Immunocytochemistry of Acutely Isolated Adrenal Medullary Chromaffin Cells.

Immunocytochemistry enables the detection and localization of proteins in cells that are acutely dissociated or in culture. There are advantages and disadvantages to the use of cultured cells for immunocytochemistry. One of the advantages is that cultured cells can be used for one or more weeks after the dissociation of cells, whereas one of the disadvantages is that the properties of cells in culture might change under artificial conditions. On the other hand, acutely dissociated cells are expected to have the original properties of cells because almost all procedures before fixation, except for enzymatic digestion, are carried out at low temperatures. Here, we describe how adrenal medullary cells of small animals are acutely dissociated for immunostaining.

Expression of p11 and TASK1 Channels in Rat Carotid Body Glomus Cells Subjected to Chronic Intermittent Hypoxia.

Chronic intermittent hypoxia (CIH) has been used as a model to mimic nocturnal apnea, which is associated with hypertension. One of the mechanisms for hypertension in patients with nocturnal apnea is an enhancement of the plasma membrane response to acute hypoxia in carotid body glomus cells. Hypoxia is known to induce depolarization via inhibiting TWIK-related acid-sensitive K+ (TASK) channels, one type of leak K+ channels, in glomus cells. The present experiment was undertaken to immunocytochemically investigate the effects of CIH on the expression and intracellular localization of TASK1 channels and p11 that critically affect the trafficking of TASK1 to the cell surface. The expression levels of TASK1 proteins and p11 and their intracellular localization in rat carotid body glomus cells were not noticeably affected by CIH, suggesting that the enhanced membrane response to acute hypoxia is not due to an increase in surface TASK channels.

Expression of p11 and heteromeric TASK channels in mouse adrenal cortical cells and H295R cells.

TWIK-related acid-sensitive K+ (TASK) channels are thought to contribute to the resting membrane potential in adrenal cortical (AC) cells. However, the molecular identity of TASK channels in AC cells have not yet been elucidated. Thus, immunocytochemical and molecular biological approaches were employed to investigate the expression and intracellular distribution of TASK1 and TASK3 in mouse AC cells and H295R cells derived from human adrenocortical carcinoma. Immunocytochemical study revealed that immunoreactive materials were mainly located in the cytoplasm for TASK1 and at the cell periphery for TASK3 in mouse AC cells. A similar pattern of localization was observed when GFP-TASK1 and GFP-TASK3 were exogenously expressed in H295R cells. In addition, p11 that is known to suppress the endoplasmic reticulum exit of TASK1 was localized in the cytoplasm in mouse AC and H295R cells, but not in adrenal medullary cells. Proximity ligation assay (PLA) suggested formation of heteromeric TASK1-3 channels that were found predominantly in the cytoplasm and weakly at the cell periphery. A similar distribution was observed following exogenous expression of tandem TASK1-3 channels in H295R cells. When stimulated by angiotensin II, however, tandem TASK1-3 channels were present mainly in the cytoplasm in all H295R cells. In contrast to that in H295R cells, tandem channels were exclusively located at the cell periphery in all non-stimulated and exclusively in the cytoplasm in stimulated PC12 cells, respectively. From these results, we conclude that TASK1 proteins are present mainly in the cytoplasm and minimally at the cell periphery as a heteromeric channel with TASK3, whereas the majority of TASK3 is at the cell periphery as homomeric and heteromeric channels.

Brain-derived neurotrophic factor predominantly regulates the expression of synapse-related genes in the striatum: Insights from in vitro transcriptomics.

AIM: The striatum, a main component of the basal ganglia, is a critical part of the motor and reward systems of the brain. It consists of GABAergic and cholinergic neurons and receives projections of dopaminergic, glutamatergic, and serotonergic neurons from other brain regions. Brain-derived neurotrophic factor (BDNF) plays multiple roles in the central nervous system, and striatal BDNF has been suggested to be involved in psychiatric and neurodegenerative disorders. However, the transcriptomic impact of BDNF on the striatum remains largely unknown. In the present study, we performed transcriptomic profiling of striatal cells stimulated with BDNF to identify enriched gene sets (GSs) and their novel target genes in vitro. METHODS: We carried out RNA sequencing (RNA-Seq) of messenger RNA extracted from primary dissociated cultures of rat striatum stimulated with BDNF and conducted Generally Applicable Gene-set Enrichment (GAGE) analysis on 10599 genes. Significant differentially expressed genes (DEGs) were determined by differential expression analysis for sequence count data 2 (DESeq2). RESULTS: GAGE analysis identified significantly enriched GSs that included GSs related to regulation and dysregulation of synaptic functions, such as synaptic vesicle cycle and addiction to nicotine and morphine, respectively. It also detected GSs related to various types of synapses, including not only GABAergic and cholinergic synapses but also dopaminergic and glutamatergic synapses. DESeq2 revealed 72 significant DEGs, among which the highest significance was observed in the apolipoprotein L domain containing 1 (Apold1). CONCLUSIONS: The present study indicates that BDNF predominantly regulates the expression of synaptic-function-related genes and that BDNF promotes synaptogenesis in various subtypes of neurons in the developing striatum. Apold1 may represent a unique target gene of BDNF in the striatum.

Mechanisms for establishment of GABA signaling in adrenal medullary chromaffin cells.

γ-Aminobutyric acid (GABA) is thought to play a paracrine role in adrenal medullary chromaffin (AMC) cells. Comparative physiological and immunocytochemical approaches were used to address the issue of how the paracrine function of GABA in AMC cells is established. GABAA receptor Cl- channel activities in AMC cells of rats and mice, where corticosterone is the major glucocorticoid, were much smaller than those in AMC cells of guinea-pigs and cattle, where cortisol is the major. The extent of enhancement of GABAA receptor α3 subunit expression in rat pheochromocytoma (PC12) cells by cortisol was larger than that by corticosterone in parallel with their glucocorticoid activities. Thus, the species difference in GABAA receptor expression may be ascribed to a difference in glucocorticoid activity between corticosterone and cortisol. GABAA receptor Cl- channel activity in mouse AMC cells was enhanced by allopregnanolone, as noted with that in guinea-pig AMC cells, and the enzymes involved in allopregnanolone production were immunohistochemically detected in the zona fasciculata in both mice and guinea pigs. The expression of glutamic acid decarboxylase 67 (GAD67), one of the GABA synthesizing enzymes, increased after birth, whereas GABAA receptors already developed at birth. Stimulation of pituitary adenylate cyclase-activating polypeptide (PACAP) receptors, but not nicotinic or muscarinic receptors, in PC12 cells, resulted in an increase in GAD67 expression in a protein-kinase A-dependent manner. The results indicate that glucocorticoid and PACAP are mainly responsible for the expressions of GABAA receptors and GAD67 involved in GABA signaling in AMC cells, respectively.

Expression of p11 and Heteromeric TASK Channels in Rat Carotid Body Glomus Cells and Nerve Growth Factor-differentiated PC12 Cells.

TWIK-related acid-sensitive K+ (TASK) homomeric channels, TASK1 and TASK3, are present in PC12 cells. The channels do not heteromerize due plausibly to a lack of p11 protein. Single-channel recording reveals that most of the rat carotid body (CB) glomus cells express heteromeric TASK1-TASK3 channels, but the presence of p11 in glomus cells has not yet been verified. TASK1, but not TASK3, binds to p11, which has a retention signal for the endoplasmic reticulum. We hypothesized that p11 could facilitate heteromeric TASK1-TASK3 formation in glomus cells. We investigated this hypothesis in isolated immunocytochemically identified rat CB glomus cells. The findings were that glomus cells expressed p11-like immunoreactive (IR) material, and TASK1- and TASK3-like IR material mainly coincided in the cytoplasm. The proximity ligation assay showed that TASK1 and TASK3 heteromerized. In separate experiments, supporting evidence for the major role of p11 for channel heteromerization was provided in PC12 cells stimulated by nerve growth factor. p11 production took place there via multiple signaling pathways comprising mitogen-activated protein kinase and phospholipase C, and heteromeric TASK1-TASK3 channels were formed. We conclude that p11 is expressed and TASK1 and TASK3 heteromerize in rat CB glomus cells.

Vexin is upregulated in cerebral cortical neurons by brain-derived neurotrophic factor.

AIM: Chromosome 8 open reading frame 46 (C8orf46), a human protein-coding gene, has recently been named Vexin. A recent study indicated that Vexin is involved in embryonic neurogenesis. Additionally, some transcriptomic studies detected changes in the mRNA levels of patients with psychiatric and neurological diseases. In our previous study, we sought for target genes of brain-derived neurotrophic factor (BDNF) in cultured rat cortical neurons, finding that BDNF potentially leads to the upregulation of Vexin mRNA. However, its underlying mechanisms are unknown. In the present study, we assessed the regulatory mechanisms of the BDNF-induced gene expression of Vexin in vitro. METHODS: We reanalyzed ChIP-seq data in various human organs provided by the ENCODE project, evaluating acetylation levels of the 27th lysine residue of the histone H3 (H3K27ac) at the Vexin locus. The transcriptomic effects of BDNF on rat Vexin (RGD1561849) were evaluated by real-time quantitative PCR (RT-qPCR) in primary cultures of cerebral cortical neurons, in the presence or absence of inhibitors for signaling molecules activated by BDNF. RESULTS: The Vexin locus and its promoter region in the brain angular gyrus show higher acetylation levels of the H3K27 than those in other organs. Stimulation of cultured rat cortical neurons, but not astrocyte, with BDNF, led to marked elevations in the mRNA levels of Vexin, which was inhibited in the presence of K252a and U0126. CONCLUSION: The upregulated H3K27ac in the brain may be associated with the enriched gene expression of Vexin in the brain. It is indicated that BDNF induces the gene expression of Vexin in the cortical neurons via the TrkB-MEK signaling pathway.

TASK channels: channelopathies, trafficking, and receptor-mediated inhibition.

TWIK-related acid-sensitive K+ (TASK) channels contribute to the resting membrane potential in various kinds of cells, such as brain neurons, smooth muscle cells, and endocrine cells. Loss-of-function mutations at multiple sites in the KCNK3 gene encoding for TASK1 channels are one of the causes of pulmonary arterial hypertension in humans, whereas a mutation at only one site is reported for TASK3 channels, resulting in a syndrome of mental retardation, hypotonia, and facial dysmorphism. TASK channels are subject to regulation by G protein-coupled receptors (GPCRs). Two mechanisms have been proposed for the GPCR-mediated inhibition of TASK channels: a change in gating and channel endocytosis. The most feasible mechanism for altered gating is diacylglycerol binding to a site in the C-terminus, which is shared by TASK1 and TASK3. The inhibition of channel function by endocytosis requires the presence of a tyrosine residue subjected to phosphorylation by the non-receptor tyrosine kinase Src and a dileucine motif in the C-terminus of TASK1. Therefore, homomeric TASK1 and heteromeric TASK1-TASK3 channels, but not homomeric TASK3, are internalized by GPCR stimulation. Tyrosine phosphorylation by Src is expected to result in a conformational change in the C-terminus, allowing for AP-2, an adaptor protein for clathrin, to bind to the dileucine motif. It is likely that a raft membrane domain is a platform where TASK1 is located and the signaling molecules protein kinase C, Pyk2, and Src are recruited in sequence in response to GPCR stimulation.

Mechanisms for pituitary adenylate cyclase-activating polypeptide-induced increase in excitability in guinea-pig and mouse adrenal medullary cells.

Pituitary adenylate cyclase-activating polypeptide (PACAP) acts on adrenal medullary (AM) cells as a neurotransmitter of the sympathetic preganglionic nerve. In guinea-pig AM cells, PACAP induces little catecholamine secretion, but enhances secretion evoked by stimulants, whereas in other animals, such as mouse, PACAP itself induces depolarization and/or catecholamine secretion. The present studies aim to explore the physiological implication of these species differences in PACAP actions, the ion channel mechanism for PACAP-induced depolarization, and the mechanism for facilitation of muscarinic receptor-mediated cation currents in mouse and guinea-pig AM cells. The perforated patch clamp technique was used to record the whole-cell current in isolated AM cells. The amplitudes of 3 nM PACAP-induced inward currents were significantly larger in mouse AM cells than guinea-pig, whereas 1 µM muscarine-induced currents were larger in guinea-pig AM cells than mouse. Exposure to PACAP consistently resulted in enhancement of muscarine-induced currents in guinea-pig AM cells and facilitation of cell membrane insertion of heteromeric TRPC1-TRPC4 channels in response to muscarine in PC12 cells. The PACAP-induced current was inhibited by 30 µM 9-phenanthrol, a specific TRPM4 channel inhibitor, and abolished by replacement of external Na+ with N-methyl D-glucamine. TRPM4-like immunoreactivity was located at the cell periphery in AM cells. The present results indicate that PACAP and muscarinic receptors are major metabotropic receptors mediating generation of depolarizing inward currents in mouse and guinea-pig AM cells, respectively. We conclude that PACAP activates TRPM4-like channels and enhance the muscarinic current through facilitating the membrane insertion of TRPC1-TRPC4 channels in AM cells.

Muscarinic receptor stimulation induces TASK1 channel endocytosis through a PKC-Pyk2-Src pathway in PC12 cells.

Muscarinic receptor stimulation or protein kinase C (PKC) activation in rat adrenal medullary and PC12 cells rapidly induces tyrosine phosphorylation of TWIK-related-acid-sensitive K+ 1 (TASK1) channels with the subsequent clathrin-dependent endocytosis. Our previous study suggested that the muscarinic signal is transmitted to the non-receptor tyrosine kinase Src through PKC and Pyk2. Although PKC activation is known to stimulate Pyk2 in certain types of cells, its molecular mechanism remains unclear. In this study, proximity ligation assay (PLA) and other molecular biological approaches were used to elucidate the details of this muscarinic signaling in PC12 cells. When green fluorescent protein (GFP)-TASK1 was expressed, the majority of GFP-TASK1 was located at the cell periphery. However, the simultaneous expression of GFP-TASK1 and PKCα, but not PKCδ, led to GFP-TASK1 internalization. Muscarinic receptor stimulation resulted in transient co-localization of Pyk2 and Src at the cell periphery, and expression of kinase dead (KD) Pyk2 and Src, but not Pyk2 and KD Src, resulted in GFP-TASK1 internalization. PLA analysis revealed that in response to muscarine, PKCαactivates Pyk2 through phosphorylating its serine residues. These results indicate that muscarinic receptor stimulation induces TASK1 channel endocytosis sequentially through PKCα, Pyk2, and Src, and PKCα activates Pyk2 through phosphorylation.

STIM1-dependent membrane insertion of heteromeric TRPC1-TRPC4 channels in response to muscarinic receptor stimulation.

Muscarinic receptor stimulation results in activation of nonselective cation (NSC) channels in guinea pig adrenal medullary (AM) cells. The biophysical and pharmacological properties of the NSC channel suggest the involvement of heteromeric channels of TRPC1 with TRPC4 or TRPC5. This possibility was explored in PC12 cells and guinea pig AM cells. Proximity ligation assay (PLA) revealed that when exogenously expressed in PC12 cells, TRPC1 forms a heteromeric channel with TRPC4, but not with TRPC5, in a STIM1-dependent manner. The heteromeric TRPC1-TRPC4 channel was also observed in AM cells and trafficked to the cell periphery in response to muscarine stimulation. To explore whether heteromeric channels are inserted into the cell membrane, tags were attached to the extracellular domains of TRPC1 and TRPC4. PLA products developed between the tags in cells stimulated by muscarine, but not in resting cells, indicating that muscarinic stimulation results in the membrane insertion of channels. This membrane insertion required expression of full-length STIM1. We conclude that muscarinic receptor stimulation results in the insertion of heteromeric TRPC1-TRPC4 channels into the cell membrane in PC12 cells and guinea pig AM cells.

Differences among muscarinic agonists in M1 receptor-mediated nonselective cation channel activation and TASK1 channel inhibition in adrenal medullary cells.

Muscarinic receptor stimulation induces depolarizing inward currents and catecholamine secretion in adrenal medullary (AM) cells from various mammals. In guinea-pig AM cells muscarine and oxotremorine at concentrations ≤ 1 µM produce activation of nonselective cation channels with a similar potency and efficacy, whereas muscarine at higher concentrations produces not only nonselective cation channel activation, but also TASK1 channel inhibition. In rat AM cells, the muscarinic M1 receptor is involved in TASK1 channel inhibition in response to muscarinic agonists, and the efficacy of oxotremorine is half that of muscarine. These pharmacological findings might indicate that different muscarinic receptor subtypes are responsible for the regulation of nonselective cation and TASK1 channel activities. The present study aimed to determine the muscarinic receptor subtypes involved in nonselective cation channel activation in guinea-pig and mouse AM cells. The inward current evoked by 1 µM muscarine was completely suppressed by 100 µM quinine, whereas 30 µM muscarine-induced inward currents were comprised of quinine-sensitive and -insensitive components. The electrophysiological and pharmacological properties of the muscarine-induced currents indicated that the quinine-sensitive and insensitive components are due to nonselective cation channel activation and TASK1 channel inhibition, respectively. Muscarine at 30 µM failed to induce any current in AM cells treated with muscarinic toxin 7 or genetically deleted of the M1 receptor. The KD value of VU0255035 against the muscarinic receptor mediating nonselective cation channel activation was 17.5 nM. These results indicate that the M1 receptor mediates nonselective cation channel activation as well as TASK1 channel inhibition.

Lack of p11 expression facilitates acidity-sensing function of TASK1 channels in mouse adrenal medullary cells.

External acidity induces catecholamine secretion by inhibiting TASK1-like channels in rat adrenal medullary (AM) cells. TASK channels can function as a heteromer or homomer in the TASK subfamily. In this study, we elucidate the molecular identity of TASK1-like channels in mouse AM cells using gene knockout. Genetic deletion of TASK1, but not TASK3, abolished the depolarizing inward current and catecholamine secretion in response to acidity, whereas it did not affect the resting current level. Immunocytochemistry revealed that AM cells exhibited predominantly TASK1-like and little TASK3-like immunoreactivity. A proximity ligation assay showed that TASK1/3 heteromeric channels were not formed in AM cells or PC12 cells. However, the exogenous expression of p11 in PC12 cells resulted in the heteromeric formation of TASK isoforms, which were mainly located in the cytoplasm, and p11 was not expressed in rat adrenal medullae or PC12 cells. In AM cells, genetic deletion of TASK1 resulted in enhancement of the immunoreactivity of the TALK2 channel, but not TASK3. The results indicate that TASK1 homomeric channels function as acidity sensors in AM cells, and that function is facilitated by the lack of p11 expression.-Inoue, M., Matsuoka, H., Lesage, F., Harada, K. Lack of p11 expression facilitates acidity-sensing function of TASK1 channels in mouse adrenal medullary cells.

Expression and regulation of M-type K+ channel in PC12 cells and rat adrenal medullary cells.

M-type K+ channels contribute to the resting membrane potential in the sympathetic ganglion neurons of various animals, whereas their expression in adrenal medullary (AM) cells has been controversial. The present experiment aims to explore the expression of M channels comprising the KCNQ2 subunit in the rat AM cell and its immortalized cell line PC12 cells at the protein level and how its expression in PC12 cells is regulated. The KCNQ2 isoform was recognized in homogenates of PC12 cells but not the rat adrenal medullae by immunoblotting and KCNQ2-like immunoreactivity (IR) was detected in PC12 cells but not in rat AM cells. When the PC12 cells were maintained in a dexamethasone-containing medium, KCNQ2-like IR in the cells was suppressed, whereas the removal of fetal bovine serum from the culture medium for 1 day resulted in an increase in KCNQ2-like IR. A similar enhancement occurred when PC12 cells were cultured under conditions where glucocorticoid receptor (GR) and/or mineralocorticoid receptor (MR) activities were suppressed. These morphological findings were confirmed in functional analysis. The cells cultured in the presence of an inhibitor of either GR or MR exhibited larger amplitudes of Ca2+ signal in response to an M channel inhibitor than did the cells in its absence, whereas the resting Ca2+ level in the former was lower than that in the latter. These results indicate that the M channel is not expressed in rat AM cells and this absence of expression may be ascribed to the suppression by glucocorticoid activity.

Endocytosis of particulate matter induces cytokine production by neutrophil via Toll-like receptor 4.

Particulate matter (PM) with a median diameter <2.5 µm, is associated with respiratory and cardiovascular diseases. We previously reported the biological effects of PM in vivo, and although neutrophils play an important role in initiating inflammation, few reports have focused on the relationship between PM inhalation and immune responses. Here, we investigated the effect of PM particle size on neutrophils, including their endocytosis activity and reactive oxygen species (ROS) production. Flow cytometry analysis indicated that 1 µm particles are readily endocytosed by neutrophils and that endocytosis is reduced at 4 °C. Inhibitors of the pleckstrin homology domain of dynamin repressed this process; however, GTPase and clathrin inhibitors did not affect endocytosis. Endocytosis by neutrophils in Toll-like receptor 4 (TLR4)- and MyD88-knockout mice was reduced compared with that in wild-type mice, indicating that TLR4 and MyD88 are important for the process. Neutrophil-mediated endocytosis caused oxidative stress, and N-acetylcysteine enhanced endocytosis. Expression levels of the oxidative stress markers, heme oxygenase-1 and p62 protein, were increased in an endocytosis-dependent manner. Phagocytosed neutrophils produced IL-6 and TNFα, whose production was decreased by dynamin inhibitors. We observed that infiltrated CD11b-positive cells in bronchoalveolar lavage fluid endocytose PMs. Overall, these results indicate that endocytosis and ROS production via TLR4 are important for the initiation of immune responses by neutrophils.

Correction to: Expression and regulation of M-type K+ channel in PC12 cells and rat adrenal medullary cells.

The published online version contains some mistakes for the additional corrections were missed by typesetter which also include the replacement of Fig. 5.

Corticotropin-releasing hormone-binding protein is up-regulated by brain-derived neurotrophic factor and is secreted in an activity-dependent manner in rat cerebral cortical neurons.

A recent study revealed that corticotropin-releasing hormone (CRH) in the cerebral cortex (CTX) plays a regulatory role in emotional behaviors in rodents. Given the functional interaction between brain-derived neurotrophic factor (BDNF) and the CRH-signaling pathway in the hypothalamic-pituitary-adrenal axis, we hypothesized that BDNF may regulate gene expression of CRH and its related molecules in the CTX. Findings of real-time quantitative PCR (RT-qPCR) indicated that stimulation of cultured rat cortical neurons with BDNF led to marked elevations in the mRNA levels of CRH and CRH-binding protein (CRH-BP). The BDNF-induced up-regulation of CRH-BP mRNA was attenuated by inhibitors of tropomyosin related kinase (Trk) and MEK, but not by an inhibitor for PI3K and Phospholipase C gamma (PLCγ). The up-regulation was partially blocked by an inhibitor of lysine-specific demethylase (KDM) 6B. Fluorescent imaging identified the vesicular pattern of pH-sensitive green fluorescent protein-fused CRH-BP (CRH-BP-pHluorin), which co-localized with mCherry-tagged BDNF in cortical neurons. In addition, live-cell imaging detected drastic increases of pHluorin fluorescence in neurites upon membrane depolarization. Finally, we confirmed that tetrodotoxin partially attenuated the BDNF-induced up-regulation of CRH-BP mRNA, but not that of the protein. These observations indicate the following: In cortical neurons, BDNF led to gene expression of CRH-BP and CRH. TrkB, MEK, presumably ERK, and KDM6B are involved in the BDNF-induced gene expression of CRH-BP, and BDNF is able to induce the up-regulation in a neuronal activity-independent manner. It is suggested that CRH-BP is stored into BDNF-containing secretory granules in cortical neurons, and is secreted in response to membrane depolarization.

Muscarinic receptors in adrenal chromaffin cells: physiological role and regulation of ion channels.

Adrenal medullary chromaffin cells in mammals are innervated by sympathetic preganglionic nerve fibers, as are sympathetic ganglion neurons. Acetylcholine in the ganglion neurons is well established as mediating fast and slow excitatory postsynaptic potentials through nicotinic and muscarinic acetylcholine receptors (AChRs), respectively. The role of muscarinic AChRs during neuronal transmission in chromaffin cells varies among different mammals. Furthermore, the ion channel mechanisms associated with the muscarinic AChR-mediated increase in excitability of chromaffin cells are complicated and different from the excitation of ganglion neurons, which has been ascribed to the inhibition of M-type K+ channels. In this review, we focus on muscarinic receptor-mediated excitation in rodent and guinea pig chromaffin cells, in particular, on the role of muscarinic receptors in neuronal transmission, the muscarinic receptor subtypes involved in excitation and secretion, and the muscarinic regulation of ion channels including TWIK-related acid-sensitive K+ channels. Finally, we discuss prospectively the future of muscarinic receptor research in adrenal chromaffin cells.

Molecular mechanism for muscarinic M1 receptor-mediated endocytosis of TWIK-related acid-sensitive K+ 1 channels in rat adrenal medullary cells.

KEY POINTS: The muscarinic acetylcholine receptor (mAChR)-mediated increase in excitability in rat adrenal medullary cells is at least in part due to inhibition of TWIK (tandem of P domains in a weak inwardly rectifying K+ channel)-related acid-sensitive K+ (TASK)1 channels. In this study we focused on the molecular mechanism of mAChR-mediated inhibition of TASK1 channels. Exposure to muscarine resulted in a clathrin-dependent endocytosis of TASK1 channels following activation of the muscarinic M1 receptor (M1 R). This muscarinic signal for the endocytosis was mediated in sequence by phospholipase C (PLC), protein kinase C (PKC), and then the non-receptor tyrosine kinase Src with the consequent tyrosine phosphorylation of TASK1. The present results establish that TASK1 channels are tyrosine phosphorylated and internalized in a clathrin-dependent manner in response to M1 R stimulation and this translocation is at least in part responsible for muscarinic inhibition of TASK1 channels in rat AM cells. ABSTRACT: Activation of muscarinic receptor (mAChR) in rat adrenal medullary (AM) cells induces depolarization through the inhibition of TWIK-related acid-sensitive K+ (TASK)1 channels. Here, pharmacological and immunological approaches were used to elucidate the molecular mechanism for this mAChR-mediated inhibition. TASK1-like immunoreactive (IR) material was mainly located at the cell periphery in dissociated rat AM cells, and its majority was internalized in response to muscarine. The muscarine-induced inward current and translocation of TASK1 were suppressed by dynasore, a dynamin inhibitor. The muscarinic translocation was suppressed by MT7, a specific M1 antagonist, and the dose-response curves for muscarinic agonist-induced translocation were similar to those for the muscarinic inhibition of TASK1 currents. The muscarine-induced inward current and/or translocation of TASK1 were suppressed by inhibitors for phospholipase C (PLC), protein kinase C (PKC), and/or Src. TASK1 channels in AM cells and PC12 cells were transiently associated with Src and were tyrosine phosphorylated in response to muscarinic stimulation. After internalization, TASK1 channels were quickly dephosphorylated even while they remained in the cytoplasm. The cytoplasmic TASK1-like IR material quickly recycled back to the cell periphery after muscarine stimulation for 0.5 min, but not 10 min. We conclude that M1 R stimulation results in internalization of TASK1 channels through the PLC-PKC-Src pathway with the consequent phosphorylation of tyrosine and that this M1 R-mediated internalization is at least in part responsible for muscarinic inhibition of TASK1 channels in rat AM cells.