Project description:The mechano-responsiveness of osteocytes is critical for maintaining bone health, yet the molecular mechanisms underlying this process remain poorly understood. Here, we investigate the impact of mechanical loading on transcriptional and epigenetic remodeling in osteocytes. Using MLO-Y4 cells, we subjected osteocytes to mechanical loading and profiled their transcriptome and histone modifications. Our findings revealed significant transcriptional and epigenetic changes, with NRF2 emerging as a key regulator. We demonstrated that mechanical loading stabilizes NRF2 protein levels and promotes its nucleus translocation, leading to enhanced genomic binding of NRF2 and activation of its target genes. Further analysis confirmed cell type-specific functions of NRF2, with distinct binding profiles in osteocytes compared to astrocytes. These results highlight the pivotal role of NRF2 in the mechano-responsiveness of osteocytes. Unlike pharmacologic agents that stabilize NRF2, mechanical loading uniquely promoted NRF2 nucleus translocation and transcriptional activity. This underscores the irreplaceable role of mechanical stimuli, such as exercise, in promoting bone health. This study advances our understanding of osteocyte mechanotransduction and identifies potential therapeutic interventions for bone diseases.

Project description:The mechano-responsiveness of osteocytes is critical for maintaining bone health, yet the molecular mechanisms underlying this process remain poorly understood. Here, we investigate the impact of mechanical loading on transcriptional and epigenetic remodeling in osteocytes. Using MLO-Y4 cells, we subjected osteocytes to mechanical loading and profiled their transcriptome and histone modifications. Our findings revealed significant transcriptional and epigenetic changes, with NRF2 emerging as a key regulator. We demonstrated that mechanical loading stabilizes NRF2 protein levels and promotes its nucleus translocation, leading to enhanced genomic binding of NRF2 and activation of its target genes. Further analysis confirmed cell type-specific functions of NRF2, with distinct binding profiles in osteocytes compared to astrocytes. These results highlight the pivotal role of NRF2 in the mechano-responsiveness of osteocytes. Unlike pharmacologic agents that stabilize NRF2, mechanical loading uniquely promoted NRF2 nucleus translocation and transcriptional activity. This underscores the irreplaceable role of mechanical stimuli, such as exercise, in promoting bone health. This study advances our understanding of osteocyte mechanotransduction and identifies potential therapeutic interventions for bone diseases.

Project description:Osteoarthritis (OA) is the most common degenerative joint disease. During its initiation and early progression a disruption in subchondral bone (SCB) remodeling, induced by excessive and cumulative mechanical loading, occurs before cartilage degeneration. While it is known that osteocytes in the SCB are mainly responsible for mechanosensing, their role in the early phases of OA are still unclear. Here, we found that mechanical stress induces SCB osteocytes to secrete extracellular vesicles (EVs) that accelerate cartilage metabolic dysregulation. By gain- and loss-of function experiments we show that such EVs via miR-23b-3p promote cartilage catabolism while inhibiting their anabolism. Mechanistically, miR-23b-3p inhibits mitophagy by targeting OTUD4 to promote this metabolic skewing. Further, by inhibiting miR-23b-3p in either osteocytes or chondrocytes we could alleviate cartilage degeneration and OA progression in a mouse model. Together, our findings show that SCB osteocytes communicate with chondrocytes via EVs and that targeting a key EV-derived miRNA can ameliorate OA progression.

Project description:Osteoarthritis (OA) is the most common degenerative joint disease. During its initiation and early progression a disruption in subchondral bone (SCB) remodeling, induced by excessive and cumulative mechanical loading, occurs before cartilage degeneration. While it is known that osteocytes in the SCB are mainly responsible for mechanosensing, their role in the early phases of OA are still unclear. Here, we found that mechanical stress induces SCB osteocytes to secrete extracellular vesicles (EVs) that accelerate cartilage metabolic dysregulation. By gain- and loss-of function experiments we show that such EVs via miR-23b-3p promote cartilage catabolism while inhibiting their anabolism. Mechanistically, miR-23b-3p inhibits mitophagy by targeting OTUD4 to promote this metabolic skewing. Further, by inhibiting miR-23b-3p in either osteocytes or chondrocytes we could alleviate cartilage degeneration and OA progression in a mouse model. Together, our findings show that SCB osteocytes communicate with chondrocytes via EVs and that targeting a key EV-derived miRNA can ameliorate OA progression.

Project description:Osteoarthritis (OA) is the most common degenerative joint disease. During its initiation and early progression a disruption in subchondral bone (SCB) remodeling, induced by excessive and cumulative mechanical loading, occurs before cartilage degeneration. While it is known that osteocytes in the SCB are mainly responsible for mechanosensing, their role in the early phases of OA are still unclear. Here, we found that mechanical stress induces SCB osteocytes to secrete extracellular vesicles (EVs) that accelerate cartilage metabolic dysregulation. By gain- and loss-of function experiments we show that such EVs via miR-23b-3p promote cartilage catabolism while inhibiting their anabolism. Mechanistically, miR-23b-3p inhibits mitophagy by targeting OTUD4 to promote this metabolic skewing. Further, by inhibiting miR-23b-3p in either osteocytes or chondrocytes we could alleviate cartilage degeneration and OA progression in a mouse model. Together, our findings show that SCB osteocytes communicate with chondrocytes via EVs and that targeting a key EV-derived miRNA can ameliorate OA progression.

Project description:Osteoarthritis (OA) is the most common degenerative joint disease. During its initiation and early progression a disruption in subchondral bone (SCB) remodeling, induced by excessive and cumulative mechanical loading, occurs before cartilage degeneration. While it is known that osteocytes in the SCB are mainly responsible for mechanosensing, their role in the early phases of OA are still unclear. Here, we found that mechanical stress induces SCB osteocytes to secrete extracellular vesicles (EVs) that accelerate cartilage metabolic dysregulation. By gain- and loss-of function experiments we show that such EVs via miR-23b-3p promote cartilage catabolism while inhibiting their anabolism. Mechanistically, miR-23b-3p inhibits mitophagy by targeting OTUD4 to promote this metabolic skewing. Further, by inhibiting miR-23b-3p in either osteocytes or chondrocytes we could alleviate cartilage degeneration and OA progression in a mouse model. Together, our findings show that SCB osteocytes communicate with chondrocytes via EVs and that targeting a key EV-derived miRNA can ameliorate OA progression.

Project description:Bone metastases is a common severe complication for breast cancer. We previously showed that conditioned medium (CM) from osteocytes stimulated with oscillatory fluid flow, mimicking bone mechanical loading during routine physical activities, reduced breast cancer cell extravasation across endothelial monolayers. Endothelial cells are situated at an ideal location to mediate signals between osteocytes in the bone matrix and metastasizing cancer cells in the blood vessels. Therefore, we used RNA sequencing to show that CM from endothelial cells conditioned in CM from flow-stimulated osteocytes significantly altered gene expression in bone-metastatic breast cancer cells. This This provides insights into the capability of bone-loading activity in preventing bone metastases.

Project description:Skeletal integrity in humans and animals is maintained by daily mechanical loading. It has been widely accepted that osteocytes function as mechanosensors. Many biochemical signaling molecules are involved in the response of osteocytes to mechanical stimulation. The aim of this study was to identify genes involved in the translation of mechanical stimuli into bone formation. The four-point bending model was used to induce a single period of mechanical loading (comprising 300 cycles (2 Hz) using a peak magnitude of 60 N) on the right tibia, while the contra lateral left tibia served as control. Six hours after loading, the effects of mechanical loading on gene-expression were determined with microarray analysis. Protein expression of differentially regulated genes was evaluated with immunohistochemistry. Nine genes were found to exhibit a significant differential gene expression in LOAD compared to control. MEPE, Garnl1, V2R2B, and QFG TN1 olfactory receptor were up-regulated, and creatine kinase (muscle form), fibrinogen-B beta-polypeptide, monoamine oxidase A, troponin-C and kinesin light chain-C were down-regulated. Validation with real-time RT-PCR analysis confirmed the up regulation of MEPE and the down-regulation of creatine kinase (muscle form) and troponin-C in the loaded tibia. Immunohistochemistry showed that the increase of MEPE protein expression was already detectable six hours after mechanical loading. In conclusion, these genes probably play a role during translation of mechanical stimuli six hours after mechanical loading. The modulation of MEPE expression may indicate a connection between bone mineralization and bone formation after mechanical stimulation. Two groups: LOAD vs contralateral control and SHAM vs contralateral control (n=5/group)

Project description:Skeletal integrity in humans and animals is maintained by daily mechanical loading. It has been widely accepted that osteocytes function as mechanosensors. Many biochemical signaling molecules are involved in the response of osteocytes to mechanical stimulation. The aim of this study was to identify genes involved in the translation of mechanical stimuli into bone formation. The four-point bending model was used to induce a single period of mechanical loading (comprising 300 cycles (2 Hz) using a peak magnitude of 60 N) on the right tibia, while the contra lateral left tibia served as control. Six hours after loading, the effects of mechanical loading on gene-expression were determined with microarray analysis. Protein expression of differentially regulated genes was evaluated with immunohistochemistry. Nine genes were found to exhibit a significant differential gene expression in LOAD compared to control. MEPE, Garnl1, V2R2B, and QFG TN1 olfactory receptor were up-regulated, and creatine kinase (muscle form), fibrinogen-B beta-polypeptide, monoamine oxidase A, troponin-C and kinesin light chain-C were down-regulated. Validation with real-time RT-PCR analysis confirmed the up regulation of MEPE and the down-regulation of creatine kinase (muscle form) and troponin-C in the loaded tibia. Immunohistochemistry showed that the increase of MEPE protein expression was already detectable six hours after mechanical loading. In conclusion, these genes probably play a role during translation of mechanical stimuli six hours after mechanical loading. The modulation of MEPE expression may indicate a connection between bone mineralization and bone formation after mechanical stimulation.

Project description:Osteocytes, positioned within bone’s interstitial space, are subject to fluid flow upon whole bone loading. Such fluid flow is widely theorized to be a mechanical signal transduced by osteocytes, initiating a poorly understood cascade of signaling events mediating bone metabolism. The objective of this study was to utilize high-throughput approaches to examine the time course of flow-induced changes in osteocyte gene transcript and protein levels. Microarray analysis demonstrated fluid flow regulation of genes consistent with known anabolic loading responses, including Ptgs2, NF-κB inhibitors, MAP3 kinases, and Wnt/β-catenin pathway signaling molecules. However, two of the most highly up-regulated gene products—Cxcl1 and Cxcl2, confirmed by qPCR—have not previously been reported to be responsive to fluid flow. Gene ontology analysis suggested a highly significant inflammatory and immune response, with cellular functions including trafficking, cell-to-cell signaling, and tissue development. Proteomic analysis of the same samples demonstrated greatest up-regulation of the ATP-producing enzyme NDK, calcium-binding Calcyclin, and G protein-coupled receptor kinase 6. An integrative pathway analysis merging fold changes in transcript and protein levels predicted signaling nodes not directly detected at the sampled time points, including STAT3 and c-Myc. These results extend our knowledge of the osteocytic response to fluid flow, most notably up-regulation of Cxcl1 and Cxcl2 as a possible paracrine agent for osteoblastic and osteoclastic recruitment.