Crossfibrillar mineral tessellation in normal and <em>Hyp</em> mouse bone as revealed by 3D FIB-SEM microscopy

Buss, Daniel J.; Reznikov, Natalie; McKee, Marc D.

Affiliations

¹Department of Anatomy and Cell Biology, McGill University, 3640 University Street, Montreal, Quebec H3A 0C7, Canada

²Object Research Systems Inc., Object Research Systems, 760 Saint Paul West, Montreal, Quebec H3C 1M4, Canada

³Faculty of Dentistry, McGill University, 3640 University Street, Montreal, Quebec H3A 0C7, Canada

Abstract

In bone, structural components such as mineral extend across length scales to provide essential biomechanical functions. Using X-ray micro-computed tomography (µCT), and focused ion beam scanning electron microscopy (FIB-SEM) in serial-surface-view mode, together with 3D reconstruction, entire mouse skeletons and small bone tissue volumes were examined in normal wildtype (WT) and mutant Hyp mice (an animal model for X-linked hypophosphatemia/XLH, a disease with severe hypomineralization of bone). 3D thickness maps of the skeletons showed pronounced irregular thickening and abnormalities of many skeletal elements in Hyp mice compared to WT mice. At the micro- and nanoscale, near the mineralization front in WT tibial bone volumes, mineralization foci grow as expanding prolate ellipsoids (tesselles) to abut and pack against one another to form a congruent and contiguous mineral tessellation pattern within collagen bundles that contributes to lamellar periodicity. In the osteomalacic Hyp mouse bone, mineralization foci form and begin initial ellipsoid growth within normally organized collagen assembly, but their growth trajectory aborts. Mineralization-inhibiting events in XLH/Hyp (low circulating serum phosphate, and increased matrix osteopontin) combine to result in decreased mineral ellipsoid tessellation – a defective mineral-packing organization that leaves discrete mineral volumes isolated in the extracellular matrix such that ellipsoid packing/tessellation is not achieved. Such a severely altered mineralization pattern invariably leads to abnormal compliance, other aberrant biomechanical properties, and altered remodeling of bone, all of which indubitably lead to macroscopic bone deformities and anomalous mechanical performance in XLH/Hyp. Also, we show the relationship of osteocytes and their cell processes to this mineralization pattern.

Links

DOI: 10.1016/j.jsb.2020.107603

PubMed: 32805412

WoS: 000579373100002

History

Received: 2020-05-30

Revised: 2020-08-10

Accepted: 2020-08-12

Online: 2020-08-14

Cited Works (24)

Year	Entry
2017	Achrai B, Wagner HD. The turtle carapace as an optimized multi-scale biological composite armor: a review. J Mech Behav Biomed Mater. September 2017;73:50-67.
2002	Currey JD. Bones: Structure and Mechanics. Princeton, NJ: Princeton University Press; 2002.
1993	Landis WJ, Song MJ, Leith A, McEwen L, McEwen BF. Mineral and organic matrix interaction in normally calcifying tendon visualized in three dimensions by high-voltage electron microscopic tomography and graphic image reconstruction. J Struct Biol. January 1993;110(1):39-54.
2012	McNally EA, Schwarcz HP, Botton GA, Arsenault AL. A model for the ultrastructure of bone based on electron microscopy of ion-milled sections. PLoS One. January 17, 2012;7(1):e29258.
2013	Dallas SL, Prideaux M, Bonewald LF. The osteocyte: an endocrine cell … and more. Endocr Rev. October 2013;34(4):658-690.
2010	Dallas SL, Bonewald LF. Dynamics of the transition from osteoblast to osteocyte. Annals NY Acad Sci. March 2010;1192(1):437-443.
1965	Ascenzi A, Bonucci E, Bocciarelli DS. An electron microscope study of osteon calcification. J Ultrastruct Res. April 1965;12(3-4):287-303.
2020	Reznikov N, Hoac B, Buss DJ, Addison WN, Barros NMT, McKee MD. Biological stenciling of mineralization in the skeleton: local enzymatic removal of inhibitors in the extracellular matrix. Bone. September 2020;138:115447.
1969	Boyde A, Hobdell MH. Scanning electron microscopy of primary membrane bone. Z Zellforsch. 1969;99(1):98-108.
2007	Rath Bonivtch A, Bonewald LF, Nicolella DP. Tissue strain amplification at the osteocyte lacuna: a microstructural finite element analysis. J Biomech. 2007;40(10):2199-2206.
2016	Millán JL, Whyte MP. Alkaline phosphatase and hypophosphatasia. Calcif Tiss Int. April 2016;98(4):398-416.
2018	Hasegawa T, Yamamoto T, Hongo H, Qiu Z, Abe M, Kanesaki T, Tanaka K, Endo T, de Freitas PHL, Li M, Amizuka N. Three-dimensional ultrastructure of osteocytes assessed by focused ion beam-scanning electron microscopy (FIB-SEM). Histochem Cell Biol. April 2018;149(4):423-432.
2020	Orriss IR. Extracellular pyrophosphate: the body's “water softener”. Bone. May 2020;134:115243.
1984	Currey JD. Mechanical Adaptations of Bone. Princeton, NJ: Princeton University Press; 1984.
2001	You L, Cowin SC, Schaffler MB, Weinbaum S. A model for strain amplification in the actin cytoskeleton of osteocytes due to fluid drag on pericellular matrix. J Biomech. November 2001;34(11):1375-1386.
2014	Reznikov N, Shahar R, Weiner S. Three-dimensional structure of human lamellar bone: the presence of two different materials and new insights into the hierarchical organization. Bone. February 2014;59:93-104.
1995	McKee MD, Nanci A. Osteopontin and the bone remodeling sequence: colloidal-gold immunocytochemistry of an interfacial extracellular matrix protein. Annals NY Acad Sci. 1995;760(1):177-189.
2013	Reznikov N, Almany-Magal R, Shahar R, Weiner S. Three-dimensional imaging of collagen fibril organization in rat circumferential lamellar bone using a dual beam electron microscope reveals ordered and disordered sub-lamellar structures. Bone. February 2013;52(2):676-683.
2018	Reznikov N, Bilton M, Lari L, Stevens MM, Kröger R. Fractal-like hierarchical organization of bone begins at the nanoscale. Science. May 4, 2018;360(6388):eaao2189.
1996	McKee MD, Nanci A. Osteopontin at mineralized tissue interfaces in bone, teeth, and osseointegrated implants: ultrastructural distribution and implications for mineralized tissue formation, turnover, and repair. Microsc Res Tech. February 1996;33(2):141-164.
2018	Grandfield K, Vuong V, Schwarcz HP. Ultrastructure of bone: hierarchical features from nanometer to micrometer scale revealed in focused ion beam sections in the TEM. Calcif Tiss Int. December 2018;103(6):606-616.
1986	Weiner S, Traub W. Organization of hydroxyapatite crystals within collagen fibrils. FEBS Lett. October 1986;206(2):262-266.
1967	Marino AA, Becker RO, Bachman CH. Dielectric determination of bound water of bone. Phys Med Biol. 1967;12(3):367-378.
2015	Schwarcz HP. The ultrastructure of bone as revealed in electron microscopy of ion-milled sections. Semin Cell Dev Biol. October 2015;46:44-50.

Cited By (12)

Year	Entry
2021	Raguin E, Rechav K, Shahar R, Weiner S. Focused ion beam-SEM 3D analysis of mineralized osteonal bone: lamellae and cement sheath structures. Acta Biomater. February 2021;121:497-513.
2022	Grandfield K, Micheletti C, Deering J, Arcuri G, Tang T, Langelier B. Atom probe tomography for biomaterials and biomineralization. Acta Biomater. August 2022;148:44-60.
2022	Micheletti C, Hurley A, Gourrier A, Palmquist A, Tang T, Shah FA, Grandfield K. Bone mineral organization at the mesoscale: a review of mineral ellipsoids in bone and at bone interfaces. Acta Biomater. April 1, 2022;142:1-13.
2021	Ayoubi M, van Tol AF, Weinkamer R, Roschger P, Brugger PC, Berzlanovich A, Bertinetti L, Roschger A, Fratzl P. 3D interrelationship between osteocyte network and forming mineral during human bone remodeling. Adv Healthc Mater. June 2021;10(12):2100113.
2023	Deering J, Chen J, Mahmoud D, Tang T, Lin Y, Fang Q, Wohl GR, Elbestawi M, Grandfield K. Characterizing mineral ellipsoids in new bone formation at the interface of Ti6Al4V porous implants. Adv Mater Interfaces. August 24, 2023;10(24):2300333.
2022	Tang T, Landis W, Raguin E, Werner P, Bertinetti L, Dean M, Wagermaier W, Fratzl P. A 3D network of nanochannels for possible ion and molecule transit in mineralizing bone and cartilage. Adv NanoBiomed Res. 2022;2(8):2100162.
2023	Buss DJ, Rechav K, Reznikov N, McKee MD. Mineral tessellation in mouse enthesis fibrocartilage, Achilles tendon, and Hyp calcifying enthesopathy: a shared 3D mineralization pattern. Bone. September 2023;174:116818.
2023	Tang T, Landis W, Blouin S, Bertinetti L, Hartmann MA, Berzlanovich A, Weinkamer R, Wagermaier W, Fratzl P. Subcanalicular nanochannel volume is inversely correlated with calcium content in human cortical bone. J Bone Miner Res. February 2023;38(2):313-325.
2022	Buss DJ, Kröger R, McKee MD, Reznikov N. Hierarchical organization of bone in three dimensions: a twist of twists. J Struct Biol X. 2022;6:100057.
2024	Tang T, Casagrande T, Mohammadpour P, Landis W, Lievers B, Grandfield K. Characterization of human trabecular bone across multiple length scales using a correlative approach combining X-ray tomography with LaserFIB and plasma FIB-SEM. Sci Rep. September 16, 2024;14:21604.
2023	Micheletti C. Multimodal and Multiscale Characterization of Bone and Bone Interfaces in Health and Disease [PhD thesis]. University of Gothenburg; 2023.
2023	Buss DJ. Mineralization of Biological Fiber Systems [PhD thesis]. McGill University; July 2023.