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The L‐enantiomer of β‐aminoisobutyric acid (BAIBA) is secreted by contracted muscle in mice, and exercise increases serum levels in humans. In mice, L‐BAIBA reduces bone loss with unloading, but whether it can have a positive effect with loading is unknown. Since synergism can be more easily observed with sub‐optimal amounts of factors/stimulation, we sought to determine whether L‐BAIBA could potentiate the effects of sub‐optimal loading to enhance bone formation. L‐BAIBA was provided in drinking water to C57Bl/6 male mice subjected to either 7 N or 8.25 N of sub‐optimal unilateral tibial loading for 2 weeks. The combination of 8.25 N and L‐BAIBA significantly increased the periosteal mineral apposition rate and bone formation rate compared to loading alone or BAIBA alone. Though L‐BAIBA alone had no effect on bone formation, grip strength was increased, suggesting a positive effect on muscle function. Gene expression analysis of the osteocyte‐enriched bone showed that the combination of L‐BAIBA and 8.25 N induced the expression of loading‐responsive genes such as Wnt1, Wnt10b, and the TGFb and BMP signaling pathways. One dramatic change was the downregulation of histone genes in response to sub‐optimal loading and/or L‐BAIBA. To determine early gene expression, the osteocyte fraction was harvested within 24 hours of loading. A dramatic effect was observed with L‐BAIBA and 8.25 N loading as genes were enriched for pathways regulating the extracellular matrix (Chad, Acan, Col9a2), ion channel activity (Scn4b, Scn7a, Cacna1i), and lipid metabolism (Plin1, Plin4, Cidec). Few changes in gene expression were observed with sub‐optimal loading or L‐BAIBA alone after 24 hours. These results suggest that these signaling pathways are responsible for the synergistic effects between L‐BAIBA and sub‐optimal loading. Showing that a small muscle factor can enhance the effects of sub‐optimal loading of bone may be of relevance for individuals unable to benefit from optimal exercise. © 2023 The Authors. JBMR Plus published by Wiley Periodicals LLC on behalf of American Society for Bone and Mineral Research. The muscle metabolite L‐BAIBA synergizes with sub‐optimal mechanical loading of the mouse tibia to promote new bone formation and regulate the transcriptional response of osteocyte‐enriched cortical bone.

Abstract Musculoskeletal disorders are a significant complication of aging, leading to increased morbidity and mortality. However, current understanding of the mechanisms by which aging affects skeletal health is limited. Osteocytes are the most numerous and long-lived bone cells and play key roles in maintaining bone mass by responding to anabolic signals such as mechanical loading. Energy metabolism is dysregulated in many cells with aging, however regulation of energy metabolism in osteocytes and how this is affected during aging and by mechanical loading remains undefined. To investigate this, we first used IDG-SW3 osteocyte cells to determine the effects of mechanical loading on osteocytes in vitro by applying fluid flow shear stress (FFSS). FFSS increased Pparδ and Cpt1 expression, key promoters of fatty acid β-oxidation (FAO). Pharmacological antagonism of PPARδ or CPT1 resulted in dysregulated expression of key bone remodeling genes and impaired ATP release in response to FFSS. In vivo, mechanical loading significantly increased FAO in tibia cortical bone. However, FAO was impaired in the bones from aged mice. To further elucidate the role of osteocyte FAO, we deleted PPARδ specifically in osteocytes (PPARδ cKO), which resulted in decreased FAO and bone volume in female PPARδ cKO mice. Lastly, treatment of aging mice with the PPARδ activator GW0742 resulted in significantly increased bone mineral content, density and trabecular bone volume. These findings suggest important functions of osteocyte energy metabolism during aging and with mechanical loading on bone and identify PPARδ-driven FAO as a novel therapeutic target for improving skeletal health with aging.

Mice harbouring a dentin matrix protein 1 (Dmp1) promoter-driven human diphtheria toxin (DT) receptor (HDTR) transgene (Tg) have recently been used to attain targeted ablation of osteocytes by diphtheria toxin (DT) treatment in order to define osteocyte function. Use of these Tg mice has asserted mechano- and novel paracrine regulatory osteocyte functions. To explore osteocyte roles fully, we sought to confirm the selectivity of DT effects in these transgenic mice. However, our findings revealed incomplete DT-induced osteocyte ablation, prevalent HDTR misexpression, as well as more prominent histopathological DT-induced changes in multiple organs in Tg than in wild-type (WT) littermate mice. Mechanistic evidence for DT action, via prominent regulation of phosphorylation status of elongation factor-2 (EF-2), was also found in many non-skeletal tissues in Tg mice; indicative of direct “off-target” DT action. Finally, very rapid deterioration in health and welfare status in response to DT treatment was observed in these Tg when compared to WT control mice. Together, these data lead us to conclude that alternative models for osteocyte ablation should be sought and caution be exercised when drawing conclusions from experiments using these Tg mice alone.

Recent research has identified metabolic pathways which play key roles in the differentiation and function of osteoblasts and osteoclasts. However, the mechanisms by which osteocytes, the most numerous cells in bone, meet their energetic demands are still unknown. To address this, we used the IDG-SW3 osteocyte cell line to examine changes in metabolism during differentiation from late osteoblasts to mature osteocytes. There was a significant increase in the expression of glycolysis genes (including and ), glucose consumption and lactate production during late differentiation of these cells. This was concurrent with the onset of the expression of mature osteocyte markers. Inhibition of glycolysis using the glucose analogue 2-deoxy-d-glucose (2-DG) inhibited IDG-SW3 cell mineralization and differentiation into osteocytes. To examine the effect of glycolysis inhibition on mature osteocytes, we treated differentiated IDG-SW3 cells and long bone osteocytes with 2-DG. Glycolysis inhibition resulted in decreased expression of the bone formation inhibitor and mineralization inhibitor . Concurrently, there was an increase in genes associated with lipolysis ( ) fatty acid β-oxidation ( and ). Treatment of differentiated IDG-SW3 cells with the unsaturated fatty acid oleic acid increased expression and downregulated and . Application of mechanical stress to IDG-SW3 cells resulted in upregulation of oxidative metabolism, and expression. Long and short chain acylcarnitines were increased in the cortical bone of axially loaded tibiae compared to non-loaded controls, indicative of increased β-oxidation. Overall, our data suggests that while glycolysis is essential for osteocyte differentiation, mature osteocytes are metabolically flexible. Furthermore, β-oxidation may play an important role in the osteocyte response to mechanical stress.

Irisin, released from exercised muscle, has been shown to have beneficial effects on numerous tissues but its effects on bone are unclear. We found significant sex and genotype differences in bone from wildtype (WT) mice compared to mice lacking (KO), with and without calcium deficiency. Despite their bone being indistinguishable from WT females, KO female mice were partially protected from osteocytic osteolysis and osteoclastic bone resorption when allowed to lactate or when placed on a low-calcium diet. Male KO mice have more but weaker bone compared to WT males, and when challenged with a low-calcium diet lost more bone than WT males. To begin to understand responsible molecular mechanisms, osteocyte transcriptomics was performed. Osteocytes from WT females had greater expression of genes associated with osteocytic osteolysis and osteoclastic bone resorption compared to WT males which had greater expression of genes associated with steroid and fatty acid metabolism. Few differences were observed between female KO and WT osteocytes, but with a low calcium diet, the KO females had lower expression of genes responsible for osteocytic osteolysis and osteoclastic resorption than the WT females. Male KO osteocytes had lower expression of genes associated with steroid and fatty acid metabolism, but higher expression of genes associated with bone resorption compared to male WT. In conclusion, irisin plays a critical role in the development of the male but not the female skeleton and protects male but not female bone from calcium deficiency. We propose irisin ensures the survival of offspring by targeting the osteocyte to provide calcium in lactating females, a novel function for this myokine.