Nonviral Gene Therapy for Cancer: A Review

Hidai, Chiaki; Kitano, Hisataka

doi:10.3390/diseases6030057

Cited by 55 publications

(35 citation statements)

References 86 publications

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“…Viral vectors are generally chosen for their ability to infect both dividing and quiescent cells, required to restore functionality of a defective gene in all cells of the targeted tissue. This main advantage is counterbalanced by immunogenicity and manufacturing bottlenecks [2]. To decrease immunogenicity, modified viral vectors with minimal viral genome are preferred.…”

Section: Viral Vector For Treatment Of Monogenic Diseasesmentioning

confidence: 99%

Non-Viral Vector Mediated Gene Delivery: the Outsider to Watch Out For in Gene Therapy

Nyamay’Antu¹,

Dumont²,

Kedinger³

et al. 2019

Cell Gene Therapy Insights

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Nucleic acids have considerable potential as therapeutic agents in the treatment of pathologies including genetic diseases, viral infections and cancer therapies. The major challenge for the use of nucleic acids in therapy lies in safely delivering these anionic macromolecules to their intended sites of action. The increasing use of viral vectors in Human Gene Therapy clinical trials has emphasized the potential of nucleic acid-based approaches to address the unmet needs of drug-based treatments. While viral vector-based Gene Therapy is on everyone's mind with recently approved Luxturna™, as well as other viral vector-based treatments under Fast Track Designation, it is key to remember that non-viral vectors present considerable advantages in terms of reliability, safety and costs for nucleic-acid based therapies. At Polyplus-transfection ® , we develop powerful non-viral vectors to safely deliver nucleic acids in vivo to target a wide range of tissues, through various routes of administrations. Of these reagents, in vivo-jetPEI ® and its highest quality grade cGMP in vivo-jetPEI ® are acknowledged as a non-viral vector of choice to deliver nucleic acids respectively in animal preclinical studies and in human clinical trials, notably for cancer and immunotherapy.

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Section: Viral Vector For Treatment Of Monogenic Diseasesmentioning

confidence: 99%

Non-Viral Vector Mediated Gene Delivery: the Outsider to Watch Out For in Gene Therapy

Nyamay’Antu¹,

Dumont²,

Kedinger³

et al. 2019

Cell Gene Therapy Insights

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“…Nanocarriers with diverse structures and characteristics have been developed in the last decade to enhance the pharmacological action of drugs and to mitigate the side effects produced by the use of naked pharmaceuticals [3][4][5][6]. Nowadays, many studies about gene therapy are being carried out as a promising option to treat numerous acquired diseases such as cancer, AIDS or genetic disorders [7][8][9][10][11][12]. Biological defense mechanisms of the human body against the presence of foreign substances obligate the researchers to synthesize biocompatible and biodegradable nanosystems, also known as vectors, able to protect the genetic material.…”

Section: Introductionmentioning

confidence: 99%

Metallo-Liposomes of Ruthenium Used as Promising Vectors of Genetic Material

et al. 2020

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Gene therapy is a therapeutic process consisting of the transport of genetic material into cells. The design and preparation of novel carriers to transport DNA is an important research line in the medical field. Hybrid compounds such as metallo-liposomes, containing a mixture of lipids, were prepared and characterized. Cationic metal lipids derived from the [Ru(bpy)3]2+ complex, RuC11C11 or RuC19C19, both with different hydrophobic/lipophilic ratios, were mixed with the phospholipid DOPE. A relation between the size and the molar fraction α was found and a multidisciplinary study about the interaction between the metallo-liposomes and DNA was performed. The metallo-liposomes/DNA association was quantified and a relationship between Kapp and α was obtained. Techniques such as AFM, SEM, zeta potential, dynamic light scattering and agarose gel electrophoresis demonstrated the formation of lipoplexes and showed the structure of the liposomes. L/D values corresponding to the polynucleotide’s condensation were estimated. In vitro assays proved the low cell toxicity of the metallo-liposomes, lower for normal cells than for cancer cell lines, and a good internalization into cells. The latter as well as the transfection measurements carried out with plasmid DNA pEGFP-C1 have demonstrated a good availability of the Ru(II)-based liposomes for being used as non-toxic nanovectors in gene therapy.

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“…Other important cationic polymers like poly l ‐lysine, one of the most often used polymers for the complexing and delivery of DNA, have been known to be cytotoxic and possess low capacities for maintaining DNA integrity and endosomal escape . Due to such conflicting reports, up to the year 2018 only 0.24% were reported to examine the use of nonviral delivery systems through gene therapy . The limitations arise from the significant challenges of overcoming three barriers in gene delivery: maintaining the chemical and physical integrity of DNA; successful entry through the cell membrane; and endosomal escape prior to nuclear uptake for expression of the gene through transcription and translation .…”

mentioning

confidence: 99%

“…[9] Due to such conflicting reports, up to the year 2018 only 0.24% were reported to examine the use of nonviral delivery systems through gene therapy. [14] The limitations arise from the significant challenges of overcoming three barriers in gene delivery: maintaining the chemical and physical integrity of DNA; successful entry through the cell membrane; and endosomal escape prior to nuclear uptake for expression of the gene through transcription and translation. [15] Therefore, the development of improved synthetic systems that allow the vector to address the above limitations is essential.…”

mentioning

confidence: 99%

Encapsulation, Visualization and Expression of Genes with Biomimetically Mineralized Zeolitic Imidazolate Framework‐8 (ZIF‐8)

Poddar

Conesa

Liang

et al. 2019

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105

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Recent work in biomolecule‐metal–organic framework (MOF) composites has proven to be an effective strategy for the protection of proteins. However, for other biomacromolecules such as nucleic acids, the encapsulation into nano MOFs and the related characterizations are in their infancy. Herein, encapsulation of a complete gene‐set in zeolitic imidazolate framework‐8 (ZIF‐8) MOFs and cellular expression of the gene delivered by the nano MOF composites are reported. Using a green fluorescent protein (GFP) plasmid (plGFP) as a proof‐of‐concept genetic macromolecule, successful transfection of mammalian cancer cells with plGFP for up to 4 days is shown. Cell transfection assays and soft X‐ray cryo‐tomography (cryo‐SXT) demonstrate the feasibility of DNA@MOF biocomposites as intracellular gene delivery vehicles. Expression occurs over relatively prolonged time points where the cargo nucleic acid is released gradually in order to maintain sustained expression.

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Nonviral Gene Therapy for Cancer: A Review

Cited by 55 publications

References 86 publications

Non-Viral Vector Mediated Gene Delivery: the Outsider to Watch Out For in Gene Therapy

Non-Viral Vector Mediated Gene Delivery: the Outsider to Watch Out For in Gene Therapy

Metallo-Liposomes of Ruthenium Used as Promising Vectors of Genetic Material

Encapsulation, Visualization and Expression of Genes with Biomimetically Mineralized Zeolitic Imidazolate Framework‐8 (ZIF‐8)

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