Investigating Mammalian Axon Regeneration: <em>In Vivo</em> Electroporation of Adult Mouse Dorsal Root Ganglion

Qiao Li; Cheng Qian; Feng-Quan Zhou

doi:10.3791/58171

Soruşturma memeli Axon rejenerasyon: Vivo Elektroporasyon yetişkin fare Dorsal kök gangl...

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JoVE Journal Neuroscience

Investigating Mammalian Axon Regeneration: In Vivo Electroporation of Adult Mouse Dorsal Root Ganglion

Soruşturma memeli Axon rejenerasyon: Vivo Elektroporasyon yetişkin fare Dorsal kök gangliyon

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06:17 min

September 1, 2018

DOI: 10.3791/58171-v

Qiao Li¹, Cheng Qian¹, Feng-Quan Zhou^1,2

¹Department of Orthopaedic Surgery,Johns Hopkins University School of Medicine, ²The Solomon H. Snyder Department of Neuroscience,Johns Hopkins University School of Medicine

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Overview

This study explores electroporation as an efficient method for gene delivery into adult mouse dorsal root ganglion (DRG) neurons, aimed at enhancing understanding of axon regeneration. By applying this technique in vivo, the authors establish a model for investigating mechanisms behind neuronal regeneration.

Key Study Components

Area of Science

Neuroscience
Gene delivery techniques
Axon regeneration

Background

Regeneration of axons in the peripheral nervous system is crucial for recovery from injuries.
Electroporation is hypothesized to facilitate gene expression manipulation in neurons.
This method allows simultaneous overexpression and knockdown of target genes.
Adult mouse sensory neurons serve as the biological model for this study.

Purpose of Study

To develop an in vivo gene transfection method in adult mouse DRG neurons.
To study the biological processes involved in axon regeneration.
To establish a framework for future research on PNS regeneration mechanisms.

Methods Used

The main platform used is in vivo gene delivery via electroporation.
The key biological model includes adult mouse DRGs and associated sciatic nerve.
Critical steps involve precise surgical manipulation of the iliac crest, incision, and the electroporation protocol.
Key methodological details include injecting DNA plasmids or RNA oligos and applying electric pulses to the target tissues.

Main Results

Successful electroporation resulted in fluorescence labeling of DRG neurons, enabling visualization of axon regeneration.
Distinctive trajectories and identifiable distal axon ends of regenerated axons were documented.
EGFP plasmids enabled tracking and imaging of dorsal column axons in the spinal cord.
The study provides a detailed methodology reaffirming the potential of this technique in regenerative research.

Conclusions

The study effectively demonstrates the viability of electroporation for gene manipulation in sensory neurons.
This method opens avenues for exploring gene functions relevant to peripheral nervous system regeneration.
Overall, the findings contribute valuable insights into neuronal regeneration processes and potential targets for therapeutic interventions.

Frequently Asked Questions

What are the advantages of using electroporation for gene delivery?

Electroporation allows for efficient gene delivery with reduced time and labor compared to traditional methods, enabling simultaneous manipulation of gene expression.

How is the DRG model implemented in this study?

The DRG model is established through surgical exposure of the L4 and L5 ganglia, followed by direct electroporation and injection of DNA or RNA solutions.

What types of outcomes can be observed with this method?

The method yields fluorescence imaging data that allows tracking of axon regeneration and identification of changes in neuronal structure and function.

How can this technique be adapted for other studies?

The electroporation method can be adapted to other neuronal targets or gene constructs, expanding its utility in various regenerative and functional studies.

What are the key limitations of this study?

The complexity of surgical procedures and variability in individual mice responses may pose challenges in replicability and standardization of results.

Elektroporasyon genler çıkarlarının hücrelere teslim etmek için etkili bir yaklaşımdır. Bu yaklaşım içinde vivo yetişkin fare dorsal kök gangliyon (DRG) nöronlar üzerinde uygulayarak, biz axon yenilenme içinde vivoçalışmaya bir modeli açıklar.

Bu yöntem, memeli ekzo-rejenerasyonunun gelecekteki çalışmaları için yetişkin fare duyusal nöronlarında gen ekspresyonunu manipüle etmek için bir in vivo gen transfeksiyon tekniği sağlar. Bu tekniğin temel avantajı, daha az emek ve zaman alıcı olması ve hedef genleri aynı anda ve ayrı ayrı hem aşırı ifade edebilmesi hem de yıkabilmesidir. Bu işleme başlamak için, anestezi uygulanmış bir farenin iliak tepesinin her iki tarafını da ince bir işaretleyici ile işaretleyin.

L5 DRG konumlarının tanımlanmasını kolaylaştırmak için iliak tepenin iki noktasını birleştiren bir çizgi çizin. Ardından, mikro makasla alt sırtın orta hattı boyunca üç santimetrelik bir kesi yapın. Daha sonra, musculus multifidus ve musculus longissimus lumborum gibi paraspinöz kasları L3'ten S1'e kadar olan spinöz süreçlerden ayırın ve L4-5 ve L5-6'nın fasya eklemini ortaya çıkarın.

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