Low pHo boosts burst firing and catecholamine release by blocking TASK‐1 and BK channels while preserving Cav1 channels in mouse chromaffin cells

Key points Mouse chromaffin cells (MCCs) generate spontaneous burst‐firing that causes large increases of Ca2+‐dependent catecholamine release, and is thus a key mechanism for regulating the functions of MCCs. With the aim to uncover a physiological role for burst‐firing we investigated the effects...

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Bibliographic Details
Published in:The Journal of physiology 2017-04, Vol.595 (8), p.2587-2609
Main Authors: Guarina, Laura, Vandael, David H. F., Carabelli, Valentina, Carbone, Emilio
Format: Article
Language:English
Subjects:
BK channels
Burst firing
Catecholamines
Cellular and Molecular Neuroscience
Cellular and Molecular Physiology
chromaffin cells
L‐type Cav1 channels
Neuroscience ‐ Cellular/Molecular
Research Paper
secretion
TASK‐1 channels
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Summary:Key points Mouse chromaffin cells (MCCs) generate spontaneous burst‐firing that causes large increases of Ca2+‐dependent catecholamine release, and is thus a key mechanism for regulating the functions of MCCs. With the aim to uncover a physiological role for burst‐firing we investigated the effects of acidosis on MCC activity. Lowering the extracellular pH (pHo) from 7.4 to 6.6 induces cell depolarizations of 10–15 mV that generate bursts of ∼330 ms at 1–2 Hz and a 7.4‐fold increase of cumulative catecholamine‐release. Burst‐firing originates from the inhibition of the pH‐sensitive TASK‐1‐channels and a 60% reduction of BK‐channel conductance at pHo 6.6. Blockers of the two channels (A1899 and paxilline) mimic the effects of pHo 6.6, and this is reverted by the Cav1 channel blocker nifedipine. MCCs act as pH‐sensors. At low pHo, they depolarize, undergo burst‐firing and increase catecholamine‐secretion, generating an effective physiological response that may compensate for the acute acidosis and hyperkalaemia generated during heavy exercise and muscle fatigue. Mouse chromaffin cells (MCCs) generate action potential (AP) firing that regulates the Ca2+‐dependent release of catecholamines (CAs). Recent findings indicate that MCCs possess a variety of spontaneous firing modes that span from the common ‘tonic‐irregular’ to the less frequent ‘burst’ firing. This latter is evident in a small fraction of MCCs but occurs regularly when Nav1.3/1.7 channels are made less available or when the Slo1β2‐subunit responsible for BK channel inactivation is deleted. Burst firing causes large increases of Ca2+‐entry and potentiates CA release by ∼3.5‐fold and thus may be a key mechanism for regulating MCC function. With the aim to uncover a physiological role for burst‐firing we investigated the effects of acidosis on MCC activity. Lowering the extracellular pH (pHo) from 7.4 to 7.0 and 6.6 induces cell depolarizations of 10–15 mV that generate repeated bursts. Bursts at pHo 6.6 lasted ∼330 ms, occurred at 1–2 Hz and caused an ∼7‐fold increase of CA cumulative release. Burst firing originates from the inhibition of the pH‐sensitive TASK‐1/TASK‐3 channels and from a 40% BK channel conductance reduction at pHo 7.0. The same pHo had little or no effect on Nav, Cav, Kv and SK channels that support AP firing in MCCs. Burst firing of pHo 6.6 could be mimicked by mixtures of the TASK‐1 blocker A1899 (300 nm) and BK blocker paxilline (300 nm) and could be prevented by blocking L‐type
ISSN:0022-3751
1469-7793
DOI:10.1113/JP273735