred with a half-life of several minutes. Functionally, this equilibrium reactivity allows thioester-containing adhesins to sample potential substrates without irreversible cleavage and inactivation. We propose that such reversible thioester reactivity would circumvent potential soluble inhibitors, such as histamine released at sites of inflammation, and allow the bacterial adhesin to selectively associate with surface-bound ligands.
Highlights
Bacteria must withstand large mechanical shear forces when adhering to and colonizing hosts
We found that when Spy0125 was in a folded state, its thioester bond could be cleaved with the small-molecule nucleophiles methylamine and histamine, but when Spy0125 was mechanically unfolded and subjected to forces of 50 –350 piconewtons, thioester cleavage was no longer observed
This equilibrium reactivity allows thioester-containing adhesins to sample potential substrates without irreversible cleavage and inactivation. We propose that such reversible thioester reactivity would circumvent potential soluble inhibitors, such as histamine released at sites of inflammation, and allow the bacterial adhesin to selectively associate with surface-bound ligands
Summary
A2M, ␣2-macroglobulin; pN, piconewton; AFM, atomic force microscopy; PDB, Protein Data Bank; TED, thioester domain. We developed a single-molecule technique to study thioester chemistry with atomic force microscopy (AFM)based force spectroscopy. Using the Spy0125 pilus adhesin from Streptococcus pyogenes as our model bacterial TED, we unambiguously identify the state of the thioester bond (formed versus cleaved) with chemical and mutagenic modifications. We find that methylamine and histamine nucleophiles can cleave the thioester bond in the folded Spy0125. The Cys-Gln thioester bond spontaneously reforms at zero-force, preventing such soluble nucleophiles from permanently inactivating the adhesin. We propose that the Gram-positive bacterial TED may bind ligands in a reversible regime at zeroforce, but with a longer-lived interaction at sufficiently high force
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