In the brain, not only neurons contribute to forming the neuronal network, instead glial cells are as well important to support brain functions. Oligodendroglial cells generate myelin sheaths in order to support and protect neuronal fibers (or axons). We know that neurons die during the course of neurodegenerative diseases, such as Alzheimer’s and Parkinson’s Disease or Epilepsy. Neurodegeneration also affects the glial cells that are in contact with these neurons, as has recently been brought to the attention of researchers around the globe by genetic screens for risk factors. On the contrary, oligodendrocytes are lost during the course of the autoimmune disease Multiple Sclerosis, leaving the neurons at a high risk to degenerate. Based on demographic changes in Europe, it is expected that the number of patients suffering from neurodegenerative disorders will greatly increase in the decades to come. Thus, we urgently need more therapies that protect neurons and glial cells from degenerating.
In this project, we focus on oligodendrocyte precursor cells (OPCs or NG2 cells), that give rise to mature oligodendrocytes, the myelin generating cells of the central nervous system.
In contrast to neurons, which cannot be regenerated once they are lost (with very few exceptions), NG2 cells keep the ability to divide and generate new oligodendrocytes throughout life. Thus, NG2 cells could provide a great regenerative potential, if we understand how they are regulated, and if we find ways to positively influence their generation and maturation into oligodendrocytes. We study how NG2 cells react to alterations in neuronal activity in in vivo-models for epilepsy. In these models, mutations in ion channels that have been identified in human epilepsy patients are expressed in experimental systems, resulting in an increase in neuronal activity. Understanding the physiological and morphological interactions between neurons and NG2 cells in the healthy as well as in the diseased brain will help us to understand how they influence each other, and find possible points of intervention in order to enhance the capability of NG2 cells to regenerate oligodendrocytes that have been lost and protect neurons from degeneration.