Ensembles, dynamics, and cell types: Revisiting the statistical mechanics perspective on cellular regulation

Bornholdt, Stefan; Kauffman, Stuart

doi:10.1016/j.jtbi.2019.01.036

Cited by 35 publications

(35 citation statements)

References 62 publications

(70 reference statements)

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“…Several features of developmental gene regulation resist modeling by conventional mathematical frameworks: lack of stoichiometry and mass action, and changeability of network topology, for example (reviewed in Newman, ). This prevents drawing any inferences about the global properties of the regulatory genome of an organism, for example, identifying its attractors with the organism's full array of cell types as has been proposed (Bornholdt & Kauffman, ; Kaneko & Yomo, ; Kauffman, ). Nevertheless, the bi‐ or tristability properties of Boolean or ordinary differential equation (ODE) networks with small numbers of experimentally relevant variables can serve as good heuristics for studying transitions between cell types that are adjacent to one another in a developmental lineage.…”

Section: Discussionmentioning

confidence: 99%

Multiscale modeling of vertebrate limb development

Glimm

Bhat

Newman

2020

WIREs Mechanisms of Disease

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We review the current state of mathematical modeling of cartilage pattern formation in vertebrate limbs. We place emphasis on several reaction–diffusion type models that have been proposed in the last few years. These models are grounded in more detailed knowledge of the relevant regulatory processes than previous ones but generally refer to different molecular aspects of these processes. Considering these models in light of comparative phylogenomics permits framing of hypotheses on the evolutionary order of appearance of the respective mechanisms and their roles in the fin‐to‐limb transition. This article is categorized under: Analytical and Computational Methods > Computational Methods Models of Systems Properties and Processes > Mechanistic Models Developmental Biology > Developmental Processes in Health and Disease Analytical and Computational Methods > Analytical Methods

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Section: Discussionmentioning

confidence: 99%

Multiscale modeling of vertebrate limb development

Glimm

Bhat

Newman

2020

WIREs Mechanisms of Disease

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“…Contemporary systems biology aims to understand the rules governing dynamic regulatory networks across different scales (genes, RNA, proteins, cells, systems, metasystems, organism). Self-organization underlies a generic property of many complex networks and of gene regulatory networks in particular, which control cell ontogeny ( 16 , 17 ).…”

Section: A Journey From Consciousness To Cell Biologymentioning

confidence: 99%

Self and the Brain. The Immune Metaphor

Sánchez-Ramón

Faure

2020

Front. Psychiatry

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One of the fundamental questions in neuroscience is how brain activity relates to conscious experience. Even though self-consciousness is considered an emergent property of the brain network, a quantum physics-based theory assigns a momentum of consciousness to the single neuron level. In this work, we present a brain self theory from an evolutionary biological perspective by analogy with the immune self . In this scheme, perinatal reactivity to self inputs would guide the selection of neocortical neurons within the subplate, similarly to T lymphocytes in the thymus. Such self-driven neuronal selection would enable effective discrimination of external inputs and avoid harmful “autoreactive” responses. Multiple experimental and clinical evidences for this model are provided. Based on this self tenet, we outline the postulates of the so-called autophrenic diseases, to then make the case for schizophrenia, an archetypic disease with rupture of the self. Implications of this model are discussed, along with potential experimental verification.

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“…Single-cell analyses revealed complex dynamics of gene regulation in differentiating cells (Spiller et al, 2010;Junker and van Oudenaarden, 2014;Paul et al, 2015;Marr et al, 2016;Plass et al, 2018). It is believed that dynamic effects possibly superimposed by stochastic fluctuations in gene expression levels may play crucial roles in cell fate choice, commitment, and reprogramming (Graf and Enver, 2009;Huang et al, 2009;Zhou and Huang, 2011;FerrellJr., 2012;Il Joo et al, 2018;Bornholdt and Kauffman, 2019). Changes in gene expression over time have not been directly measured in single mammalian cells as cells are -for technical reasons -sacrificed during the analysis procedure and hence can be measured only once.…”

Section: Introductionmentioning

confidence: 99%

Regulatory Dynamics of Cell Differentiation Revealed by True Time Series From Multinucleate Single Cells

et al. 2021

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Dynamics of cell fate decisions are commonly investigated by inferring temporal sequences of gene expression states by assembling snapshots of individual cells where each cell is measured once. Ordering cells according to minimal differences in expression patterns and assuming that differentiation occurs by a sequence of irreversible steps, yields unidirectional, eventually branching Markov chains with a single source node. In an alternative approach, we used multi-nucleate cells to follow gene expression taking true time series. Assembling state machines, each made from single-cell trajectories, gives a network of highly structured Markov chains of states with different source and sink nodes including cycles, revealing essential information on the dynamics of regulatory events. We argue that the obtained networks depict aspects of the Waddington landscape of cell differentiation and characterize them as reachability graphs that provide the basis for the reconstruction of the underlying gene regulatory network.

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Ensembles, dynamics, and cell types: Revisiting the statistical mechanics perspective on cellular regulation

Cited by 35 publications

References 62 publications

Multiscale modeling of vertebrate limb development

Multiscale modeling of vertebrate limb development

Self and the Brain. The Immune Metaphor

Regulatory Dynamics of Cell Differentiation Revealed by True Time Series From Multinucleate Single Cells

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