Project description:Although our data is providing the evidence that Ihh regulates nasal and mandibular cartilage development to establish facial and masticatory system, the cartilage gene network conducted by Ihh signaling has not been broadly investigated. To establish such gene expression profile, we selected mandibular condylar cartilage to examine differentiating cartilage tissue. The cartilage histologically indicates simple endochondral ossification and mutant sections positive to Tomato staining presented decreased and disrupted cartilage.

Project description:Background Extracellular matrix (ECM) protein malfunction or defect may lead to temporomandibular joint osteoarthritis (TMJ OA). Dentin sialophophoprotein (DSPP) is a mandibular condylar cartilage ECM protein, and its deletion impacted cell proliferation and other extracellular matrix alterations of postnatal condylar cartilage. However, it remains unclear if long-term loss of function of DSPP leads to TMJ OA. The study aimed to test the hypothesis that long-term haploinsufficiency of DSPP causes TMJ OA. Materials and Methods To determine whether Dspp+/- mice exhibit TMJ OA but no severe tooth defects, mandibles of wild-type (WT), Dspp+/-, and Dspp homozygous (Dspp-/-) mice were analyzed by Micro-computed tomography (micro-CT). To characterize the progression and possible mechanisms of osteoarthritic degeneration over time in Dspp+/- mice over time, condyles of Dspp+/- and WT mice were analyzed radiologically, histologically, and immunohistochemically. Results Micro-CT and histomorphometric analyses revealed that Dspp+/- and Dspp-/- mice had significantly lower subchondral bone mass, bone volume fraction, bone mineral density, and trabecular thickness compared to WT mice at 12 months. Interestingly, in contrast to Dspp-/- mice which exhibited tooth loss, Dspp+/- mice had minor tooth defects. RNA sequencing data showed that haplodeficency of DSPP affects the biological process of ossification and osteoclast differentiation. Additionally, histological analysis showed that Dspp+/- mice had condylar cartilage fissures, reduced cartilage thickness, decreased articular cell numbers and severe subchondral bone cavities, and with signs that were exaggerated with age. Radiographic data showed an increase in subchondral osteoporosis up to 18 months and osteophyte formation at 21 months. Moreover, Dspp+/- mice showed increased distribution of osteoclast in the subchondal bone and increased expression of MMP2, IL-6, FN-1, and TLR4 in the mandibular condylar cartilage. Conclusions Dspp+/- mice exhibit TMJ OA in a time-dependent manner, with lesions in the mandibular condyle attributed to hypomineralization of subchondral bone and breakdown of the mandibular condylar cartilage, accompanied by upregulation of inflammatory markers.

Project description:Mesenchymal cell-derived septoclasts resorb cartilage during endochondral ossification and fracture healing

Project description:Two distinct and anatomically restricted modes of ossification, which are endochondral ossification and intramembranous ossification, govern osteogenesis and joint formation throughout the human skeleton and, to our knowledge, the cellular bases by which they form and mature remain incompletely described in human development at single-cell resolution. To address this, we apply single-nuclei paired RNA and ATAC sequencing to decipher the molecular gene regulatory programmes that mediate maturation of the distinct bone and joint-forming niches in the cranium and appendicular skeleton across space and time from 5-11 PCW.

Project description:Skeletal growth promoted by endochondral ossification is tightly coordinated by self-renewal and differentiation of chondrogenic progenitors. Emerging evidence has shown that multiple skeletal stem cells (SSCs) participate in cartilage formation. However, as yet, no study has reported the existence of common long-lasting chondrogenic progenitors in various types of cartilage. Here, we identified Gli1+ chondrogenic progenitors (Gli1+ CPs), which were distinct from SSCs, were responsible for the lifelong generation of chondrocytes in the growth plate, vertebrae, ribs, and other cartilage. The absence of Gli1+ CPs led to cartilage defects and dwarfishness phenotype in mice. Furthermore, we found that the BMP signal played an important role in self-renewal and maintenance of Gli1+ CPs. The deletion of Bmpr1α caused the exhaustion of Gli1+ CPs, consequently disrupting columnar cartilage. Collectively, our data demonstrate that Gli1+ CPs are common long-term chondrogenic progenitors in multiple types of cartilage and are essential to maintain cartilage homeostasis.

Project description:Bone fracture healing requires skeletal stem cells (SSCs), which facilitate intramembranous ossification and endochondral ossification in long bone fractures. Although the periosteum is necessary for bone homeostasis and regeneration, the in vivo origin and regulatory mechanisms of periosteal SSCs (P-SSCs) remain unclear. Here, we identified Postn+ P-SSCs at the cambium layer of the periosteum that actively orchestrate regeneration in response to bone injury. Notably, the Postn+ P-SSCs that arise during bicortical fractures are likely derived from Gli1+ P-SSCs. In addition, Postn+ cell ablation compromises cortical bone homeostasis and bone regeneration. The IGF signal is indispensable in the regulatory effect of Postn+ P-SSCs on bicortical fractures since the genetic deletion of Igf1r in Postn+ cells dampens bone fracture healing. Taken together, adult Postn+ cells are region-specific P-SSCs that contribute to bone homeostasis and regeneration and are partially dependent upon IGF signaling.

Project description:Runx2 and Axin2 regulate skeletal development. We recently determined that Axin2 and Runx2 molecularly interact in differentiating osteoblasts to regulate intramembranous bone formation, but the relationship between these factors in endochondral bone formation was unresolved. To address this, we examined the effects of Axin2 deficiency on the cleidocranial dysplasia (CCD) phenotype of Runx2+/- mice, focusing on skeletal defects attributed to improper endochondral bone formation. Axin2 deficiency unexpectedly exacerbated calvarial components of the CCD phenotype in the Runx2+/- mice; the endocranial layer of the frontal suture, which develops by endochondral bone formation, failed to mineralize in the Axin2-/-:Runx2+/-mice, resulting in a cartilaginous, fibrotic and larger fontanel than observed in Runx2+/- mice. Transcripts associated with cartilage development (e.g., Acan, miR140) were expressed at higher levels, whereas blood vessel morphogenesis transcripts (e.g., Slit2) were suppressed in Axin2-/-:Runx2+/-calvaria. Cartilage maturation was impaired, as primary chondrocytes from double mutant mice demonstrated delayed differentiation and produced less calcified matrix in vitro. The genetic dominance of Runx2 was also reflected during endochondral fracture repair, as both Runx2+/- and double mutant Axin2-/-:Runx2+/- mice had enlarged fracture calluses at early stages of healing. However, by the end stages of fracture healing, double mutant animals diverged from the Runx2+/- mice, showing smaller calluses and increased torsional strength indicative of more rapid end stage bone formation as seen in the Axin2-/- mice. Taken together, our data demonstrate a dominant role for Runx2 in chondrocyte maturation, but implicate Axin2 as an important modulator of the terminal stages of endochondral bone formation. 4 mice per genotype X 4 genotypes: wildtype (WT), Runx2+/- (R-Het), Axin2-/- (A-KO), Axin2-/-:Runx2+/- (A-KO:R-Het). Total = 16 samples

Project description:Antler primary growth center is located in the distal tip of growing antler with five consecutive tissue layers under the velvet skin. Because of blastema progenitor cells of outmost reserve mesenchymal layer with multipotent differentiation capacity, antler regeneration recapitulates embryonic skeletal development through endochondral os-sification process. To further decipher this modified endochondral ossification, we profile deer antler proteome atlas with 8000 proteins, covering the whole five layers that comprehensively represent the mesenchymal condensation, rapid mesenchymal proliferation, chondrocyte hypertrophy, cartilage mineralization. By integrating three clustering methods including WGCNA, Fuzzy C-means clustering, and Monotonic feature selector, we elucidate proteome dynamics within the growth center, identifying key factors and elucidating biological processes through GO enrichment analysis. Through comparative analysis of RNA-seq and Proteomic studies, our results reveal that mRNA exhibits greater fluctuations during the endochondral ossification process. This research offers a valuable model for investigating hub genes and their biological function involved in organ regeneration.

Project description:Regeneration of human cartilage and bone remains a challenge due to the limitations from current stem cell sources. Here, we developed a four-day differentiation strategy that achieved near uniform derivation (>98.5%) of SOX9+ sclerotomal progenitorsfrom multiple human pluripotent stem cells (hPSCs). Importantly, SOX9+ sclerotomal progenitors exhibited typical bipotential of mesenchymal progenitors during skeletal development. Upon lineage-specific induction, they were able to differentiate either into chondroprogenitors that could repair articular cartilage defects or early chondrocytes that could undergo endochondral ossification for human bone formation. Furthermore, we identified ITGA9 as the specific surface marker that facilitated reporter-independent isolation of SOX9+ sclerotomal progenitors and established an in vitro culture system that could expand these cells for at least 15,000-fold . Collectively, these findings highlight the SOX9+ sclerotomal progenitors a promising stem cell source for next-generation human cartilage/bone bioengineering.

Project description:Regeneration of human cartilage and bone remains a challenge due to the limitations from current stem cell sources. Here, we developed a four-day differentiation strategy that achieved near uniform derivation (>98.5%) of SOX9+ sclerotomal progenitors from multiple human pluripotent stem cells (hPSCs). Importantly, SOX9+ sclerotomal progenitors exhibited typical bipotential of mesenchymal progenitors during skeletal development. Upon lineage-specific induction, they were able to differentiate either into chondroprogenitors that could repair articular cartilage defects and early chondrocytes that could undergo endochondral ossification for human bone formation. Furthermore, we identified ITGA9 as the specific surface marker that facilitated reporter-independent isolation of SOX9+ sclerotomal progenitors and established an in vitro culture system that could expand these cells for at least 15,000-fold. Collectively, these findings highlight the SOX9+ sclerotomal progenitors as a promising stem cell source for next-generation human cartilage/bone bioengineering.