Noncollagenous proteins regulate the formation of the mineral constituent in hard tissue. The mineral formed contains apatite crystals coated by a functional disordered calcium phosphate phase. Although the crystalline phase of bone mineral was extensively investigated, little is known about the disordered layer's composition and structure, and less is known regarding the function of noncollagenous proteins in the context of this layer. In the current study, apatite was prepared with an acidic peptide (ON29) derived from the bone/dentin protein osteonectin. The mineral formed comprises needle-shaped hydroxyapatite crystals like in dentin and a stable disordered phase coating the apatitic crystals as shown using X-ray diffraction, transmission electron microscopy, and solid-state NMR techniques. The peptide, embedded between the mineral particles, reduces the overall phosphate content in the mineral formed as inferred from inductively coupled plasma and elemental analysis results. Magnetization transfers between disordered phase species and apatitic phase species are observed for the first time using 2D (1)H-(31)P heteronuclear correlation NMR measurements. The dynamics of phosphate magnetization transfers reveal that ON29 decreases significantly the amount of water molecules in the disordered phase and increases slightly their content at the ordered-disordered interface. The peptide decreases hydroxyl to disordered phosphate transfers within the surface layer but does not influence transfer within the bulk crystalline mineral. Overall, these results indicate that control of crystallite morphology and properties of the inorganic component in hard tissue by biomolecules is more involved than just direct interaction between protein functional groups and mineral crystal faces. Subtler mechanisms such as modulation of the disordered phase composition and structural changes at the ordered-disordered interface may be involved.
Osteonectin is a regulator of bone mineralization. It interacts specifically with collagen and apatite through its N-terminal domain, inhibiting crystal growth. In this work, we investigated the interface formed between the mineral and an acidic peptide, ON29, derived from the protein's apatite binding domain. The structural properties of the peptide bound to the mineral and the mineral−peptide interface are characterized using NMR and computational methods. A biomaterial complex is formed by precipitation of the mineral in the presence of the acidic peptide. The peptide gets embedded between mineral particles, which comprise a disordered hydrated coat covering apatite-like crystals. 31 P SEDRA measurements show that the peptide does not affect the overall proximity between phosphate ions in the mineral. { 15 N} 13 C REDOR measurements reveal an α-turn in the center of the free peptide, which is unchanged when it is bound to the mineral. { 31 P} 13 C REDOR and 1 H− 13 C HETCOR measurements show that Glu/Asp carboxylates and Thr/Ala/Val side chains from ON29 are proximate to phosphate and hydroxyl groups in the mineral phases. Predictions of ON29's fold on and off hydroxyapatite crystal faces using ROSETTA-surface are used to model the molecular conformation of the peptide and its apatite-binding interface. The models constructed without bias from experimental results are consistent with NMR measurements and map out extensively the residues forming an interface with apatitic crystals.
Details of apatite formation and development in bone below the nanometer scale remain enigmatic. Regulation of mineralization was shown to be governed by the activity of non-collagenous proteins with many bone diseases stemming from improper activity of these proteins. Apatite crystal growth inhibition or enhancement is thought to involve direct interaction of these proteins with exposed faces of apatite crystals. However, experimental evidence of the molecular binding events that occur and that allow these proteins to exert their functions are lacking. Moreover, recent high-resolution measurements of apatite crystallites in bone have shown that individual crystallites are covered by a persistent layer of amorphous calcium phosphate. It is therefore unclear whether non-collagenous proteins can interact with the faces of the mineral crystallites directly and what are the consequences of the presence of a disordered mineral layer to their functionality. In this work, the regulatory effect of recombinant osteopontin on biomimetic apatite is shown to produce platelet-shaped apatite crystallites with disordered layers coating them. The protein is also shown to regulate the content and properties of the disordered mineral phase (and sublayers within it). Through solid-state NMR atomic carbon-phosphorous distance measurements, the protein is shown to be located in the disordered phases, reaching out to interact with the surfaces of the crystals only through very few sidechains. These observations suggest that non-phosphorylated osteopontin acts as regulator of the coating mineral layers and exerts its effect on apatite crystal growth processes mostly from afar with a limited number of contact points with the crystal.
The conversion of biomass into biofuels can reduce the strategic vulnerability of petroleum-based systems and at the same time have a positive effect on global climate issues. Lignocellulose is the cheapest and most abundant source of biomass and consequently has been widely considered as a source for liquid fuel. However, despite ongoing efforts, cellulosic biofuels are still far from commercial realization, one of the major bottlenecks being the hydrolysis of cellulose into simpler sugars. Inspired by the structural and functional modularity of cellulases used by many organisms for the breakdown of cellulose, we propose to mimic the cellulose binding domain (CBD) and the catalytic domain of these proteins by small molecular entities. Multiple copies of these mimics could subsequently be tethered together to enhance hydrolytic activity. In this work, we take the first step toward achieving this goal by applying computational approaches to the design of efficient, cost-effective mimetics of the CBD. The design is based on low molecular weight peptides that are amenable to large-scale production. We provide an optimized design of four short (i.e., ∼18 residues) peptide mimetics based on the three-dimensional structure of a known CBD and demonstrate that some of these peptides bind cellulose as well as or better than the full CBD. The structures of these peptides were studied by circular dichroism and their interactions with cellulose by solid phase NMR. Finally, we present a computational strategy for predicting CBD/peptide-cellulose binding free energies and demonstrate its ability to provide values in good agreement with experimental data. Using this computational model, we have also studied the dissociation pathway of the CBDs/peptides from the surface of cellulose.
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