Project description:The bone-defect-repair process involves complex interaction between mesenchymal stem cells (MSCs) and immune cells, while the heterogeneity of osteoimmune microenvironment around implanted biomaterials remains elusive. By combining analysis of scRNA-seq and spatial transcriptomics technologies, we revealed that MgphiMSCs subpopulation served as the pioneers during the early stage of biomaterials-mediated bone defect healing process. They performed efficient osteogenic differentiation potential and had close interactions with immune cells. Remarkably, the MgphiMSCs could response to biomaterials-mediated osteoimmune microenvironment, rewired the polarization and osteoclastic differentiation of macrophages via midkine (MDK) signaling pathway. The inhibition of MDK activated the pro-inflammatory programs of macrophages and osteoclastogenesis. Meanwhile, multiple innate and adaptive immune-cell subsets exhibited close crosstalk between MgphiMSCs via SPP1 signaling pathway. These cellular profiles and interactions characterized in this study could broaden our understanding of the functional MSCs subpopulations at the early stage of biomaterial-mediated bone regeneration and provide the basis for the materials-designed strategies that target osteoimmune modulation.

Project description:Macrophages efferocytosis of apoptotic osteoblasts (apoOBs) is a key osteoimmune process for bone homeostasis that is highly regulated in osteoimmune surveillance. However, apoOBs accumulate in aged bone marrow, where they might mount proinflammatory responses and progressive bone loss. Why apoOBs were not cleared during aging remains unknown. Here, we show that apoOBs upregulate immune checkpoint molecule CD47 with age to evade macrophages clearance. Using osteoblast- and myeloid-specific gene knockout mice, we identify histone deacetylase SIRT6 as an essential regulator of the CD47–SIRPα checkpoint. Further, apoOBs that require SIRT6-mediated chemotaxis signals can recruit macrophages by releasing apoptotic extracellular vesicles. Therapeutically, we develop two targeting delivery strategies to enhance SIRT6 activity, showing increased apoOBs clearance and delayed age-related bone loss. Collectively, our data revealed a previously unknown linkage between immune surveillance and bone homeostasis and targeting the mechanism of SIRT6-regulated apoOBs clearance could be a promising therapeutic strategy for age-related bone diseases.

Project description:Macrophages efferocytosis of apoptotic osteoblasts (apoOBs) is a key osteoimmune process for bone homeostasis that is highly regulated in osteoimmune surveillance. However, apoOBs accumulate in aged bone marrow, where they might mount proinflammatory responses and progressive bone loss. Why apoOBs were not cleared during aging remains unknown. Here, we show that apoOBs upregulate immune checkpoint molecule CD47 with age to evade macrophages clearance. Using osteoblast- and myeloid-specific gene knockout mice, we identify histone deacetylase SIRT6 as an essential regulator of the CD47–SIRPα checkpoint. Further, apoOBs that require SIRT6-mediated chemotaxis signals can recruit macrophages by releasing apoptotic extracellular vesicles. Therapeutically, we develop two targeting delivery strategies to enhance SIRT6 activity, showing increased apoOBs clearance and delayed age-related bone loss. Collectively, our data revealed a previously unknown linkage between immune surveillance and bone homeostasis and targeting the mechanism of SIRT6-regulated apoOBs clearance could be a promising therapeutic strategy for age-related bone diseases.

Project description:Macrophages efferocytosis of apoptotic osteoblasts (apoOBs) is a key osteoimmune process for bone homeostasis that is highly regulated in osteoimmune surveillance. However, apoOBs accumulate in aged bone marrow, where they might mount proinflammatory responses and progressive bone loss. Why apoOBs were not cleared during aging remains unknown. Here, we show that apoOBs upregulate immune checkpoint molecule CD47 with age to evade macrophages clearance. Using osteoblast- and myeloid-specific gene knockout mice, we identify histone deacetylase SIRT6 as an essential regulator of the CD47–SIRPα checkpoint. Further, apoOBs that require SIRT6-mediated chemotaxis signals can recruit macrophages by releasing apoptotic extracellular vesicles. Therapeutically, we develop two targeting delivery strategies to enhance SIRT6 activity, showing increased apoOBs clearance and delayed age-related bone loss. Collectively, our data revealed a previously unknown linkage between immune surveillance and bone homeostasis and targeting the mechanism of SIRT6-regulated apoOBs clearance could be a promising therapeutic strategy for age-related bone diseases.

Project description:Macrophages efferocytosis of apoptotic osteoblasts (apoOBs) is a key osteoimmune process for bone homeostasis that is highly regulated in osteoimmune surveillance. However, apoOBs accumulate in aged bone marrow, where they might mount proinflammatory responses and progressive bone loss. Why apoOBs were not cleared during aging remains unknown. Here, we show that apoOBs upregulate immune checkpoint molecule CD47 with age to evade macrophages clearance. Using osteoblast- and myeloid-specific gene knockout mice, we identify histone deacetylase SIRT6 as an essential regulator of the CD47–SIRPα checkpoint. Further, apoOBs that require SIRT6-mediated chemotaxis signals can recruit macrophages by releasing apoptotic extracellular vesicles. Therapeutically, we develop two targeting delivery strategies to enhance SIRT6 activity, showing increased apoOBs clearance and delayed age-related bone loss. Collectively, our data revealed a previously unknown linkage between immune surveillance and bone homeostasis and targeting the mechanism of SIRT6-regulated apoOBs clearance could be a promising therapeutic strategy for age-related bone diseases.

Project description:Periodontitis, delineated by the destruction of structures that support teeth, is predominantly propelled by intricate immune responses. Immunomodulatory treatments offer considerable promise for the management of this ailment; however, the modulation of the periodontal immune microenvironment to facilitate tissue regeneration presents a substantial biomedical challenge. Herein, our study investigates the role of Wilms' tumor 1-associating protein (WTAP), a critical m6A methyltransferase, in the immunomodulation of periodontitis and assesses its viability as a therapeutic target. We observed heightened expression of WTAP in macrophages extracted from gingival tissues impacted by periodontitis, with a strong association with M1 polarization. Via loss-of-function experiments, we demonstrated that diminishing WTAP expression precipitates a transition from M1 to M2 macrophage phenotypes amidst inflammatory conditions, thus improving the periodontal immune landscape. Further, RNA sequencing and indirect co-culture assays indicated that suppressing of WTAP expression modulates osteoimmune responses and enhances the osteogenic differentiation of bone marrow stromal cells. The local deployment of adeno-associated virus-shWTAP in murine models of periodontitis robustly validated the therapeutic promise of targeting WTAP in this disease. Collectively, our findings highlight the crucial role of WTAP in orchestrating macrophage-mediated osteoimmune responses and tissue regeneration in periodontitis, proposing novel avenues for immunotherapeutic interventions in its treatment.

Project description:Background: The developing field of osteoimmunology supports importance of an interferon(IFN) response pathway in osteoblasts. Clarifying osteoblast-IFN interactions is important because IFN is used as salvage anti-tumor therapy but systemic toxicity is high with variable clinical results. In addition, osteoblast response to systemic bursts and disruptions of IFN pathways induced by viral infection may influence bone remodeling. ZIKA virus(ZIKV) infection impacts bone development in humans and IFN response in vitro. Consistently, initial evidence of permissivity to ZIKV has been reported in human osteoblasts. Hypothesis: Osteoblast-like Saos-2 cells are permissive to ZIKV and responsive to IFN. Methods: Multiple approaches were used to assess whether Saos-2 cells are permissive to ZIKV infection and exhibit IFN-mediated ZIKV suppression. Proteomic methods were used to evaluate impact of ZIKV and IFN on Saos-2 cells. Results: Evidence is presented confirming Saos-2 cells are permissive to ZIKV and support IFN-mediated suppression of ZIKV. ZIKV and IFN differentially impact the Saos-2 proteome. Both ZIKV and IFN suppress proteins associated with microcephaly/pseudo-TORCH syndrome (BI1, KIF20 and UBP18), and ZIKV induces potential entry factor PLVAP. Conclusions: Transient ZIKV infection influences osteoimmune state, and IFN and ZIKV activate distinct proteomes in Saos-2 cells, which could inform therapeutic, engineered, disruptions.

Project description:Cranial bone defect is a major clinical challenge that increases the life burden of patients. Tricarboxylic acid (TCA) cycle metabolites have recently drawn considerable attention in the field of bone tissue regeneration due to their bio-safety, low cost, structural stability, and effectiveness. However, the development of TCA cycle metabolite-modified biomimetic grafts for skull bone regeneration via a facile and general approach remains lacking. Moreover, the mechanism underlying the release of TCA cycle metabolites from biomaterials in immune responses and mesenchymal stem cells (MSCs) fate (migration and differentiation) remain unknown. Herein, inspired by the Hofmeister effects, we developed a series of TCA metabolite (in the form of sodium salt)-coordinated biomimetic hydrogels (CGG) with strong mechanical and anti-swelling performances. Importantly, the sodium citrate (Na3Cit)-treated CGG hydrogels (CGG-Cit) with the highest mechanical modulus and strength significantly promoted skull bone regeneration in rats and mice. Mechanistically, using a transgenic mouse model, bulk RNA sequencing, and single-cell RNA sequencing, we demonstrated that CGG-Cit promotes Gli1+ MSCs migration via neutrophil-secreted OSM. Our results also indicate that CGG-Cit improved osteogenesis via enhanced H3K9ac modification on osteogenic master genes. Taken together, the immune microenvironments and MSCs fate-regulated biomimetic hydrogels developed herein represent a highly efficient and facile approach toward skull bone tissue regeneration with great potential for bench-to-bedside translation.

Project description:Cranial bone defect is a major clinical challenge that increases the life burden of patients. Tricarboxylic acid (TCA) cycle metabolites have recently drawn considerable attention in the field of bone tissue regeneration due to their bio-safety, low cost, structural stability, and effectiveness. However, the development of TCA cycle metabolite-modified biomimetic grafts for skull bone regeneration via a facile and general approach remains lacking. Moreover, the mechanism underlying the release of TCA cycle metabolites from biomaterials in immune responses and mesenchymal stem cells (MSCs) fate (migration and differentiation) remain unknown. Herein, inspired by the Hofmeister effects, we developed a series of TCA metabolite (in the form of sodium salt)-coordinated biomimetic hydrogels (CGG) with strong mechanical and anti-swelling performances. Importantly, the sodium citrate (Na3Cit)-treated CGG hydrogels (CGG-Cit) with the highest mechanical modulus and strength significantly promoted skull bone regeneration in rats and mice. Mechanistically, using a transgenic mouse model, bulk RNA sequencing, and single-cell RNA sequencing, we demonstrated that CGG-Cit promotes Gli1+ MSCs migration via neutrophil-secreted OSM. Our results also indicate that CGG-Cit improved osteogenesis via enhanced H3K9ac modification on osteogenic master genes. Taken together, the immune microenvironments and MSCs fate-regulated biomimetic hydrogels developed herein represent a highly efficient and facile approach toward skull bone tissue regeneration with great potential for bench-to-bedside translation.

Project description:Biomaterial-based bone tissue engineering offers a promising prospect for the treatment of bone defects. In particular, the ability of biomaterials to regulate the immune microenvironment of the defect site is essential for effective bone regeneration. Electro-biomaterials have been confirmed to induce macrophage M2 polarization through metabolic pathways, thereby enhancing bone regeneration. Considering the central role of mitochondria in cellular metabolism and their ability to influence the function of neighboring cells through intercellular transfer, and inspired by the fact that tumor cells can uptake mitochondria from immune cells to generate energy, we hypothesize that the metabolic activation of immune cells by electro-materials can be transmitted to preosteoblasts through mitochondria to promote bone repair. Therefore, this study proposed a conductive micro-hydrogel (CMH) system composed of conductive hydrogel microspheres made from GelMA and poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), which served as scaffolds for defect filling, and a biomimetic periosteum made from poly-l-lactic acid (PLLA) and polydopamine (PDA) for microsphere immobilization and isolation of soft tissue. The microspheres exhibited excellent tissue support and degradation properties, their high specific surface area enhanced tissue remodeling, and their good conductivity eliminated free radicals and induced macrophage M2 polarization, which were confirmed by tests of mechanical property, swelling and degradation, conductivity and assays of cellular biocompatibility, ROS generation, and macrophage phenotype. In vivo experiments using a rat mandibular defect model confirmed the excellent bone repair capabilities of the CMH system, and transcriptomics, metabolomics, and metabolic testing revealed that the CMH system upregulated the oxidative phosphorylation pathway of macrophage, enhancing mitochondrial respiration and ATP production. Mitochondrial tracing experiments demonstrated the transfer of macrophage mitochondria to preosteoblasts, resulting in enhanced metabolic activity and osteogenic differentiation of preosteoblasts. This study may be the first suggest that conductive biomaterials facilitate osteogenic immunomodulation through mitochondrial transfer, which provides a promising method for regulating the immune microenvironment and reveals a novel pathway by which M2 macrophages enhance osteogenesis.