New Opportunities Innovative Medicines group, AstraZeneca R&D, Alderley Park, Cheshire SK10 4TF, UK.
Toxicol Appl Pharmacol. 2013 Oct 15;272(2):399-407. doi: 10.1016/j.taap.2013.07.001. Epub 2013 Jul 18.
Wnt activation by inhibiting glycogen synthase kinase 3 (GSK-3) causes bone anabolism in rodents making GSK-3 a potential therapeutic target for osteoporotic and osteolytic metastatic bone disease. To understand the wnt pathway related to human disease translation, the ability of 3 potent inhibitors of GSK-3 (AZD2858, AR79, AZ13282107) to 1) drive osteoblast differentiation and mineralisation using human adipose-derived stem cells (hADSC) in vitro; and 2) stimulate rat bone formation in vivo was investigated. Bone anabolism/resorption was determined using clinically relevant serum biomarkers as indicators of bone turnover and bone formation assessed in femurs by histopathology and pQCT/μCT imaging. GSK-3 inhibitors caused β-catenin stabilisation in human and rat mesenchymal stem cells, stimulated hADSC commitment towards osteoblasts and osteogenic mineralisation in vitro. AZD2858 produced time-dependent changes in serum bone turnover biomarkers and increased bone mass over 28 days exposure in rats. After 7 days, AZD2858, AR79 or AZ13282107 exposure increased the bone formation biomarker P1NP, and reduced the resorption biomarker TRAcP-5b, indicating increased bone anabolism and reduced resorption in rats. This biomarker profile was differentiated from anabolic agent PTH1-34 or the anti-resorptive Alendronate-induced changes. Increased bone formation in cortical and cancellous bone as assessed by femur histopathology supported biomarker changes. 14 day AR79 treatment increased bone mineral density and trabecular thickness, and decreased trabecular number and connectivity assessed by pQCT/μCT. GSK-3 inhibition caused hADSC osteoblastogenesis and mineralisation in vitro. Increased femur bone mass associated with changes in bone turnover biomarkers confirmed in vivo bone formation and indicated uncoupling of bone formation and resorption.
Wnt 激活通过抑制糖原合酶激酶 3(GSK-3)导致啮齿动物的骨合成代谢,使 GSK-3 成为治疗骨质疏松症和溶骨性转移性骨疾病的潜在治疗靶点。为了了解与人类疾病翻译相关的 Wnt 途径,研究了 3 种强效 GSK-3 抑制剂(AZD2858、AR79、AZ13282107)的能力:1)在体外使用人脂肪来源干细胞(hADSC)驱动成骨细胞分化和矿化;2)刺激大鼠体内骨形成。使用临床相关的血清生物标志物作为骨转换的指标,并通过组织病理学和 pQCT/μCT 成像评估股骨中的骨形成,来确定骨合成代谢/吸收。GSK-3 抑制剂在人源和大鼠间充质干细胞中引起β-连环蛋白稳定化,刺激 hADSC 向成骨细胞和体外成骨矿化分化。AZD2858 在大鼠中产生了时间依赖性的血清骨转换生物标志物变化,并在 28 天的暴露中增加了骨量。7 天后,AZD2858、AR79 或 AZ13282107 暴露增加了骨形成生物标志物 P1NP,并降低了吸收生物标志物 TRAcP-5b,表明大鼠的骨合成代谢增加和吸收减少。这种生物标志物谱与合成代谢剂 PTH1-34 或抗吸收剂阿仑膦酸盐诱导的变化不同。股骨组织病理学评估的皮质骨和松质骨的骨形成增加支持了生物标志物的变化。14 天的 AR79 治疗增加了骨密度和小梁厚度,并减少了 pQCT/μCT 评估的小梁数量和连通性。GSK-3 抑制导致 hADSC 成骨细胞分化和矿化。在体内增加股骨骨量与骨转换生物标志物的变化相关,证实了骨形成,并表明骨形成和吸收的解偶联。
