Abstract
Collagen and fibronectin (Fn) are two key extracellular matrix proteins, which are known to interact and jointly shape matrix structure and function. Most proteins that interact with collagen bind only to the native triple-helical form, whereas Fn is unusual in binding strongly to denatured collagen and more weakly to native collagen. The consequences of replacing a Gly by Ser at each position in the required (Gly-Xaa-Yaa)6 Fn-binding sequence are probed here, using model peptides and a recombinant bacterial collagen system. Fluorescence polarization and solid-state assays indicated that Gly replacements at four sites within the Fn-binding sequence led to decreased Fn binding to denatured collagen. Molecular dynamics simulations showed these Gly replacements interfered with the interaction of a collagen β-strand with the β-sheet structure of Fn modules seen in the high resolution crystal structure. Whereas previous studies showed that Gly to Ser mutations within an integrin-binding site caused no major structural perturbations, mutations within the Fn-binding site caused the triple helix to become highly sensitive to trypsin digestion. This trypsin susceptibility is consistent with the significant local unfolding and loss of hydrogen bonding seen in molecular dynamics simulations. Protease sensitivity resulting from mutations in the Fn-binding sequence could lead to degradation of type I collagen, early embryonic lethality, and the scarcity of reported osteogenesis imperfecta mutations in this region.
Highlights
By their triple helix structure, composed of three polyproline II (PPII) helices supercoiled about a common axis [1, 2]
Molecular dynamics simulations are consistent with the decreased binding being due to disruption of the interaction of the collagen -strand with the Fn module -sheet reported in the crystal structure [5]
Most proteins that interact with collagen, such as integrins and SPARC, have a stringent requirement for a triple-helical collagen structure, and the structural basis for this requirement can be seen in the high resolution structure of co-crystals of the integrin I domain or SPARC with a triple helix peptide [21, 22]
Summary
Collagen and fibronectin (Fn) are two key extracellular matrix proteins, which are known to interact and jointly shape matrix structure and function. Whereas previous studies showed that Gly to Ser mutations within an integrinbinding site caused no major structural perturbations, mutations within the Fn-binding site caused the triple helix to become highly sensitive to trypsin digestion This trypsin susceptibility is consistent with the significant local unfolding and loss of hydrogen bonding seen in molecular dynamics simulations. The consequences of Gly to Ser replacements within the FBS of type II collagen are investigated using fluorescence polarization studies of singlestranded collagen model peptides and solid-state binding assays on the recombinant bacterial protein containing the human FBS. These studies showed that Gly substitutions at four positions in the FBS decreased Fn binding to denatured collagen. The unfolding and trypsin sensitivity caused by mutations in the FBS contrasts with the trypsin resistance seen for similar missense mutations within the integrin-binding site of collagen, indicating the importance of the sequence context in determining the structural consequence of mutations
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