Pattern formation features might explain homoplasy: fertile surfaces in higher fungi as an example.

IF 1.3 4区生物学 Q3 BIOLOGY

Theory in Biosciences Pub Date : 2022-02-01 Epub Date: 2022-02-16 DOI:10.1007/s12064-022-00363-z

Francisco Kuhar, Leticia Terzzoli, Eduardo Nouhra, Gerardo Robledo, Moritz Mercker

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引用次数: 1

Abstract

Fungi show a high degree of morphological convergence. Regarded for a long time as an obstacle for phylogenetic studies, homoplasy has also been proposed as a source of information about underlying morphogenetic patterning mechanisms. The "local-activation and long-range inhibition principle" (LALIP), underlying the famous reaction-diffusion model proposed by Alan Turing in 1952, appears to be one of the universal phenomena that can explain the ontogenetic origin of seriate patterns in living organisms. Reproductive structures of fungi in the class Agaricomycetes show a highly periodic structure resulting in, for example, poroid, odontoid, lamellate or labyrinthic hymenophores. In this paper, we claim that self-organized patterns might underlie the basic ontogenetic processes of these structures. Simulations based on LALIP-driven models and covering a wide range of parameters show an absolute mutual correspondence with the morphospace explored by extant agaricomycetes. This could not only explain geometric particularities but could also account for the limited possibilities displayed by hymenial configurations, thus making homoplasy a direct consequence of the limited morphospace resulting from the proposed patterning dynamics.

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模式形成特征可以解释同质性:高等真菌的可育表面就是一个例子。

真菌表现出高度的形态趋同。长期以来，同型性一直被认为是系统发育研究的障碍，但它也被认为是潜在形态发生模式机制的信息来源。“局部激活和远程抑制原理”(LALIP)是艾伦·图灵在1952年提出的著名的反应扩散模型的基础，似乎是可以解释生物体中序列模式的个体发生起源的普遍现象之一。菌丝菌类真菌的生殖结构具有高度的周期性结构，如孔状、齿状、层状或迷路膜孔。在本文中，我们声称自组织模式可能是这些结构的基本个体发生过程的基础。基于lalip驱动模型的模拟，涵盖了广泛的参数，显示了与现存菌丝体探索的形态空间的绝对相互对应。这不仅可以解释几何特性，还可以解释膜结构所显示的有限可能性，从而使同质性成为由提出的模式动力学所产生的有限形态空间的直接结果。

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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来源期刊

Theory in Biosciences 生物-生物学

CiteScore

2.70

自引率

9.10%

发文量

审稿时长

3 months

期刊介绍： Theory in Biosciences focuses on new concepts in theoretical biology. It also includes analytical and modelling approaches as well as philosophical and historical issues. Central topics are: Artificial Life; Bioinformatics with a focus on novel methods, phenomena, and interpretations; Bioinspired Modeling; Complexity, Robustness, and Resilience; Embodied Cognition; Evolutionary Biology; Evo-Devo; Game Theoretic Modeling; Genetics; History of Biology; Language Evolution; Mathematical Biology; Origin of Life; Philosophy of Biology; Population Biology; Systems Biology; Theoretical Ecology; Theoretical Molecular Biology; Theoretical Neuroscience & Cognition.