Orientation of Mineral Crystallites and Mineral Density During Skeletal Development in Mice Deficient in Tissue Nonspecific Alkaline Phosphatase

Tissue nonspecific alkaline phosphatase (TNALP) is thought to play an important role in mineralization processes, although its exact working mechanism is not known. In the present investigation we have studied mineral crystal characteristics in the developing skeleton of TNALP‐deficient mice. Null mutants (n = 7) and their wild‐type littermates (n = 7) were bred and killed between 8 and 22 days after birth. Skeletal tissues were processed to assess mineral characteristics (small angle X‐ray scattering, quantitative backscattered electron imaging), and to analyze bone by light microscopy and immunolabeling. The results showed a reduced longitudinal growth and a strongly delayed epiphyseal ossification in the null mutants. This was accompanied by disturbances in mineralization pattern, in that crystallites were not orderly aligned with respect to the longitudinal axis of the cortical bone. Among the null mutants, a great variability in the mineralization parameters was noticed. Also, immunolabeling of osteopontin (OPN) revealed an abnormal distribution pattern of the protein within the bone matrix. Whereas in the wild‐type animals OPN was predominantly observed in cement and reversal lines, in the null mutants, OPN was also randomly dispersed throughout the nonmineralized matrix, with focal densities. In contrast, the distribution pattern of osteocalcin (OC) was comparable in both types of animals. It is concluded that ablation of TNALP results not only in hypomineralization of the skeleton, but also in a severe disorder of the mineral crystal alignment pattern in the corticalis of growing long bone in association with a disordered matrix architecture, presumably as a result of impaired bone remodeling and maturation.

[1]  C. Scriver,et al.  The Metabolic and Molecular Bases of Inherited Disease, 8th Edition 2001 , 2001, Journal of Inherited Metabolic Disease.

[2]  S. Narisawa,et al.  Abnormal vitamin B6 metabolism in alkaline phosphatase knock‐out mice causes multiple abnormalities, but not the impaired bone mineralization , 2001, The Journal of pathology.

[3]  J. Millán,et al.  Functional Characterization of Osteoblasts and Osteoclasts from Alkaline Phosphatase Knockout Mice , 2000, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[4]  R. Terkeltaub,et al.  Osteoblast tissue-nonspecific alkaline phosphatase antagonizes and regulates PC-1. , 2000, American journal of physiology. Regulatory, integrative and comparative physiology.

[5]  C. Giachelli,et al.  Phosphorylation of Osteopontin Is Required for Inhibition of Vascular Smooth Muscle Cell Calcification* , 2000, The Journal of Biological Chemistry.

[6]  J. Millán,et al.  Alkaline Phosphatase Knock‐Out Mice Recapitulate the Metabolic and Skeletal Defects of Infantile Hypophosphatasia , 1999, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[7]  P. Schneider,et al.  Bone metabolism and bone mineral density in childhood hypophosphatasia. , 1999, Bone.

[8]  V. Everts,et al.  Root Development in Mice Lacking Functional Tissue Non-specific Alkaline Phosphatase Gene: Inhibition of Acellular Cementum Formation , 1999, Journal of dental research.

[9]  P. Fratzl,et al.  Scanning Small Angle X-ray Scattering Analysis of Human Bone Sections , 1999, Calcified Tissue International.

[10]  P. Mäenpää,et al.  Cross-linking of Osteopontin by Tissue Transglutaminase Increases Its Collagen Binding Properties* , 1999, The Journal of Biological Chemistry.

[11]  R. Cancedda,et al.  Vis‐à‐Vis Cells and the Priming of Bone Formation , 1998, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[12]  P. Fratzl,et al.  Validation of quantitative backscattered electron imaging for the measurement of mineral density distribution in human bone biopsies. , 1998, Bone.

[13]  H. Anderson,et al.  Matrix vesicles in osteomalacic hypophosphatasia bone contain apatite-like mineral crystals. , 1997, The American journal of pathology.

[14]  C. Kovacs,et al.  Maternal-fetal calcium and bone metabolism during pregnancy, puerperium, and lactation. , 1997, Endocrine reviews.

[15]  S. Manolagas,et al.  Osteopontin expression by osteoclast and osteoblast progenitors in the murine bone marrow: demonstration of its requirement for osteoclastogenesis and its increase after ovariectomy. , 1997, Endocrinology.

[16]  J. Millán,et al.  Inactivation of two mouse alkaline phosphatase genes and establishment of a model of infantile hypophosphatasia , 1997, Developmental dynamics : an official publication of the American Association of Anatomists.

[17]  M. McKee,et al.  Osteopontin at mineralized tissue interfaces in bone, teeth, and osseointegrated implants: Ultrastructural distribution and implications for mineralized tissue formation, turnover, and repair , 1996, Microscopy research and technique.

[18]  T. Guilarte,et al.  Mice lacking tissue non–specific alkaline phosphatase die from seizures due to defective metabolism of vitamin B–6 , 1995, Nature Genetics.

[19]  P. Henthorn,et al.  Alkaline phosphatase: placental and tissue-nonspecific isoenzymes hydrolyze phosphoethanolamine, inorganic pyrophosphate, and pyridoxal 5'-phosphate. Substrate accumulation in carriers of hypophosphatasia corrects during pregnancy. , 1995, The Journal of clinical investigation.

[20]  H. Plenk,et al.  A new scanning electron microscopy approach to the quantification of bone mineral distribution: backscattered electron image grey-levels correlated to calcium K alpha-line intensities. , 1995, Scanning microscopy.

[21]  Y. Mikuni‐Takagaki,et al.  Matrix mineralization and the differentiation of osteocyte‐like cells in culture , 1995, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[22]  J. Gorski,et al.  Calcium and collagen binding properties of osteopontin, bone sialoprotein, and bone acidic glycoprotein-75 from bone. , 1992, The Journal of biological chemistry.

[23]  A L Boskey,et al.  Mineral-matrix interactions in bone and cartilage. , 1992, Clinical orthopaedics and related research.

[24]  P. Fratzl,et al.  Mineral crystals in calcified tissues: A comparative study by SAXS , 1992, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[25]  T. Chambers,et al.  Bone cells predispose bone surfaces to resorption by exposure of mineral to osteoclastic contact. , 1985, Journal of cell science.

[26]  I. Radde,et al.  Calcium and phosphate fluxes across the fetal membranes of the guinea pig: in vitro measurement. , 1983, Biochemical and biophysical research communications.

[27]  A. Villanueva,et al.  Modifications of the Goldner and Gomori one-step trichrome stains for plastic-embedded thin sections of bone. , 1977, The American journal of medical technology.

[28]  R. Whitehead Biopsies , 1954, British medical journal.

[29]  H. Roach Association of Matrix Acid and Alkaline Phosphatases with Mineralization of Cartilage and Endochondral Bone , 2004, The Histochemical Journal.

[30]  M. McKee,et al.  Bone sialoprotein mRNA expression and ultrastructural localization in fetal porcine calvarial bone: comparisons with osteopontin , 2004, The Histochemical Journal.

[31]  P. Fratzl,et al.  Bone mineralization as studied by small-angle x-ray scattering. , 1996, Connective tissue research.

[32]  M. McKee,et al.  Osteopontin: an interfacial extracellular matrix protein in mineralized tissues. , 1996, Connective tissue research.

[33]  H. Plenk,et al.  Formation of Ultracracks in Methacrylate-Embedded Undecalcified Bone Samples by Exposure to Aqueous Solutions , 1993 .

[34]  A. Caplan,et al.  Morphological and histochemical events during first bone formation in embryonic chick limbs. , 1986, Bone.