ENP Newswire -
Release date- 28082013 - Stem cell technology has long offered the hope of regenerating tissue to repair broken or damaged neural tissue.
Findings from a team of
'Our findings represent an important conceptual advance in stem cell research,' said
The brain is made up predominantly of two cell types: neurons and glial cells. Neurons are regarded as responsible for thought and sensation. Glial cells surround, support and communicate with neurons, helping neurons process and transmit information using electrical and chemical signals. One type of glial cell - the oligodendrocyte - produces a sheath called myelin that provides support and insulation to neurons. Myelin, which has been compared to insulation around electrical wires that helps to prevent short circuits, is essential for normal neural conduction and brain function; well-recognized conditions involving defective myelin development or myelin loss include multiple sclerosis and leukodystrophies.
In this study, the
They next compared electrophysiological properties of the derived OPCs to naturally occurring OPCs. They found that unlike natural OPCs, the ESC-derived OPCs lacked sodium ion channels in their cell membranes, making them unable to generate spikes when electrically stimulated. Using a technique called viral transduction, they then introduced DNA that codes for sodium channels into the ESC-derived OPCs. These OPCs then expressed ion channels in their cells and developed the ability to generate spikes.
According to Deng, this is the first time that scientists have successfully generated OPCs with so-called spiking properties. This achievement allowed them to compare the capabilities of spiking cells to non-spiking cells.
In cell culture, they found that only spiking OPCs received electrical input from neurons, and they showed superior capability to mature into oligodendrocytes.
They also transplanted spiking and non-spiking OPCs into the spinal cord and brains of mice that are genetically unable to produce myelin. Both types of OPCs had the capability to mature into oligo-dendrocytes and produce myelin, but those from spiking OPCs produced longer and thicker myelin sheaths around axons.
'We actually developed 'super cells' with an even greater capacity to spike than natural cells,' Deng said. 'This appears to give them an edge for maturing into oligodendrocytes and producing better myelin.'
It is well known that adult human neural tissue has a poor capacity to regenerate naturally. Although early cells such as OPCs are present, they do not regenerate tissue very effectively when disease or injury strikes.
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