Extrusion without a motor: a new take on the loop extrusion model of genome organization.

IF 4.5 Nucleus (Austin, Tex.) Pub Date : 2018-01-01 DOI:10.1080/19491034.2017.1421825

C A Brackley, J Johnson, D Michieletto, A N Morozov, M Nicodemi, P R Cook, D Marenduzzo

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Abstract

Chromatin loop extrusion is a popular model for the formation of CTCF loops and topological domains. Recent HiC data have revealed a strong bias in favour of a particular arrangement of the CTCF binding motifs that stabilize loops, and extrusion is the only model to date which can explain this. However, the model requires a motor to generate the loops, and although cohesin is a strong candidate for the extruding factor, a suitable motor protein (or a motor activity in cohesin itself) has yet to be found. Here we explore a new hypothesis: that there is no motor, and thermal motion within the nucleus drives extrusion. Using theoretical modelling and computer simulations we ask whether such diffusive extrusion could feasibly generate loops. Our simulations uncover an interesting ratchet effect (where an osmotic pressure promotes loop growth), and suggest, by comparison to recent in vitro and in vivo measurements, that diffusive extrusion can in principle generate loops of the size observed in the data. Extra View on : C. A. Brackley, J. Johnson, D. Michieletto, A. N. Morozov, M. Nicodemi, P. R. Cook, and D. Marenduzzo "Non-equilibrium chromosome looping via molecular slip-links", Physical Review Letters 119 138101 (2017).

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无马达挤出：基因组组织环挤出模型的新进展。

染色质环挤压是CTCF环和拓扑结构域形成的一种流行模型。最近的HiC数据显示，强烈倾向于CTCF结合基序的特定排列，稳定环，挤出是迄今为止唯一可以解释这一点的模型。然而，该模型需要一个马达来产生环路，尽管内聚蛋白是挤出因子的有力候选，但合适的马达蛋白（或内聚蛋白本身的运动活性）尚未被发现。在这里，我们探索了一个新的假设：没有电机，核内的热运动驱动挤压。通过理论建模和计算机模拟，我们探讨了这种漫射挤压是否可能产生环路。我们的模拟揭示了一个有趣的棘轮效应（其中渗透压促进环生长），并表明，通过比较最近的体外和体内测量，扩散挤压原则上可以产生数据中观察到的大小的环。陈晓明，陈晓明，陈晓明，陈晓明，“基于分子链的非平衡染色体环”，《物理学报》，2017年第1期。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nucleus (Austin, Tex.)

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