In order to define the osteocytic function in accelerated bone remodeling, we examined the distribution of the osteocytic lacunar-canalicular system (OLCS) and osteocyte-secreting moleculesdentin matrix protein (DMP) 1 and sclerostin-in the epiphyses and cortical bones of osteoprotegerin deficient (OPG −/− ) mice. Silver impregnation visualized a well-arranged OLCS in the wild-type epiphyses and cortical bone, whereas OPG −/− mice had an irregular OLCS in the epiphyses, but well-arranged canaliculi in the cortical bone. DMP1-positive osteocytes were evenly distributed throughout the wild-type epiphyses and cortical bone, as well as the OPG −/− cortical bone. However, OPG −/− epiphyses revealed weak DMP1-immunoreactivity. Thus, osteocytes appear to synthesize more DMP1 as the OLCS becomes regular. In contrast, sclerostin-immunoreactivity was significantly diminished in the OPG −/− epiphyses and cortical bone. In OPG −/− epiphyses and cortical bone, triple staining demonstrated few sclerostin-positive osteocytes in the periphery of a thick cell layer of alkaline phosphatase-positive osteoblasts and many tartrate resistant acid phosphatasepositive osteoclasts. Summarizing, the regular distribution of OLCS may affect DMP1 synthesis, while the cellular activities of osteoclasts and osteoblasts rather than the regularity of OLCS may ultimately influence sclerostin synthesis.Osteocytes are the most numerous cells in bone, being localized within their lacunae. The osteocytes are connected each other by means of their cytoplasmic processes interconnected through gap junctions (9, 23), which pass through narrow passage ways referred to as osteocytic canaliculi. Therefore, osteocytes build up functional syncytia, i.e., the osteocytic lacunar-canalicular system (OLCS) (1,7,15). To date, osteocytes and their canaliculi have been shown to sense the direction and strength of mechanical stress in bone and then, affect the communication among osteocytes and between osteocytes and osteoblasts (7,14,35). They may also regulate bone remodeling (16,22,27) and mineral metabolism (4,10,27). Osteocytes might control trafficking of minerals such as calcium and phosphate through their canaliculi, and might regulate osteoclastic and osteoblastic activities on the bone surface. These putative functions imply that OLCS feature a finely tuned arrangement, which may be altered by physical or chemical imbalances. Our previous work demonstrated that physiological bone remodeling would reconstruct the arrangement of OLCS more regularly; especially, the speed of bone deposition during remodeling would influence the regularity of OLCS (13, 31). The regularity of OLCS appears to be different in each region of
