Potent Block of Cx36 and Cx50 Gap Junction Channels by Mefloquine

Recently, great interest has been shown in understanding the functional roles of specific gap junction proteins (connexins) in brain, lens, retina, and elsewhere. Some progress has been made by studying knockout mice with targeted connexin deletions. For example, such studies have implicated the gap...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2004-08, Vol.101 (33), p.12364-12369
Main Authors: Cruikshank, Scott J., Hopperstad, Matthew, Younger, Meg, Connors, Barry W., Spray, David C., Srinivas, Miduturu, Michael V. L. Bennett
Format: Article
Language:English
Subjects:
Animals
Antimalarials
Biological Sciences
Brain
Cell Line
Connexins
Connexins - antagonists & inhibitors
Electric current
Eye Proteins - antagonists & inhibitors
Eyes & eyesight
Gap Junction delta-2 Protein
Gap junctions
Hippocampus - drug effects
Hippocampus - physiology
In Vitro Techniques
Interneurons
Interneurons - drug effects
Interneurons - physiology
Mefloquine - pharmacology
Mice
Neocortex - drug effects
Neocortex - physiology
Neurons
Neuroscience
Pharmacology
Proteins
Rats
Rats, Sprague-Dawley
Recombinant Proteins - antagonists & inhibitors
Reed Sternberg cells
Retina
Roles
Side effects
Synapses
Synaptic Transmission - drug effects
Transfection
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Summary:Recently, great interest has been shown in understanding the functional roles of specific gap junction proteins (connexins) in brain, lens, retina, and elsewhere. Some progress has been made by studying knockout mice with targeted connexin deletions. For example, such studies have implicated the gap junction protein Cx36 in synchronizing rhythmic activity of neurons in several brain regions. Although knockout strategies are informative, they can be problematic, because compensatory changes sometimes occur during development. Therefore, it would be extremely useful to have pharmacological agents that block specific connexins, without major effects on other gap junctions or membrane channels. We show that mefloquine, an antimalarial drug, is one such agent. It blocked Cx36 channels, expressed in transfected N2A neuroblastoma cells, at low concentrations ( IC50≈ 300 nM). Mefloquine also blocked channels formed by the lens gap junction protein, Cx50 ( IC50≈ 1.1 μ M). However, other gap junctions (e.g., Cx43, Cx32, and Cx26) were only affected at concentrations 10- to 100-fold higher. To further examine the utility and specificity of this compound, we characterized its effects in acute brain slices. Mefloquine, at 25 μM, blocked gap junctional coupling between interneurons in neocortical slices, with minimal nonspecific actions. At this concentration, the only major side effect was an increase in spontaneous synaptic activity. Mefloquine (25 μM) caused no significant change in evoked excitatory or inhibitory postsynaptic potentials, and intrinsic cellular properties were also mostly unaffected. Thus, mefloquine is expected to be a useful tool to study the functional roles of Cx36 and Cx50.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.0402044101