Potassium Channels and Neurovascular Coupling

Dunn, Kathryn M.; Nelson, Mark T.

doi:10.1253/circj.cj-10-0174

Cited by 72 publications

(65 citation statements)

References 131 publications

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“…In brain slices from healthy animals, elevation of endfoot Ca 2+ to <550 nM activates BK channels, increasing perivascular K + to cause vasodilation (19,33). Moderate levels of extracellular K + (<20 mM) cause arteriolar dilation through membrane potential hyperpolarization caused by activation of smooth muscle inward rectifier K + (Kir) channels (19,33,34). Notably, however, levels of extracellular K + greater than ∼20 mM cause arteriolar constriction as the result of a depolarizing shift in the K + equilibrium potential and activation of voltage-dependent Ca 2+ channels.…”

Section: Resultsmentioning

confidence: 99%

“…The peak increase in Ca 2+ during these spontaneous oscillations was ∼490 nM in brain slices from SAH animals, or ∼170 nM higher than spontaneous events in brain slices of control animals and ∼90 nM greater than EFS-evoked increases in endfoot Ca 2+ in either group. Considering that EFS-induced increases in endfoot Ca 2+ have been shown to increase K + efflux through BK channels (19,21,33), it is reasonable to suppose that these high-amplitude spontaneous events occurring after SAH enhance BK-channel activity to increase basal [K + ] o in the perivascular space between astrocyte endfeet and parenchymal arteriolar myocytes. The narrow gap between astrocyte endfeet and arteriolar smooth muscle membrane prohibits the accurate use of K + -sensing electrodes or dyes to measure [K + ] o directly in this restricted perivascular space.…”

Section: Discussionmentioning

confidence: 99%

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Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca ²⁺ -activated K ⁺ (BK) channels

Koide

Bonev

Nelson

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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101

108

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The cellular events that cause ischemic neurological damage following aneurysmal subarachnoid hemorrhage (SAH) have remained elusive. We report that subarachnoid blood profoundly impacts communication within the neurovascular unit-neurons, astrocytes, and arterioles-causing inversion of neurovascular coupling. Elevation of astrocytic endfoot Ca 2+ to ∼400 nM by neuronal stimulation or to ∼300 nM by Ca 2+ uncaging dilated parenchymal arterioles in control brain slices but caused vasoconstriction in post-SAH brain slices. Inhibition of K + efflux via astrocytic endfoot large-conductance Ca 2+ -activated K + (BK) channels prevented both neurally evoked vasodilation (control) and vasoconstriction (SAH

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca ²⁺ -activated K ⁺ (BK) channels

Koide

Bonev

Nelson

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

101

108

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“…In response to synaptically released glutamate, mGluR activation, putatively in astrocytes, mediates NVC via release of vasodilatory compounds. 1,4 Thus, as an indirect measure of astrocytic contributions to NVC, 14,15 we measured PA luminal diameter changes after mGluR activation with the agonist t-ACPD (100 μmol/L). Figure 6A shows representative traces of t-ACPD-induced dilations.…”

Section: Metabotropic Glutamate Receptor-induced Parenchymal Arteriolmentioning

confidence: 99%

Enhanced Parenchymal Arteriole Tone and Astrocyte Signaling Protect Neurovascular Coupling Mediated Parenchymal Arteriole Vasodilation in the Spontaneously Hypertensive Rat

Iddings

Kim

Zhou

et al. 2015

J Cereb Blood Flow Metab

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Functional hyperemia is the regional increase in cerebral blood flow upon increases in neuronal activity which ensures that the metabolic demands of the neurons are met. Hypertension is known to impair the hyperemic response; however, the neurovascular coupling mechanisms by which this cerebrovascular dysfunction occurs have yet to be fully elucidated. To determine whether altered cortical parenchymal arteriole function or astrocyte signaling contribute to blunted neurovascular coupling in hypertension, we measured parenchymal arteriole reactivity and vascular smooth muscle cell Ca 2+ dynamics in cortical brain slices from normotensive Wistar Kyoto (WKY) and spontaneously hypertensive (SHR) rats. We found that vasoconstriction in response to the thromboxane A 2 receptor agonist U46619 and basal vascular smooth muscle cell Ca 2+ oscillation frequency were significantly increased in parenchymal arterioles from SHR. In perfused and pressurized parenchymal arterioles, myogenic tone was significantly increased in SHR. Although K + -induced parenchymal arteriole dilations were similar in WKY and SHR, metabotropic glutamate receptor activation-induced parenchymal arteriole dilations were enhanced in SHR. Further, neuronal stimulation-evoked parenchymal arteriole dilations were similar in SHR and WKY. Our data indicate that neurovascular coupling is not impaired in SHR, at least at the level of the parenchymal arterioles. Keywords: astrocytes; brain slice; cerebral blood flow; hypertension; neurovascular coupling; parenchymal arterioles INTRODUCTION Functional hyperemia (FH), the process in which neuronal activation triggers local increases in cerebral blood flow (CBF), is of particular importance for cerebral homeostasis as it ensures that neuronal metabolic demands are met. 1 Despite recent controversy, 2,3 numerous in vitro and in vivo studies suggest that astrocytes act as intermediaries in the neurovascular coupling (NVC)-mediated vascular responses that govern the hyperemic response. Although NVC-mediated signaling can elicit both vasodilation and vasoconstriction, the focus of this study is to address NVC-mediated vasodilatory responses. During the orchestrated signaling among neurons, astrocytes, and the cerebral vasculature that occurs during NVC-mediated vasodilation, synaptically released glutamate binds to astrocytic metabotropic glutamate receptors (mGluR) increasing intracellular Ca 2+ , 1,4 which, in turn, results in the release of vasoactive signals such as arachidonic acid (AA) metabolites 4 and K + . 5 Although FH is impaired in hypertensive patients and animal models of hypertension, 6-9 the mechanisms by which hypertension disrupts NVC among cells in the neurovascular unit is not fully understood. A few elegantly designed studies, primarily evaluating pial arteriole function, have used regional CBF measurements to deliver valuable insight into the vascular mechanisms underlying NVC disruptions during acute, short-term Angiotensin II-induced hypertension 6,9 and chronic hypertension. 8 However,

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“…Recent evidence suggests that astrocytes play a significant role in the regulation of local CBF. 73, 74 Astrocytes grown in high glucose show increased oxidative stress. Prolonged hyperglycemia interferes with astrocytic gap junctional communication.…”

Section: Neurovascular Coupling Disorder In Diabetesmentioning

confidence: 99%

Neurovascular Coupling in Cognitive Impairment Associated With Diabetes Mellitus

Mogi

Horiuchi

2011

Circ J

109

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Although it is feared that diabetes-induced cognitive decline will become a major clinical problem worldwide in the future, the detailed pathological mechanism is not well known. Because patients with diabetes have various complications of vascular disease, with not only macrovascular but also microvascular disorders, vascular disorders in the brain are considered to be one of the mechanisms in diabetes-induced cognitive impairment. Indeed, disruption of the blood - brain barrier (BBB) has been observed in some diabetic patients and experimental diabetes models. Moreover, white matter lesions, part of the evidence of BBB dysfunction, are reported to be observed more frequently in patients with diabetes. Animal studies demonstrate that diabetes enhances BBB permeability through a decrease in the level of tight junction proteins and an increase in matrix metalloproteinase activity. However, there are several reports indicating that BBB disruption does not occur with diabetes. Therefore, the association of BBB breakdown with diabetes-induced cognitive impairment is not conclusive. Recently, neuronal diseases involving dementia have been induced experimentally through dysfunction of neurovascular coupling, which involves blood vessels, astrocytes and neutrons. Diabetes-induced cognitive decline may be induced via disruption of neurovascular coupling, with not only vascular disorder but also impairment of astrocytic trafficking. Here, the relation between vascular disorder and cognitive impairment in diabetes is discussed. (Circ J 2011; 75: 1042 - 1048

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Potassium Channels and Neurovascular Coupling

Cited by 72 publications

References 131 publications

Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca ²⁺ -activated K ⁺ (BK) channels

Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca ²⁺ -activated K ⁺ (BK) channels

Enhanced Parenchymal Arteriole Tone and Astrocyte Signaling Protect Neurovascular Coupling Mediated Parenchymal Arteriole Vasodilation in the Spontaneously Hypertensive Rat

Neurovascular Coupling in Cognitive Impairment Associated With Diabetes Mellitus

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Potassium Channels and Neurovascular Coupling

Cited by 72 publications

References 131 publications

Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca 2+ -activated K + (BK) channels

Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca 2+ -activated K + (BK) channels

Enhanced Parenchymal Arteriole Tone and Astrocyte Signaling Protect Neurovascular Coupling Mediated Parenchymal Arteriole Vasodilation in the Spontaneously Hypertensive Rat

Neurovascular Coupling in Cognitive Impairment Associated With Diabetes Mellitus

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Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca ²⁺ -activated K ⁺ (BK) channels

Inversion of neurovascular coupling by subarachnoid blood depends on large-conductance Ca ²⁺ -activated K ⁺ (BK) channels