Acoustically triggered mechanotherapy using genetically encoded gas vesicles

Acoustically triggered mechanotherapy using genetically encoded gas vesicles

Recent advances in molecular engineering and synthetic biology provide biomolecular and cell-based therapies with a high degree of molecular specificity, but limited spatiotemporal control. Here we show that biomolecules and cells can be engineered to deliver potent mechanical effects at specific lo...

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Bibliographic Details
Published in:Nature nanotechnology Vol. 16; no. 12; pp. 1403 - 1412
Main Authors: Bar-Zion, Avinoam, Nourmahnad, Atousa, Mittelstein, David R., Shivaei, Shirin, Yoo, Sangjin, Buss, Marjorie T., Hurt, Robert C., Malounda, Dina, Abedi, Mohamad H., Lee-Gosselin, Audrey, Swift, Margaret B., Maresca, David, Shapiro, Mikhail G.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-12-2021
Nature Publishing Group
Subjects:
631/61/350/2093
631/61/54/152
639/166/985
639/925/352/2733
Acoustics
Actuation
Animals
Archaea
Bacteria
Biomechanical Phenomena
Biomolecules
Cavitation
Cell Line, Tumor
Chemical compounds
Chemistry and Materials Science
Damage
Female
Gases - chemistry
Genetic code
Genetic engineering
Genetic modification
Genetic Techniques
Humans
Immunotherapy
Mammalian cells
Materials Science
Mice
Mice, Inbred BALB C
Microbubbles
Nanostructure
Nanotechnology
Nanotechnology and Microengineering
Optical Imaging
Payloads
Pharmacology
Probiotics
Probiotics - pharmacology
Proteins
Receptors, Cell Surface - metabolism
Tumors
Ultrasonic imaging
Ultrasonography
Ultrasound
Vesicles
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Description
Summary:Recent advances in molecular engineering and synthetic biology provide biomolecular and cell-based therapies with a high degree of molecular specificity, but limited spatiotemporal control. Here we show that biomolecules and cells can be engineered to deliver potent mechanical effects at specific locations inside the body through ultrasound-induced inertial cavitation. This capability is enabled by gas vesicles, a unique class of genetically encodable air-filled protein nanostructures. We show that low-frequency ultrasound can convert these biomolecules into micrometre-scale cavitating bubbles, unleashing strong local mechanical effects. This enables engineered gas vesicles to serve as remotely actuated cell-killing and tissue-disrupting agents, and allows genetically engineered cells to lyse, release molecular payloads and produce local mechanical damage on command. We demonstrate the capabilities of biomolecular inertial cavitation in vitro, in cellulo and in vivo, including in a mouse model of tumour-homing probiotic therapy. Gas vesicles are air-filled protein nanostructures naturally expressed by certain bacteria and archaea to achieve cellular buoyancy. Here the authors show that, under the stimulation of pulsed ultrasound, targeted gas vesicles and gas vesicles expressed in genetically modified bacteria and mammalian cells release nanobubbles that, collapsing, lead to controlled mechanical damage of the surrounding biological milieu, demonstrating that, under focused ultrasound actuation, gas vesicles have potential applications as therapeutic agents.
ISSN:1748-3387
1748-3395
DOI:10.1038/s41565-021-00971-8