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Rune Enger,
Georg Andreas Gundersen,
Nadia Nabil Haj-Yasein,
Martine Eilert-Olsen,
Anna Elisabeth Thoren, Gry Fluge Vindedal,
Pétur Henry Petersen,
Oivind Skare,
Maiken Nedergaard,
Ole Petter Ottersen,
Erlend A Nagelhus
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ABSTRACT: Key roles of macroglia are inextricably coupled to specialized membrane domains. The perivascular endfoot membrane has drawn particular attention, as this domain contains a unique complement of aquaporin-4 (AQP4) and other channel proteins that distinguishes it from perisynaptic membranes. Recent studies indicate that the polarization of macroglia is lost in a number of diseases, including temporal lobe epilepsy and Alzheimer's disease. A better understanding is required of the molecular underpinning of astroglial polarization, particularly when it comes to the significance of the dystrophin associated protein complex (DAPC). Here, we employ immunofluorescence and immunogold cytochemistry to analyze the molecular scaffolding in perivascular endfeet in macroglia of retina and three regions of brain (cortex, dentate gyrus, and cerebellum), using AQP4 as a marker. Compared with brain astrocytes, Müller cells (a class of retinal macroglia) exhibit lower densities of the scaffold proteins dystrophin and α-syntrophin (a DAPC protein), but higher levels of AQP4. In agreement, depletion of dystrophin or α-syntrophin-while causing a dramatic loss of AQP4 from endfoot membranes of brain astrocytes-had only modest or insignificant effect, respectively, on the AQP4 pool in endfoot membranes of Müller cells. In addition, while polarization of brain macroglia was less affected by dystrophin depletion than by targeted deletion of α-syntrophin, the reverse was true for retinal macroglia. These data indicate that the molecular scaffolding in perivascular endfeet is more complex than previously assumed and that macroglia are heterogeneous with respect to the mechanisms that dictate their polarization. © 2012 Wiley Periodicals, Inc.
Glia 09/2012; 60(12):2018-26. · 4.82 Impact Factor
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Martine Eilert-Olsen,
Nadia Nabil Haj-Yasein, Gry Fluge Vindedal,
Rune Enger,
Georg Andreas Gundersen,
Eystein Hellstrøm Hoddevik,
Pétur Henry Petersen,
Finn-Mogens S Haug,
Øivind Skare,
Marvin E Adams,
Stanley C Froehner,
John Michael Burkhardt,
Anna E Thoren,
Erlend A Nagelhus
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ABSTRACT: Expression of the water channel aquaporin-4 (AQP4) at the blood-brain interface is dependent upon the dystrophin associated protein complex. Here we investigated whether deletion of the Aqp4 gene affects the molecular composition of this protein scaffold and the integrity of the blood-brain barrier. High-resolution immunogold cytochemistry revealed that perivascular expression of α-syntrophin was reduced by 60% in Aqp4(-/-) mice. Additionally, perivascular AQP4 expression was reduced by 88% in α-syn(-/-) mice, in accordance with earlier reports. Immunofluorescence showed that Aqp4 deletion also caused a modest reduction in perivascular dystrophin, whereas β-dystroglycan labeling was unaltered. Perivascular microglia were devoid of AQP4 immunoreactivity. Deletion of Aqp4 did not alter the ultrastructure of capillary endothelial cells, the expression of tight junction proteins (claudin-5, occludin, and zonula occludens 1), or the vascular permeability to horseradish peroxidase and Evans blue albumin dye. We conclude that Aqp4 deletion reduces the expression of perivascular glial scaffolding proteins without affecting the endothelial barrier. Our data also indicate that AQP4 and α-syntrophin are mutually dependent upon each other for proper perivascular expression.
Glia 11/2011; 60(3):432-40. · 4.82 Impact Factor
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Nadia Nabil Haj-Yasein, Gry Fluge Vindedal,
Martine Eilert-Olsen,
Georg Andreas Gundersen,
Øivind Skare,
Petter Laake,
Arne Klungland,
Anna Elisabeth Thorén,
John Michael Burkhardt,
Ole Petter Ottersen,
Erlend Arnulf Nagelhus
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ABSTRACT: Tissue- and cell-specific deletion of the Aqp4 gene is required to differentiate between the numerous pools of aquaporin-4 (AQP4) water channels. A glial-conditional Aqp4 knockout mouse line was generated to resolve whether astroglial AQP4 controls water exchange across the blood-brain interface. The conditional knockout was driven by the glial fibrillary acidic protein promoter. Brains from conditional Aqp4 knockouts were devoid of AQP4 as assessed by Western blots, ruling out the presence of a significant endothelial pool of AQP4. In agreement, immunofluorescence analysis of cryostate sections and quantitative immunogold analysis of ultrathin sections revealed no AQP4 signals in capillary endothelia. Compared with litter controls, glial-conditional Aqp4 knockout mice showed a 31% reduction in brain water uptake after systemic hypoosmotic stress and a delayed postnatal resorption of brain water. Deletion of astroglial Aqp4 did not affect the barrier function to macromolecules. Our data suggest that the blood-brain barrier (BBB) is more complex than anticipated. Notably, under certain conditions, the astrocyte covering of brain microvessels is rate limiting to water movement.
Proceedings of the National Academy of Sciences 10/2011; 108(43):17815-20. · 9.68 Impact Factor
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ABSTRACT: Mutations in the human Kir4.1 potassium channel gene (KCNJ10) are associated with epilepsy. Using a mouse model with glia-specific deletion of Kcnj10, we have explored the mechanistic underpinning of the epilepsy phenotype. The gene deletion was shown to delay K(+) clearance after synaptic activation in stratum radiatum of hippocampal slices. The activity-dependent changes in extracellular space volume did not differ between Kcnj10 mutant and wild-type mice, indicating that the Kcnj10 gene product Kir4.1 mediates osmotically neutral K(+) clearance. Combined, our K(+) and extracellular volume recordings indicate that compromised K(+) spatial buffering in brain underlies the epilepsy phenotype associated with human KCNJ10 mutations.
Glia 07/2011; 59(11):1635-42. · 4.82 Impact Factor
