Mice with hypomorphic expression of the sodium-phosphate cotransporter PiT1/Slc20a1 have an unexpected normal bone mineralization

The formation of hydroxyapatite crystals and their insertion into collagen fibrils of the matrix are essential steps for bone mineralization. As phosphate is a main structural component of apatite crystals, its uptake by skeletal cells is critical and must be controlled by specialized membrane prote...

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Bibliographic Details
Published in:PloS one 2013-06, Vol.8 (6), p.e65979-e65979
Main Authors: Bourgine, Annabelle, Pilet, Paul, Diouani, Sara, Sourice, Sophie, Lesoeur, Julie, Beck-Cormier, Sarah, Khoshniat, Solmaz, Weiss, Pierre, Friedlander, Gérard, Guicheux, Jérôme, Beck, Laurent
Format: Article
Language:English
Subjects:
Alizarin
Animals
Apatite
Biological Transport
Biomedical materials
Body Size - genetics
Bone and Bones - diagnostic imaging
Bone and Bones - metabolism
Bone and Bones - pathology
Bone growth
Bones
Calcification, Physiologic - genetics
Calcification, Physiologic - physiology
Cell growth
Chondrocytes
Clonal deletion
Collagen
Computed tomography
Crystal defects
Crystals
Embryos
Energy consumption
Female
Femur
Fibrils
Gene expression
Gene Expression Regulation
Genotype
Growth factors
Hydroxyapatite
Hydroxyapatites
Insertion
Lethality
Life Sciences
Male
Membrane proteins
Mice
Mice, Transgenic
Mineralization
Mouse devices
Phenotype
Phosphate minerals
Phosphates
Physiology
Pit1 protein
Proteins
Radiography
Rodents
Sodium
Sodium-Phosphate Cotransporter Proteins, Type III - genetics
Sodium-Phosphate Cotransporter Proteins, Type III - metabolism
Spectrometry, X-Ray Emission
Spectroscopy
Staining
Studies
Surgical implants
Tissue engineering
X-ray spectroscopy
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Summary:The formation of hydroxyapatite crystals and their insertion into collagen fibrils of the matrix are essential steps for bone mineralization. As phosphate is a main structural component of apatite crystals, its uptake by skeletal cells is critical and must be controlled by specialized membrane proteins. In mammals, in vitro studies have suggested that the high-affinity sodium-phosphate cotransporter PiT1 could play this role. In vivo, PiT1 expression was detected in hypertrophic chondrocytes of murine metatarsals, but its implication in bone physiology is not yet deciphered. As the complete deletion of PiT1 results in embryonic lethality at E12.5, we took advantage of a mouse model bearing two copies of PiT1 hypomorphic alleles to study the effect of a low expression of PiT1 on bone mineralization in vivo. In this report, we show that a 85% down-regulation of PiT1 in long bones resulted in a slight (6%) but significant reduction of femur length in young mice (15- and 30-day-old). However, despite a defect in alcian blue / alizarin red S and Von Kossa staining of hypomorphic 1-day-old mice, using X-rays micro-computed tomography, energy dispersive X-ray spectroscopy and histological staining techniques we could not detect differences between hypomorphic and wild-type mice of 15- to 300-days old. Interestingly, the expression of PiT2, the paralog of PiT1, was increased 2-fold in bone of PiT1 hypomorphic mice accounting for a normal phosphate uptake in mutant cells. Whether this may contribute to the absence of bone mineralization defects remains to be further deciphered.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0065979