Abstract
Collagen fibril interactions with cells and macromolecules in the extracellular matrix drive numerous cellular functions. Binding motifs for dozens of collagen-binding proteins have been determined on fully exposed collagen triple helical monomers. However, when the monomers are assembled into the functional collagen fibril, many binding motifs become inaccessible, and yet critical cellular processes occur. Here, we have developed an early stage atomic model of the smallest repeating unit of the type I collagen fibril at the fibril surface that provides a novel framework to address questions about these functionally necessary yet seemingly obstructed interactions. We use an integrative approach by combining molecular dynamics (MD) simulations with atomic force microscopy (AFM) experiments and show that reconstruction of the collagen monomers within the complex fibril play a critical role in collagen interactions. In particular, the fibril surface shows three major conformational changes, which allow cryptic binding sites, including an integrin motif involved in platelet aggregation, to be exposed. The observed dynamics and reconstruction of the fibril surface promote its role as a “smart fibril” to keep certain binding sites cryptic, and to allow accessibility of recognition domains when appropriate.
Highlights
The extracellular matrix (ECM) in connective tissues contains a mixture of biological components that regulate cell migration, growth, and differentiation through cellular interactions
In order to characterize these motions in further detail over the time course of the simulation and address how the surface reconstruction may facilitate ligand binding, we analyzed time points of the simulation in terms of displacements, dynamics, hydrogen bond modulation, and accessibilities
Our simulation is certainly not fully equilibrated, we have found that fluctuations at the interaction surface of the type I collagen fibril allow sampling of rare events on the hundreds of nanoseconds timescale
Summary
The extracellular matrix (ECM) in connective tissues contains a mixture of biological components that regulate cell migration, growth, and differentiation through cellular interactions. The approximate locations of the six highlighted integrin binding motifs are shown within the smallest repeating unit (SRU) of the fibril, which is one D-period length of the microfibril and contains a bundle of five unique segments from different collagen monomers (Fig. 1c). These “D-segments” contain the entire type I collagen sequence. The X-ray fiber diffraction model provides only the Cα positions and does not have the resolution to make conclusions about atomic-level details of triple helical conformations within the fibril, it importantly provides the arrangement of collagen monomers within the repeating unit of the fibril, which allows us to model relative positions of interaction sites near the fibril surface. The conformational fluctuations change the accessibility of certain binding regions over time and suggest that the dynamics on the surface are critical for collagen fibril interactions and dependent cellular processes
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