Korvasová K, Gaffney E A, Maini P K, Ferreira M A, Klika V
Department of Mathematics, Faculty of Nuclear Sciences and Physical Engineering, Czech Technical University in Prague, Trojanova 13, 120 00 Prague 2, Czech Republic.
Wolfson Centre for Mathematical Biology, Mathematical Institute, University of Oxford, Radcliffe Observatory Quarter, Woodstock Road, OX2 6GG Oxford, United Kingdom.
J Theor Biol. 2015 Feb 21;367:286-295. doi: 10.1016/j.jtbi.2014.11.024. Epub 2014 Dec 4.
Turing's diffusion-driven instability for the standard two species reaction-diffusion system is only achievable under well-known and rather restrictive conditions on both the diffusion rates and the kinetic parameters, which necessitates the pairing of a self-activator with a self-inhibitor. In this study we generalize the standard two-species model by considering the case where the reactants can bind to an immobile substrate, for instance extra-cellular matrix, and investigate the influence of this dynamics on Turing's diffusion-driven instability. Such systems have been previously studied on the grounds that binding of the self-activator to a substrate may effectively reduce its diffusion rate and thus induce a Turing instability for species with equal diffusion coefficients, as originally demonstrated by Lengyel and Epstein (1992) under the assumption that the bound state dynamics occurs on a fast timescale. We, however, analyse the full system without any separation of timescales and demonstrate that the full system also allows a relaxation of the standard constraints on the reaction kinetics for the Turing instability, increasing the type of interactions that could give rise to spatial patterning. In particular, we show that two self-activators can undertake a diffusively driven instability in the presence of a binding immobile substrate, highlighting that the interactions required of a putative biological Turing instability need not be associated with a self-activator-self-inhibitor morphogen pair.
图灵针对标准双物种反应扩散系统提出的扩散驱动不稳定性,只有在扩散速率和动力学参数方面满足众所周知且颇为严格的条件时才能实现,这就要求自激活剂与自抑制剂配对。在本研究中,我们通过考虑反应物可与固定底物(如细胞外基质)结合的情况,对标准双物种模型进行了推广,并研究了这种动力学对图灵扩散驱动不稳定性的影响。此前已有研究表明,自激活剂与底物的结合可能会有效降低其扩散速率,从而在扩散系数相等的物种中引发图灵不稳定性,这最初是由伦吉尔和爱泼斯坦在1992年假设束缚态动力学发生在快速时间尺度的情况下证明的。然而,我们对整个系统进行了分析,没有对时间尺度进行任何分离,并证明整个系统也允许放宽图灵不稳定性对反应动力学的标准约束,增加了可能导致空间图案形成的相互作用类型。特别是,我们表明在存在结合固定底物的情况下,两种自激活剂可以发生扩散驱动的不稳定性,这突出表明假定的生物图灵不稳定性所需的相互作用不一定与自激活剂 - 自抑制剂形态发生素对相关。