Abstract
Retinal Müller cells are highly polarized macroglial cells with accumulation of the aquaporin-4 (AQP4) water channel and the inwardly rectifying potassium channel Kir4.1 at specialized endfoot membrane domains abutting microvessels and corpus vitreum. Proper water and potassium homeostasis in retina depends on these membrane specializations. Here we show that targeted deletion of β1-syntrophin leads to a partial loss of AQP4 from perivascular Müller cell endfeet and that a concomitant deletion of both α1- and β1-syntrophin causes a near complete loss of AQP4 from both perivascular and subvitreal endfoot membranes. α1-syntrophin is normally very weakly expressed in Müller cell endfeet but β1-syntrophin knockout mice display an increased amount of α1-syntrophin at these sites. We suggest that upregulation of perivascular α1-syntrophin restricts the effect of β1-syntrophin deletion. The present findings indicate that β1-syntrophin plays an important role in maintaining the functional polarity of Müller cells and that α1-syntrophin can partially substitute for β1-syntrophin in AQP4 anchoring. Functional polarization of Müller cells thus depends on an interplay between two syntrophin isoforms.
Highlights
Macroglia are polarized cells whose functions are governed by distinct membrane domains that are specialized in terms of their structure, function and molecular composition [1,2,3,4]
The present study shows that β1-syn is the most important anchor of AQP4 in Müller cell processes but that α1-syn may partly substitute as anchor if β1-syn is lost
Müller cells are the archetypical class of macroglia for studies of homeostatic processes in the central nervous system
Summary
Macroglia are polarized cells whose functions are governed by distinct membrane domains that are specialized in terms of their structure, function and molecular composition [1,2,3,4]. Studies on Müller cells revealed a strikingly uneven distribution of K+ conductance along the plasma membrane, with high conductance in membrane domains facing vessels and corpus vitreum [5,6,7,8,9,10,11,12]. This finding laid the Immunoelectron microscopy revealed a loss of AQP4 from glial endfoot membranes in hippocampal specimens obtained from patients with mesial temporal lobe. This begs the question of how macroglial polarization is established and maintained
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