Regulation of cell migration by biochemical and mechanical environmental cues

生化和机械环境因素对细胞迁移的调节

• 批准号: RGPIN-2015-05114
• 负责人: Plotnikov, Sergey
• 金额: $ 2.33万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=662319
• 关键词: Regulation; cell; migration; biochemical; mechanical

Cell migration is a fundamental phenomenon that is critical for life of unicellular and multicellular organisms. Simple organisms, such as amebae, have to migrate to find food and to mate. Complexity of multicellular organisms, such as vertebrates, brings the necessity for individual cells and groups of cells to position themselves during developmental morphogenesis that is largely achieved through directed cell migration. In the adult, directed migration plays an important role in a wide range of physiological and pathological processes, including renewal of skin and intestinal epithelium, immune system function, and wound healing, as well as cancer metastasis and cardiovascular diseases.***Over the last two decades, immense progress has been made in understanding the complexity of mechanisms that regulate directed cell migration. This includes discovery of various extracellular cues such as biochemical gradients, mechanical forces, and gradients of extracellular matrix (ECM) stiffness and topology that guide migrating cells. Another key finding was identification of signaling pathways transducing individual environmental cues into directed cell movement. Despite this, much less is known about molecular mechanisms regulating directional cell movement in a tissue environment where multiple cues of different nature are presented simultaneously.***Here, we propose to reveal these mechanisms by using a combination of state-of-the-art biophysical techniques: synthetic hydrogels with tunable mechanical properties to mimic stiffness landscape of biological tissues and microfluidics to control local concentration of soluble biochemical cues. By coupling these approaches with quantitative live-cell imaging, and molecular analysis of intracellular signaling pathways we will reveal specific molecular players that integrate multiple cues, and direct cell migration in tissue environment.***The specific aims of this proposal include: (1) To determine the crosstalk between chemical and mechanical guidance cues in a novel in vitro model of directed cell migration; (2) To determine the molecular mechanisms mediating the crosstalk between chemical and mechanical guidance cues and directing cells in environments where multiple cues co-exist. This work will shed light on how biochemical cues regulate cell migration guided by physical gradients (ECM stiffness). It will also identify signaling pathways that integrate biochemical and mechanical guidance cues and dynamically regulate the cytoskeletal network to provide stereotypical cell behavior during crucial physiological or pathological processes, including tumor metastasis.**

细胞迁移是单细胞和多细胞生物生命的基本现象。简单的生物体，如阿米巴原虫，必须迁移以寻找食物和交配。多细胞生物（如脊椎动物）的复杂性使得个体细胞和细胞群在发育形态发生期间定位自身的必要性，这主要通过定向细胞迁移来实现。在成人中，定向迁移在广泛的生理和病理过程中起着重要作用，包括皮肤和肠上皮的更新，免疫系统功能和伤口愈合，以及癌症转移和心血管疾病。在过去的二十年中，在理解调节定向细胞迁移的机制的复杂性方面取得了巨大进展。这包括发现各种细胞外线索，如生物化学梯度，机械力，以及引导迁移细胞的细胞外基质（ECM）刚度和拓扑结构的梯度。另一个关键发现是识别将个体环境线索转换为定向细胞运动的信号通路。尽管如此，在同时呈现多种不同性质的线索的组织环境中，对调节定向细胞运动的分子机制知之甚少。在这里，我们建议通过使用最先进的生物物理技术的组合来揭示这些机制：具有可调机械特性的合成水凝胶，以模拟生物组织的刚度景观和微流体，以控制可溶性生化线索的局部浓度。通过将这些方法与定量活细胞成像和细胞内信号传导途径的分子分析相结合，我们将揭示整合多种线索的特定分子参与者，并指导组织环境中的细胞迁移。本提案的具体目的包括：（1）确定在一种新的体外定向细胞迁移模型中化学和机械引导信号之间的串扰;（2）确定介导化学和机械引导信号之间串扰的分子机制，并在多种信号共存的环境中引导细胞。这项工作将阐明生物化学线索如何调节细胞迁移的物理梯度（ECM刚度）。它还将识别整合生物化学和机械指导线索的信号通路，并动态调节细胞骨架网络，以在关键的生理或病理过程中提供刻板的细胞行为，包括肿瘤转移。