隐藏在生物细胞自动机下的预测性景观

IF 1.8 4区 生物学 Q3 BIOPHYSICS Journal of Biological Physics Pub Date : 2021-11-05 DOI:10.1007/s10867-021-09592-7
Lars Koopmans, Hyun Youk
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引用次数: 2

摘要

为了庆祝Hans Frauenfelder的成就,我们研究了复杂生命系统的能量(类似)“景观”。能量景观概括了某些物理系统的所有可能的动力学。能量(类)景观可以解释一些生物分子过程,包括基因表达,正如弗劳恩费尔德所展示的,蛋白质折叠。但是,像能量一样的景观和现有的框架,比如统计力学,对于描述许多生命系统似乎是不切实际的。困难源于生命系统是高维的、非线性的,并且由许多紧密耦合的嘈杂成分所控制。主要的建模方法是设计适合每个生命系统的微分方程。这种特别的方法面临着臭名昭著的“参数问题”:模型有许多具有未知参数值的非线性数学函数,甚至仅用于描述几个细胞内过程。人们不能测量许多细胞内参数,或者只能测量它们作为时间快照。另一种建模方法使用元胞自动机将生命系统表示为具有二元变量的离散动力系统。定量(基于哈密顿的)规则可以指示细胞自动机(例如,细胞波茨模型)。但是,在目前的实践中,许多生物学特征是定性描述而不是定量描述(例如,基因(高)表达或不(高)表达)。由语言规则控制的元胞自动机是对生命系统有用的表示,可以缓解参数问题。然而,它们可能产生难以理解的复杂动力学,因为自动机控制规则不是定量的,而且许多现有的数学工具和定理适用于连续而不是离散动力系统。最近的研究找到了克服这一挑战的方法。这些研究要么发现了,要么暗示了一种预测性“景观”的存在,其形状由李雅普诺夫函数描述,并产生了“伪粒子”的“运动方程”。伪粒子代表整个细胞晶格并在景观上移动,从而给出细胞自动机动态的低维表示。我们概述了这个有前途的建模策略。
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Predictive landscapes hidden beneath biological cellular automata

To celebrate Hans Frauenfelder’s achievements, we examine energy(-like) “landscapes” for complex living systems. Energy landscapes summarize all possible dynamics of some physical systems. Energy(-like) landscapes can explain some biomolecular processes, including gene expression and, as Frauenfelder showed, protein folding. But energy-like landscapes and existing frameworks like statistical mechanics seem impractical for describing many living systems. Difficulties stem from living systems being high dimensional, nonlinear, and governed by many, tightly coupled constituents that are noisy. The predominant modeling approach is devising differential equations that are tailored to each living system. This ad hoc approach faces the notorious “parameter problem”: models have numerous nonlinear, mathematical functions with unknown parameter values, even for describing just a few intracellular processes. One cannot measure many intracellular parameters or can only measure them as snapshots in time. Another modeling approach uses cellular automata to represent living systems as discrete dynamical systems with binary variables. Quantitative (Hamiltonian-based) rules can dictate cellular automata (e.g., Cellular Potts Model). But numerous biological features, in current practice, are qualitatively described rather than quantitatively (e.g., gene is (highly) expressed or not (highly) expressed). Cellular automata governed by verbal rules are useful representations for living systems and can mitigate the parameter problem. However, they can yield complex dynamics that are difficult to understand because the automata-governing rules are not quantitative and much of the existing mathematical tools and theorems apply to continuous but not discrete dynamical systems. Recent studies found ways to overcome this challenge. These studies either discovered or suggest an existence of predictive “landscapes” whose shapes are described by Lyapunov functions and yield “equations of motion” for a “pseudo-particle.” The pseudo-particle represents the entire cellular lattice and moves on the landscape, thereby giving a low-dimensional representation of the cellular automata dynamics. We outline this promising modeling strategy.

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来源期刊
Journal of Biological Physics
Journal of Biological Physics 生物-生物物理
CiteScore
3.00
自引率
5.60%
发文量
20
审稿时长
>12 weeks
期刊介绍: Many physicists are turning their attention to domains that were not traditionally part of physics and are applying the sophisticated tools of theoretical, computational and experimental physics to investigate biological processes, systems and materials. The Journal of Biological Physics provides a medium where this growing community of scientists can publish its results and discuss its aims and methods. It welcomes papers which use the tools of physics in an innovative way to study biological problems, as well as research aimed at providing a better understanding of the physical principles underlying biological processes.
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