Abstract
Astrocytes and neurons express several large pore (hemi)channels that may open in response to various stimuli, allowing fluorescent dyes, ions, and cytoplasmic molecules such as ATP and glutamate to permeate. Several of these large pore (hemi)channels have similar characteristics with regard to activation, permeability, and inhibitor sensitivity. Consequently, their behaviors and roles in astrocytic and neuronal (patho)physiology remain undefined. We took advantage of the Xenopus laevis expression system to determine the individual characteristics of several large pore channels in isolation. Expression of connexins Cx26, Cx30, Cx36, or Cx43, the pannexins Px1 or Px2, or the purinergic receptor P2X7 yielded functional (hemi)channels with isoform-specific characteristics. Connexin hemichannels had distinct sensitivity to alterations of extracellular Ca(2+) and their permeability to dyes and small atomic ions (conductance) were not proportional. Px1 and Px2 exhibited conductance at positive membrane potentials, but only Px1 displayed detectable fluorescent dye uptake. P2X7, in the absence of Px1, was permeable to fluorescent dyes in an agonist-dependent manner. The large pore channels displayed overlapping sensitivity to the inhibitors Brilliant Blue, gadolinium, and carbenoxolone. These results demonstrated isoform-specific characteristics among the large pore membrane channels; an open (hemi)channel is not a nonselective channel. With these isoform-specific properties in mind, we characterized the divalent cation-sensitive permeation pathway in primary cultured astrocytes. We observed no activation of membrane conductance or Cx43-mediated dye uptake in astrocytes nor in Cx43-expressing C6 cells. Our data underscore that although Cx43-mediated transport is observed in overexpressing cell systems, such transport may not be detectable in native cells under comparable experimental conditions.
Highlights
The permeability and physiological role of several large porechannels are unresolved
Dye Permeability and Conductance of Connexin-expressing Oocytes—To determine the isoform-specific permeability characteristics of connexins Cx26, Cx30, Cx36, and Cx43, these constructs were expressed in X. laevis oocytes
In control solution containing divalent cations (1 mM of each), the ethidium uptake observed in Cx26- and Cx30-expressing oocytes was not significantly different from that of the uninjected oocytes (Fig. 1a, white bars), indicating no basal hemichannel activity by these connexin isoforms
Summary
The permeability and physiological role of several large pore (hemi)channels are unresolved. Astrocytes and neurons express several large pore (hemi)channels that may open in response to various stimuli, allowing fluorescent dyes, ions, and cytoplasmic molecules such as ATP and glutamate to permeate Several of these large pore (hemi)channels have similar characteristics with regard to activation, permeability, and inhibitor sensitivity. Interpretation of the findings is complicated by many uncontrolled factors, including protein-protein interactions, alternative splice variants, altered transcriptomes, and/or altered basal ATP concentrations, among others [9, 21,22,23,24], rendering the exact contribution of the different (hemi)channels to dye uptake, ion conductance, and ATP/glutamate release unresolved Several of these large pore channels serve as dye/ ATP conduits as well as ion channels, some channels exhibit a noticeable disconnect between the ability to pass dyes/ATP and current; dye uptake and ATP/glutamate/cAMP permeability can be detected at physiologically relevant membrane potentials in the negative range [4, 9, 27,28,29], membrane conductance for Px1 and Cx43 appears predominantly at positive membrane potentials [1, 4, 9, 25]. We employed primary cultured astrocytes and Cx43-expressing C6 cells to determine the quantitative contribution of Cx43 hemichannels in divalent cation-free solution (DCFS)2-induced dye uptake and membrane conductance in a physiologically relevant setting
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