Osteoblastic heparan sulfate regulates osteoprotegerin function and bone mass
Satoshi Nozawa, Toshihiro Inubushi, Fumitoshi Irie, Iori Takigami, Kazu Matsumoto, Katsuji Shimizu, Haruhiko Akiyama, Yu Yamaguchi
Satoshi Nozawa, Toshihiro Inubushi, Fumitoshi Irie, Iori Takigami, Kazu Matsumoto, Katsuji Shimizu, Haruhiko Akiyama, Yu Yamaguchi
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Research Article Bone biology

Osteoblastic heparan sulfate regulates osteoprotegerin function and bone mass

Abstract

Bone remodeling is a highly coordinated process involving bone formation and resorption, and imbalance of this process results in osteoporosis. It has long been recognized that long-term heparin therapy often causes osteoporosis, suggesting that heparan sulfate (HS), the physiological counterpart of heparin, is somehow involved in bone mass regulation. The role of endogenous HS in adult bone, however, remains unclear. To determine the role of HS in bone homeostasis, we conditionally ablated Ext1, which encodes an essential glycosyltransferase for HS biosynthesis, in osteoblasts. Resultant conditional mutant mice developed severe osteopenia. Surprisingly, this phenotype is not due to impairment in bone formation but to enhancement of bone resorption. We show that osteoprotegerin (OPG), which is known as a soluble decoy receptor for RANKL, needs to be associated with the osteoblast surface in order to efficiently inhibit RANKL/RANK signaling and that HS serves as a cell surface binding partner for OPG in this context. We also show that bone mineral density is reduced in patients with multiple hereditary exostoses, a genetic bone disorder caused by heterozygous mutations of Ext1, suggesting that the mechanism revealed in this study may be relevant to low bone mass conditions in humans.

Authors

Satoshi Nozawa, Toshihiro Inubushi, Fumitoshi Irie, Iori Takigami, Kazu Matsumoto, Katsuji Shimizu, Haruhiko Akiyama, Yu Yamaguchi

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Figure 3

Osteoclastogenesis and bone resorption are enhanced in Oc-Cre;Ext1flox/flox mice.

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Osteoclastogenesis and bone resorption are enhanced in Oc-Cre;Ext1flox/f...
(A) Tartrate-resistant acid phosphatase (TRAP) staining of 1-month-old Oc-Cre;Ext1flox/flox (CKO) and WT vertebrae. TRAP-positive osteoclasts (stained purple) are greatly increased in CKO mice. (B) Histomorphometric analysis of osteoclasts in 1-month-old CKO and WT vertebrae. (C) Urinary excretion of DPD (normalized by the level of creatinine in the same urine sample). (D) Cocultures of bone marrow monocytes with either Ext1-null or control primary osteoblasts at 4 days in vitro. Ext1-null and control osteoblasts were prepared by infecting Ext1flox/flox osteoblasts with Cre-expressing adenovirus or control adenovirus, respectively. Note the increase in the number of TRAP-positive giant cells in the coculture with Ext1-null osteoblasts (KO Ob + WT BMM) compared with the coculture with control osteoblasts (WT Ob + WT BMM). (E) Quantification of osteoclasts in cocultures. The number of TRAP-positive cells containing more than 3 nuclei is significantly increased in cocultures with Ext1-null osteoblasts. Data represent the mean ± SD (n = 3 in B, C, and E). T.Ar, osteoclast volume density; B.Pm, osteoclast bone surface density. *P < 0.05, **P < 0.01, ***P < 0.001 by Student’s t test (B, C, and E). Scale bar: 5 μm (A); 0.2 mm (D).