Susanne Rönicke scite author profile

Despite their overwhelming complexity, living cells display a high degree of internal mechanical and functional organization which can largely be attributed to the intracellular biopolymer scaffold, the cytoskeleton. Being a very complex system far from thermodynamic equilibrium, the cytoskeleton's ability to organize is at the same time challenging and fascinating. The extensive amounts of frequently interacting cellular building blocks and their inherent multifunctionality permits highly adaptive behavior and obstructs a purely reductionist approach. Nevertheless (and despite the field's relative novelty), the physics approach has already proved to be extremely successful in revealing very fundamental concepts of cytoskeleton organization and behavior. This review aims at introducing the physics of the cytoskeleton ranging from single biopolymer filaments to multicellular organisms. Throughout this wide range of phenomena, the focus is set on the intertwined nature of the different physical scales (levels of complexity) that give rise to numerous emergent properties by means of self-organization or self-assembly.

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Single cell viability and impact of heating by laser absorption

Wetzel

Rönicke

Müller

et al. 2011

Eur Biophys J

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Optical traps such as tweezers and stretchers are widely used to probe the mechanical properties of cells. Beyond their large range of applications, the use of infrared laser light in optical traps causes significant heating effects in the cell. This study investigated the effect of laser-induced heating on cell viability. Common viability assays are not very sensitive to damages caused in short periods of time or are not practicable for single cell analysis. We used cell spreading, a vital ability of cells, as a new sensitive viability marker. The optical stretcher, a two beam laser trap, was used to simulate heat shocks that cells typically experience during measurements in optical traps. The results show that about 60% of the cells survived heat shocks without vital damage at temperatures of up to 58 ± 2°C for 0.5 s. By varying the duration of the heat shocks, it was shown that 60% of the cells stayed viable when exposed to 48 ± 2°C for 5 s.

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Cells in Slow Motion: Apparent Undercooling Increases Glassy Behavior at Physiological Temperatures

et al. 2021

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Solvent conditions are unexpectedly sufficient to drastically and reversibly slow down cells. In vitro on the molecular level, protein–solvent interactions drastically change in the presence of heavy water (D2O) and its stronger hydrogen bonds. Adding D2O to the cell medium of living cells increases the molecular intracellular viscosity. While cell morphology and phenotype remain unchanged, cellular dynamics transform into slow motion in a changeable manner. This is exemplified in the slowdown of cell proliferation and migration, which is caused by a reversible gelation of the cytoplasm. In analogy to the time–temperature superposition principle, where temperature is replaced by D2O, an increase in viscosity slows down the effective time. Actin networks, crucial structures in the cytoplasm, switch from a power‐law‐like viscoelastic to a more rubber‐like elastic behavior. The resulting intracellular resistance and dissipation impair cell movement. Since cells are highly adaptive non‐equilibrium systems, they usually respond irreversibly from a thermodynamic perspective. D2O induced changes, however, are fully reversible and their effects are independent of signaling as well as expression. The stronger hydrogen bonds lead to glass‐like, drawn‐out intramolecular dynamics, which may facilitate longer storage times of biological matter, for instance, during transport of organ transplants.

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Cells in Slow Motion: Cells in Slow Motion: Apparent Undercooling Increases Glassy Behavior at Physiological Temperatures (Adv. Mater. 29/2021)

et al. 2021

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In article number 2101840, Jörg Schnauß and co‐workers show that heavy water (D2O) reversibly slows down cells, retards cell invasion, and drastically impacts cell mechanics, possibly prolonging storage times for biological materials. The cellular dynamics, which transform into slow motion, can be captured via the time‐temperature superposition principle, where temperature is replaced by D2O. Induced changes are fully reversible and effects are independent of signaling/expression.

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