Competing instabilities reveal how to rationally design and control active crosslinked gels

Najma, Bibi; Varghese, Minu; Tsidilkovski, Lev; Lemma, Linnea; Baskaran, Aparna; Duclos, Guillaume

doi:10.1038/s41467-022-34089-9

Cited by 9 publications

(6 citation statements)

References 75 publications

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“…1B ). After an initial instability [9,16,44], the three-dimensional active gel reaches a long-lived out-of-equilibrium steady state, forming a network of extensile microtubule bundles that continuously reconfigure, driving chaotic flows [14] ( Fig. 1D, Video S1 ).…”

Section: Resultsmentioning

confidence: 99%

“…Hence, we first tested if the transition could be due to a stiffening of the network due to an increasing fraction of molecular motors functioning as passive microtubule crosslinkers when ATP is limited. Indeed, kinesin-1 motor clusters are known to have a dual antagonistic role, fluidizing or stiffening the network depending on ATP concentration [9,44,60].…”

Section: Resultsmentioning

confidence: 99%

“…In vivo , these active processes underlie cellular force generation and mechanics [6]. In vitro , they provide a blueprint to build active machines endowed with life-like properties, such as the ability to spontaneously flow [7,8], change shape [9–11], or divide [12,13].…”

Section: Introductionmentioning

confidence: 99%

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Microscopic interactions control a structural transition in active mixtures of microtubules and molecular motors

Najma

Baskaran

Foster

et al. 2023

Preprint

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Microtubules and molecular motors are essential components of the cellular cytoskeleton, driving fundamental processes in vivo, including chromosome segregation and cargo transport. When reconstituted in vitro, these cytoskeletal proteins serve as energy-consuming building blocks to study the self-organization of active matter. Cytoskeletal active gels display rich emergent dynamics, including extensile chaotic flows, locally contractile asters, and bulk contraction. However, it is unclear which protein-scale interactions, if any, set the contractile or extensile nature of the active gel, or how to control the transition from one phase to another in a simple active system. Here, we explore the microscopic origin of the extensile-to-contractile transition in a reconstituted active material composed of stabilized microtubules, depletant, ATP, and clusters of kinesin-1 motors. We show that microscopic interactions between highly processive motor clusters and microtubules can trigger the end-accumulation of motor proteins, which in turn drives polarity sorting and aster formation. Combining experiments and simple scaling arguments, we demonstrate that the extensile-to-contractile transition is akin to a self-assembly process where nematic and polar aligning interactions compete. We identify a single control parameter given by the ratio of the different component concentrations that dictates the material-scale organization into either a contractile aster or an extensile bundle. Overall, this work shows that robust self-organization of cytoskeletal active materials can be controlled by precise biochemical and mechanical tuning at the microscopic level.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Microscopic interactions control a structural transition in active mixtures of microtubules and molecular motors

Najma

Baskaran

Foster

et al. 2023

Preprint

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“…The passive Fréedericksz transition describes the change of an isotropic state to an anisotropic state under the influence of external electric or magnetic fields [10]. In active liquid crystals, the transition is driven by active molecular processes causing spontaneous material flow [11][12][13].Recent works suggest such instabilities to also exist in three-dimensional (3D) active polar fluids [14]. For example, an extensile active fluid was found to exhibit a bending instability in a simplified model [15], and flow-aligning active fluids were found to display coherent motion in 3D channels upon increased activity [16].…”

mentioning

confidence: 99%

“…Recent works suggest such instabilities to also exist in three-dimensional (3D) active polar fluids [14]. For example, an extensile active fluid was found to exhibit a bending instability in a simplified model [15], and flow-aligning active fluids were found to display coherent motion in 3D channels upon increased activity [16].…”

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confidence: 99%

Three Dimensional Spontaneous Flow Transition in Active Polar Fluids

Shrivastava¹,

Vagne²,

Jülicher³

et al. 2023

Preprint

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Active liquid crystals exhibit spontaneous flow when sufficient active stress is generated by internal molecular mechanisms. This is also referred to as active Fréedericksz transition. We show this transition in three dimensions and study its dependence on the boundary conditions. Using nonlinear numerical solutions and linear perturbation analysis, we find an out-of-plane transition under extensile active stress for perpendicular polarity anchoring at the boundary, whereas parallel anchoring permits both in-plane flow under contractile stress and out-of-plane wrinkling under extensile stress.Active fluids are out-of-equilibrium materials driven by energy injection at the microscopic scale [1, 2]. Active materials can have a polar or nematic alignment symmetry of the orientation vector field, and the constituents of the material allow it to generate contractile or extensile active stress. Prominent examples of active fluids are found in living matter across scales, from the cytoskeleton [3, 4] and tissues [5][6][7] to collective behavior in flocks [8]. The hydrodynamic theory of incompressible active polar fluids describes the dynamics of such active liquid crystals at long wavelengths. A key behavior of active polar fluids is their ability to generate spontaneous flow under confinement and sufficient active stress. It has been shown in two dimensions (2D) that spontaneous flow can emerge due to a Fréedericksz-type transition first observed in passive liquid crystals [9]. The passive Fréedericksz transition describes the change of an isotropic state to an anisotropic state under the influence of external electric or magnetic fields [10]. In active liquid crystals, the transition is driven by active molecular processes causing spontaneous material flow [11][12][13].Recent works suggest such instabilities to also exist in three-dimensional (3D) active polar fluids [14]. For example, an extensile active fluid was found to exhibit a bending instability in a simplified model [15], and flow-aligning active fluids were found to display coherent motion in 3D channels upon increased activity [16]. Furthermore, It has been shown that 3D contractile active fluids dampen out-of-plane perturbations, whereas extensile fluids amplify them in the absence of boundary effects [17]. 3D active fluids under confinement behave fundamentally different from their 2D counterparts. Notably, they exhibit flow due to buckling under extensile active stress, which is not possible in 2D for rigid boundaries [18]. Experimentally, this instability has been observed in microtubule assays capable of generating extensile active stresses [18,19].Here, we consider the active Ericksen-Leslie hydrodynamic model and show that the instability exists in 3D. We consider a thick active polar film, which is the 3D extension of a Fréedericksz cell, with anchoring of the polarity and stress-free boundary conditions on the walls. We show how the steady-state spontaneous flow depends on the polarity boundary conditions and the sign of active stress. We derive a...

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