Abstract
Degenerative joint diseases such as osteoarthritis are characterised by aberrant region-specific bone formation and abnormal bone mineral content. A recent study suggested a role for the complement membrane attack complex in experimental models of osteoarthritis. Since CD59a is the principal regulator of the membrane attack complex in mice, we evaluated the impact of CD59a gene deletion upon maintenance of bone architecture.In vivo bone morphology analysis revealed that male CD59a-deficient mice have increased femur length and cortical bone volume, albeit with reduced bone mineral density. However, this phenomenon was not observed in female mice. Histomorphometric analysis of the trabecular bone showed increased rates of bone homeostasis, with both increased bone resorption and mineral apposition rate in CD59a-deficient male mice. When bone cells were studied in isolation, in vitro osteoclastogenesis was significantly increased in male CD59a-deficient mice, although osteoblast formation was not altered.Our data reveal, for the first time, that CD59a is a regulator of bone growth and homeostasis. CD59a ablation in male mice results in longer and wider bones, but with less density, which is likely a major contributing factor for their susceptibility to osteoarthritis. These findings increase our understanding of the role of complement regulation in degenerative arthritis.
Highlights
The balanced activity of bone-forming osteoblasts and boneresorbing osteoclasts maintains bone homeostasis [1]
CD59 is unique as it is the only complement regulator that controls membrane attack complex (MAC) assembly by preventing lytic pore formation
Scale bar, 0.25 mm. (B) Quantification of tartrate-resistant acid phosphatase (TRAP)-positive MNCs produced from RANKL-induced cultures
Summary
The balanced activity of bone-forming osteoblasts and boneresorbing osteoclasts maintains bone homeostasis [1]. Mechanosignalling and systemic mediators activate resting bone surfaces, induce remodelling, and modulate the recruitment and maturation of osteoclast precursor cells [2,3,4,5]. Osteoclastogenesis and consequential resorption of bone induces osteoblast maturation and the secretion of bone matrix and hydroxyapatite [6]. Osteoclast and osteoblast function is coupled during bone remodelling. In 1991, Sato et al discovered that osteoblast–osteoclast cross-talk is modulated by complement components [7]. The complement (C) system consists of activation pathways and the membrane attack complex (MAC).
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