The glia doctrine: Addressing the role of glial cells in healthy brain ageing

•Glial cells impact on brain structure and function.•Astrocytes are key players in ageing and neurological disease.•Exosomes from glial and bacterial cells facilitate intercellular communication.•Physical exercise can curb age-related brain deterioration.•Links between astrocytes and cognition can b...

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Bibliographic Details
Published in:Mechanisms of ageing and development 2013-10, Vol.134 (10), p.449-459
Main Authors: Nagelhus, Erlend A., Amiry-Moghaddam, Mahmood, Bergersen, Linda H., Bjaalie, Jan G., Eriksson, Jens, Gundersen, Vidar, Leergaard, Trygve B., Morth, J. Preben, Storm-Mathisen, Jon, Torp, Reidun, Walhovd, Kristine B., Tønjum, Tone
Format: Article
Language:English
Subjects:
Ageing
Aging - metabolism
Aging - pathology
Alzheimer's disease
Astrocytes
Astrocytes - metabolism
Astrocytes - pathology
Brain - metabolism
Brain - pathology
Brain Diseases - metabolism
Brain Diseases - pathology
Brain imaging
Cell Communication
Exosomes
Exosomes - metabolism
Exosomes - pathology
Glial cells
Humans
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Summary:•Glial cells impact on brain structure and function.•Astrocytes are key players in ageing and neurological disease.•Exosomes from glial and bacterial cells facilitate intercellular communication.•Physical exercise can curb age-related brain deterioration.•Links between astrocytes and cognition can be measured by imaging. Glial cells in their plurality pervade the human brain and impact on brain structure and function. A principal component of the emerging glial doctrine is the hypothesis that astrocytes, the most abundant type of glial cells, trigger major molecular processes leading to brain ageing. Astrocyte biology has been examined using molecular, biochemical and structural methods, as well as 3D brain imaging in live animals and humans. Exosomes are extracelluar membrane vesicles that facilitate communication between glia, and have significant potential for biomarker discovery and drug delivery. Polymorphisms in DNA repair genes may indirectly influence the structure and function of membrane proteins expressed in glial cells and predispose specific cell subgroups to degeneration. Physical exercise may reduce or retard age-related brain deterioration by a mechanism involving neuro-glial processes. It is most likely that additional information about the distribution, structure and function of glial cells will yield novel insight into human brain ageing. Systematic studies of glia and their functions are expected to eventually lead to earlier detection of ageing-related brain dysfunction and to interventions that could delay, reduce or prevent brain dysfunction.
ISSN:0047-6374
1872-6216
DOI:10.1016/j.mad.2013.10.001