Syed Farhan A, Fraser Daniel G, Spelsberg Thomas C, Rosen Clifford J, Krust Andree, Chambon Pierre, Jameson J Larry, Khosla Sundeep
Endocrine Research Unit, Department of Biochemistry and Molecular Biology, Mayo Clinic College of Medicine, 200 First Street SW, Rochester, Minnesota 55905, USA.
Endocrinology. 2007 Apr;148(4):1902-10. doi: 10.1210/en.2006-1165. Epub 2007 Jan 4.
The role of estrogen signaling in the male skeleton via estrogen receptor (ER)-alpha is now well established. ERalpha can elicit responses through either classical estrogen response elements (ERE) pathways or nonclassical, non-ERE pathways. In the present study, we examined the effects of either the attenuation or loss of classical ERalpha signaling on the murine male skeleton. To accomplish this, we crossed male mice heterozygous for a knock-in mutation [nonclassical ERalpha knock-in (NERKI)], which abolishes the ERE-mediated pathway with female heterozygous ERalpha knockout mice (ERalpha+/-) and studied the F1 generation ERalpha+/+, ERalpha+/-, ERalpha+/NERKI, and ERalpha-/NERKI male progeny longitudinally using bone density and histomorphometry. The only ERalpha allele present in ERalpha-/NERKI mice is incapable of classical ERE-mediated signaling, whereas the heterozygous ERalpha+/NERKI mice have both one intact ERalpha and one NERKI allele. As compared with ERalpha+/+ littermates (n=10/genotype), male ERalpha+/NERKI and ERalpha-/NERKI mice displayed axial and appendicular skeletal osteopenia at 6, 12, 20, and 25 wk of age, as demonstrated by significant reductions in total bone mineral density (BMD) at representative sites (areal BMD by dual-energy x-ray absorptiometry at the lumbar vertebrae and femur and volumetric BMD by peripheral quantitative computed tomography at the tibia; P<0.05-0.001 vs. ERalpha+/+). The observed osteopenia in these mice was evident in both trabecular and cortical bone compartments. However, these decreases were more severe in mice lacking classical ERalpha signaling (ERalpha-/NERKI mice), compared with mice in which one wild-type ERalpha allele was present (ERalpha+/NERKI mice). Collectively, these data demonstrate that classical ERalpha signaling is crucial for the development of the murine male skeleton.
雌激素信号通过雌激素受体(ER)-α在雄性骨骼中的作用现已得到充分证实。ERα可通过经典雌激素反应元件(ERE)途径或非经典、非ERE途径引发反应。在本研究中,我们检测了经典ERα信号减弱或缺失对小鼠雄性骨骼的影响。为实现这一目的,我们将携带敲入突变[非经典ERα敲入(NERKI)]的雄性杂合小鼠(该突变消除了ERE介导的途径)与雌性杂合ERα敲除小鼠(ERα+/-)杂交,并使用骨密度和组织形态计量学对F1代ERα+/+、ERα+/ -、ERα+/NERKI和ERα-/NERKI雄性后代进行纵向研究。ERα-/NERKI小鼠中存在的唯一ERα等位基因无法进行经典的ERE介导信号传导,而杂合ERα+/NERKI小鼠既有一个完整的ERα等位基因,又有一个NERKI等位基因。与ERα+/+同窝小鼠(每组n = 10)相比,雄性ERα+/NERKI和ERα-/NERKI小鼠在6、12、20和25周龄时表现出轴向和附属骨骼骨质减少,这通过代表性部位的总骨矿物质密度(BMD)显著降低得以证明(腰椎和股骨处通过双能X线吸收法测量面积BMD,胫骨处通过外周定量计算机断层扫描测量体积BMD;与ERα+/+相比,P<0.05 - 0.001)。在这些小鼠中观察到的骨质减少在小梁骨和皮质骨区域均很明显。然而,与存在一个野生型ERα等位基因的小鼠(ERα+/NERKI小鼠)相比,缺乏经典ERα信号的小鼠(ERα-/NERKI小鼠)的骨质减少更为严重。总体而言,这些数据表明经典ERα信号对小鼠雄性骨骼的发育至关重要。
