Highly efficient method for gene delivery into mouse dorsal root ganglia neurons

The development of gene transfection technologies has greatly advanced our understanding of life sciences. While use of viral vectors has clear efficacy, it requires specific expertise and biological containment conditions. Electroporation has become an effective and commonly used method for introdu...

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Bibliographic Details
Published in:Frontiers in molecular neuroscience 2015-02, Vol.8, p.2-2
Main Authors: Yu, Lingli, Reynaud, Florie, Falk, Julien, Spencer, Ambre, Ding, Yin-Di, Baumlé, Véronique, Lu, Ruisheng, Castellani, Valérie, Yuan, Chonggang, Rudkin, Brian B
Format: Article
Language:English
Subjects:
Antibiotics
Cell culture
Deoxyribonucleic acid
DNA
Dorsal root ganglia
Electroporation
Embryos
Gene transfer
Growth factors
Nerve growth factor
Neurons
Neuroscience
Plasmids
Signal transduction
Spinal cord
Toxicity
Transfection
Viral infections
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Summary:The development of gene transfection technologies has greatly advanced our understanding of life sciences. While use of viral vectors has clear efficacy, it requires specific expertise and biological containment conditions. Electroporation has become an effective and commonly used method for introducing DNA into neurons and in intact brain tissue. The present study describes the use of the Neon® electroporation system to transfect genes into dorsal root ganglia neurons isolated from embryonic mouse Day 13.5-16. This cell type has been particularly recalcitrant and refractory to physical or chemical methods for introduction of DNA. By optimizing the culture condition and parameters including voltage and duration for this specific electroporation system, high efficiency (60-80%) and low toxicity (>60% survival) were achieved with robust differentiation in response to Nerve growth factor (NGF). Moreover, 3-50 times fewer cells are needed (6 × 10(4)) compared with other traditional electroporation methods. This approach underlines the efficacy of this type of electroporation, particularly when only limited amount of cells can be obtained, and is expected to greatly facilitate the study of gene function in dorsal root ganglia neuron cultures.
ISSN:1662-5099
1662-5099
DOI:10.3389/fnmol.2015.00002