Theory and in Vivo Application of Electroporative Gene Delivery

Somiari, Stella; Glasspool-Malone, Jill; Drabick, Joseph J.; Gilbert, R. Alton; Heller, Richard; Jaroszeski, Mark J.; Malone, Robert E.

doi:10.1006/mthe.2000.0124

Cited by 280 publications

(172 citation statements)

References 75 publications

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“…It was already proposed that this observation could be due to the specific properties of the tumor tissue, such as differences in tissue organisation, in extracellular matrix, presence or absence of necrosis, overall tissue conductivity, the ability of cells to express transfected genes, cell density, and cell size. 13,19,33 A correlation between cell density and transfection efficiency by electroporation demonstrated that lower cell density yielded better transfection (Fig 7 ), which is in agreement with in vitro data obtained on adherent cells. 36 The correlation was not very high, as only four tumor types were included and should be expanded in a further study to prove the hypothesis.…”

Section: Discussionsupporting

confidence: 88%

“…13 In the case of tumors, many different electrical parameters for electroporation were employed for delivering plasmid DNA encoding either reporter (luciferase, -galactosidase, GFP ) or therapeutic genes (IL -12, Stat3, GM -CSF, IL -2). 25 -35 Our study focused on optimisation of plasmid DNA delivery to tumors by using different electrical parameters and DNA concentrations in the SaF tumor model.…”

Section: Discussionmentioning

confidence: 99%

“…11,12 In addition, some recent studies have examined the use of electroporation to deliver plasmid DNA to various types of tissues in vivo, such as skin, liver, testis, brain, skeletal muscle, and tumors. 13 Various settings of electroporation were used, with no general conclusion on the optimal electrical, DNA, and environmental parameters for effective DNA transfer, especially when delivering DNA to tumors. High -voltage microsecond pulses, which were used in electrochemotherapy, and low-voltage milliseconds pulses, which were found to be the most suitable for skeletal muscle transfection, were both used in gene delivery protocols for transfecting tumors.…”

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confidence: 99%

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Effective gene transfer to solid tumors using different nonviral gene delivery techniques: Electroporation, liposomes, and integrin-targeted vector

et al. 2002

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In this study, we measured transfection efficiency in vitro and in vivo using the following nonviral approaches of gene delivery: injection of plasmid DNA, electroporation -assisted, liposome -enhanced, and integrin -targeted gene delivery, as well as the combination of these methods. Four histologically different tumor models were transfected with a plasmid encoding the green fluorescent protein ( GFP ) ( B16 mouse melanoma, P22 rat carcinosarcoma, SaF mouse sarcoma, and T24 human bladder carcinoma ) using adherent cells, dense cell suspensions, and solid tumors. Emphasis was placed on different electroporation conditions to optimise the duration and amplitude of the electric pulses, as well as on different DNA concentrations for effective gene delivery. In addition, transfection efficiency was correlated with cell density of the tumors. The major in vivo findings were: ( a ) electroporationassisted gene delivery with plasmid DNA, employing long electric pulses with low amplitude, yielded significantly better GFP expression than short electric pulses with high amplitude; ( b ) electroporation combined with liposome -DNA complexes yielded the highest percentage of transfected tumor area in B16F1 tumor ( 6% ); ( c ) transfection efficiency of electroporation -assisted plasmid DNA delivery was dependent on tumor type; ( d ) integrin -targeted vector, alone or combined with electroporation, was largely ineffective. In conclusion, our results demonstrate that some nonviral methods of gene delivery are feasible and efficient in transfecting solid tumors. Therefore, this makes nonviral methods attractive for further development.

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Section: Discussionsupporting

confidence: 88%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Effective gene transfer to solid tumors using different nonviral gene delivery techniques: Electroporation, liposomes, and integrin-targeted vector

et al. 2002

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“…12 In addition, efficacy is also dependent on the concentration gradient of the molecules that are to be delivered. 21 The longer the loading period, the longer the cell surface is open. Hence, it is likely that more of the agent would be transferred from the extracellular to the intracellular space.…”

Section: Low-voltage Ep and Antiangiogenic Gene Therapy M Uesato Et Almentioning

confidence: 99%

Synergistic antitumor effect of antiangiogenic factor genes on colon 26 produced by low-voltage electroporation

et al. 2004

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Antiangiogenic factors are potent endothelial cell growth inhibitors that have been shown to inhibit angiogenesis in vitro and tumor growth in mice. We have demonstrated the synergistic antitumor effect of antiangiogenic genes (mouse angiostatin: pBLASTmAngio; and mouse endostatin: p-BLAST42-mEndo XV) delivered to tumors by low-voltage electroporation in mouse colon 26 models. A synergistic antitumor effect was strongly suggested by in vivo tumor growth kinetics, as well as in survival studies with the mice. RT-PCR confirmed that the fragments of each gene were transferred by low-voltage electroporation in the tumor. Decreased microvessel density measurements in tumors also confirmed the efficacy of the synergistic antitumor effect of both genes. Significant growth inhibition was observed in mice treated with a 1:1 proportion of angiostatin and endostatin genes, and the order of the both genes transferred (first the endostatin gene, followed 1 week later by the angiostatin gene) had a profound inhibitory effect on tumor growth. These data suggest that in vivo delivery of antiangiogenic genes with low-voltage electroporation could be a possible therapeutic strategy for established solid tumors when both genes were applied in combination.

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“…Then a sequential process progresses spontaneously with escape from endosomes, dissociation of complexes, and diffusion of naked DNAs in the cytoplasm to reach the nucleus [4][5][6]. On the other hand, physical approaches such as microinjection [7,8] and electroporation [9] are performed to incorporate naked DNAs directly into cytoplasm across the plasma membrane. Some naked DNAs diffuse in the cytoplasm to the nucleus [10].…”

Section: Introductionmentioning

confidence: 99%

Monitoring intracellular degradation of exogenous DNA using diffusion properties

Sasaki¹,

Kinjo²

2010

Journal of Controlled Release

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Artificial nonviral gene vectors have the potential to improve the safety of gene therapy; however, such artificial vectors are less efficient for gene expression due to the existence of various barriers to delivery of exogenous DNAs to the nucleus in the living cell. Here we describe the degradation activities of cytoplasmic nucleases, which are involved as a barrier to efficient exogenous gene expression. The size and structure of degraded DNA were monitored by fluorescence correlation spectroscopy (FCS) and fluorescence cross-correlation spectroscopy (FCCS) in solution and in the cytoplasm of living cells. Differences in degradation by endo-and exonucleases were confirmed by differences in the size and structure of DNA. Moreover, we confirmed the influence of the exonuclease degradation in cytoplasm on the expression rate of DNA transfection with a cationic lipid. Based on a comparison of in vitro and cell measurements, we conclude that cytoplasmic degradation by exonucleases can be a considerable barrier against efficient gene delivery.

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Theory and in Vivo Application of Electroporative Gene Delivery

Cited by 280 publications

References 75 publications

Effective gene transfer to solid tumors using different nonviral gene delivery techniques: Electroporation, liposomes, and integrin-targeted vector

Effective gene transfer to solid tumors using different nonviral gene delivery techniques: Electroporation, liposomes, and integrin-targeted vector

Synergistic antitumor effect of antiangiogenic factor genes on colon 26 produced by low-voltage electroporation

Monitoring intracellular degradation of exogenous DNA using diffusion properties

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