FORNEUROCELL II

The association

Research over the last two decades revealed the presence of cells in the adult mammalian brain, which have the ability to proliferate and to differentiate into the major cell types of the central nervous system, i.e. neurons, astrocytes and oligodendrocytes. In the adult brain there are two regions where stem cells generate new neurons. Understanding signaling in adult neural stem cells and their potential for therapeutic applications are the focus of the Bavarian research network“Adult NeuralStem Cells” (ForNeuroCell)

The research network ForNeuroCell will contribute essentially to the development of a regenerative cell replacement therapy for acute and chronic diseases of the central nervous system on the basis of adult stem cells. During the past years, it has become increasingly evident that next to neuroprotection, meaning the strategy of protecting damaged cells from dying off, the regenerative cell replacement therapy is the treatment approach with the greatest potential for the most common afflictions of the brain (trauma, cerebral ischemia, neurodegenerative diseases).
There are two complementary strategies for the therapeutic application of adult stem cells
a) Increase and modulation of endogenous neurogenesis
b) transplantation of ex vivo generated neural and/or glial precursors cells

ForNeuroCell aims by advancing basic research and biotechnological development for adult stem cells of the nervous system to achieve regeneration of neural cells and reconstitution of the damaged central nervous system by
(1) identification of signalling pathways in maintenance and differentiation of adult neural stem cells
(2) targeted programming or reprogramming of stem cells
(3) preclinical testing in lesion models
(4) development of imaging techniques for the detection of endogenous as well as transplanted stem cells in the living organism
(5) transfer of stem cell technology to human cells.

Network:

ForNeuroCell represents a network of 10 research groups based
at

the Friedrich Alexander University of Erlangen-Nürnberg,

the Ludwig-Maximilians University Munich,

the Technical University of Munich,

the University of Regensburg,

the Julius Maximilians University of Würzburg and

the Hemholtz Center Munich.

This consortium is highly suitable for working on the challenging
questions as the following technological resources are well
established there:

a) state-of-the-art molecular biology

b) innovative cell biology

c) pre-clinical animal models for acute and chronic CNS
disorders

d) cutting edge imaging technology

• Flyer FORNEUROCELL II

Organisation

Partner

Projects

• Identification of signalling pathways in maintenance and differentiation of adult neural stem cells
  • Identification of signalling pathways regulating adult neural stem cell maintenance
  • The Role of Brain-derived Neurotrophic Factor Signaling for Differentiation and Maintenance of Neural Stem Cells and Newborn Neurons in the Hippocampus
• Development of imaging techniques for the detection of endogenous as well as transplanted stem cells in the living organism
  • Non-invasive detection of functional integration of optically-controlled stem cells by (f)MRI in vivo
  • Watch me if you can: Optical and MRS imaging of neurogenesis in the adult brain
• Preclinical testing in lesion models
  • Long-term in vivo imaging of the integration, the maturation and the survival of adult-born neurons in the olfactory bulb of transgenic animal models of Alzheimer’s disease
  • Characterization of adult neural progenitor cells inthe striatum in models of Parkinson's disease
  • Differentiation of adult human astroglia into functional neurons
  • Watch me if you can: Optical and MRS imaging of neurogenesis in the adult brain
• Targeted programming or reprogramming of stem cells
  • Characterization of adult neural progenitor cells inthe striatum in models of Parkinson's disease
  • Impact of Sox proteins on adult oligodendrogenesis in the normal and lesioned spinal cord
  • Differentiation of adult human astroglia into functional neurons
  • Functional characterization od adult human hippocampal stem cells and their targeted differentiation into dopaminergic neurons
  • Canonical Wnt-signalling in dopaminergic differentiation in vivo and in vitro
• Transfer of stem cell technology to human cells
  • Characterization of adult neural progenitor cells inthe striatum in models of Parkinson's disease
  • Differentiation of adult human astroglia into functional neurons
  • Functional characterization od adult human hippocampal stem cells and their targeted differentiation into dopaminergic neurons
  • Canonical Wnt-signalling in dopaminergic differentiation in vivo and in vitro

News

Contact

Dr. Rosi Lederer
Institute of Physiological Genomics
Pettenkoferstr.12
80336 Munich
phone  +49 89 2180 75258
            +49 89 3187 3864
Fax      +49 89 2180 75216
<link>rosi.lederer@med.uni-muenchen.de
<link>forneurocell@uk-erlangen.de <link>