Can a bulky glycocalyx promote catch bonding in early integrin adhesion? Perhaps a bit

IF 3 3区 医学 Q2 BIOPHYSICS Biomechanics and Modeling in Mechanobiology Pub Date : 2023-09-13 DOI:10.1007/s10237-023-01762-x
Aaron T. Blanchard
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Abstract

Many types of cancer cells overexpress bulky glycoproteins to form a thick glycocalyx layer. The glycocalyx physically separates the cell from its surroundings, but recent work has shown that the glycocalyx can paradoxically increase adhesion to soft tissues and therefore promote the metastasis of cancer cells. This surprising phenomenon occurs because the glycocalyx forces adhesion molecules (called integrins) on the cell’s surface into clusters. These integrin clusters have cooperative effects that allow them to form stronger adhesions to surrounding tissues than would be possible with equivalent numbers of un-clustered integrins. These cooperative mechanisms have been intensely scrutinized in recent years. A more nuanced understanding of the biophysical underpinnings of glycocalyx-mediated adhesion could uncover therapeutic targets, deepen our general understanding of cancer metastasis, and elucidate general biophysical processes that extend far beyond the realm of cancer research. This work examines the hypothesis that the glycocalyx has the additional effect of increasing mechanical tension experienced by clustered integrins. Integrins function as mechanosensors that undergo catch bonding—meaning the application of moderate tension increases integrin bond lifetime relative to the lifetime of integrins experiencing low tension. In this work, a three-state chemomechanical catch bond model of integrin tension is used to investigate catch bonding in the presence of a bulky glycocalyx. A pseudo-steady-state approximation is applied, which relies on the assumption that integrin bond dynamics occur on a much faster timescale than the evolution of the full adhesion between the plasma membrane and the substrate. Force-dependent kinetic rate constants are used to calculate a steady-state distribution of integrin-ligand bonds for Gaussian-shaped adhesion geometries. The relationship between the energy of the system and adhesion geometry is then analyzed in the presence and absence of catch bonding in order to evaluate the extent to which catch bonding alters the energetics of adhesion formation. This modeling suggests that a bulky glycocalyx can lightly trigger catch bonding, increasing the bond lifetime of integrins at adhesion edges by up to 100%. The total number of integrin-ligand bonds within an adhesion is predicted to increase by up to ~ 60% for certain adhesion geometries. Catch bonding is predicted to decrease the activation energy of adhesion formation by ~ 1–4 kBT, which translates to a ~ 3–50 × increase in the kinetic rate of adhesion nucleation. This work reveals that integrin mechanics and clustering likely both contribute to glycocalyx-mediated metastasis.

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庞大的糖盏能促进早期整合素粘附中的捕获结合吗?也许有一点。
许多类型的癌症细胞过度表达庞大的糖蛋白以形成厚的糖盏层。糖盏在物理上将细胞与其周围环境分离,但最近的研究表明,糖盏可以矛盾地增加对软组织的粘附,从而促进癌症细胞的转移。之所以会出现这种令人惊讶的现象,是因为糖盏迫使细胞表面的粘附分子(称为整合素)形成簇。这些整合素簇具有协同作用,使它们能够与周围组织形成比同等数量的未聚集整合素更强的粘附。近年来,这些合作机制受到了严格审查。更细致地理解糖盖介导的粘附的生物物理基础可以揭示治疗靶点,加深我们对癌症转移的一般理解,并阐明远远超出癌症研究领域的一般生物物理过程。这项工作检验了糖盏具有增加聚集整合素所经历的机械张力的额外作用的假设。整合素起到进行捕获结合的机械传感器的作用,这意味着相对于经历低张力的整合素的寿命,中等张力的应用增加了整合素结合寿命。在这项工作中,使用整合素张力的三态化学机械捕获键模型来研究在存在大体积糖盏的情况下的捕获键。应用伪稳态近似,其依赖于整合素键动力学发生在比质膜和基底之间的完全粘附的演变快得多的时间尺度上的假设。力依赖的动力学速率常数用于计算高斯形状粘附几何形状的整合素配体键的稳态分布。然后在存在和不存在捕获结合的情况下分析系统的能量和粘附几何形状之间的关系,以评估捕获结合改变粘附形成的能量学的程度。该模型表明,体积庞大的糖盏可以轻微触发捕获结合,使整合素在粘附边缘的结合寿命增加100%。粘附中整合素配体键的总数预计将增加至多 ~ 对于某些粘附几何形状,60%。捕捉结合被预测为通过以下方式降低粘附形成的活化能 ~ 1-4 kBT,翻译为 ~ 3-50 × 粘附成核的动力学速率增加。这项工作揭示了整合素机制和聚集可能都有助于糖盏介导的转移。
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来源期刊
Biomechanics and Modeling in Mechanobiology
Biomechanics and Modeling in Mechanobiology 工程技术-工程:生物医学
CiteScore
7.10
自引率
8.60%
发文量
119
审稿时长
6 months
期刊介绍: Mechanics regulates biological processes at the molecular, cellular, tissue, organ, and organism levels. A goal of this journal is to promote basic and applied research that integrates the expanding knowledge-bases in the allied fields of biomechanics and mechanobiology. Approaches may be experimental, theoretical, or computational; they may address phenomena at the nano, micro, or macrolevels. Of particular interest are investigations that (1) quantify the mechanical environment in which cells and matrix function in health, disease, or injury, (2) identify and quantify mechanosensitive responses and their mechanisms, (3) detail inter-relations between mechanics and biological processes such as growth, remodeling, adaptation, and repair, and (4) report discoveries that advance therapeutic and diagnostic procedures. Especially encouraged are analytical and computational models based on solid mechanics, fluid mechanics, or thermomechanics, and their interactions; also encouraged are reports of new experimental methods that expand measurement capabilities and new mathematical methods that facilitate analysis.
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