{"title":"Dynamic cluster field modeling of collective chemotaxis","authors":"Aditya Paspunurwar, Adrian Moure, Hector Gomez","doi":"arxiv-2408.04748","DOIUrl":null,"url":null,"abstract":"Collective migration of eukaryotic cells is often guided by chemotaxis, and\nis critical in several biological processes, such as cancer metastasis, wound\nhealing, and embryogenesis. Understanding collective chemotaxis has challenged\nexperimental, theoretical and computational scientists because cells can sense\nvery small chemoattractant gradients that are tightly controlled by cell-cell\ninteractions and the regulation of the chemoattractant distribution by the\ncells. Computational models of collective cell migration that offer a\nhigh-fidelity resolution of the cell motion and chemoattractant dynamics in the\nextracellular space have been limited to a small number of cells. Here, we\npresent Dynamic cluster field modeling (DCF), a novel computational method that\nenables simulations of collective chemotaxis of cellular systems with O(1000)\ncells and high-resolution transport dynamics of the chemoattractant in the\ntime-evolving extracellular space. We illustrate the efficiency and predictive\ncapabilities of our approach by comparing our numerical simulations with\nexperiments in multiple scenarios that involve chemoattractant secretion and\nuptake by the migrating cells, regulation of the attractant distribution by\ncell motion, and interactions of the chemoattractant with an enzyme. The\nproposed algorithm opens new opportunities to address outstanding problems that\ninvolve collective cell migration in the central nervous system, immune\nresponse and cancer metastasis.","PeriodicalId":501040,"journal":{"name":"arXiv - PHYS - Biological Physics","volume":"69 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-08-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - PHYS - Biological Physics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2408.04748","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Collective migration of eukaryotic cells is often guided by chemotaxis, and
is critical in several biological processes, such as cancer metastasis, wound
healing, and embryogenesis. Understanding collective chemotaxis has challenged
experimental, theoretical and computational scientists because cells can sense
very small chemoattractant gradients that are tightly controlled by cell-cell
interactions and the regulation of the chemoattractant distribution by the
cells. Computational models of collective cell migration that offer a
high-fidelity resolution of the cell motion and chemoattractant dynamics in the
extracellular space have been limited to a small number of cells. Here, we
present Dynamic cluster field modeling (DCF), a novel computational method that
enables simulations of collective chemotaxis of cellular systems with O(1000)
cells and high-resolution transport dynamics of the chemoattractant in the
time-evolving extracellular space. We illustrate the efficiency and predictive
capabilities of our approach by comparing our numerical simulations with
experiments in multiple scenarios that involve chemoattractant secretion and
uptake by the migrating cells, regulation of the attractant distribution by
cell motion, and interactions of the chemoattractant with an enzyme. The
proposed algorithm opens new opportunities to address outstanding problems that
involve collective cell migration in the central nervous system, immune
response and cancer metastasis.
真核细胞的集体迁移通常由趋化作用引导,在癌症转移、伤口愈合和胚胎发育等多个生物过程中至关重要。由于细胞能感知非常微小的趋化梯度,而这种梯度受细胞-细胞相互作用和细胞对趋化物质分布的调节的严格控制,因此理解集体趋化现象对实验、理论和计算科学家提出了挑战。细胞集体迁移的计算模型能高保真地解析细胞运动和细胞外空间的趋化因子动态,但这种模型仅限于少数细胞。在这里,我们将介绍动态簇场建模(Dynamic cluster field modeling,DCF),这是一种新颖的计算方法,可以模拟细胞数为 O(1000)个的细胞系统的集体趋化以及趋化物质在随时间演变的细胞外空间的高分辨率迁移动力学。我们通过将数值模拟与多种情况下的实验进行比较,包括迁移细胞分泌和吸收趋化吸引剂、细胞运动对吸引剂分布的调节以及趋化吸引剂与酶的相互作用,说明了我们的方法的效率和预测能力。提出的算法为解决涉及中枢神经系统细胞集体迁移、免疫反应和癌症转移等悬而未决的问题提供了新的机遇。