Kulkarni Nalini H, Onyia Jude E, Zeng Qingqiang, Tian Xioayan, Liu Min, Halladay David L, Frolik Charles A, Engler Thomas, Wei Tao, Kriauciunas Aidas, Martin T John, Sato Masahiko, Bryant Henry U, Ma Yanfei L
Lilly Research Laboratories, Eli Lilly and Company, Lilly Corporate Center, Indianapolis, Indiana 46285, USA.
J Bone Miner Res. 2006 Jun;21(6):910-20. doi: 10.1359/jbmr.060316.
GSK-3, a component of the canonical Wnt signaling pathway, is implicated in regulation of bone mass. The effect of a small molecule GSK-3 inhibitor was evaluated in pre-osteoblasts and in osteopenic rats. GSK-3 inhibitor induced osteoblast differentiation in vitro and increased markers of bone formation in vitro and in vivo with concomitant increased bone mass and strength in rats.
Inactivation of glycogen synthase kinase -3 (GSK-3) leads to stabilization, accumulation, and translocation of beta-catenin into the nucleus to activate downstream Wnt target genes. To examine whether GSK-3 directly regulates bone formation and mass we evaluated the effect of 603281-31-8, a small molecule GSK-3 alpha/beta dual inhibitor in preosteoblastic cells and in osteopenic rats.
Murine mesenchymal C3H10T1/2 cells were treated with GSK-3 inhibitor (603281-31-8) and assayed for beta-catenin levels, activity of Wnt-responsive promoter, expression of mRNA for bone formation, and adipogenic markers and alkaline phosphatase activity. In vivo, 6-month-old rats were ovariectomized (OVX), allowed to lose bone for 1 month, and treated with GSK-3 inhibitor at 3 mg/kg/day orally for 60 days. At the end of treatment, BMD was measured by DXA, bone formation rate by histomorphometry, vertebral strength (failure in compression), and the expression levels of osteoblast-related genes by real-time PCR.
Treatment of C3H10T1/2 cells with the GSK-3 inhibitor increased the levels of beta-catenin accompanied by activation of Wnt-responsive TBE6-luciferase reporter gene. This was associated with an increased expression of mRNA for bone sialoprotein (1.4-fold), collagen alpha1 (I) (approximately 2-fold), osteocalcin (1.2-fold), collagen alpha1(V) (1.5-fold), alkaline phosphatase (approximately 160-fold), and runx2 (1.6-fold), markers of the osteoblast phenotype and bone formation activity. Alkaline phosphatase mRNA expression paralleled alkaline phosphatase activity. The mRNA levels of collagens alpha1 (I), alpha1 (V), biglycan, osteonectin, and runx-2 increased on treatment with the GSK-3 inhibitor in rat femur compared with the OVX control. DXA analyses revealed significant increases in BMC and BMD in cancellous and cortical bone of OVX rats treated with GSK-3 inhibitor. This was associated with increased strength (peak load, energy, and stiffness) assessed by lumbar vertebra load to failure in compression. Histomorphometric analyses showed that 603281-31-8 robustly increased bone formation but did not exclude a small effect on osteoclasts (resorption).
An orally active, small molecule GSK-3 inhibitor induced osteoblast differentiation and increased markers of bone formation in vitro, and increased markers of bone formation, bone mass, and strength in vivo, consistent with a role for the canonical Wnt pathway in osteogenesis.
糖原合酶激酶3(GSK-3)是经典Wnt信号通路的一个组成部分,与骨量调节有关。在成骨前体细胞和骨质疏松大鼠中评估了一种小分子GSK-3抑制剂的作用。GSK-3抑制剂在体外诱导成骨细胞分化,并在体外和体内增加骨形成标志物,同时增加大鼠的骨量和骨强度。
糖原合酶激酶-3(GSK-3)失活导致β-连环蛋白稳定、积累并转运至细胞核,从而激活下游Wnt靶基因。为了研究GSK-3是否直接调节骨形成和骨量,我们评估了小分子GSK-3α/β双重抑制剂603281-31-8对成骨前体细胞和骨质疏松大鼠的作用。
用GSK-3抑制剂(603281-31-8)处理小鼠间充质C3H10T1/2细胞,并检测β-连环蛋白水平、Wnt反应性启动子活性、骨形成相关mRNA表达、脂肪生成标志物及碱性磷酸酶活性。在体内,对6月龄大鼠进行卵巢切除(OVX),使其骨质流失1个月,然后以3mg/kg/天的剂量口服GSK-3抑制剂,持续60天。治疗结束时,通过双能X线吸收法(DXA)测量骨密度,通过组织形态计量学测量骨形成率,测量椎体强度(压缩破坏),并通过实时PCR检测成骨细胞相关基因的表达水平。
用GSK-3抑制剂处理C3H10T1/2细胞可增加β-连环蛋白水平,并伴有Wnt反应性TBE6-荧光素酶报告基因的激活。这与骨涎蛋白(1.4倍)、胶原蛋白α1(I)(约2倍)、骨钙素(1.2倍)、胶原蛋白α1(V)(1.5倍)、碱性磷酸酶(约160倍)和runx2(1.6倍)的mRNA表达增加有关,这些都是成骨细胞表型和骨形成活性的标志物。碱性磷酸酶mRNA表达与碱性磷酸酶活性平行。与OVX对照组相比,用GSK-3抑制剂处理大鼠股骨后,胶原蛋白α1(I)、α1(V)、双糖链蛋白聚糖、骨连接蛋白和runx-2的mRNA水平增加。DXA分析显示,用GSK-3抑制剂处理的OVX大鼠的松质骨和皮质骨的骨矿含量(BMC)和骨密度(BMD)显著增加。这与通过腰椎压缩破坏负荷评估的强度增加(峰值负荷、能量和刚度)有关。组织形态计量学分析表明,603281-31-8能显著增加骨形成,但不排除对破骨细胞有轻微影响(吸收)。
一种口服活性小分子GSK-3抑制剂在体外诱导成骨细胞分化并增加骨形成标志物,在体内增加骨形成标志物、骨量和强度,这与经典Wnt通路在骨生成中的作用一致。
