Shimizu Emi, Matsuda-Honjyo Yuko, Samoto Hiroshi, Saito Ryoichiro, Nakajima Yu, Nakayama Youhei, Kato Naoko, Yamazaki Muneyoshi, Ogata Yorimasa
Department of Periodontology, Nihon University School of Dentistry at Matsudo, Chiba 271-8587, Japan.
J Cell Biochem. 2004 Apr 15;91(6):1183-96. doi: 10.1002/jcb.20002.
Bone sialoprotein (BSP) is a sulfated and phosphorylated glycoprotein found almost exclusively in mineralized connective tissues. Recent studies on the developmental expression of BSP mRNA and temporo-spatial appearance of the protein during bone formation in vivo and in vitro have demonstrated that BSP is expressed by differentiated osteoblasts, and that it may function in the initial nucleation of hydroxyapatite crystals in de novo bone formation. Physical forces may play a fundamental role in the regulation of cell function in bone, but little is known about how cells are able to sense mechanical loads and signal transduction. Magnetic fields of sufficient magnitude have been shown to affect various biologic systems at organ, tissue, cellular, and subcellular levels. In the present study, rat osteosarcoma-derived osteoblast-like cells, UMR 106, were used to assess the effect of static magnetic fields (SMF) on gene transcription of BSP. In our culture system, application of 300 and 800 Gauss SMF increased BSP mRNA levels after 24 h stimulation. To determine the molecular basis of the transcriptional regulation of BSP gene transcription by SMF, we conducted transient transfection analyses with chimeric constructs of the rat BSP gene promoter linked to a luciferase (LUC) reporter gene. SMF (300 and 800 Gauss) increased expression of the construct (pLUC3; -116 to +60) after 24 h treatment. Further deletion analysis of the BSP promoter showed that a region within nt -116 to -84 was targeted by SMF, the effect of which was inhibited by the tyrosine kinase inhibitor herbimycin A (HA). Mutations (2 bp) were made in an inverted CCAAT box between nt -50 and -46, a cyclicAMP response element (CRE; between nt -75 and -68), a fibroblast growth factor-2 response element (FRE; -92 to -85), and a pituitary-specific transcription factor-1 motif (Pit-1; nt -111 to -105) within the pLUC3 construct. Transcriptional stimulation by SMF was almost completely abrogated in constructs that included 2-bp mutations in the FRE and Pit-1. Binding of nuclear proteins to a radiolabeled FRE was increased and that to a Pit-1 was decreased in nuclear extracts prepared from SMF-stimulated UMR 106 cells. Further, the stimulatory and inhibitory effects of SMF on FRE and Pit-1 DNA-protein complexes were completely abolished by HA treatment. These studies, therefore, show that SMF increases BSP transcription through a tyrosine kinase-dependent pathway and that the SMF effects are mediated through juxtaposed FRE and Pit-1elements in the proximal promoter of the BSP gene.
骨唾液蛋白(BSP)是一种几乎仅在矿化结缔组织中发现的硫酸化和磷酸化糖蛋白。最近关于BSP mRNA在体内和体外骨形成过程中的发育表达以及该蛋白的时空出现的研究表明,BSP由分化的成骨细胞表达,并且它可能在新生骨形成中羟基磷灰石晶体的初始成核中发挥作用。物理力可能在骨细胞功能的调节中起基本作用,但关于细胞如何感知机械负荷和信号转导知之甚少。已表明足够强度的磁场会在器官、组织、细胞和亚细胞水平上影响各种生物系统。在本研究中,使用大鼠骨肉瘤来源的成骨样细胞UMR 106来评估静磁场(SMF)对BSP基因转录的影响。在我们的培养系统中,施加300和800高斯的SMF在刺激24小时后增加了BSP mRNA水平。为了确定SMF转录调控BSP基因转录的分子基础,我们用与荧光素酶(LUC)报告基因相连的大鼠BSP基因启动子的嵌合构建体进行了瞬时转染分析。SMF(300和800高斯)在处理24小时后增加了构建体(pLUC3;-116至+60)的表达。对BSP启动子的进一步缺失分析表明,nt -116至-84内的一个区域是SMF的作用靶点,其作用被酪氨酸激酶抑制剂赫伯霉素A(HA)抑制。在pLUC3构建体中,在nt -50至-46之间的反向CCAAT框、一个环磷酸腺苷反应元件(CRE;在nt -75至-68之间)、一个成纤维细胞生长因子-2反应元件(FRE;-92至-85)和一个垂体特异性转录因子-1基序(Pit-1;nt -111至-105)中进行了(2 bp)突变。在包含FRE和Pit-1中2-bp突变的构建体中,SMF的转录刺激几乎完全被消除。在从SMF刺激的UMR 106细胞制备的核提取物中,核蛋白与放射性标记的FRE的结合增加,而与Pit-1的结合减少。此外,HA处理完全消除了SMF对FRE和Pit-1 DNA-蛋白质复合物的刺激和抑制作用。因此,这些研究表明,SMF通过酪氨酸激酶依赖性途径增加BSP转录,并且SMF的作用是通过BSP基因近端启动子中并列的FRE和Pit-1元件介导的。
