Abstract

Adherence of bacteria to biotic or abiotic surfaces is a prerequisite for host colonization and represents an important step in microbial pathogenicity. This attachment is facilitated by bacterial adhesins at the cell surface. Because of their size and often elaborate multidomain architectures, these polypeptides represent challenging targets for detailed structural and functional characterization. The multifunctional fibrillar adhesin CshA, which mediates binding to both host molecules and other microorganisms, is an important determinant of colonization by Streptococcus gordonii, an oral commensal and opportunistic pathogen of animals and humans. CshA binds the high-molecular-weight glycoprotein fibronectin (Fn) via an N-terminal non-repetitive region, and this protein-protein interaction has been proposed to promote S. gordonii colonization at multiple sites within the host. However, the molecular details of how these two proteins interact have yet to be established. Here we present a structural description of the Fn binding N-terminal region of CshA, derived from a combination of X-ray crystallography, small angle X-ray scattering, and complementary biophysical methods. In vitro binding studies support a previously unreported two-state "catch-clamp" mechanism of Fn binding by CshA, in which the disordered N-terminal domain of CshA acts to "catch" Fn, via formation of a rapidly assembled but also readily dissociable pre-complex, enabling its neighboring ligand binding domain to tightly clamp the two polypeptides together. This study presents a new paradigm for target binding by a bacterial adhesin, the identification of which will inform future efforts toward the development of anti-adhesive agents that target S. gordonii and related streptococci.

Highlights

  • Ramachandran outliers (%) 2.3 a Two separate CshA_NR2-SeMet crystals were used to collect data. b Values in parentheses are for highest resolution shell

  • Electrostatic Potential Calculations—For figures showing an electrostatic potential projected on the molecular surface of protein structures, the Poisson-Boltzmann electrostatic potential on the solvent-accessible surface is shown, with potential values ranging from Ϫ15 kT/e to 15 kT/e

  • Acknowledgments—We thank Jane Brittan and Lindsay Dutton for technical assistance, Dr Christopher Arthur for mass spectrometry analysis, and Kristian Le Vay, Genevieve Baker, and Dr Steven Burston for fruitful discussions

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Summary

Edited by Norma Allewell

Adherence of bacteria to biotic or abiotic surfaces is a prerequisite for host colonization and represents an important step in microbial pathogenicity. The filamentous adhesins, comprising pili and fibrils, are among the largest and most complex of all bacterial surface proteins They are found in both Gram-positive and Gram-negative bacteria, including many pathogenic species, and have attracted considerable attention due to their roles in colonization, infection, and as vaccine candidates [2, 3]. These proteins form sizable polymeric assemblies that project outwards from the bacterial cell surface, presenting an adhesive target-binding region at their tip. In vitro and in vivo binding assays, gene disruption experiments, and heterologous expression studies in the non-adherent bacterium Enterococcus faecalis have established CshA as an important determinant of S. gordonii adherence

Streptococcus gordonii CshA
Results
CshA domain KD ka ka error kd kd error
Discussion
Primer name
Experimental Procedures
Root mean square deviations

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