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Your search keyword '"Ueda, Yuika"' showing total 11 results
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11 results on '"Ueda, Yuika"'

1. Intracellular order formation through stepwise phase transitions

Author

Ueda, Yuika and Deguchi, Shinji

Subjects
Quantitative Biology - Cell Behavior, Quantitative Biology - Molecular Networks, Quantitative Biology - Subcellular Processes
Abstract

Living cells inherently exhibit the ability to spontaneously reorganize their structures in response to changes in both their internal and external environments. Among these responses, the organization of stress fibers composed of actin molecules changes in direct accordance with the mechanical stiffness of their environments. On soft substrates, SFs are rarely formed, but as stiffness increases, they emerge with random orientation, progressively align, and eventually form thicker bundles as stiffness surpasses successive thresholds. These transformations share similarities with phase transitions studied in condensed matter physics, yet despite extensive research on cellular dynamics, the introduction of the statistical mechanics perspective to the environmental dependence of intracellular structures remains underexplored. With this physical framework, we identify key relationships governing these intracellular transitions, highlighting the delicate balance between energy and entropy. Our analysis provides a unified understanding of the stepwise phase transitions of actin structures, offering new insights into related biological mechanisms. Notably, our study suggests the existence of mechanical checkpoints in the G1 phase of the cell cycle, which sequentially regulate the formation of intracellular structures to ensure proper cell cycle progression.

Published
2024

2. Nonthermal driving forces in cells revealed by nonequilibrium fluctuations

Author

Ueda, Yuika and Deguchi, Shinji

Subjects
Physics - Biological Physics, Quantitative Biology - Cell Behavior
Abstract

The mechanical properties within living cells play a critical role in the adaptive regulation of their biological functions upon environmental and internal stimuli. While these properties exhibit nonequilibrium dynamics due to the thermal and nonthermal forces that universally coexist in actin-myosin-active proliferative cells, quantifying them within such complex systems remains challenging. Here, we develop a nonequilibrium framework that combines fluorescence correlation spectroscopy (FCS) measurements of intracellular diffusion with nonequilibrium theory to quantitatively analyze cell-specific nonthermal driving forces and cellular adaptability. Our results reveal that intracellular particle diffusion is influenced not only by common thermal forces but also by nonthermal forces generated by approximately 10-100 motor proteins. Furthermore, we derive a physical parameter that quantitatively assesses the sensitivity of intracellular particle responses to these nonthermal forces, showing that systems with more active diffusion exhibit higher response sensitivity. Our work highlights the biological fluctuations arising from multiple interacting elements, advancing the understanding of the complex mechanical properties within living cells.

Published
2024

11. Asymmetric response emerges between creation and disintegration of force-bearing subcellular structures as revealed by percolation analysis.

Author

Ueda Y, Matsunaga D, and Deguchi S

Subjects
Computer Simulation, Mechanotransduction, Cellular physiology, Stress, Mechanical, Humans, Animals, Actins metabolism, Actins chemistry, Models, Biological, Actin Cytoskeleton chemistry, Stochastic Processes, Stress Fibers physiology, Stress Fibers metabolism
Abstract

Cells dynamically remodel their internal structures by modulating the arrangement of actin filaments (AFs). In this process, individual AFs exhibit stochastic behavior without knowing the macroscopic higher-order structures they are meant to create or disintegrate, but the mechanism allowing for such stochastic process-driven remodeling of subcellular structures remains incompletely understood. Here we employ percolation theory to explore how AFs interacting only with neighboring ones without recognizing the overall configuration can nonetheless create a substantial structure referred to as stress fibers (SFs) at particular locations. We determined the interaction probabilities of AFs undergoing cellular tensional homeostasis, a fundamental property maintaining intracellular tension. We showed that the duration required for the creation of SFs is shortened by the increased amount of preexisting actin meshwork, while the disintegration occurs independently of the presence of actin meshwork, suggesting that the coexistence of tension-bearing and non-bearing elements allows cells to promptly transition to new states in accordance with transient environmental changes. The origin of this asymmetry between creation and disintegration, consistently observed in actual cells, is elucidated through a minimal model analysis by examining the intrinsic nature of mechano-signal transmission. Specifically, unlike the symmetric case involving biochemical communication, physical communication to sense environmental changes is facilitated via AFs under tension, while other free AFs dissociated from tension-bearing structures exhibit stochastic behavior. Thus, both the numerical and minimal models demonstrate the essence of intracellular percolation, in which macroscopic asymmetry observed at the cellular level emerges not from microscopic asymmetry in the interaction probabilities of individual molecules, but rather only as a consequence of the manner of the mechano-signal transmission. These results provide novel insights into the role of the mutual interplay between distinct subcellular structures with and without tension-bearing capability. Insight: Cells continuously remodel their internal elements or structural proteins in response to environmental changes. Despite the stochastic behavior of individual structural proteins, which lack awareness of the larger subcellular structures they are meant to create or disintegrate, this self-assembly process somehow occurs to enable adaptation to the environment. Here we demonstrated through percolation simulations and minimal model analyses that there is an asymmetry in the response between the creation and disintegration of subcellular structures, which can aid environmental adaptation. This asymmetry inherently arises from the nature of mechano-signal transmission through structural proteins, namely tension-mediated information exchange within cells, despite the stochastic behavior of individual proteins lacking asymmetric characters in themselves., (© The Author(s) 2024. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2024
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