Monomeric Amelogenin’s C-Terminus Modulates Biomineralization Dynamics of Calcium Phosphate

Wu, Shanshan; Zhai, Hang; Zhang, Wenjun; Wang, Lijun

doi:10.1021/acs.cgd.5b00754

Cited by 13 publications

(27 citation statements)

References 47 publications

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“…The present study of two structural analogues reveals the mechanism that is different from step density determined crystallization rates 29,50 and kink blocking. 26,27 Commonly, inhibitors adsorb to step edges or terraces ahead of migrating steps and impede the addition of solute molecules.…”

Section: ■ Introductionmentioning

confidence: 55%

“…The measured surface free energy determines the strength of substrate interaction with liquid and is supposed to manifest in the extent of the hydrophilicity of the substrates. , The difference of γ S–air , a proxy for γ SL at the solid (S)–liquid (L) interface, showed that HCA, at concentrations greater than 8.5 μM, dramatically increased DCPD–liquid interfacial energy compared to CA (Figure C). Because of γ SL correlating with the mean value of all crystal-plane-step energies, , a higher γ SL is associated with higher step edge free energy (γ step ) that will delay the formation of critical 1D steps . Consequently, the high affinity of HCA bound to DCPD displays stronger potency in decreasing step density than that of CA (Figure C,D).…”

Section: Resultsmentioning

confidence: 99%

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Mechanisms of Modulation of Calcium Phosphate Pathological Mineralization by Mobile and Immobile Small-Molecule Inhibitors

Zhang

Wang

et al. 2018

J. Phys. Chem. B

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Potential pathways for inhibiting crystal growth are via either disrupting local microenvironments surrounding crystal-solution interfaces or physically blocking solute molecule attachment. However, the actual mode of inhibition may be more complicated due to the characteristic time scale for the inhibitor adsorption and relaxation to a well-bound state at crystal surfaces. Here we demonstrate the role of citrate (CA) and hydroxycitrate (HCA) in brushite (DCPD, CaHPO·2HO) crystallization over a broad range of both inhibitor concentrations and supersaturations by in situ atomic force microscopy (AFM). We observed that both inhibitors exhibit two distinct actions: control of surface crystallization by the decrease of step density at high supersaturations and the decrease of the [1̅00] step velocity at high inhibitor concentration and low supersaturation. The switching of the two distinct modes depends on the terrace lifetime, and the slow kinetics along the [1̅00] step direction provides specific sites for the newly formed dislocations. Molecular modeling shows the strong HCA-crystal interaction by molecular recognition, explaining the AFM observations for the formation of new steps and surface dissolution along the [101] direction due to the introduction of strong localized strain in the crystal lattice. These direct observations highlight the importance of the inhibitor coverage on mineral surfaces, as well as the solution supersaturation in predicting the inhibition efficacy, and reveal an improved understanding of inhibition of calcium phosphate biomineralization, with clinical implications for the full therapeutic potential of small-molecule inhibitors for kidney stone disease.

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Section: ■ Introductionmentioning

confidence: 55%

Section: Resultsmentioning

confidence: 99%

Mechanisms of Modulation of Calcium Phosphate Pathological Mineralization by Mobile and Immobile Small-Molecule Inhibitors

Zhang

Wang

et al. 2018

J. Phys. Chem. B

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“…Once secreted into the extracellular space, amelogenin undergoes a series of proteolytic cleavages starting at the C‐Ame and assemble into nanospheres with a diameter of ≈10–20 nm, which are believed to play a key role in the mineralization and structural organization of enamel. [ 7–9 ] The N‐Ame is crucial for amelogenin self‐assembly into amyloid‐like aggregation through β‐sheet stacking to template the growth of HAp crystals, [ 10,11 ] and the C‐Ame mediate parallel alignment of these crystals [ 12–14 ] ( Scheme ). Hierarchically organized HAp nanorods are further formed in nature involving an aggregation of amorphous calcium phosphate (ACP) nanospheres and a transformation of ACP to HAp crystals (Figure S1, Supporting Information).…”

Section: Methodsmentioning

confidence: 99%

Controlling Enamel Remineralization by Amyloid‐Like Amelogenin Mimics

Wang

Deng

et al. 2020

Advanced Materials

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In situ regeneration of the enamel‐like structure of hydroxyapatite (HAp) crystals under oral conditions is significant for dental caries treatment. However, it is still a challenge for dentists to duplicate the elegant and well‐aligned apatite structure bonding to the surface of demineralized enamel. A biocompatible amelogenin‐inspired matrix, a phase‐transited lysozyme (PTL) film mimicking an N‐terminal amelogenin with central domain (N‐Ame) combined with synthetic peptide (C‐AMG) based on the functional domains of C‐terminal telopeptide (C‐Ame) is shown here, which is formed by amyloid‐like lysozyme aggregation at the enamel interface through a rapid one‐step aqueous coating process. In the PTL/C‐AMG matrix, C‐AMG facilitated the oriented arrangement of amorphous calcium phosphate (ACP) nanoparticles and their transformation to ordered enamel‐like HAp crystals, while PTL served as a strong interfacial anchor to immobilize the C‐AMG peptide and PTL/C‐AMG matrix on versatile substrate surfaces. PTL/C‐AMG film‐coated enamel induced both of the in vivo and in vitro synthesis of HAp crystals, facilitated epitaxial growth of HAp crystals and recovered the highly oriented structure and mechanical properties to levels nearly identical to those of natural enamel. This work underlines the importance of amyloid‐like protein aggregates in the biomineralization of enamel, providing a promising strategy for treating dental caries.

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“…For example, solid-state nuclear magnetic resonance (ssNMR), which accurately determines distances between specific atoms, is costly and difficult to perform on substrates lacking phosphorus or carbon. Single-molecule force spectroscopy (SMFS) techniques, such as atomic force microscopy ,− (AFM), can determine the energy (Δ G ) of protein adsorption, yielding thermodynamic information about protein–surface binding, but they do not provide sufficient imaging resolution to determine biomolecular structures …”

Section: Introductionmentioning

confidence: 99%

A Parametric Rosetta Energy Function Analysis with LK Peptides on SAM Surfaces

2018

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Although structures have been determined for many soluble proteins and an increasing number of membrane proteins, experimental structure determination methods are limited for complexes of proteins and solid surfaces. An economical alternative or complement to experimental structure determination is molecular simulation. Rosetta is one software suite that models protein-surface interactions, but Rosetta is normally benchmarked on soluble proteins. For surface interactions, the validity of the energy function is uncertain because it is a combination of independent parameters from energy functions developed separately for solution proteins and mineral surfaces. Here, we assess the performance of the RosettaSurface algorithm and test the accuracy of its energy function by modeling the adsorption of leucine/lysine (LK)-repeat peptides on methyl- and carboxy-terminated self-assembled monolayers (SAMs). We investigated how RosettaSurface predictions for this system compare with the experimental results, which showed that on both surfaces, LK-α peptides folded into helices and LK-β peptides held extended structures. Utilizing this model system, we performed a parametric analysis of Rosetta's Talaris energy function and determined that adjusting solvation parameters offered improved predictive accuracy. Simultaneously increasing lysine carbon hydrophilicity and the hydrophobicity of the surface methyl head groups yielded computational predictions most closely matching the experimental results. De novo models still should be interpreted skeptically unless bolstered in an integrative approach with experimental data.

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Monomeric Amelogenin’s C-Terminus Modulates Biomineralization Dynamics of Calcium Phosphate

Cited by 13 publications

References 47 publications

Mechanisms of Modulation of Calcium Phosphate Pathological Mineralization by Mobile and Immobile Small-Molecule Inhibitors

Mechanisms of Modulation of Calcium Phosphate Pathological Mineralization by Mobile and Immobile Small-Molecule Inhibitors

Controlling Enamel Remineralization by Amyloid‐Like Amelogenin Mimics

A Parametric Rosetta Energy Function Analysis with LK Peptides on SAM Surfaces

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