Emergent memory in cell signaling: Persistent adaptive dynamics in cascades can arise from the diversity of relaxation time-scales

Mitra, Tanmay; Menon, Shakti N.; Sinha, Sitabhra

doi:10.1101/247684

Cited by 3 publications

(3 citation statements)

References 45 publications

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“…Because cells under normal physiological conditions signal in the context of multiple signaling inputs, we hypothesized that treatment of cells with a different growth factor would generate a short-term memory (19) that modified subsequent CXCL12-CXCR4 signaling. To test this hypothesis, we conditioned cells for 4 hours with fetal bovine serum (FBS) before adding CXCL12.…”

Section: Resultsmentioning

confidence: 99%

Short-term cellular memory tunes the signaling responses of the chemokine receptor CXCR4

et al. 2019

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The chemokine receptor CXCR4 regulates fundamental processes in development, normal physiology, and diseases, including cancer. Small subpopulations of CXCR4-positive cells drive the local invasion and dissemination of malignant cells during metastasis, emphasizing the need to understand the mechanisms controlling responses at the single-cell level to receptor activation by the chemokine ligand CXCL12. Using single-cell imaging, we discovered that short-term cellular memory of changes in environmental conditions tuned CXCR4 signaling to Akt and ERK, two kinases activated by this receptor. Conditioning cells with growth stimuli before CXCL12 exposure increased the number of cells that initiated CXCR4 signaling and the amplitude of Akt and ERK activation. Data-driven, single-cell computational modeling revealed that growth factor conditioning modulated CXCR4-dependent activation of Akt and ERK by decreasing extrinsic noise (preexisting cell-to-cell differences in kinase activity) in PI3K and mTORC1. Modeling established mTORC1 as critical for tuning single-cell responses to CXCL12-CXCR4 signaling. Our single-cell model predicted how combinations of extrinsic noise in PI3K, Ras, and mTORC1 superimposed on different driver mutations in the ERK and/or Akt pathways to bias CXCR4 signaling. Computational experiments correctly predicted that selected kinase inhibitors used for cancer therapy shifted subsets of cells to states that were more permissive to CXCR4 activation, suggesting that such drugs may inadvertently potentiate pro-metastatic CXCR4 signaling. Our work establishes how changing environmental inputs modulate CXCR4 signaling in single cells and provides a framework to optimize the development and use of drugs targeting this signaling pathway.

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Section: Resultsmentioning

confidence: 99%

Short-term cellular memory tunes the signaling responses of the chemokine receptor CXCR4

et al. 2019

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“…Different relaxation rates of cascade components lead to 'post-activation bursts' keeping the cascade in an 'activation-competent' state. This can form a system-level memory of the first activation making later responses faster and more robust [23]. Such a short-term molecular memory was demonstrated in the yeast osmotic stress response, too.…”

Section: System-level Memory Of Signaling Cascades and Protein-protei...mentioning

confidence: 91%

Learning of Signaling Networks: Molecular Mechanisms

Csermely

Kunsic

Mendik

et al. 2020

Trends in Biochemical Sciences

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Molecular processes of neuronal learning have been well-described. However, learning mechanisms of non-neuronal cells have not been fully understood at the molecular level. Here, we discuss molecular mechanisms of cellular learning, including conformational memory of intrinsically disordered proteins and prions, signaling cascades, protein translocation, RNAs (microRNA and lncRNA), and chromatin memory. We hypothesize that these processes constitute the learning of signaling networks and correspond to a generalized Hebbian learning process of single, non-neuronal cells, and discuss how cellular learning may open novel directions in drug design and inspire new artificial intelligence methods. Highlights--Besides the well-known learning processes of neurons, non-neuronal single cells are able to learn and show a more robust (and often faster) adaptive response when the same stimulus is repeated.--Known examples of cellular learning are sensitization-or habituation-type responses.--Several molecular mechanisms of neuronal learning, such as conformational memory, protein translocation, signaling cascades, microRNAs, lncRNAs and chromatin memory, also participate in learning of non-neuronal, single cells.--We propose that these molecular mechanisms form the integrative memory of signaling networks and display a generalized Hebbian learning process by increasing those edge weights through which the signal has been propagated. Learning of non-neural cells: Adaptive Molecular Responses Observed when the same Stimulus is RepeatedMolecular mechanisms of neuronal learning have been well-established in the past decades [1]. However, we know relatively little about the molecular details of learning mechanisms of non-neuronal cells. We define cellular learning as an adaptive response to a simple stimulus observed when the same stimulus is repeated in a short time -as compared to the duration of the cell cycle of the given cell. We note that it is crucial to discriminate between molecular changes which are indeed adaptive, and those which are fortuitous by-products of other, co-* Correspondence: csermely.peter@med.semmelweis-univ.hu (P. Csermely)

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“…Several mechanistic models have been put forward to explain the relationship between mechanics and cell differentiation (5,(26)(27)(28), but these models do not simultaneously capture 1) the timescale disparity between mechanical signaling / cell adaptation and memory development and 2) the continuous range of memory outcomes. More generally, regulatory gene network models with different topologies can give rise to memory using network motifs such as positive and negative reinforcement (29)(30)(31)(32)(33)(34). However, explicit molecular network models for mechanotransduction are difficult to develop because there is not enough data available to determine the many model parameters or assert which components of the regulatory network are rate-limiting.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Self-Reinforcement of Gene Expression Determines Acquisition and Retention of Cellular Mechanical Memory

Price

Mathur

et al. 2021

Preprint

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Mechanotransduction describes activation of gene expression by changes in the cell's physical microenvironment. Recent experiments show that mechanotransduction can lead to long-term "mechanical memory", where cells cultured on stiff substrates for sufficient time (priming phase) maintain altered phenotype after switching to soft substrates (dissipation phase), as compared to unprimed controls. The timescale of memory acquisition and retention is orders of magnitude larger than the timescale of mechanosensitive cellular signaling, and memory retention time changes continuously with priming time. We develop a model that captures these features by accounting for positive reinforcement in mechanical signaling. The sensitivity of reinforcement represents the dynamic transcriptional state of the cell composed of protein lifetimes and 3D chromatin organization. Our model provides a single framework connecting microenvironment mechanical history to cellular outcomes ranging from no memory to terminal differentiation. Predicting cellular memory of environmental changes can help engineer cellular dynamics through changes in culture environments.

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Emergent memory in cell signaling: Persistent adaptive dynamics in cascades can arise from the diversity of relaxation time-scales

Cited by 3 publications

References 45 publications

Short-term cellular memory tunes the signaling responses of the chemokine receptor CXCR4

Short-term cellular memory tunes the signaling responses of the chemokine receptor CXCR4

Learning of Signaling Networks: Molecular Mechanisms

Dynamic Self-Reinforcement of Gene Expression Determines Acquisition and Retention of Cellular Mechanical Memory

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