Molecular Delivery of Plasmids for Genetic Vaccination

Mazid, Romiza Rehana; Tan, Melvin; Danquah, Michael K.

doi:10.2174/138920101131400226

Cited by 10 publications

(7 citation statements)

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“…1, 2, 3, 4, 5, 6, 7, 8, 9, 10 As nucleic acids alone are not able to penetrate the cell membrane, they must be transported with a suitable carrier. 11 Different strategies have been developed to address this problem, ranging from physical methods like electroporation 12 over viral transduction 13 to various kinds of nanosystems.…”

Section: Introductionmentioning

confidence: 99%

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Live-cell imaging to compare the transfection and gene silencing efficiency of calcium phosphate nanoparticles and a liposomal transfection agent

Chernousova

Epple

2017

Gene Ther

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The processing of DNA (for transfection) and short interfering RNA (siRNA; for gene silencing), introduced into HeLa cells by triple-shell calcium phosphate nanoparticles, was followed by live-cell imaging. For comparison, the commercial liposomal transfection agent Lipofectamine was used. The cells were incubated with these delivery systems, carrying either enhanced green fluorescent protein (eGFP)-encoding DNA or siRNA against eGFP. In the latter case, HeLa cells that stably expressed eGFP were used. The expression of eGFP started after 5 h in the case of nanoparticles and after 4 h in the case of Lipofectamine. The corresponding times for gene silencing were 5 h (nanoparticles) and immediately after incubation (Lipofectamine). The expression of eGFP was notably enhanced 2–3 h after cell division (mitosis). In general, the transfection and gene silencing efficiencies of the nanoparticles were lower than those of Lipofectamime, even at a substantially higher dose (factor 20) of nucleic acids. However, the cytotoxicity of the nanoparticles was lower than that of Lipofectamine, making them suitable vectors for in vivo application.

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Section: Introductionmentioning

confidence: 99%

“…3, 5, 6, 7, 11, 14, 15, 16, 17 Typical nanoparticles for transfection comprise gold, 18, 19, 20 iron oxide, 21 silica, 22 carbon nanotubes 23 and many different polymers. 2, 24, 25 …”

Section: Introductionmentioning

confidence: 99%

Live-cell imaging to compare the transfection and gene silencing efficiency of calcium phosphate nanoparticles and a liposomal transfection agent

Chernousova

Epple

2017

Gene Ther

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“…This model study emphasized the importance of well-defined chain length for cationic polymers in DNA vaccines; this type of cationic polymer poly (2-aminoethyl methacrylate) was also recently reviewed for exploring structure–function relationship while delivering DNA [ 174 ]. Excellent reviews are available on micro- and nanoparticles for DNA vaccine delivery [ 175 ] and on molecular delivery of plasmids for genetic vaccination [ 176 ].…”

Section: Assemblies Based On Cationic Polymersmentioning

confidence: 99%

Cationic Nanostructures for Vaccines Design

Carmona-Ribeiro

Betancourt

2020

Biomimetics

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Subunit vaccines rely on adjuvants carrying one or a few molecular antigens from the pathogen in order to guarantee an improved immune response. However, to be effective, the vaccine formulation usually consists of several components: an antigen carrier, the antigen, a stimulator of cellular immunity such as a Toll-like Receptors (TLRs) ligand, and a stimulator of humoral response such as an inflammasome activator. Most antigens are negatively charged and combine well with oppositely charged adjuvants. This explains the paramount importance of studying a variety of cationic supramolecular assemblies aiming at the optimal activity in vivo associated with adjuvant simplicity, positive charge, nanometric size, and colloidal stability. In this review, we discuss the use of several antigen/adjuvant cationic combinations. The discussion involves antigen assembled to 1) cationic lipids, 2) cationic polymers, 3) cationic lipid/polymer nanostructures, and 4) cationic polymer/biocompatible polymer nanostructures. Some of these cationic assemblies revealed good yet poorly explored perspectives as general adjuvants for vaccine design.

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“…Moreover, nucleic acids can be tailored to express antigens that are chemically or structurally different from their native form, with the intention of improving their immunogenicity (Alpar et al, 2005;Deering et al, 2014;Kramps and Probst, 2013). The main limitation of this approach is the low level of gene expression achieved upon administration, a limitation that can be overcome by designing effective viral and non-viral transfection vectors (Alpar et al, 2005;Mazid et al, 2013).…”

Section: Genetic Vaccinationmentioning

confidence: 99%

“…Plasmid DNA vaccination, based on the administration of selected antigen-encoding DNA through a plasmid vector, has been applied to prevent diseases such as malaria and HIV and also as a therapeutic approach in cancer immunotherapy. Some of these formulations have already reached the clinical development phase, as recently reviewed by Mazid et al (Liu, 2003;Mazid et al, 2013). Nevertheless, the risk of genome integration and long-term effects of these vaccines are yet to be clarified (Schalk et al, 2006).…”

Section: Genetic Vaccinationmentioning

confidence: 99%

Nanoengineering of vaccines using natural polysaccharides

Cordeiro

Alonso

Fuente

2015

Biotechnology Advances

100

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Currently, there are over 70 licensed vaccines, which prevent the pathogenesis of around 30 viruses and bacteria. Nevertheless, there are still important challenges in this area, which include the development of more active, non-invasive, and thermo-resistant vaccines. Important biotechnological advances have led to safer subunit antigens, such as proteins, peptides, and nucleic acids. However, their limited immunogenicity has demanded potent adjuvants that can strengthen the immune response. Particulate nanocarriers hold a high potential as adjuvants in vaccination. Due to their pathogen-like size and structure, they can enhance immune responses by mimicking the natural infection process. Additionally, they can be tailored for non-invasive mucosal administration (needle-free vaccination), and control the delivery of the associated antigens to a specific location and for prolonged times, opening room for single-dose vaccination. Moreover, they allow co-association of immunostimulatory molecules to improve the overall adjuvant capacity. The natural and ubiquitous character of polysaccharides, together with their intrinsic immunomodulating properties, their biocompatibility, and biodegradability, justify their interest in the engineering of nanovaccines. In this review, we aim to provide a state-of-the-art overview regarding the application of nanotechnology in vaccine delivery, with a focus on the most recent advances in the development and application of polysaccharide-based antigen nanocarriers.

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Molecular Delivery of Plasmids for Genetic Vaccination

Cited by 10 publications

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Live-cell imaging to compare the transfection and gene silencing efficiency of calcium phosphate nanoparticles and a liposomal transfection agent

Live-cell imaging to compare the transfection and gene silencing efficiency of calcium phosphate nanoparticles and a liposomal transfection agent

Cationic Nanostructures for Vaccines Design

Nanoengineering of vaccines using natural polysaccharides

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