Your search keyword '"gas vesicles"' showing total 10 results

1. Microbial gas vesicles as nanotechnology tools: exploiting intracellular organelles for translational utility in biotechnology, medicine and the environment.

Author

Hill AM and Salmond GPC

Subjects

Animals, Bacillus megaterium genetics, Biotechnology instrumentation, Environment, Gases metabolism, Halobacterium genetics, Humans, Medicine, Nanotechnology instrumentation, Organelles genetics, Bacillus megaterium metabolism, Biotechnology methods, Halobacterium metabolism, Nanotechnology methods, Organelles metabolism

Abstract

A range of bacteria and archaea produce gas vesicles as a means to facilitate flotation. These gas vesicles have been purified from a number of species and their applications in biotechnology and medicine are reviewed here. Halobacterium sp. NRC-1 gas vesicles have been engineered to display antigens from eukaryotic, bacterial and viral pathogens. The ability of these recombinant nanoparticles to generate an immune response has been quantified both in vitro and in vivo . These gas vesicles, along with those purified from Anabaena flos-aquae and Bacillus megaterium , have been developed as an acoustic reporter system. This system utilizes the ability of gas vesicles to retain gas within a stable, rigid structure to produce contrast upon exposure to ultrasound. The susceptibility of gas vesicles to collapse when exposed to excess pressure has also been proposed as a biocontrol mechanism to disperse cyanobacterial blooms, providing an environmental function for these structures.

Published

2020

2. Cryo-electron microscopy of an extremely halophilic microbe: technical aspects.

Author

Bollschweiler D, Schaffer M, Lawrence CM, and Engelhardt H

Subjects

Sodium Chloride chemistry, Vitrification, Cryoelectron Microscopy methods, Halobacterium ultrastructure

Abstract

Most halophilic Archaea of the class Halobacteriaceae depend on the presence of several molar sodium chloride for growth and cell integrity. This poses problems for structural studies, particularly for electron microscopy, where the high salt concentration results in diminished contrast. Since cryo-electron microscopy of intact cells provides new insights into the cellular and molecular organization under close-to-live conditions, we evaluated strategies and conditions to make halophilic microbes available for investigations in situ. Halobacterium salinarum, the test organism for this study, usually grows at 4.3 M NaCl. Adaptation to lower concentrations and subsequent NaCl reduction via dialysis led to still vital cells at 3 M salt. A comprehensive evaluation of vitrification parameters, thinning of frozen cells by focused-ion-beam micromachining, and cryo-electron microscopy revealed that structural studies under high salt conditions are possible in situ.

Published

2017

3. Biosynthetic Gas Vesicles from Halobacteria NRC-1 : A Potential Ultrasound Contrast Agent for Tumor Imaging.

Author

Wei, Mingjie, Lai, Manlin, Zhang, Jiaqi, Pei, Xiaoqing, and Yan, Fei

Subjects

*ULTRASOUND contrast media, *MICROBUBBLE diagnosis, *HALOBACTERIUM, *DIAGNOSTIC ultrasonic imaging, *CONTRAST-enhanced ultrasound, *DIAGNOSTIC equipment

Abstract

Ultrasound contrast agents are valuable for diagnostic imaging and drug delivery. Generally, chemically synthesized microbubbles (MBs) are micro-sized particles. Particle size is a limiting factor for the diagnosis and treatment of many extravascular diseases. Recently, gas vesicles (GVs) from some marine bacteria and archaea have been reported as novel nanoscale contrast agents, showing great potential for biomedical applications. However, most of the GVs reported in the literature show poor contrast imaging capabilities due to their small size, especially for the in vivo condition. In this study, we isolated the rugby-ball-shaped GVs from Halobacteria NRC-1 and characterized their contrast imaging properties in vitro and in vivo. Our results showed that GVs could produce stable and strong ultrasound contrast signals in murine liver tumors using clinical diagnostic ultrasound equipment at the optimized parameters. Interestingly, we found these GVs, after systemic administration, were able to perfuse the ischemic region of a tumor where conventional lipid MBs failed, producing a 6.84-fold stronger contrast signal intensity than MBs. Immunohistochemistry staining assays revealed that the nanoscale GVs, in contrast to the microscale MBs, could penetrate through blood vessels. Thus, our study proved these biosynthesized GVs from Halobacterium NRC-1 are useful for future molecular imaging and image-guided drug delivery. [ABSTRACT FROM AUTHOR]

Published

2022

4. The Function of Gas Vesicles in Halophilic Archaea and Bacteria: Theories and Experimental Evidence

Author

Aharon Oren

Subjects

gas vesicles, Halobacterium, Haloferax, Haloquadratum, Haloplanus, Halogeometricum, bacteriorhodopsin, oxygen, Science

Abstract

A few extremely halophilic Archaea (Halobacterium salinarum, Haloquadratum walsbyi, Haloferax mediterranei, Halorubrum vacuolatum, Halogeometricum borinquense, Haloplanus spp.) possess gas vesicles that bestow buoyancy on the cells. Gas vesicles are also produced by the anaerobic endospore-forming halophilic Bacteria Sporohalobacter lortetii and Orenia sivashensis. We have extensive information on the properties of gas vesicles in Hbt. salinarum and Hfx. mediterranei and the regulation of their formation. Different functions were suggested for gas vesicle synthesis: buoying cells towards oxygen-rich surface layers in hypersaline water bodies to prevent oxygen limitation, reaching higher light intensities for the light-driven proton pump bacteriorhodopsin, positioning the cells optimally for light absorption, light shielding, reducing the cytoplasmic volume leading to a higher surface-area-to-volume ratio (for the Archaea) and dispersal of endospores (for the anaerobic spore-forming Bacteria). Except for Hqr. walsbyi which abounds in saltern crystallizer brines, gas-vacuolate halophiles are not among the dominant life forms in hypersaline environments. There only has been little research on gas vesicles in natural communities of halophilic microorganisms, and the few existing studies failed to provide clear evidence for their possible function. This paper summarizes the current status of the different theories why gas vesicles may provide a selective advantage to some halophilic microorganisms.

Published

2012

5. Microbial gas vesicles as nanotechnology tools: exploiting intracellular organelles for translational utility in biotechnology, medicine and the environment

Author

George P. C. Salmond and Amy M Hill

Subjects

Halobacterium, recombinant vaccines, Review, 02 engineering and technology, Environment, cyanobacterial blooms, Microbiology, law.invention, 03 medical and health sciences, law, In vivo, Animals, Humans, magnetic resonance imaging, gas vesicles, 030304 developmental biology, Bacillus megaterium, Organelles, 0303 health sciences, nanotechnology, biology, Anabaena, Chemistry, business.industry, Vesicle, 021001 nanoscience & nanotechnology, biology.organism_classification, In vitro, Biotechnology, Recombinant DNA, Medicine, Gases, 0210 nano-technology, business, Bacteria, Archaea

Abstract

A range of bacteria and archaea produce gas vesicles as a means to facilitate flotation. These gas vesicles have been purified from a number of species and their applications in biotechnology and medicine are reviewed here. Halobacterium sp. NRC-1 gas vesicles have been engineered to display antigens from eukaryotic, bacterial and viral pathogens. The ability of these recombinant nanoparticles to generate an immune response has been quantified both in vitro and in vivo. These gas vesicles, along with those purified from Anabaena flos-aquae and Bacillus megaterium , have been developed as an acoustic reporter system. This system utilizes the ability of gas vesicles to retain gas within a stable, rigid structure to produce contrast upon exposure to ultrasound. The susceptibility of gas vesicles to collapse when exposed to excess pressure has also been proposed as a biocontrol mechanism to disperse cyanobacterial blooms, providing an environmental function for these structures.

Published

2020

6. Microbial gas vesicles as nanotechnology tools: exploiting intracellular organelles for translational utility in biotechnology, medicine and the environment

Author

Salmond, George, Hill, Amy, Salmond, George [0000-0002-5197-2198], Hill, Amy [0000-0003-0897-2798], and Apollo - University of Cambridge Repository

Subjects

Halobacterium, Organelles, FOS: Nanotechnology, recombinant vaccines, nanotechnology, Environment, cyanobacterial blooms, Bacillus megaterium, magnetic resonance imaging, Animals, Humans, Medicine, Gases, health care economics and organizations, gas vesicles, Biotechnology

Abstract

A range of bacteria and archaea produce gas vesicles as a means to facilitate flotation. These gas vesicles have been purified from a number of species and their applications in biotechnology and medicine are reviewed here. Halobacterium sp. NRC-1 gas vesicles have been engineered to display antigens from eukaryotic, bacterial and viral pathogens. The ability of these recombinant nanoparticles to generate an immune response has been quantified both in vitro and in vivo. These gas vesicles along with those purified from Anabaena flos-aquae and Bacillus megaterium have been developed as an acoustic reporter system. This system utilizes the ability of gas vesicles to retain gas within a stable, rigid structure to produce contrast upon exposure to ultrasound. The susceptibility of gas vesicles to collapse when exposed to excess pressure has also been proposed as a biocontrol mechanism to disperse cyanobacterial blooms providing an environmental function for these structures., Funding information: Work in the Salmond lab was generously supported by the BBSRC, UK (awards BB/K001833/1 and BB/N008081/1). Amy Hill was funded by an award from the Woolf Fisher Trust.

Published

2020

7. The Function of Gas Vesicles in Halophilic Archaea and Bacteria: Theories and Experimental Evidence.

Author

Oren, Aharon

Subjects

*HALOBACTERIUM, *BACTERIORHODOPSIN, *OXYGEN, *VESICLES (Cytology), *HALOPHILIC microorganisms

Abstract

A few extremely halophilic Archaea (Halobacterium salinarum, Haloquadratum walsbyi, Haloferax mediterranei, Halorubrum vacuolatum, Halogeometricum borinquense, Haloplanus spp.) possess gas vesicles that bestow buoyancy on the cells. Gas vesicles are also produced by the anaerobic endospore-forming halophilic Bacteria Sporohalobacter lortetii and Orenia sivashensis. We have extensive information on the properties of gas vesicles in Hbt. salinarum and Hfx. mediterranei and the regulation of their formation. Different functions were suggested for gas vesicle synthesis: buoying cells towards oxygen-rich surface layers in hypersaline water bodies to prevent oxygen limitation, reaching higher light intensities for the light-driven proton pump bacteriorhodopsin, positioning the cells optimally for light absorption, light shielding, reducing the cytoplasmic volume leading to a higher surface-area-to-volume ratio (for the Archaea) and dispersal of endospores (for the anaerobic spore-forming Bacteria). Except for Hqr. walsbyi which abounds in saltern crystallizer brines, gas-vacuolate halophiles are not among the dominant life forms in hypersaline environments. There only has been little research on gas vesicles in natural communities of halophilic microorganisms, and the few existing studies failed to provide clear evidence for their possible function. This paper summarizes the current status of the different theories why gas vesicles may provide a selective advantage to some halophilic microorganisms. [ABSTRACT FROM AUTHOR]

Published

2013

8. Modeling of the major gas vesicle protein, GvpA: From protein sequence to vesicle wall structure

Author

Ezzeldin, Hussein M., Klauda, Jeffery B., and Solares, Santiago D.

Subjects

*PROTEIN structure, *AMINO acid sequence, *MOLECULAR dynamics, *VESICLE associated membrane protein, *VESICLES (Cytology), *HALOBACTERIUM

Abstract

Abstract: The structure and assembly process of gas vesicles have received significant attention in recent decades, although relatively little is still known. This work combines state-of-the-art computational methods to develop a model for the major gas vesicle protein, GvpA, and explore its structure within the assembled vesicle. Elucidating this protein’s structure has been challenging due to its adherent and aggregative nature, which has so far precluded in-depth biochemical analyses. Moreover, GvpA has extremely low similarity with any known protein structure, which renders homology modeling methods ineffective. Thus, alternate approaches were used to model its tertiary structure. Starting with the sequence from haloarchaeon Halobacterium sp. NRC-1, we performed ab initio modeling and threading to acquire a multitude of structure decoys, which were equilibrated and ranked using molecular dynamics and mechanics, respectively. The highest ranked predictions exhibited an α-β-β-α secondary structure in agreement with earlier experimental findings, as well as with our own secondary structure predictions. Afterwards, GvpA subunits were docked in a quasi-periodic arrangement to investigate the assembly of the vesicle wall and to conduct simulations of contact-mode atomic force microscopy imaging, which allowed us to reconcile the structure predictions with the available experimental data. Finally, the GvpA structure for two representative organisms, Anabaena flos-aquae and Calothrix sp. PCC 7601, was also predicted, which reproduced the major features of our GvpA model, supporting the expectation that homologous GvpA sequences synthesized by different organisms should exhibit similar structures. [Copyright &y& Elsevier]

Published

2012

9. Gas vesicles isolated from Halobacterium cells by lysis in hypotonic solution are structurally weakened

Author

Oren, Aharon, Pri-El, Nuphar, Shapiro, Orr, and Siboni, Nachshon

Subjects

*GRAM-negative bacteria, *HALOPHILIC microorganisms, *ARCHAEBACTERIA, *PROTEINS

Abstract

Abstract: Analysis of pressure-collapse curves of Halobacterium cells containing gas vesicles and of gas vesicles released from such cells by hypotonic lysis shows that the isolated gas vesicles are considerably weaker than those present within the cells: their mean critical collapse pressure was around 0.049–0.058MPa, as compared to 0.082–0.095MPa for intact cells. The hypotonic lysis procedure, which is widely used for the isolation of gas vesicles from members of the Halobacteriaceae, thus damages the mechanical properties of the vesicles. The phenomenon can possibly be attributed to the loss of one or more structural gas vesicle proteins such as GvpC, the protein that strengthens the vesicles built of GvpA subunits: Halobacterium GvpC is a highly acidic, typically “halophilic” protein, expected to denature in the absence of molar concentrations of salt. [Copyright &y& Elsevier]

Published

2005

10. Cryo-electron microscopy of an extremely halophilic microbe: technical aspects

Author

C. Martin Lawrence, Miroslava Schaffer, Harald Engelhardt, and Daniel Bollschweiler

Subjects

0301 basic medicine, Halobacterium salinarum, Halobacterium, Cryo-electron microscopy, 030106 microbiology, Sodium Chloride, Microbiology, 03 medical and health sciences, Halobacteriaceae, Cryo-electron tomography, Original Paper, biology, Haloarchaea, Cryoelectron Microscopy, General Medicine, biology.organism_classification, Vitrification, Halophile, 030104 developmental biology, Gas vesicles, Focused-ion-beam micromachining, Biophysics, Molecular Medicine, Archaea

Abstract

Most halophilic Archaea of the class Halobacteriaceae depend on the presence of several molar sodium chloride for growth and cell integrity. This poses problems for structural studies, particularly for electron microscopy, where the high salt concentration results in diminished contrast. Since cryo-electron microscopy of intact cells provides new insights into the cellular and molecular organization under close-to-live conditions, we evaluated strategies and conditions to make halophilic microbes available for investigations in situ. Halobacterium salinarum, the test organism for this study, usually grows at 4.3 M NaCl. Adaptation to lower concentrations and subsequent NaCl reduction via dialysis led to still vital cells at 3 M salt. A comprehensive evaluation of vitrification parameters, thinning of frozen cells by focused-ion-beam micromachining, and cryo-electron microscopy revealed that structural studies under high salt conditions are possible in situ. Electronic supplementary material The online version of this article (doi:10.1007/s00792-016-0912-0) contains supplementary material, which is available to authorized users.