Abstract
Although gap junctions are widely expressed in the developing central nervous system, the role of electrical coupling of neurons and glial cells via gap junctions in the spinal cord in adults is largely unknown. We investigated whether gap junctions are expressed in the mature spinal cord of the mudpuppy and tested the effects of applying gap junction blocker on the walking-like activity induced by NMDA or glutamate in an in vitro mudpuppy preparation. We found that glial and neural cells in the mudpuppy spinal cord expressed different types of connexins that include connexin 32 (Cx32), connexin 36 (Cx36), connexin 37 (Cx37), and connexin 43 (Cx43). Application of a battery of gap junction blockers from three different structural classes (carbenexolone, flufenamic acid, and long chain alcohols) substantially and consistently altered the locomotor-like activity in a dose-dependent manner. In contrast, these blockers did not significantly change the amplitude of the dorsal root reflex, indicating that gap junction blockers did not inhibit neuronal excitability nonselectively in the spinal cord. Taken together, these results suggest that gap junctions play a significant modulatory role in the spinal neural networks responsible for the generation of walking-like activity in the adult mudpuppy.
Highlights
Gap junctions are specific structures that link the cytoplasm of adjoining cells and enable direct electrical communications between them
Are gap junction proteins expressed in the spinal cord of the adult mudpuppy? If they are expressed, do they contribute to the neural networks for walking? Using immunohistochemistry, we demonstrated that several connexins were expressed in the adult mudpuppy spinal cord
Immunohistochemistry of gap junctions in the adult mudpuppy spinal cord Sections of the spinal cord were incubated with antisera directed against four different gap junctions’ proteins, connexin 32 (Cx32), connexin (Cx36), connexin (Cx37), and connexin 43 (Cx43)
Summary
Gap junctions are specific structures that link the cytoplasm of adjoining cells and enable direct electrical communications between them. Electrical coupling tends to synchronize spontaneous activities in different brain regions including the neocortex [6, 7], cortex [5, 8], brainstem [9], embryonic retina [10], and the spinal cord [11,12]. Their roles in development have been extensively studied, much less is known about their function in adult spinal cord [13].
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