A Tridimensional Model of Proangiogenic Calcium Signals in Endothelial Cells

L. Munaron
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引用次数: 7

Abstract

Angiogenic factors, including bFGF and VEGF, induce cytosolic calcium (Cac) increases in endothelial cells, critically involved in angiogenesis progression. At low agonist concentrations, Cac elevation is mainly due to calcium entry controlled by a complex interplay between two intracellular messengers, arachidonic acid (AA) and nitric oxide (NO), released upon stimulation with proangiogenic factors: they trigger spatially localized calcium signals restricted to the cell periphery, and such a spatiotemporal pattern could contribute to the specificity of cellular responses. Based on experimental measurements, here we provide the first quantitative spatiotemporal 3D modeling of proangiogenic calcium events in endothelial cells using Virtual Cell framework. The main aims were to validate previously proposed signaling pathways and to suggest new experimental protocols. The most relevant conclusions are: 1. The interplay between AA and NO, previously proposed to be responsible for VEGF/bFGF-dependent calcium entry in endothelial cells, triggers peripheral calcium signals that reproduce the experimental measurements; 2. Spatial restriction is not an artefact due to the calcium-sensitive dye; 3. Channels clusterization in thin lamellipodia plays a key role in the generation of the peripheral-restricted proangiogenic calcium signals; 4. A model containing two distinct channels, named AAAC and NOAC, respectively activated by AA or NO, explains the basic properties of proangiogenic calcium signals. This could be considered an 'open model' containing the simplest conditions leading to a satisfactory reproduction of the experimental results: it should be implemented in order to make it more complete and to maximize physical and biochemical constraints.
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内皮细胞促血管生成钙信号的三维模型
血管生成因子,包括bFGF和VEGF,诱导内皮细胞的胞质钙(Cac)增加,在血管生成过程中起关键作用。在低激动剂浓度下,Cac升高主要是由于钙的进入,这是由两种细胞内信使——花生四烯酸(AA)和一氧化氮(NO)之间的复杂相互作用控制的,它们在促血管生成因子的刺激下释放:它们触发局限于细胞外周的空间定位钙信号,这种时空模式可能有助于细胞反应的特异性。基于实验测量,我们使用Virtual Cell框架首次提供内皮细胞中促血管生成钙事件的定量时空3D建模。主要目的是验证先前提出的信号通路,并提出新的实验方案。最相关的结论是:1。AA和NO之间的相互作用,先前被认为是内皮细胞中VEGF/ bfgf依赖性钙进入的原因,触发外周钙信号,再现实验测量;2. 空间限制不是由于钙敏感染料造成的人工制品;3.薄板足的通道聚集在外周限制性促血管生成钙信号的产生中起关键作用;4. 一个包含AAAC和NOAC两个不同通道的模型,分别被AA或NO激活,解释了促血管生成钙信号的基本特性。这可以被认为是一个“开放模型”,它包含了最简单的条件,导致实验结果的令人满意的再现:它应该被实施,以使它更完整,并最大化物理和生化限制。
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