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Extent of intercellular calcium wave propagation is related to gap junction permeability and level of connexin-43 expression in astrocytes in primary cultures from four brain regions.

Journal article
Authors Fredrik Blomstrand
N David Åberg
Peter S Eriksson
Elisabeth Hansson
Lars Rönnbäck
Published in Neuroscience
Volume 92
Issue 1
Pages 255-65
ISSN 0306-4522
Publication year 1999
Published at Institute of Clinical Neurosciences
Institute of Clinical Neurosciences, Section of Experimental Neuroscience
Pages 255-65
Language en
Links www.ncbi.nlm.nih.gov/entrez/query.f...
Keywords Animals, Astrocytes, drug effects, metabolism, Brain, cytology, drug effects, metabolism, Calcium, metabolism, Cells, Cultured, Coloring Agents, pharmacokinetics, Connexin 43, genetics, metabolism, Extracellular Space, metabolism, Gap Junctions, metabolism, Glutamic Acid, pharmacology, Immunohistochemistry, Permeability, RNA, Messenger, metabolism, Rats, Rats, Sprague-Dawley, Serotonin, pharmacology
Subject categories Medical and Health Sciences, Experimental brain research, Neurobiology, Neurology

Abstract

Astrocytes are coupled via gap junctions, predominantly formed by connexin-43 proteins, into cellular networks. This coupling is important for the propagation of intercellular calcium waves and for the spatial buffering of K+. Using the scrape-loading/dye transfer technique, we studied gap junction permeability in rat astrocytes cultured from four different brain regions. The cultures were shown to display regional heterogeneity with the following ranking of the gap junction coupling strengths: hippocampus = hypothalamus > cerebral cortex = brain stem. Similar relative patterns were found in connexin-43 messenger RNA and protein levels using solution hybridization/RNase protection assay and western blots, respectively. The percentages of the propagation area of mechanically induced intercellular calcium waves for cortical, brain stem and hypothalamic astrocytes compared with hippocampal astrocytes were approximately 77, 42, and 52, respectively. Thus, the extent of calcium wave propagation was due to more than just gap junctional permeability as highly coupled hypothalamic astrocytes displayed relatively small calcium wave propagation areas. Incubation with 5-hydroxytryptamine decreased and incubation with glutamate increased the calcium wave propagation area in hippocampal (67% and 170% of the control, respectively) and in cortical astrocytes (82% and 163% of the control, respectively). Contrary to hippocampal and cortical astrocytes, the calcium wave propagation in brain stem astrocytes was increased by 5-hydroxytryptamine incubation (158% of control), while in hypothalamic astrocytes, no significant effects were seen. Similar effects from 5-hydroxytryptamine or glutamate treatments were observed on dye transfer, indicating an effect on the junctional coupling strength. These results demonstrate a strong relationship between connexin-43 messenger RNA levels, protein expression, and gap junction permeability among astroglial cells. Furthermore, our results suggest heterogeneity among astroglial cells from different brain regions in intercellular calcium signaling and in its differential modulation by neurotransmitters, probably reflecting functional requirements in various brain regions.

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