Archaeosomes and Gas Vesicles as Tools for Vaccine Development

Adamiak, Natalia; Krawczyk, Krzysztof; Locht, Camille; Kowalewicz-Kulbat, Magdalena

doi:10.3389/fimmu.2021.746235

Cited by 14 publications

(9 citation statements)

References 49 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To our knowledge, this is the first report on the effect of halophilic archaea on the maturation of human DCs and the subsequent orientation of CD4 + T cells. However, archaeosomes, which are unique liposomes composed of specific lipid extracts from halophilic archaea, almost exclusively from Halobacterium salinarum, have been produced and assessed as vaccine vehicles against various pathogens [for a recent review see (31)]. These liposomes have been shown to induce both antibody and T cell responses to the passenger antigens, implying that halophile compounds can activate antigen-presenting cells and trigger adaptive immunity.…”

Section: Discussionmentioning

confidence: 99%

Halophilic Archaea Halorhabdus Rudnickae and Natrinema Salaciae Activate Human Dendritic Cells and Orient T Helper Cell Responses

Krawczyk

Locht²,

Kowalewicz-Kulbat³

2022

Front. Immunol.

Self Cite

View full text Add to dashboard Cite

Halophilic archaea are procaryotic organisms distinct from bacteria, known to thrive in hypersaline environments, including salt lakes, salterns, brines and salty food. They have also been identified in the human microbiome. The biological significance of halophiles for human health has rarely been examined. The interactions between halophilic archaea and human dendritic cells (DCs) and T cells have not been identified so far. Here, we show for the first time that the halophilic archaea Halorhabdus rudnickae and Natrinema salaciae activate human monocyte-derived DCs, induce DC maturation, cytokine production and autologous T cell activation. In vitro both strains induced DC up-regulation of the cell-surface receptors CD86, CD80 and CD83, and cytokine production, including IL-12p40, IL-10 and TNF-α, but not IL-23 and IL-12p70. Furthermore, autologous CD4+ T cells produced significantly higher amounts of IFN-γ and IL-13, but not IL-17A when co-cultured with halophile-stimulated DCs in comparison to T cells co-cultured with unstimulated DCs. IFN-γ was almost exclusively produced by naïve T cells, while IL-13 was produced by both naïve and memory CD4+ T cells. Our findings thus show that halophilic archaea are recognized by human DCs and are able to induce a balanced cytokine response. The immunomodulatory functions of halophilic archaea and their potential ability to re-establish the immune balance may perhaps participate in the beneficial effects of halotherapies.

show abstract

Section: Discussionmentioning

confidence: 99%

Halophilic Archaea Halorhabdus Rudnickae and Natrinema Salaciae Activate Human Dendritic Cells and Orient T Helper Cell Responses

Krawczyk

Locht²,

Kowalewicz-Kulbat³

2022

Front. Immunol.

Self Cite

View full text Add to dashboard Cite

show abstract

“…Archaea, a domain of single-celled living things morphologically similar to bacteria but genetically distinct, are also used as vaccine delivery systems, especially in the form of archaeosomes [191]. The archaeosome is a liposome-based nano-delivery system developed for gene delivery.…”

Section: Archaea Bacteria and Their By-productsmentioning

confidence: 99%

Enhancing the Effect of Nucleic Acid Vaccines in the Treatment of HPV-Related Cancers: An Overview of Delivery Systems

et al. 2022

View full text Add to dashboard Cite

Prophylactic vaccines against human papillomavirus (HPV) have proven efficacy in those who have not been infected by the virus. However, they do not benefit patients with established tumors. Therefore, the development of therapeutic options for HPV-related malignancies is critical. Third-generation vaccines based on nucleic acids are fast and simple approaches to eliciting adaptive immune responses. However, techniques to boost immunogenicity, reduce degradation, and facilitate their capture by immune cells are frequently required. One option to overcome this constraint is to employ delivery systems that allow selective antigen absorption and help modulate the immune response. This review aimed to discuss the influence of these different systems on the response generated by nucleic acid vaccines. The results indicate that delivery systems based on lipids, polymers, and microorganisms such as yeasts can be used to ensure the stability and transport of nucleic acid vaccines to their respective protein synthesis compartments. Thus, in view of the limitations of nucleic acid-based vaccines, it is important to consider the type of delivery system to be used—due to its impact on the immune response and desired final effect.

show abstract

“…The lipid film is then resuspended in chloroform, methanol, and water mixture, and again evaporated under vacuum. The dried lipid film is then hydrated with an aqueous buffer to form archaeosomes . Usually, the drug or a biomolecule (e.g., protein) of interest can be either encapsulated (hydrophilic) or entrapped (hydrophobic) in the archaeosomes during their formulation or incubated with the archaeosomes after their formation .…”

Section: Archaeosomes: Preparation and Characterizationmentioning

confidence: 99%

“…The dried lipid film is then hydrated with an aqueous buffer to form archaeosomes. 2 Usually, the drug or a biomolecule (e.g., protein) of interest can be either encapsulated (hydrophilic) or entrapped (hydrophobic) in the archaeosomes during their formulation or incubated with the archaeosomes after their formation. 17 A variety of microscopic techniques such as cryo-transmission electron microscopy, scanning electron microscopy, fluorescence microscopy, and phase-contrast light microscopy are widely used to analyze the morphology of archaeosomes.…”

Section: Archaeosomes: Preparation and Characterizationmentioning

confidence: 99%

“…They represent the third domain of life on earth and are evolutionarily distinct from the other two domains, namely bacteria and Eukarya. Archaea are well-known for their ability to grow and thrive in extreme habitats ranging from hot springs and volcanoes to hypersaline environments such as salt lakes and oceans, highly acidic or alkaline conditions, and high pressure that are hostile to most other organisms on earth. , Such organisms, known as extremophiles have been found at depths of 6.7 km inside the earth’s crust, more than 10 km deep inside the ocean at pressures of up to 110 MPa, from extreme acidic (pH 0) to extreme basic conditions (pH 12.8), and from hydrothermal vents at 122 °C to frozen seawater at −20 °C . Based on their living habitats, they are classified into different groups such as thermophiles and hyperthermophiles (able to grow at high or very high temperatures, respectively), psychrophiles (adapted to grow best at low temperatures), acidophiles and alkaliphiles (survive at high acidic or basic pH values, respectively), barophiles (able to thrive under pressure), and halophiles (organisms that require NaCl for growth) .…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Archaeosomes: New Generation of Liposomes Based on Archaeal Lipids for Drug Delivery and Biomedical Applications

Santhosh

Genova

2022

ACS Omega

View full text Add to dashboard Cite

Archaeosomes are a new generation of stable liposomes composed of natural ether lipids extracted from archaea, or synthetic archaeal lipids. Archaea constitute a domain of singlecelled microorganisms that are structurally similar to but evolutionarily distinct from bacteria. They synthesize unique membrane lipids with isoprenoid hydrocarbon side chains attached via an ether linkage to the glycerol-phosphate backbone. Compared to the ester linkages found in the lipids of Eukarya and bacteria, the ether linkages in archaeal lipids are more stable in various environmental conditions such as high/low temperatures, acidic or alkaline pH, bile salts, and enzymatic hydrolysis. This feature has intrigued scientists to use archaeal lipids to prepare archaeosomes with superior physicochemical stability and utilize them as effective carriers to deliver various cargos of biomedical importance such as drugs, proteins, peptides, genes, and antioxidants to the target site. Archaeosomes carrying antigens and/or adjuvants are also proven to be better candidates for stimulating antigenspecific, humoral, and cell-mediated immune responses, which broadens their scope in vaccine delivery. These properties associated with excellent biocompatibility and a safety profile provide numerous advantages to the archaeosomes to function as a versatile delivery system. This mini-review will provide an overview of the unique features of archaeal lipids, preparation and characterization of archaeosomes, and emphasize the prospects related to drug delivery and other biomedical applications.

show abstract

Archaeosomes and Gas Vesicles as Tools for Vaccine Development

Cited by 14 publications

References 49 publications

Halophilic Archaea Halorhabdus Rudnickae and Natrinema Salaciae Activate Human Dendritic Cells and Orient T Helper Cell Responses

Halophilic Archaea Halorhabdus Rudnickae and Natrinema Salaciae Activate Human Dendritic Cells and Orient T Helper Cell Responses

Enhancing the Effect of Nucleic Acid Vaccines in the Treatment of HPV-Related Cancers: An Overview of Delivery Systems

Archaeosomes: New Generation of Liposomes Based on Archaeal Lipids for Drug Delivery and Biomedical Applications

Contact Info

Product

Resources

About