Active liquid crystals powered by force-sensing DNA-motor clusters

Tayar, Alexandra M.; Hagan, Michael F.; Dogic, Zvonimir

doi:10.1073/pnas.2102873118

Cited by 19 publications

(16 citation statements)

References 64 publications

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“…Indeed, experiments suggested that kinesin-1 motors in active nematics are under a significant loads that are directed along the direction of MT alignment. 59…”

Section: Discussionmentioning

confidence: 99%

“…Importantly, K560-SNAP like K401 and to lesser extend K365 can spontaneously oligomerize and thus could power the active fluid even in the absence of any BG-labeled MTs. 53 This non-specific activity was eliminated using the dissociation buffer and the centrifugation steps in this protocol which removes the K560-SNAP that are not attached to the BG-MT via SNAP-BG reaction.…”

Section: Methodsmentioning

confidence: 99%

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Engineering stability, longevity, and miscibility of microtubule-based active fluids

et al. 2022

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“…Indeed, experiments suggested that kinesin-1 motors in active nematics are under a significant loads that are directed along the direction of MT alignment. 59…”

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Engineering stability, longevity, and miscibility of microtubule-based active fluids

et al. 2022

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“…self-propelled particles) can expend energy and perform actions on microscopic scales. Such systems are potentially capable of learning either by combining synthetic active matter with DNA-based elements (67) and through rearrangement of nematic or polar filaments as in natural systems such as the cytoskeleton (68,69). Related ideas have been explored through simulations (70,71,72), though truly autonomous learning has yet to be demonstrated on the molecular scale.…”

Section: Molecular Systems and Active Mattermentioning

confidence: 99%

Learning without neurons in physical systems

Stern¹,

Murugan²

2022

Preprint

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Learning is traditionally studied in biological or computational systems. The power of learning frameworks in solving hard inverse-problems provides an appealing case for the development of 'physical learning' in which physical systems adopt desirable properties on their own without computational design. It was recently realized that large classes of physical systems can physically learn through local learning rules, autonomously adapting their parameters in response to observed examples of use. We review recent work in the emerging field of physical learning, describing theoretical and experimental advances in areas ranging from molecular self-assembly to flow networks and mechanical materials. Physical learning machines provide multiple practical advantages over computer designed ones, in particular by not requiring an accurate model of the system, and their ability to autonomously adapt to changing needs over time. As theoretical constructs, physical learning machines afford a novel perspective on how physical constraints modify abstract learning theory.

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“…25−29 Whereas the former have the advantage of greater programmability, they lack the self-organization properties of cytoskeletal active gels. 30−33 Despite progress in using DNA to tune the rheology of active gels 29,34 or to trigger its activity on the microscale, 25,26,35 we lack methods to control the spatiotemporal self-organization of cytoskeletal active gels on the macroscale, as we demonstrate in the following.…”

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confidence: 99%

“…A promising route relies on DNA hybridization reactions triggering forces that change the shape of hydrogels. Indeed, DNA reactions can be exquisitely controlled − and coupled to a great variety of materials. − The mechanical amplification of a DNA signal can be performed by either DNA reactions, such as in DNA-responsive hydrogels, , or motor proteins, such as in DNA-based cytoskeletal active gels. − Whereas the former have the advantage of greater programmability, they lack the self-organization properties of cytoskeletal active gels. − Despite progress in using DNA to tune the rheology of active gels , or to trigger its activity on the microscale, ,, we lack methods to control the spatiotemporal self-organization of cytoskeletal active gels on the macroscale, as we demonstrate in the following.…”

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confidence: 99%

DNA-Controlled Spatiotemporal Patterning of a Cytoskeletal Active Gel

2021

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Living cells move and change their shape because signaling chemical reactions modify the state of their cytoskeleton, an active gel that converts chemical energy into mechanical forces. To create life-like materials, it is thus key to engineer chemical pathways that drive active gels. Here we describe the preparation of DNA-responsive surfaces that control the activity of a cytoskeletal active gel composed of microtubules: A DNA signal triggers the release of molecular motors from the surface into the gel bulk, generating forces that structure the gel. Depending on the DNA sequence and concentration, the gel forms a periodic band pattern or contracts globally. Finally, we show that the structuration of the active gel can be spatially controlled in the presence of a gradient of DNA concentration. We anticipate that such DNA-controlled active matter will contribute to the development of life-like materials with self-shaping properties.

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Active liquid crystals powered by force-sensing DNA-motor clusters

Cited by 19 publications

References 64 publications

Engineering stability, longevity, and miscibility of microtubule-based active fluids

Engineering stability, longevity, and miscibility of microtubule-based active fluids

Learning without neurons in physical systems

DNA-Controlled Spatiotemporal Patterning of a Cytoskeletal Active Gel

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