Spatio-temporal correlations can drastically change the response of a MAPK pathway

Takahashi, Koichi; Tănase‐Nicola, Sorin; Wolde, Pieter Rein ten

doi:10.1073/pnas.0906885107

Cited by 254 publications

(413 citation statements)

References 46 publications

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“…In contrast, in crowded conditions when diffusion is slower it is more probable that the first kinase molecule will remains bound or close to its substrate while regaining activity by binding ATP and will then phosphorylate the second site, a processive mode ( Figure 6A) [72]. This prediction has been confirmed experimentally using purified kinases and a crowding agent in vitro [73] (Figure 6B). Thus responses of pathways of this type appear to be distributive in in vitro experiments, but in conditions in vivo are actually processive with different downstream responses to signals [74].…”

Section: Diffusion and Signalingsupporting

confidence: 60%

Structures and functions in the crowded nucleus: new biophysical insights

Hancock

2014

Front. Phys.

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Concepts and methods from the physical sciences have catalyzed remarkable progress in understanding the cell nucleus in recent years. To share this excitement with physicists and encourage their interest in this field, this review offers an overview of how the physics which underlies structures and functions in the nucleus is becoming more clear thanks to methods which have been developed to simulate and study macromolecules, polymers, and colloids. The environment in the nucleus is very crowded with macromolecules, making entropic (depletion) forces major determinants of interactions. Simulation and experiments are consistent with their key role in forming membraneless compartments such as nucleoli, PML and Cajal bodies, and discrete "territories" for chromosomes. The chromosomes, giant linear polyelectrolyte polymers, exist in vivo in a state like a polymer melt. Looped conformations are predicted in crowded conditions, and have been confirmed experimentally and are central to the regulation of gene expression. Polymer theory has revealed how the chromosomes are so highly compacted in the nucleus, forming a "crumpled globule" with fractal properties which avoids knots and entanglements in DNA while allowing facile accessibility for its replication and transcription. Entropic repulsion between looped polymers can explain the confinement of each chromosome to a discrete region of the nucleus. Crowding and looping are predicted to facilitate finding the specific targets of factors which modulate activities of DNA. Simulation shows that entropic effects contribute to finding and repairing potentially lethal double-strand breaks in DNA by increasing the mobility of the broken ends, favoring their juxtaposition for repair. Signaling pathways are strongly influenced by crowding, which favors a processive mode of response (consecutive reactions without releasing substrates). This new information contributes to understanding the sometimes counter-intuitive consequences and the evolutionary advantages of a crowded environment in the nucleus.

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Section: Diffusion and Signalingsupporting

confidence: 60%

Structures and functions in the crowded nucleus: new biophysical insights

Hancock

2014

Front. Phys.

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“…This means that upon unbinding, proteins that are confined to membranes can have a high probability of rebinding (instead of diffusing apart) and this process is predicted to be rapid (occurring within submilliseconds). Given that rebinding has been theoretically predicted 80 and experimentally observed 81 for cytosolic proteins, it is expected to be even more pronounced when both proteins are confined to membranes.…”

Section: Rebinding May Influence 2d Dissociation Timesmentioning

confidence: 99%

Phenotypic models of T cell activation

et al. 2014

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“…The simulations were performed using Green's Function Reaction Dynamics, which is an exact algorithm to simulate reaction-diffusion systems at the particle level in time and space, and hence does not rely on the approximation used to derive the analytical result of Kaizu et al [75,82,83]. Figure 1 shows the results for the zero-frequency limit of the power spectrum, P n (ω → 0) = 2σ 2 n τ c , which provides a test for the receptor correlation time τ c and hence the sensing error (see Eqs.…”

Section: The Expression Of Kaizu and Coworkersmentioning

confidence: 99%

Fundamental Limits to Cellular Sensing

et al. 2016

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In recent years experiments have demonstrated that living cells can measure low chemical concentrations with high precision, and much progress has been made in understanding what sets the fundamental limit to the precision of chemical sensing. Chemical concentration measurements start with the binding of ligand molecules to receptor proteins, which is an inherently noisy process, especially at low concentrations. The signaling networks that transmit the information on the ligand concentration from the receptors into the cell have to filter this receptor input noise as much as possible. These networks, however, are also intrinsically stochastic in nature, which means that they will also add noise to the transmitted signal. In this review, we will first discuss how the diffusive transport and binding of ligand to the receptor sets the receptor correlation time, which is the timescale over which fluctuations in the state of the receptor, arising from the stochastic receptor-ligand binding, decay. We then describe how downstream signaling pathways integrate these receptor-state fluctuations, and how the number of receptors, the receptor correlation time, and the effective integration time set by the downstream network, together impose a fundamental limit on the precision of sensing. We then discuss how cells can remove the receptor input noise while simultaneously suppressing the intrinsic noise in the signaling network. We describe why this mechanism of time integration requires three classes (groups) of resources-receptors and their integration time, readout molecules, energy-and how each resource class sets a fundamental sensing limit. We also briefly discuss the scheme of maximum-likelihood estimation, the role of receptor cooperativity, and how cellular copy protocols differ from canonical copy protocols typically considered in the computational literature, explaining why cellular sensing systems can never reach the Landauer limit on the optimal trade-off between accuracy and energetic cost.B Pieter Rein ten Wolde tenwolde@amolf.nl

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Spatio-temporal correlations can drastically change the response of a MAPK pathway

Cited by 254 publications

References 46 publications

Structures and functions in the crowded nucleus: new biophysical insights

Structures and functions in the crowded nucleus: new biophysical insights

Phenotypic models of T cell activation

Fundamental Limits to Cellular Sensing

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