Epidermal Growth Factor Receptor (EGFR) Signaling Regulates Epiphyseal Cartilage Development through β-Catenin-dependent and -independent Pathways

The epidermal growth factor receptor (EGFR) is an essential player in the development of multiple organs during embryonic and postnatal stages. To understand its role in epiphyseal cartilage development, we generated transgenic mice with conditionally inactivated EGFR in chondrocytes. Postnatally, these mice exhibited a normal initiation of cartilage canals at the perichondrium, but the excavation of these canals into the cartilage was strongly suppressed, resulting in a delay in the formation of the secondary ossification center (SOC). This delay was accompanied by normal chondrocyte hypertrophy but decreased mineralization and apoptosis of hypertrophic chondrocytes and reduced osteoclast number at the border of marrow space. Immunohistochemical analyses demonstrated that inactivation of chondrocyte-specific EGFR signaling reduced the amounts of matrix metalloproteinases (MMP9, -13, and -14) and RANKL (receptor activator of NF-κB ligand) in the hypertrophic chondrocytes close to the marrow space and decreased the cartilage matrix degradation in the SOC. Analyses of EGFR downstream signaling pathways in primary epiphyseal chondrocytes revealed that up-regulation of MMP9 and RANKL by EGFR signaling was partially mediated by the canonical Wnt/β-catenin pathway, whereas EGFR-enhanced MMP13 expression was not. Further biochemical studies suggested that EGFR signaling stimulates the phosphorylation of LRP6, increases active β-catenin level, and induces its nuclear translocation. In line with these in vitro studies, deficiency in chondrocyte-specific EGFR activity reduced β-catenin amount in hypertrophic chondrocytes in vivo. In conclusion, our work demonstrates that chondrocyte-specific EGFR signaling is an important regulator of cartilage matrix degradation during SOC formation and epiphyseal cartilage development and that its actions are partially mediated by activating the β-catenin pathway.     

Role of matrix metalloproteinase 13 in both endochondral and intramembranous ossification during skeletal regeneration

Extracellular matrix (ECM) remodeling is important during bone development and repair. Because matrix metalloproteinase 13 (MMP13, collagenase-3) plays a role in long bone development, we have examined its role during adult skeletal repair. In this study we find that MMP13 is expressed by hypertrophic chondrocytes and osteoblasts in the fracture callus. We demonstrate that MMP13 is required for proper resorption of hypertrophic cartilage and for normal bone remodeling during non-stabilized fracture healing, which occurs via endochondral ossification. However, no difference in callus strength was detected in the absence of MMP13. Transplant of wild-type bone marrow, which reconstitutes cells only of the hematopoietic lineage, did not rescue the endochondral repair defect, indicating that impaired healing in Mmp13-/- mice is intrinsic to cartilage and bone. Mmp13-/- mice also exhibited altered bone remodeling during healing of stabilized fractures and cortical defects via intramembranous ossification. This indicates that the bone phenotype occurs independently from the cartilage phenotype. Taken together, our findings demonstrate that MMP13 is involved in normal remodeling of bone and cartilage during adult skeletal repair, and that MMP13 may act directly in the initial stages of ECM degradation in these tissues prior to invasion of blood vessels and osteoclasts.     

Runx2参与调控Osterix 启动子活性及其基因表达

尽管Runx2和Osterix都是成骨细胞分化途径中关键的转录因子,但是Runx2是否能够调控Osterix,还不为所知.研究发现,在非成骨细胞系,无论是间充质干细胞还是已分化的细胞,以及成骨细胞系中,Runx2都能诱导Osterix的表达.同时Runx2能够上调3.2kb人的Osterix基因启动子活性.进一步实验证明,在这一段启动子中存在Runx2功能性的结合位点.因而,实验结果有力地支持了这样一个假设,即Runx2参与了Osterix基因的表达调控.瞬时转染和荧光素酶双报告分析结果显示,在非成骨细胞中,Osterix明显上调2.3kb的Ⅰ型胶原蛋白启动子活性,但Runx2却不能.这样的差别暗示,在成骨细胞分化过程中位于Runx2下游的转录因子Osterix是刺激Ⅰ型胶原蛋白基因表达所必需的.     

MMP-13 is induced during chondrocyte hypertrophy

During development, mRNA for matrix metalloproteinase-13 (MMP-13) is found associated with cartilage undergoing hypertrophy, suggesting that this collagenase plays a role in cell enlargement and/or cartilage calcification. Using chondrocytes from prehypertrophic cartilage of chick embryo sternae, we have examined the relationship between MMP-13 expression and the transition to hypertrophy. When hypertrophy was induced by serum-free culture with ascorbate and bone morphogenetic protein-2 (BMP-2), MMP-13 mRNA levels paralleled those for type X collagen. Chondrocytes from the caudal, nonhypertrophying portion of chick sternae expressed neither type X collagen nor MMP-13, confirming that MMP-13 mRNA is a marker for hypertrophy. Zymography with conditioned medium yielded a proteinase band at 59 kDa, which was absent in nonhypertrophic chondrocytes. A polyclonal antibody raised against chick MMP-13 reacted with the 59-kDa protein, confirming that it is MMP-13. Although mRNA for MMP-13 peaked at days 4-5 of culture, only low levels of MMP-13 activity were present, and the activity increased gradually in parallel with later increases in MMP-2. These results suggest that MMP-13 is activated by MMP-2 during chondrocyte maturation, and that the combination of both proteinases is required to prepare cartilage matrix for subsequent calcification, before endochondral ossification.