Osteocytes are terminally differentiated long-lived cells and account for greater than 95% of the bone cell population. It has been established that osteocytes are connected through their highly developed dendritic network, which is necessary for the maintenance of optimal bone homeostasis. However, little is known on how osteocytes use the network to coordinate their cellular function and communication that requires energy and protein turnover. Here using super-resolution confocal imaging on both live and fixed osteocytes, we demonstrated conclusively that mitochondria are widely distributed and dynamically shared between osteocytes. Using confocal live cell imaging analysis we showed that inhibiting the contact between mitochondria and endoplasmic reticulum (ER) by the knockdown of MFN2 in osteocytes impedes the transfer of mitochondria suggesting the involvement of ER contact with mitochondria in the transfer process. Moreover, we showed that transport of mitochondria between osteocytes within the network enables rescue of osteocytes with dysfunction of mitochondria. Using the 3D tetraculture system with confocal imaging, we identify the transfer of mitochondria from healthy osteocytes enables recovery of mitochondria activities in osteocytes that devoid of mitochondrial DNA by ethidium bromide. The results indicated that when osteocytes are depleted of functional mitochondria, normal parental osteocytes can transfer mitochondria to these stressed osteocytes to provide them with energy. Collectively we show for the first time that the utilisation of mitochondrial transfer enables osteocytes to function with a network and coordinate their cellular activities in response to different energy demands.

Dentin matrix protein (DMP-1), a phosphoprotein highly linked to dentin formation, has recently been reported to have an important role in skeletal development. Previously we reported that adult mice lacking the gene for DMP-1 exhibit the characteristics of chondrodysplasia, osteoarthritis, and showed severe defects in mineralization. DMP-1 knock-out (KO) mice display a profound defect in mineralization, and this is not due to a systemic defect in calcium/phosphate metabolism because serum levels of calcium and phosphate are similar to those in the wild-type mice. Although KO neonates and newborns appear normal, upon closer examination, these animals exhibit skeletal abnormalities, which include delayed secondary ossification and impaired bone remodelling. Heterozygous DMP-1 (H) mice however, show no apparent differences to the wild-type mice. In this study, biomechanical assessment tests of bones from DMP-1 KO mice were performed. Fifteen heterozygous, H, (DMP-1 +/−) and 15 KO, (DMP-1 −/−) male mice were produced and used in this study. At 1, 3 and 7.5 months of age, the mice were sacrificed and 4–5 ulnae from each animal group were harvested and stored in 70% ethanol solution. Volumetric density (BMD) measurements of the intact ulnae were performed using peripheral quantitative computed tomography (XCT960M; Stratec, Pforzheim, Germany) and Norland Stratec software version 5.10. One millimetre thick slices were scanned at a distance of 1 mm under the articular cartilage surface of the elbow as identified by the scout view of the CT scan. BMD of the corticalis and subcortical bone were recorded. Cross-sectional area measurements were also made at the mid-diaphysis of the ulnae. Biomechanical tests were performed in 3-point bending, with supports 3.5 mm apart at a rate of 3 mm/min (Lloyd Instruments Ltd, UK). The ultimate load, yield load and stiffness were determined from the load-displacement curves. All data were analysed using Mann-Whitney U tests (SPSS, Version 9, Chicago, Illinois). Differences were considered significant at p < 0.05. Density studies revealed that H mice had higher BMD than KO mice at all ages (p < 0.001). In the H and KO mice, the cortical BMD peaked at 3 and 7.5 months, respectively. At 1 month, the mean cross-sectional areas of the ulnae were larger in H mice compared to KO mice (0.50 mm2 Vs 0.33 mm2). However at 7.5 months of age, the reverse was observed (H = 0.75 mm2 and KO = 0.98 mm2). Biomechanically, stiffness increased with age at a higher rate in H mice than KO mice. Significant differences were observed at 3 months (p< 0.01) and 7.5 months (p< 0.05) between the two animal groups. There were no significant differences between stiffness values at 1 month. This study has demonstrated that DMP-1 deficiency leads to:

severely compromised bone mineralization;