A simple active fluid model unites cytokinesis, cell crawling, and axonal outgrowth.

IF 4.6 2区 生物学 Q2 CELL BIOLOGY
Frontiers in Cell and Developmental Biology Pub Date : 2024-10-17 eCollection Date: 2024-01-01 DOI:10.3389/fcell.2024.1491429
Erin M Craig, Francesca Oprea, Sajid Alam, Ania Grodsky, Kyle E Miller
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Abstract

While the structural organization and molecular biology of neurons are well characterized, the physical process of axonal elongation remains elusive. The classic view posited elongation occurs through the deposition of cytoskeletal elements in the growth cone at the tip of a stationary array of microtubules. Yet, recent studies reveal axonal microtubules and docked organelles flow forward in bulk in the elongating axons of Aplysia, chick sensory, rat hippocampal, and Drosophila neurons. Noting that the morphology, molecular components, and subcellular flow patterns of growth cones strongly resemble the leading edge of migrating cells and the polar regions of dividing cells, our working hypothesis is that axonal elongation utilizes the same physical mechanisms that drive cell crawling and cell division. As a test of that hypothesis, here we take experimental data sets of sub-cellular flow patterns in cells undergoing cytokinesis, mesenchymal migration, amoeboid migration, neuronal migration, and axonal elongation. We then apply active fluid theory to develop a biophysical model that describes the different sub-cellular flow profiles across these forms of motility and how this generates cell motility under low Reynolds numbers. The modeling suggests that mechanisms for generating motion are shared across these processes, and differences arise through modifications of sub-cellular adhesion patterns and the profiles of internal force generation. Collectively, this work suggests that ameboid and mesenchymal cell crawling may have arisen from processes that first developed to support cell division, that growth cone motility and cell crawling are closely related, and that neuronal migration and axonal elongation are fundamentally similar, differing primarily in the motion and strength of adhesion under the cell body.

一个简单的活性流体模型将细胞分裂、细胞爬行和轴突生长结合在一起。
虽然神经元的结构组织和分子生物学特征已十分明确,但轴突伸长的物理过程仍然难以捉摸。传统观点认为,伸长是通过细胞骨架元素在微管静止阵列顶端的生长锥中沉积而发生的。然而,最近的研究发现,在水蚤、小鸡感觉器官、大鼠海马和果蝇神经元的伸长轴突中,轴突微管和对接的细胞器大量向前流动。注意到生长锥的形态、分子成分和亚细胞流动模式与迁移细胞的前缘和分裂细胞的极区非常相似,我们的工作假设是,轴突的伸长利用了驱动细胞爬行和细胞分裂的相同物理机制。作为对这一假设的验证,我们在这里使用了细胞分裂、间充质迁移、变形虫迁移、神经元迁移和轴突伸长过程中细胞亚细胞流动模式的实验数据集。然后,我们运用主动流体理论建立了一个生物物理模型,该模型描述了这些运动形式中不同的亚细胞流动剖面,以及在低雷诺数条件下如何产生细胞运动。该模型表明,这些过程中产生运动的机制是相同的,而差异则是通过改变亚细胞粘附模式和内力产生曲线而产生的。总之,这项研究表明,浮游动物细胞和间充质细胞的爬行可能源于最初为支持细胞分裂而发展起来的过程;生长锥运动和细胞爬行密切相关;神经元迁移和轴突伸长基本相似,主要区别在于细胞体下粘附的运动和强度。
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来源期刊
Frontiers in Cell and Developmental Biology
Frontiers in Cell and Developmental Biology Biochemistry, Genetics and Molecular Biology-Cell Biology
CiteScore
9.70
自引率
3.60%
发文量
2531
审稿时长
12 weeks
期刊介绍: Frontiers in Cell and Developmental Biology is a broad-scope, interdisciplinary open-access journal, focusing on the fundamental processes of life, led by Prof Amanda Fisher and supported by a geographically diverse, high-quality editorial board. The journal welcomes submissions on a wide spectrum of cell and developmental biology, covering intracellular and extracellular dynamics, with sections focusing on signaling, adhesion, migration, cell death and survival and membrane trafficking. Additionally, the journal offers sections dedicated to the cutting edge of fundamental and translational research in molecular medicine and stem cell biology. With a collaborative, rigorous and transparent peer-review, the journal produces the highest scientific quality in both fundamental and applied research, and advanced article level metrics measure the real-time impact and influence of each publication.
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