Department of Biomedical Engineering, University of Rochester School of Medicine and Dentistry, 601 Elmwood Avenue, Rochester, NY 14642, USA.
Biomaterials. 2011 Mar;32(8):2077-87. doi: 10.1016/j.biomaterials.2010.11.050. Epub 2010 Dec 24.
Therapeutic protein engineering combines genetic, biochemical, and functional information to improve existing proteins or invent new protein technologies. Using these principles, we developed an approach to deliver extracellular matrix (ECM) fibronectin-specific signals to cells. Fibronectin matrix assembly is a cell-dependent process that converts the inactive, soluble form of fibronectin into biologically-active ECM fibrils. ECM fibronectin stimulates cell functions required for normal tissue regeneration, including cell growth, spreading, migration, and collagen reorganization. We have developed recombinant fibronectin fragments that mimic the effects of ECM fibronectin on cell function by coupling the cryptic heparin-binding fragment of fibronectin's first type III repeat (FNIII1H) to the integrin-binding domain (FNIII8-10). GST/III1H,8-10 supports cell adhesion and spreading and stimulates cell proliferation to a greater extent than plasma fibronectin. Deletion and site-specific mutant constructs were generated to identify the active regions in GST/III1H,8-10 and reduce construct size. A chimeric construct in which the integrin-binding, RGDS loop was inserted into the analogous site in FNIII8 (GST/III1H,8(RGD)), supported cell adhesion and migration, and enhanced cell proliferation and collagen gel contraction. GST/III1H,8(RGD) was expressed in bacteria and purified from soluble lysate fractions by affinity chromatography. Fibronectin matrix assembly is normally up-regulated in response to tissue injury. Decreased levels of ECM fibronectin are associated with non-healing wounds. Engineering fibronectin matrix mimetics that bypass the need for cell-dependent fibronectin matrix assembly in chronic wounds is a novel approach to stimulating cellular activities critical for tissue repair.
治疗性蛋白质工程结合了遗传、生化和功能信息,以改善现有蛋白质或发明新的蛋白质技术。我们利用这些原则,开发了一种向细胞传递细胞外基质(ECM)纤维连接蛋白特异性信号的方法。纤维连接蛋白基质组装是一个依赖细胞的过程,它将纤维连接蛋白的无活性可溶性形式转化为具有生物活性的 ECM 纤维。ECM 纤维连接蛋白刺激细胞功能,这些功能是正常组织再生所必需的,包括细胞生长、扩展、迁移和胶原重组。我们已经开发了模拟 ECM 纤维连接蛋白对细胞功能影响的重组纤维连接蛋白片段,方法是将纤维连接蛋白第一型 III 重复(FNIII1H)的隐蔽肝素结合片段与整合素结合域(FNIII8-10)偶联。GST/III1H,8-10 支持细胞黏附和扩展,并比血浆纤维连接蛋白更能刺激细胞增殖。我们生成了缺失和定点突变构建体,以鉴定 GST/III1H,8-10 中的活性区域并缩小构建体的大小。在 GST/III1H,8(RGDS)中插入整合素结合 RGDS 环的嵌合构建体支持细胞黏附和迁移,并增强细胞增殖和胶原凝胶收缩。GST/III1H,8(RGDS)在细菌中表达,并通过亲和层析从可溶性裂解物级分中纯化。纤维连接蛋白基质组装通常在组织损伤时上调。ECM 纤维连接蛋白水平降低与愈合不良的伤口有关。工程化纤维连接蛋白基质模拟物绕过慢性伤口中细胞依赖的纤维连接蛋白基质组装的需要,是刺激组织修复中关键细胞活动的新方法。
