Control of Calcium Phosphate Nucleation and Transformation through Interactions of Enamelin and Amelogenin Exhibits the “Goldilocks Effect”

Tao, Jinhui; Fijneman, Andreas J.; Wan, Jiaqi; Prajapati, Saumya; Mukherjee, Kaushik; Fernández-Martı́nez, Alejandro; Moradian‐Oldak, Janet; Yoreo, James J. De

doi:10.1021/acs.cgd.8b01066

Cited by 29 publications

(51 citation statements)

References 72 publications

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“…In vitro and in vivo studies have suggested that protein assembly is the principal mechanism for controlling nucleation, growth, and organization of mineral crystals during enamel biomineralization ( Margolis et al, 2006 ; Moradian-Oldak, 2012 ). Enamel extracellular proteins may function in a cooperative or synergic manner and direct interactions or co-assembly may be a requirement for their role ( Fan et al, 2011 ; Wald et al, 2017 ; Tao et al, 2018 ).…”

Section: Discussionmentioning

confidence: 99%

“…This could also explain the severe separation of ameloblasts from underlying matrix in mice with deleted Ambn exons 5 and 6 ( Fukumoto et al, 2004 ). Another aspect of such interactions may be related to the synergic function of these proteins in controlling mineral nucleation and growth ( Fan et al, 2011 ; Tao et al, 2018 ). The ability of Ambn C-terminal region to bind calcium has been well-documented ( Yamakoshi et al, 2001 ; Tarasevich et al, 2007 ; Zhang et al, 2011 ) suggesting Ambn’s involvement in mineralization.…”

Section: Discussionmentioning

confidence: 99%

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Co-Immunoprecipitation Reveals Interactions Between Amelogenin and Ameloblastin via Their Self-Assembly Domains

Bapat

Moradian‐Oldak

2020

Front. Physiol.

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Macromolecular assembly of extracellular enamel matrix proteins (EMPs) is intimately associated with the nucleation, growth, and maturation of highly organized hydroxyapatite crystals giving rise to healthy dental enamel. Although the colocalization of two of the most abundant EMPs amelogenin (Amel) and ameloblastin (Ambn) in molar enamel has been established, the evidence toward their interaction is scarce. We used co-immunoprecipitation (co-IP) to show evidence of direct molecular interactions between recombinant and native Amel and Ambn. Ambn fragments containing Y/F-x-x-Y/L/F-x-Y/F self-assembly motif were isolated from the co-IP column and characterized by mass spectroscopy. We used recombinant Ambn (rAmbn) mutants with deletion of exons 5 and 6 as well as Ambn derived synthetic peptides to demonstrate that Ambn binds to Amel via its previously identified Y/F-x-x-Y/L/F-x-Y/F self-assembly motif at the N-terminus of its exon 5 encoded region. Using an N-terminal specific anti-Ambn antibody, we showed that Ambn N-terminal fragments colocalized with Amel from secretory to maturation stages of enamel formation in a single section of developing mouse incisor, and closely followed mineral patterns in enamel rod interrod architecture. We conclude that Ambn self-assembly motif is involved in its interaction with Amel in solution and that colocalization between the two proteins persists from secretory to maturation stages of amelogenesis. Our in vitro and in situ data support the notion that Amel and Ambn may form heteromolecular assemblies that may perform important physiological roles during enamel formation.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Co-Immunoprecipitation Reveals Interactions Between Amelogenin and Ameloblastin via Their Self-Assembly Domains

Bapat

Moradian‐Oldak

2020

Front. Physiol.

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“…3g). If adsorbed randomly with no energetic bias for adsorption next to neighbouring proteins, the expected coverage of isolated monomers for the total 2nd layer coverage seen here (23%) would be 7% 38 , which is 20 times the observed 0.35% coverage of isolated monomers ( Supplementary Fig. 12).…”

Section: Resultsmentioning

confidence: 50%

Assembly of a patchy protein into variable 2D lattices via tunable multiscale interactions

et al. 2020

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Self-assembly of molecular building blocks into higher-order structures is exploited in living systems to create functional complexity and represents a powerful strategy for constructing new materials. As nanoscale building blocks, proteins offer unique advantages, including monodispersity and atomically tunable interactions. Yet, control of protein self-assembly has been limited compared to inorganic or polymeric nanoparticles, which lack such attributes. Here, we report modular self-assembly of an engineered protein into four physicochemically distinct, precisely patterned 2D crystals via control of four classes of interactions spanning Ångström to several-nanometer length scales. We relate the resulting structures to the underlying free-energy landscape by combining in-situ atomic force microscopy observations of assembly with thermodynamic analyses of protein-protein and-surface interactions. Our results demonstrate rich phase behavior obtainable from a single, highly patchy protein when interactions acting over multiple length scales are exploited and predict unusual bulk-scale properties for protein-based materials that ensue from such control.

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“…3, a to e and Supplementary Videos 1 to 5) revealed that ACP ((Ca 2 (HPO 4 ) 3 ) 2-) was the rst phase to form at all values of σ explored here for all ve sequences, as validated by in situ AFM and electron microscopy (Supplementary Figs. 11 to 13) and observed previously for nucleation on a number of proteins [18][19][20] . The ACP particles grew in size ( Supplementary Table S3) before transforming to ber-or plate-shaped mineral (Fig.…”

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confidence: 57%

“…To determine the mechanism and underlying energetic factors through which Amel NR drive ACP nucleation, the data on nucleation rates vs σ were analyzed using classical nucleation theory (CNT), which has been used previously to analyze heterogeneous nucleation on organic templates 18,19,[21][22][23] and has been shown to effectively describe ACP nucleation kinetics 18 . CNT predicts that the heterogeneous nucleation rate (J o ) varies exponentially with the effective interfacial energy (α ACP ) and σ ACP according to:…”

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confidence: 99%

Amyloid-like amelogenin nanoribbons template mineralization via a low energy interface of ion binding sites

Akkineni¹,

Zhu²,

Chen³

et al. 2021

Preprint

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Protein scaffolds direct the organization of amorphous precursors that transform into mineralized tissues, but the templating mechanism remains elusive. Inspired by a model of tooth enamel, wherein amyloid-like amelogenin nanoribbons guide apatite mineralization, we investigated the impact of nanoribbon structure and chemistry on amorphous calcium phosphate (ACP) nucleation. Using amelogenin sub-segments including an amyloid-like domain, nanoribbon conformation and function were determined by in situ atomic force microscopy and molecular dynamics simulations. All sequences substantially reduce nucleation barriers by creating low-energy interfaces, while phosphorylation dramatically enhances kinetic factors associated with ion binding. Furthermore, the predicted distribution of hydrophilic residues in the amyloid domain matches the structure of the multi-ion clusters comprising ACP. These findings provide crucial insights into structure-function relationships underlying amelogenin biomineralization and a generalizable system for synthesizing hybrid materials for various applications.

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Control of Calcium Phosphate Nucleation and Transformation through Interactions of Enamelin and Amelogenin Exhibits the “Goldilocks Effect”

Cited by 29 publications

References 72 publications

Co-Immunoprecipitation Reveals Interactions Between Amelogenin and Ameloblastin via Their Self-Assembly Domains

Co-Immunoprecipitation Reveals Interactions Between Amelogenin and Ameloblastin via Their Self-Assembly Domains

Assembly of a patchy protein into variable 2D lattices via tunable multiscale interactions

Amyloid-like amelogenin nanoribbons template mineralization via a low energy interface of ion binding sites

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