Visualization and Live Imaging of Oligodendrocyte Organelles in Organotypic Brain Slices Using Adeno-associated Virus and Confocal Microscopy

A live imaging-friendly slice culture method using collagen membranes

Aim

Organotypic brain slice culture preserves the geographical position of neurons and neuronal circuits. The slice cultures also maintain both non‐neuronal cell types and the surrounding extracellular matrix. The interface method has been widely used for slice cultures, in which brain slices are placed on semiporous polytetrafluoroethylene (PTFE) membranes. However, a low optical transparency of PTFE membrane makes it difficult to perform live imaging of deep regions of slice cultures using an inverted microscope. To overcome the issue, we evaluated the suitability of using collagen membranes for slice cultures, especially focusing on live imaging of the cellular dynamics of green fluorescent protein (GFP)‐expressing microglia.

Methods

Entorhinohippocampal slices were cultured on either collagen or PTFE membranes. The influence of membrane type on the ability to observe deep regions of slice cultures was examined by live imaging using an inverted microscope.

Results

Collagen membranes were thinner and had better optical transparency compared with PTFE membranes. There were no differences in cell viability, density of neurons or microglia. The densify of visible short branches of microglia in live imaging was higher in collagen membranes than PTFE membranes.

Conclusion

Collagen membranes are suitable for live imaging of cellular dynamics in slice cultures using an inverted microscope.

Live imaging of organotypic slice cultures has been a useful method to study cell dynamics. One remaining issue with live imaging of slice cultures is the low transparency of commonly used polytetrafluoroethylene membranes. Here we report that slice culture membranes made of collagen can solve the issue of low transparency, facilitating live imaging of small cellular structures such as microglial processes.

Developing myelin specific promoters for schwannoma gene therapy

BACKGROUND

Schwannomas are peripheral nerve sheath tumors composed entirely of Schwann-lineage cells that cause pain and sensory-motor dysfunction through compression of peripheral nerves, the spinal cord, and/or the brain stem. Treatment of schwannoma is largely limited to resection which itself has limited value. The goal of this study is to establish a technique to identify the most efficient and tissue-specific promoter for use in a schwannoma gene therapy construct.

NEW METHOD

This work involves transfection of schwannoma cells with adeno-associated viral vector plasmids expressing GFP under different myelin cell specific promoters. The transfected cells were evaluated for green fluorescence intensity in vitro, and in vivo after implantation into sciatic nerves of nude mice.

RESULTS

Our data demonstrate that myelin protein zero (MPZ, P0) and peripheral myelin protein 22 (PMP22) promoters produce greater GFP expression in schwannoma cell lines than myelin basic protein (MBP) promoter. In vitro, P0 promoter activity in schwannoma cell lines was shown to be less active than the cytomegalovirus and chicken β-actin (CBA) promoter. However, we did not observe any significant difference between the activity of the CBA and P0 promoters in a xenograft schwannoma model.

COMPARISON WITH EXISTING METHODS(S)

We show here the influence of the peripheral nerve microenvironment on promoter efficacy in expressing transgenes using simple transfection by lipofection followed by prompt implantation of the transfected cells into the sciatic nerve of nude mice.

CONCLUSIONS

We demonstrate that of the myelin specific promoters evaluated, P0 is optimal for driving expression of transgenes in schwannoma cells.