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Probing biochemical/biophysical influences on endothelial-mesenchymal transition

探讨生化/生物物理对内皮间质转化的影响

基本信息

批准号：
8596819
负责人：
WILLIAM L. MURPHY
金额：
$ 21.51万
依托单位：
UNIVERSITY OF WISCONSIN-MADISON
依托单位国家：
美国
项目类别：
财政年份：
2013
资助国家：
美国
起止时间：
2013-01-01 至 2014-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8596819
关键词：
Adult Area Biochemical Biocompatible Materials Biological Biological Phenomena Bone Diseases Cartilage Cell Adhesion Cell Culture Techniques Cell Differentiation process Cell physiology Cell-Cell Adhesion Cells Collagen Coupled Cues Development Disease Disease Progression Endothelial Cells Environment Ethylene Glycols Extracellular Matrix Fatty acid glycerol esters Fibronectins Fibrosis Growth Factor Health Heterotopic Ossification Human Hydrogels Investigation Ligands Malignant Neoplasms Mesenchymal Myofibroblast Normal tissue morphology Osteogenesis Peptides Phenotype Play Prevalence Process Property Proteoglycan Reporting Research Role Signal Transduction Skeletal Muscle System Tissues Transforming Growth Factor Beta 2 Vitronectin Work base biophysical properties bone bone morphogenetic protein 4 cell behavior cell growth cell type combinatorial density design ethylene glycol experience extracellular innovation insight laminin-10 medical implant mimetics monolayer novel progressive myositis ossificans public health relevance research study skeletal tissue therapeutic development

项目摘要

DESCRIPTION (provided by applicant): Several recent reports have demonstrated that endothelial cells can differentiate into mesenchymal cell types [1-8], a process called endothelial-mesenchymal transition (EndoMT or EndMT). In turn, endothelial cell-derived mesenchymal cells are capable of differentiating into multiple cell types, and have been shown to form fat, cartilage, and bone, respectively[8]. Recent studies indicate that EndMT contributes to disease progression in post-developmental tissue, and thorough investigations have shown roles in fibrosis[1, 3-5], cancer[2], and heterotopic ossification associated with fibrodysplasia ossificans progressiva (FOP) [8]. Therefore, the factors that influence EndMT may be of particular relevance in understanding and manipulating disease progression. The extracellular matrix (ECM) provides a wide variety of biochemical and biophysical cues that guide cell function, and several matrix components have been implicated in EndMT during tissue development, including proteoglycans [9], vitronectin, collagen, fibronectin and laminin [10-11]. In addition, TGF-b superfamily growth factors can induce EndMT[3, 8] and the influence of soluble TGF-b on endothelial cell behavior is dependent on ECM components present in culture [12]. Further, biophysical factors are also known to be important determinants of endothelial cell behavior, mesenchymal cell differentiation [13], fibrosis, and bone disease [5, 14-24]. Taken together, these previous studies implicate ECM-derived signals as likely regulators of EndMT and, in turn, disease progression. However, the role for the ECM in guiding EndMT is a largely unexplored area of research, perhaps due to the relatively recent discovery that this process occurs in adult tissue. Here, we propose an approach to identify ECM-mimetic signals that influence EndMT. The experimental approach is based on our experience creating materials to efficiently control cell-material interactions. The guiding hypothesis of the application is that biochemical and biophysical factors that mimic extracellular matrix properties will each significantly influence the process of EndMT. The proposed studies are Significant, as they will provide critical new insights into how the extracellular matrix contributes to EndMT, and the diseases in which it is implicated. The few factors that are known to influence EndMT in adult tissue (e.g., BMP-4, TGF-b1, TGF-b2) and the changes in endothelial cell phenotype that result (e.g., myofibroblast activation, heterotopic osteogenesis) are generally implicated in a range of diseases that are of substantial and broad relevance. Therefore, a better understanding of the role of EndMT could have a substantial benefit for human health. The proposed studies are Innovative, as they use novel, chemically-defined cell culture arrays to efficiently probe the effects of ECM-mimetic signals. This approach for probing ECM-mimetic signals is ideal in the case of the EndMT process, as the ECM plays a poorly understood but likely critical role in EndMT. Further, understanding how synthetic biomaterials influence EndMT could ultimately have relevance to medical implant design, particularly in scenarios in which it is important to limit fibrosis or heterotopic ossification.

描述（由申请人提供）：最近的几份报告表明，内皮细胞可以分化为间充质细胞类型[1-8]，这一过程称为内皮-间充质转化（EndoMT或EndMT）。反过来，内皮细胞衍生的间充质细胞能够分化成多种细胞类型，并已显示分别形成脂肪、软骨和骨[8]。最近的研究表明，EndMT有助于发育后组织中的疾病进展，并且彻底的研究已经显示了在纤维化[1，3-5]、癌症[2]和与进行性骨化性纤维发育不良（FOP）相关的异位骨化中的作用[8]。因此，影响EndMT的因素可能与理解和操纵疾病进展特别相关。细胞外基质（ECM）提供了指导细胞功能的多种生物化学和生物物理学线索，并且在组织发育期间，几种基质组分涉及EndMT，包括蛋白聚糖[9]、玻连蛋白、胶原蛋白、纤连蛋白和层粘连蛋白[10-11]。此外，TGF-β超家族生长因子可诱导EndMT[3，8]，可溶性TGF-β对内皮细胞行为的影响取决于培养物中存在的ECM组分[12]。此外，还已知生物物理因素是内皮细胞行为、间充质细胞分化[13]、纤维化和骨疾病的重要决定因素[5，14-24]。综上所述，这些先前的研究暗示ECM衍生的信号可能是EndMT的调节剂，进而是疾病进展的调节剂。然而，ECM在引导EndMT中的作用在很大程度上是一个未探索的研究领域，这可能是由于相对较新的发现，即该过程发生在成人组织中。在这里，我们提出了一种方法来识别ECM模拟信号的影响EndMT。实验方法是基于我们创造材料的经验，以有效地控制细胞-材料相互作用。本申请的指导假设是，模拟细胞外基质性质的生物化学和生物物理因素将各自显著影响EndMT的过程。这些研究具有重要意义，因为它们将为细胞外基质如何促进EndMT以及与之相关的疾病提供重要的新见解。已知影响成体组织中EndMT的少数因素（例如，BMP-4，TGF-β 1，TGF-β 2）和导致的内皮细胞表型的变化（例如，肌成纤维细胞活化、异位成骨）通常与一系列具有实质性和广泛相关性的疾病有关。因此，更好地了解EndMT的作用可能对人类健康有实质性的好处。拟议的研究是创新的，因为它们使用新型的化学定义的细胞培养阵列来有效地探测ECM模拟信号的影响。这种用于探测ECM模拟信号的方法在EndMT过程的情况下是理想的，因为ECM在EndMT中起着知之甚少但可能至关重要的作用。此外，了解合成生物材料如何影响EndMT最终可能与医疗植入物设计相关，特别是在限制纤维化或异位骨化非常重要的情况下。