水螅对称性破缺与驱动图灵不稳定性模型的机械遗传学耦合
Mechanogenetic coupling of Hydra symmetry breaking and driven Turing instability model.
作者信息
Soriano Jordi, Rüdiger Sten, Pullarkat Pramod, Ott Albrecht
机构信息
Dept. ECM, Facultat de Física, Universitat de Barcelona, Barcelona, Spain.
出版信息
Biophys J. 2009 Feb 18;96(4):1649-60. doi: 10.1016/j.bpj.2008.09.062.
Abstract
The freshwater polyp Hydra can regenerate from tissue fragments or random cell aggregates. We show that the axis-defining step ("symmetry breaking") of regeneration requires mechanical inflation-collapse oscillations of the initial cell ball. We present experimental evidence that axis definition is retarded if these oscillations are slowed down mechanically. When biochemical signaling related to axis formation is perturbed, the oscillation phase is extended and axis formation is retarded as well. We suggest that mechanical oscillations play a triggering role in axis definition. We extend earlier reaction-diffusion models for Hydra regrowth by coupling morphogen transport to mechanical stress caused by the oscillations. The modified reaction-diffusion model reproduces well two important experimental observations: 1), the existence of an optimum size for regeneration, and 2), the dependence of the symmetry breaking time on the properties of the mechanical oscillations.
摘要
淡水水螅可以从组织碎片或随机的细胞聚集体再生。我们发现,再生过程中确定轴的步骤(“对称性破缺”)需要初始细胞球进行机械性的膨胀-收缩振荡。我们提供的实验证据表明,如果这些振荡通过机械方式减缓,轴的确定就会延迟。当与轴形成相关的生化信号受到干扰时,振荡阶段会延长,轴的形成也会延迟。我们认为机械振荡在轴的确定中起触发作用。我们通过将形态发生素运输与振荡引起的机械应力耦合,扩展了早期关于水螅再生的反应-扩散模型。修改后的反应-扩散模型很好地再现了两个重要的实验观察结果:1)存在再生的最佳尺寸,2)对称性破缺时间对机械振荡特性的依赖性。
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