Department of Metabolic Disorders, Amgen Inc., Thousand Oaks, CA 91320-1799, USA.
Bone. 2011 Dec;49(6):1178-85. doi: 10.1016/j.bone.2011.08.012. Epub 2011 Aug 26.
Humans with inherited sclerostin deficiency have high bone mass. Targeted deletion of the sclerostin gene in mice (SOST-KO) causes increases in bone formation, bone mass and bone strength. Inhibition of sclerostin by a monoclonal antibody increases bone formation and enhances fracture healing in rodent and primate models. In this study, we describe the temporal progression of femoral fracture healing in SOST-KO mice compared with wild type (WT) control mice to further characterize the role of sclerostin in fracture healing. Sixty-seven male 9-10 week-old SOST-KO (N=37) and WT (N=30) mice underwent a closed femoral fracture. Weekly radiography was used to monitor the progress of healing. Histologic sections were used to characterize callus composition, evaluate callus bridging, and quantify lamellar bone formation on days 14 and 28. Densitometry and biomechanical testing were utilized to characterize bone mass and strength at the fractured and contralateral femurs on day 45. A significant improvement in time to radiographic healing (no discernible fracture line) was observed in SOST-KO mice, which corresponded to an increase in histologic bony bridging at 14 days (38% versus 0% in WT). Both genotypes appeared to be nearly fully bridged at 28 days post-fracture. The increased bridging at 14 days was associated with 97% greater bone area and 40% lower cartilage area in the callus of SOST-KO mice as compared to WT mice. Bone formation-related endpoints were higher in SOST-KO mice at both 14 and 28 days. At 45 days post-fracture, peak load and bone mass were significantly greater in the fractured femurs of SOST-KO mice as compared to WT mice. In conclusion, fractures in mice lacking sclerostin showed accelerated bridging, greater callus maturation, and increased bone formation and strength in the callus.
患有遗传性骨硬化蛋白缺乏症的人类骨骼密度较高。在小鼠中靶向敲除骨硬化蛋白基因(SOST-KO)会导致骨形成、骨量和骨强度增加。单克隆抗体抑制骨硬化蛋白可增加骨形成,并增强啮齿动物和灵长类动物模型中的骨折愈合。在这项研究中,我们描述了与野生型(WT)对照小鼠相比,SOST-KO 小鼠股骨骨折愈合的时间进程,以进一步确定骨硬化蛋白在骨折愈合中的作用。67 只 9-10 周龄的 SOST-KO(N=37)和 WT(N=30)雄性小鼠接受了闭合性股骨骨折。每周进行放射照相以监测愈合进展。组织学切片用于表征骨痂组成,评估骨痂桥接,并在第 14 天和第 28 天量化板层骨形成。在第 45 天,利用骨密度和生物力学测试来表征骨折和对侧股骨的骨量和强度。在 SOST-KO 小鼠中观察到放射学愈合(无明显骨折线)的时间明显改善,这与 14 天时组织学骨桥接的增加相对应(WT 中为 0%,SOST-KO 中为 38%)。两种基因型在骨折后 28 天似乎几乎完全桥接。与 WT 小鼠相比,SOST-KO 小鼠的骨痂中骨面积增加了 97%,软骨面积降低了 40%,这与 14 天时增加的桥接相对应。SOST-KO 小鼠在第 14 天和第 28 天的骨形成相关终点均较高。在骨折后 45 天,SOST-KO 小鼠骨折股骨的峰值负荷和骨量明显大于 WT 小鼠。总之,缺乏骨硬化蛋白的小鼠骨折表现出更快的桥接、更大的骨痂成熟度以及骨痂中更高的骨形成和强度。
