Litcius/Paper detail

Leading edge maintenance in migrating cells is an emergent property of branched actin network growth

Rikki M Garner, Julie A Theriot

2022eLife27 citationsDOIOpen Access PDF

Abstract

Animal cell migration is predominantly driven by the coordinated, yet stochastic, polymerization of thousands of nanometer-scale actin filaments across micron-scale cell leading edges. It remains unclear how such inherently noisy processes generate robust cellular behavior. We employed high-speed imaging of migrating neutrophil-like HL-60 cells to explore the fine-scale shape fluctuations that emerge and relax throughout the process of leading edge maintenance. We then developed a minimal stochastic model of the leading edge that reproduces this stable relaxation behavior. Remarkably, we find lamellipodial stability naturally emerges from the interplay between branched actin network growth and leading edge shape – with no additional feedback required – based on a synergy between membrane-proximal branching and lateral spreading of filaments. These results thus demonstrate a novel biological noise-suppression mechanism based entirely on system geometry. Furthermore, our model suggests that the Arp2/3-mediated ~70–80° branching angle optimally smooths lamellipodial shape, addressing its long-mysterious conservation from protists to mammals.

Topics & Concepts

PseudopodiaActinLeading edgeLamellipodiumCell migrationBranching (polymer chemistry)Enhanced Data Rates for GSM EvolutionProcess (computing)Cell biologyBiological systemBiophysicsBiologyComputer scienceLive cell imagingChemistryProperty (philosophy)PolymerizationRelaxation (psychology)Network modelCellStability (learning theory)PhysicsCellular Mechanics and InteractionsLipid Membrane Structure and BehaviorCell Adhesion Molecules Research