The role of intracellular calcium phosphate in osteoblast-mediated bone apatite formation

Boonrungsiman, Suwimon; Gentleman, Eileen; Carzaniga, Raffaella; Evans, Nicholas D.; McComb, David W.; Porter, Alexandra E.; Stevens, Molly M.

doi:10.1073/pnas.1208916109

Cited by 457 publications

(426 citation statements)

References 33 publications

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“…In native bone tissue, the structural integrity of bone is a tightly regulated process controlled by coordinated mechanism of collagen synthesis by osteoblasts and their subsequent mineralisation by poorly crystalline HA [45]. The crystal morphology of needle-like nanocrystals obtained on fibroin in our study was similar to the dimensions found on collagen-HA, as…”

Section: Discussionsupporting

confidence: 69%

Elucidation of differential mineralisation on native and regenerated silk matrices

Midha¹,

Tripathi²,

Geng

et al. 2016

Materials Science and Engineering: C

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Bone mineralisation is a well-orchestrated procedure triggered by a protein-based template inducing the nucleation of hydroxyapatite (HA) nanocrystals on the matrix. In an attempt to fabricate superior nanocomposites from silk fibroin, textile braided structures made of natively spun fibres of Bombyx mori silkworm were compared against regenerated fibroin (lyophilised and films) underpinning the influence of intrinsic properties of fibroin matrices on HA nucleation. We found that native braids could bind Ca 2+ ions through electrostatic attraction, which initiated the nucleation and deposition of HA, as evidenced by discrete shift in amide peaks via ATR-FTIR. This phenomenon also suggests the involvement of amide linkages in promoting HA nucleation on fibroin. Moreover, CaCl 2 -SBF immersion of native braids resulted in preferential growth of HA along the c-axis, forming needle-like nanocrystals and possessing Ca/P ratio comparable to commercial HA. Though regenerated lyophilised matrix also witnessed prominent peak shift in amide linkages, HA growth was restricted to (211) plane only, albeit at a significantly lower intensity than braids. Regenerated films, on the other hand, provided no crystallographic evidence of HA deposition within 7 days of SBF immersion. The present work sheds light on the primary fibroin structure of B.mori which probably plays a crucial role in regulating template-induced biomineralisation on the matrix. We also found that intrinsic material properties such as surface roughness, geometry, specific surface area, tortuosity and secondary conformation exert influence in modulating the extent of mineralisation. Thus our work generates useful insights and warrants future studies to further investigate the potential of bone mimetic, silk/mineral nanocomposite matrices for orthopaedic applications.

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Section: Discussionsupporting

confidence: 69%

Elucidation of differential mineralisation on native and regenerated silk matrices

Midha¹,

Tripathi²,

Geng

et al. 2016

Materials Science and Engineering: C

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“…Metabolomics analysis of differentiated MSC proved that glycolytic induction of lactate production is lowered; whereas, the amount of mitochondrial TCA intermediates such as citrate derived from oxidative metabolism are increased 19. A novel model for bone apatite formation proposed that calcium and phosphorus‐containing mineral aggregates in osteoblast mitochondria, transports via vesicles to the ECM and then converts to more crystalline 9. Interestingly, we determined that accumulation of citrate precipitation was closely associated with calcium deposition and ZIP1‐mediated Zn 2+ influx during osteogenesis (Figures 1, 4, and 5).…”

Section: Discussionmentioning

confidence: 99%

Runx2/Osterix and Zinc Uptake Synergize to Orchestrate Osteogenic Differentiation and Citrate Containing Bone Apatite Formation

Huang

et al. 2018

Advanced Science

101

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Citrate is essential to biomineralization of the bone especially as an integral part of apatite nanocomposite. Citrate precipitate of apatite is hypothesized to be derived from mesenchymal stem/stromal cells (MSCs) upon differentiation into mature osteoblasts. Based on 13C‐labeled signals identified by solid‐state multinuclear magnetic resonance analysis, boosted mitochondrial activity and carbon‐source replenishment of tricarboxylic acid cycle intermediates coordinate to feed forward mitochondrial anabolism and deposition of citrate. Moreover, zinc (Zn2+) is identified playing dual functions: (i) Zn2+ influx is influenced by ZIP1 which is regulated by Runx2 and Osterix to form a zinc‐Runx2/Osterix‐ZIP1 regulation axis promoting osteogenic differentiation; (ii) Zn2+ enhances citrate accumulation and deposition in bone apatite. Furthermore, age‐related bone loss is associated with Zn2+ and citrate homeostasis; whereas, restoration of Zn2+ uptake alleviates age‐associated declining osteogenic capacity and amount of citrate deposition. Together, these results indicate that citrate is not only a key metabolic intermediate meeting the emerging energy demand of differentiating MSCs but also participates in extracellular matrix mineralization, providing mechanistic insight into Zn2+ homeostasis and bone formation.

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“…(35) In both endochondral ossification and matrix mineralization, however, it seems likely that an initial phase of amorphous mineral deposition precedes the formation of more highly organized mineral. (36,37) Bone mineralization in OI In most cases of OI, mineralization processes seem to be in place and normally functioning. Two exceptions, however, may be the types V and VI OI initially identified as having distinct bone histological appearances (type V mesh-like under polarized light; type VI osteomalacic) at the level of light microscopy.…”

Section: Mineralization Of Bone Matrixmentioning

confidence: 99%

Bone Material Properties in Osteogenesis Imperfecta

Bishop

2016

Journal of Bone and Mineral Research

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Osteogenesis imperfecta entrains changes at every level in bone tissue, from the disorganization of the collagen molecules and mineral platelets within and between collagen fibrils to the macroarchitecture of the whole skeleton. Investigations using an array of sophisticated instruments at multiple scale levels have now determined many aspects of the effect of the disease on the material properties of bone tissue. The brittle nature of bone in osteogenesis imperfecta reflects both increased bone mineralization density-the quantity of mineral in relation to the quantity of matrix within a specific bone volume-and altered matrix-matrix and matrix mineral interactions. Contributions to fracture resistance at multiple scale lengths are discussed, comparing normal and brittle bone. Integrating the available information provides both a better understanding of the effect of current approaches to treatment-largely improved architecture and possibly some macroscale toughening-and indicates potential opportunities for alternative strategies that can influence fracture resistance at longer-length scales.

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The role of intracellular calcium phosphate in osteoblast-mediated bone apatite formation

Cited by 457 publications

References 33 publications

Elucidation of differential mineralisation on native and regenerated silk matrices

Elucidation of differential mineralisation on native and regenerated silk matrices

Runx2/Osterix and Zinc Uptake Synergize to Orchestrate Osteogenic Differentiation and Citrate Containing Bone Apatite Formation

Bone Material Properties in Osteogenesis Imperfecta

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