Thermodynamic Paradigm for Solution Demixing Inspired by Nuclear Transport in Living Cells.

Ching-Hao Wang,Pankaj Mehta,Michael Elbaum

doi:10.1103/physrevlett.118.158101

Ching-Hao Wang, Pankaj Mehta + Show 1 more

Open Access

https://doi.org/10.1103/physrevlett.118.158101

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Abstract

Living cells display a remarkable capacity to compartmentalize their functional biochemistry. A particularly fascinating example is the cell nucleus. Exchange of macromolecules between the nucleus and the surrounding cytoplasm does not involve traversing a lipid bilayer membrane. Instead, large protein channels known as nuclear pores cross the nuclear envelope and regulate the passage of other proteins and RNA molecules. Beyond simply gating diffusion, the system of nuclear pores and associated transport receptors is able to generate substantial concentration gradients, at the energetic expense of guanosine triphosphate hydrolysis. In contrast to conventional approaches to demixing such as reverse osmosis and dialysis, the biological system operates continuously, without application of cyclic changes in pressure or solvent exchange. Abstracting the biological paradigm, we examine this transport system as a thermodynamic machine of solution demixing. Building on the construct of free energy transduction and biochemical kinetics, we find conditions for the stable operation and optimization of the concentration gradients as a function of dissipation in the form of entropy production.

Highlights

Living cells display a remarkable capacity to compartmentalize their functional biochemistry
Building on the construct of free energy transduction and biochemical kinetics, we find conditions for the stable operation and optimization of the concentration gradients as a function of dissipation in the form of entropy production
A prominent example of molecular separation is the eukaryotic cell nucleus, wherein the concentrations of many proteins and RNA differ significantly from those in the cell body. These gradients are maintained by a transport system that shuttles molecular cargo in and out via large protein channels known as nuclear pores [6,7]

Summary

Introduction

Living cells display a remarkable capacity to compartmentalize their functional biochemistry. Thermodynamic Paradigm for Solution Demixing Inspired by Nuclear Transport in Living Cells In this context living cells adopt a fundamentally different paradigm by establishing and maintaining concentration gradients at steady state under a fixed set of intrinsic thermodynamic parameters.

Results

Conclusion