2000
DOI: 10.1002/1098-1136(200012)32:3<205::aid-glia10>3.0.co;2-6
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Developmental downregulation of ATP-sensitive potassium conductance in astrocytes in situ

Abstract: In many neural and non‐neural cells, ATP‐sensitive potassium (KATP) channels couple the membrane potential to energy metabolism. We investigated the activation of KATP currents in astrocytes of different brain regions (hippocampus, cerebellum, dorsal vagal nucleus) by recording whole‐cell currents with the patch‐clamp technique in acute rat brain slices. Pharmacological tools, hypoglycemia and specific compounds in the pipette solution (cAMP, UDP), were used to modulate putative KATP currents. The highest rate… Show more

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Cited by 19 publications
(11 citation statements)
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“…The reasons for these discrepancies are unclear, but they may indicate heterogeneity of glial Kir6.0 channel expression, similar to that found for Kir2.0 and Kir4.1 channel subtypes (see above), and electrophysiological studies have shown heterogeneity in the expression of functional K ATP channels in astrocytes in the dorsal vagal nucleus, cerebellum and hippocampus [71,75,76]. Due to the ATP-sensitivity of Kir6.0, they are only active when intracellular concentrations of ATP fall to very low levels and therefore serve to maintain the high K + conductance and hyperpolarized RMP in glia during metabolic challenge [68,69,76]. Furthermore, immunoreactivity for astroglial Kir6.1 in the cerebellum is localized to astrocyte processes surrounding synapses, and mirrors that of neuronal Kir6.2, suggesting glial and neuronal K ATP channels may act in synergy during metabolic challenges in the brain [74].…”
Section: Glial Kirmentioning
confidence: 82%
See 1 more Smart Citation
“…The reasons for these discrepancies are unclear, but they may indicate heterogeneity of glial Kir6.0 channel expression, similar to that found for Kir2.0 and Kir4.1 channel subtypes (see above), and electrophysiological studies have shown heterogeneity in the expression of functional K ATP channels in astrocytes in the dorsal vagal nucleus, cerebellum and hippocampus [71,75,76]. Due to the ATP-sensitivity of Kir6.0, they are only active when intracellular concentrations of ATP fall to very low levels and therefore serve to maintain the high K + conductance and hyperpolarized RMP in glia during metabolic challenge [68,69,76]. Furthermore, immunoreactivity for astroglial Kir6.1 in the cerebellum is localized to astrocyte processes surrounding synapses, and mirrors that of neuronal Kir6.2, suggesting glial and neuronal K ATP channels may act in synergy during metabolic challenges in the brain [74].…”
Section: Glial Kirmentioning
confidence: 82%
“…However, in other studies, no expression of Kir6.2 mRNA was found in astrocytes or oligodendrocytes [73], and immunoreactivity for only Kir6.1 and not Kir6.2 subunits was found in hippocampal, cortical and cerebellar astrocytes and cerebellar Bergmann glia [74]. The reasons for these discrepancies are unclear, but they may indicate heterogeneity of glial Kir6.0 channel expression, similar to that found for Kir2.0 and Kir4.1 channel subtypes (see above), and electrophysiological studies have shown heterogeneity in the expression of functional K ATP channels in astrocytes in the dorsal vagal nucleus, cerebellum and hippocampus [71,75,76]. Due to the ATP-sensitivity of Kir6.0, they are only active when intracellular concentrations of ATP fall to very low levels and therefore serve to maintain the high K + conductance and hyperpolarized RMP in glia during metabolic challenge [68,69,76].…”
Section: Glial Kirmentioning
confidence: 96%
“…As Purkinje cells of the isolated turtle cerebellum also do not hyperpolarize during anoxia (43), the mechanism by which K ATP channels modulate DA homeostasis is not likely to be via cellular hyperpolarization; however, an alternative method is yet unknown. Research has suggested that K ATP channels may be modulated by a variety of signaling pathways, including neurotransmitter release, H 2 O 2 , and cAMP levels (3,7); it is quite possible then that K ATP channels, in turn, can act through second messenger systems directly, without cellular hyperpolarization. The turtle may provide an interesting model to investigate such mechanisms, as in the mammal, the opening of K ATP channels is invariably associated with hyperpolarization, and the possibility of more direct effects has not been examined.…”
Section: Discussionmentioning
confidence: 99%
“…Moreover, in the nervous system, K ATP channel activation is involved in the control of neuronal excitability [16][18] and seizure propagation [14], [19][24]. Given the importance of astrocytes on brain function [25] and the enrichment of K ATP channel in glial cells, K ATP channels might be responsible for some critical activities of astrocytes or at least play a role in them [26][28]. More recently, it has been revealed that activation of astrocytic K ATP channels, particularly the mitochondrial K ATP (mitoK ATP ) channels, affects glutamate uptake and astrocytic activation [29][32].…”
Section: Introductionmentioning
confidence: 99%