The buckling-condensation mechanism driving gas vesicle collapse

The buckling-condensation mechanism driving gas vesicle collapse

Gas vesicles (GVs) are proteinaceous cylindrical shells found within bacteria or archea growing in aqueous environments and are composed primarily of two proteins, gas vesicle protein A and C (GvpA and GvpC). GVs exhibit strong performance as next-generation ultrasound contrast agents due to their g...

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Veröffentlicht in:Soft matter 2023-02, Vol.19 (6), p.1174-1185
Hauptverfasser: Zhao, Tom Y, Dunbar, Martha, Keten, Sinan, Patankar, Neelesh A
Format: Artikel
Sprache:eng
Schlagworte:
Aqueous environments
Buckling
Collapse
Contrast agents
Contrast media
Cylindrical shells
Elastic buckling
Hydrophobicity
Hydrostatic pressure
In vivo methods and tests
Membranes
Modulus of elasticity
Molecular dynamics
Nonlinear response
Plastic buckling
Pressure
Protein A
Proteins
Stability
Stress-strain curves
Structural models
Wettability
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container_end_page 1185
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container_title Soft matter
container_volume 19
creator Zhao, Tom Y
Dunbar, Martha
Keten, Sinan
Patankar, Neelesh A
description Gas vesicles (GVs) are proteinaceous cylindrical shells found within bacteria or archea growing in aqueous environments and are composed primarily of two proteins, gas vesicle protein A and C (GvpA and GvpC). GVs exhibit strong performance as next-generation ultrasound contrast agents due to their gas-filled interior, tunable collapse pressure, stability in vivo and functionalizable exterior. However, the exact mechanism leading to GV collapse remains inconclusive, which leads to difficulty in predicting collapse pressures for different species of GVs and in extending favorable nonlinear response regimes. Here, we propose a two stage mechanism leading to GV loss of echogenicity and rupture under hydrostatic pressure: elastic buckling of the cylindrical shell coupled with condensation driven weakening of the GV membrane. Our goal is to therefore test whether the final fracture of the GV membrane occurs by the interplay of both mechanisms or purely through buckling failure as previously believed. To do so, we (1) compare the theoretical condensation and buckling pressures with that for experimental GV collapse and (2) describe how condensation can lead to plastic buckling failure. GV shell properties that are necessary input to this theoretical description, such as the elastic moduli and wettability of GvpA, are determined using molecular dynamics simulations of a novel structural model of GvpA that better represents the hydrophobic core. For GVs that are not reinforced by GvpC, this analytical framework shows that the experimentally observed pressures resulting in loss of echogenicity coincide with both the elastic buckling and condensation pressure regimes. We also found that the stress strain curve for GvpA wetted on both the interior and exterior exhibits a loss of mechanical stability compared to GvpA only wetted on the exterior by the bulk solution. We identify a pressure vs. vesicle size regime where condensation can occur prior to buckling, which may preclude nonlinear shell buckling responses in contrast imaging. Gas vesicles (GVs) are protein shells that perform superbly as ultrasound contrast agents due to their tunable collapse pressure. Here, the roles of condensation and shell buckling in triggering and controlling final GV collapse are examined.
doi_str_mv 10.1039/d2sm00493c
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GVs exhibit strong performance as next-generation ultrasound contrast agents due to their gas-filled interior, tunable collapse pressure, stability in vivo and functionalizable exterior. However, the exact mechanism leading to GV collapse remains inconclusive, which leads to difficulty in predicting collapse pressures for different species of GVs and in extending favorable nonlinear response regimes. Here, we propose a two stage mechanism leading to GV loss of echogenicity and rupture under hydrostatic pressure: elastic buckling of the cylindrical shell coupled with condensation driven weakening of the GV membrane. Our goal is to therefore test whether the final fracture of the GV membrane occurs by the interplay of both mechanisms or purely through buckling failure as previously believed. To do so, we (1) compare the theoretical condensation and buckling pressures with that for experimental GV collapse and (2) describe how condensation can lead to plastic buckling failure. GV shell properties that are necessary input to this theoretical description, such as the elastic moduli and wettability of GvpA, are determined using molecular dynamics simulations of a novel structural model of GvpA that better represents the hydrophobic core. For GVs that are not reinforced by GvpC, this analytical framework shows that the experimentally observed pressures resulting in loss of echogenicity coincide with both the elastic buckling and condensation pressure regimes. We also found that the stress strain curve for GvpA wetted on both the interior and exterior exhibits a loss of mechanical stability compared to GvpA only wetted on the exterior by the bulk solution. We identify a pressure vs. vesicle size regime where condensation can occur prior to buckling, which may preclude nonlinear shell buckling responses in contrast imaging. Gas vesicles (GVs) are protein shells that perform superbly as ultrasound contrast agents due to their tunable collapse pressure. 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source Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects Aqueous environments
Buckling
Collapse
Contrast agents
Contrast media
Cylindrical shells
Elastic buckling
Hydrophobicity
Hydrostatic pressure
In vivo methods and tests
Membranes
Modulus of elasticity
Molecular dynamics
Nonlinear response
Plastic buckling
Pressure
Protein A
Proteins
Stability
Stress-strain curves
Structural models
Wettability
title The buckling-condensation mechanism driving gas vesicle collapse
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