Membrane potentials and microenvironment of rat dorsal vagal cells in vitro during energy depletion.

Ballanyi, Klaus; Doutheil, Jens; Brockhaus, Johannes

doi:10.1113/jphysiol.1996.sp021632

Cited by 65 publications

(67 citation statements)

References 35 publications

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“…This is certainly not due to the fact that the cells were whole-cell recorded with patch-electrodes containing 1-2·mmol·l -1 ATP. A similar lack of occurrence of a terminal depolarisation or massive Cai increase is observed when the dorsal vagal neurons are recorded with sharp microelectrodes (Cowan and Martin, 1992;Ballanyi et al, 1996a) or optically in a non-invasive manner using a membrane-permeable form of fura-2 . According to these results, it is proposed that the tolerance to anoxia of these mammalian neurons is rather due to a low resting metabolic rate in conjunction with effective utilisation of anaerobic metabolism (Ballanyi et al, 1996a;Trapp et al, 1996;Ballanyi and Kulik, 1998).…”

Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 82%

“…Interestingly, these cells are particularly resistant to oxygen depletion, at least in rats. They respond to hypoxic solutions resulting in anoxia of the dorsal vagal nucleus (Ballanyi et al, 1996a) with a sustained K + channel-mediated hyperpolarisation ( Fig.·2A; Cowan and Martin, 1992;Trapp and Ballanyi, 1995). Neither hypoxic anoxia nor chemical block of aerobic metabolism with K. Ballanyi Fig.·1.…”

Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 99%

“…Subpopulations of mammalian neurons (Ballanyi et al, 1996a;Richter and Ballanyi, 1996) are highly tolerant to anoxia in a fashion similar to brain structures of some coldblooded vertebrates (Lutz and Nilsson, 1994;Hochachka and Lutz, 2001). By elucidating the mechanisms of the anoxia tolerance of these mammalian neurons, it may be possible to develop pharmacological strategies to protect the brain from the consequences of hypoxic-anoxic insults.…”

Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 99%

“…Brain section taken from Paxinos (1982 Trapp and Ballanyi, 1995;Ballanyi and Kulik, 1998). By contrast, a progressive depolarisation due to extracellular accumulation of glutamate is revealed in slices of dorsal vagal neurons preincubated in glucosefree superfusate and subsequently exposed to hypoxic or chemical anoxia in the absence of glucose, mimicking ischemia in vitro (Ballanyi et al, 1996a;Kulik et al, 2000). The anoxic hyperpolarisation and the underlying outward current and increase in membrane conductance of the dorsal vagal neurons are blocked by the sulfonylurea KATP channel blockers tolbutamide, glibenclamide and gliquidone (Figs·2A,·3A).…”

Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 99%

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Protective role of neuronal KATP channels in brain hypoxia

Ballanyi

2004

Journal of Experimental Biology

129

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SUMMARY During severe arterial hypoxia leading to brain anoxia, most mammalian neurons undergo a massive depolarisation terminating in cell death. However,some neurons of the adult brain and most immature nervous structures tolerate extended periods of hypoxia–anoxia. An understanding of the mechanisms underlying this tolerance to oxygen depletion is pivotal for developing strategies to protect the brain from consequences of hypoxic-ischemic insults. ATP-sensitive K+ (KATP) channels are good subjects for this study as they are activated by processes associated with energy deprivation and can counteract the terminal anoxic-ischemic neuronal depolarisation. This review summarises in vitro analyses on the role of KATP channels in hypoxia–anoxia in three distinct neuronal systems of rodents. In dorsal vagal neurons, blockade of KATPchannels with sulfonylureas abolishes the hypoxic-anoxic hyperpolarisation. However, this does not affect the extreme tolerance of these neurons to oxygen depletion as evidenced by a moderate and sustained increase of intracellular Ca2+ (Cai). By contrast, a sulfonylurea-induced block of KATP channels shortens the delay of occurrence of a major Cai rise in cerebellar Purkinje neurons. In neurons of the neonatal medullary respiratory network, KATP channel blockers reverse the anoxic hyperpolarisation associated with slowing of respiratory frequency. This may constitute an adaptive mechanism for energy preservation. These studies demonstrate that KATP channels are an ubiquituous feature of mammalian neurons and may, indeed, play a protective role in brain hypoxia.

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Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 82%

Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 99%

Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 99%

Section: Katp Channels In Anoxia-tolerant Dorsal Vagal Neuronsmentioning

confidence: 99%

See 2 more Smart Citations

Protective role of neuronal KATP channels in brain hypoxia

Ballanyi

2004

Journal of Experimental Biology

129

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“…In hippocampal slices, hypoxia induces a significant drop in both pH i and pH o , and a brief alkaline peak is also occasionally observed (Fujiwara et al, 1992;Melzian et al, 1996;Roberts & Chih, 1997). In slice preparations from various brain regions, hypoxia causes acidosis with an approximately 0.8-1.2 pH i unit drop (Ballanyi et al, 1996;Knopfel et al, 1998;Pirttila & Kauppinen, 1994). Cytosolic calcium changes are observed during ischemia in cortical brain slices that can be only partially inhibited by combined blockade of ion channels (Bickler and Hansen, 1994).…”

Section: Brain Slicementioning

confidence: 99%

The Na+/H+ Exchanger-1 as a New Molecular Target in Stroke Interventions

Chanana¹,

Sun²,

Ferrazzano³

2012

Advances in the Preclinical Study of Ischemic Stroke

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Developmental downregulation of ATP-sensitive potassium conductance in astrocytes in situ

Brockhaus

Deitmer

2000

Glia

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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 of KATP specific currents was observed with a pipette solution containing cAMP and external stimulation with diazoxide (0.3 mM). The diazoxide‐activated current had a reversal potential negative to −80 mV and was inhibited by tolbutamide (0.2 mM). We found that not all cells activated a KATP current, and that the portion of cells with functional KATP channel expression was developmentally downregulated. Whereas diazoxide activated KATP currents in 57% of the astrocytes in rats aged 8–11 days (n = 21), the rate decreased to 38% at 12–15 days (n = 29) and to 8% at 16–19 days (n = 12). No significant difference was observed for the three brain regions. In recordings without cAMP in the internal solution, only 21% (12–15 days; n = 19) or none (16–19 days; n = 7), respectively, showed a potassium current upon diazoxide application. This metabolically regulated potassium conductance may be of importance, particularly in immature astrocytes with a complex current pattern, which have a relatively high input resistance: KATP currents activated by energy depletion may hyperpolarize the cells, or stabilize a negative resting potential during depolarizing stimuli mediated, e.g., by glutamate receptors and/or uptake carriers. GLIA 32:205–213, 2000. © 2000 Wiley‐Liss, Inc.

show abstract

Membrane potentials and microenvironment of rat dorsal vagal cells in vitro during energy depletion.

Cited by 65 publications

References 35 publications

Protective role of neuronal KATP channels in brain hypoxia

Protective role of neuronal KATP channels in brain hypoxia

The Na+/H+ Exchanger-1 as a New Molecular Target in Stroke Interventions

Developmental downregulation of ATP-sensitive potassium conductance in astrocytes in situ

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