Abstract
Biglycan (Bgn) and Fibromodulin (Fmod) are subtypes of the small leucine-rich family of proteoglycans (SLRP). In this study we examined the skeletal phenotype of BgnFmod double knockout (BgnFmod KO) mice and found they were smaller in size and have markedly reduced bone mass compared to WT. The low bone mass (LBM) phenotype is the result of both the osteoblasts and osteoclasts from BgnFmod KO mice having higher differentiation potential and being more active compared to WT mice. Using multiple approaches, we showed that both Bgn and Fmod directly bind TNFα as well as RANKL in a dose dependent manner and that despite expressing higher levels of both TNFα and RANKL, BgnFmod KO derived osteoblasts cannot retain these cytokines in the vicinity of the cells, which leads to elevated TNFα and RANKL signaling and enhanced osteoclastogenesis. Furthermore, adding either Bgn or Fmod to osteoclast precursor cultures significantly attenuated the cells ability to form TRAP positive, multinucleated giant cells. In summary, our data indicates that Bgn and Fmod expressed by the bone forming cells, are novel coupling ECM components that control bone mass through sequestration of TNFα and/or RANKL, thereby adjusting their bioavailability in order to regulate osteoclastogenesis.
Highlights
Biglycan (Bgn) and Fibromodulin (Fmod) are subtypes of the small leucine-rich family of proteoglycans (SLRP)
At early stages of osteoclast differentiation, macrophage colony-stimulating factor (M-CSF) promotes the expression of RANK by myeloid progenitors, further increasing the number of RANK–expressing cells and priming them to react to RANKL6
While the skulls of the DKO are clearly affected with a low bone mass phenotype, in this paper we focused on the axial skeleton to gain further mechanistic insight
Summary
Biglycan (Bgn) and Fibromodulin (Fmod) are subtypes of the small leucine-rich family of proteoglycans (SLRP). The direct binding of these molecules to sites on the core protein or to the GAG chains controls their bioavailability and activity, either by (1) sequestering them in the ECM creating a biological gradient or reservoir close to the cell surface, (2) presenting them to their individual receptors, enhancing the signaling aptitude or (3) keeping them away from the relevant receptors, by preventing the ligand-receptor interaction attenuating signal transduction[13,21,22] All these interactions have a direct effect on cell-signaling pathways regulating proliferation, migration and the complement immune system[23,24,25,26]
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