Sage E H, Bassuk J A, Yost J C, Folkman M J, Lane T F
Department of Biological Structure, University of Washington School of Medicine, Seattle 98195.
J Cell Biochem. 1995 Jan;57(1):127-40. doi: 10.1002/jcb.240570113.
SPARC (secreted protein, acidic and rich in cysteine, also known as osteonectin and BM-40) is a metal-binding glycoprotein secreted by a variety of cultured cells and characteristic of tissues undergoing morphogenesis, remodeling, and repair. Recently it has been shown that SPARC inhibits the progression of the endothelial cell cycle in mid-G1, and that a synthetic peptide (amino acids 54-73 of secreted murine SPARC, peptide 2.1) from a cationic, disulfide-bonded region was in part responsible for the growth-suppressing activity [Funk and Sage (1991): Proc Natl Acad Sci USA 88:2648-2652]. Moreover, SPARC was shown to interact directly with bovine aortic endothelial (BAE) cells through a C-terminal EF-hand sequence comprising a high-affinity Ca(2+)-binding site of SPARC and represented by a synthetic peptide (amino acids 254-273) termed 4.2 [Yost and Sage (1993): J Biol Chem 268:25790-25796]. In this study we show that peptide 4.2 is a more potent inhibitor of DNA synthesis that acts cooperatively with peptide 2.1 to diminish the incorporation of [3H]-thymidine by both BAE and bovine capillary endothelial (BCE) cells. At concentrations of 0.019-0.26 mM peptide 4.2, thymidine incorporation by BAE cells was decreased incrementally, relative to control values, from approximately 100 to 10%. Although somewhat less responsive, BCE cells exhibited a dose-responsive decrement in thymidine incorporation, with a maximal inhibition of 55% at 0.39 mM. The inhibitory effect of peptide 4.2 was essentially independent of heparin and basic fibroblast growth factor and was blocked by anti-SPARC peptide 4.2 IgG, but not by antibodies specific for other domains of SPARC. To identify residues that were necessary for inhibition of DNA synthesis, we introduced single amino acid substitutions into synthetic peptide 4.2 and tested their activities and cell-surface binding characteristics on endothelial cells. Two peptides displayed null to diminished effects in the bioassays that were concentration-dependent: peptide 4.2 K, containing an Asp258 --> Lys substitution, and peptide 4.2 AA, in which the two disulfide-bonded Cys (positions 255 and 271) were changed to Ala residues. Peptide 4.2 K, which failed to fulfill the EF-hand consensus formula, exhibited an anomalous fluorescence emission spectrum, in comparison with the wild-type 4.2 sequence, that was indicative of a compromised affinity for Ca2(+).(ABSTRACT TRUNCATED AT 400 WORDS)
SPARC(分泌性蛋白质,酸性且富含半胱氨酸,也称为骨连接蛋白和BM - 40)是一种金属结合糖蛋白,由多种培养细胞分泌,是经历形态发生、重塑和修复的组织所特有的。最近研究表明,SPARC在G1期中期抑制内皮细胞周期进程,并且来自阳离子、二硫键连接区域的合成肽(分泌型小鼠SPARC的氨基酸54 - 73,肽2.1)部分负责这种生长抑制活性[芬克和塞奇(1991年):《美国国家科学院院刊》88:2648 - 2652]。此外,SPARC通过包含SPARC高亲和力Ca(2 + )结合位点的C末端EF - 手序列与牛主动脉内皮(BAE)细胞直接相互作用,该序列由称为4.2的合成肽(氨基酸254 - 273)代表[约斯特和塞奇(1993年):《生物化学杂志》268:25790 - 25796]。在本研究中,我们表明肽4.2是一种更有效的DNA合成抑制剂,它与肽2.1协同作用,减少BAE细胞和牛毛细血管内皮(BCE)细胞对[3H] - 胸苷的掺入。在肽4.2浓度为0.019 - 0.26 mM时,相对于对照值,BAE细胞的胸苷掺入量逐渐减少,从约100%降至10%。虽然BCE细胞反应稍弱,但也表现出胸苷掺入的剂量反应性降低,在0.39 mM时最大抑制率为55%。肽4.2的抑制作用基本上与肝素和碱性成纤维细胞生长因子无关,并且被抗SPARC肽4.2 IgG阻断,但不被针对SPARC其他结构域的抗体阻断。为了确定抑制DNA合成所需的残基,我们在合成肽4.2中引入单个氨基酸取代,并测试它们在内皮细胞上的活性和细胞表面结合特性。两种肽在生物测定中表现出无效或减弱的作用,且呈浓度依赖性:肽4.2 K含有Asp258→Lys取代,肽4.2 AA中两个二硫键连接的半胱氨酸(位置255和271)被替换为丙氨酸残基。与野生型4.2序列相比,未能满足EF - 手共有模式的肽4.2 K表现出异常的荧光发射光谱,这表明其对Ca2( + )的亲和力受损。(摘要截短至400字)
