AMPA receptor properties and coexpression with sodium-calcium exchangers in rat hypothalamic neurons

Acid-sensing hypothalamic neurons controlling arousal

Breathing and vigilance are regulated by pH and CO2 levels in the central nervous system. The hypocretin/orexin (Hcrt/Orx)- and histamine (HA)-containing hypothalamic neurons synergistically control different aspects of the waking state. Acidification inhibits firing of most neurons but these two groups in the caudal hypothalamus are excited by hypercapnia and protons, similar to the chemosensory neurons in the brain stem. Activation of hypothalamic wake-on neurons in response to hypercapnia, seen with the c-Fos assay, is supported by patch-clamp recordings in rodent brain slices: Hcrt/Orx and HA neurons are excited by acidification in the physiological range (pH from 7.4 to 7.0). Multiple molecular mechanisms mediate wake-promoting effects of protons in HA neurons in the tuberomamillary nucleus (TMN): among them are acid-sensing ion channels, Na(+),K(+)-ATPase, group I metabotropic glutamate receptors (mGluRI). HA neurons are remarkably sensitive to the mGluRI agonist DHPG (threshold concentration 0.5 µM) and mGluRI antagonists abolish proton-induced excitation of HA neurons. Hcrt/Orx neurons are excited through block of a potassium conductance and release glutamate with their peptides in TMN. The two hypothalamic nuclei and the serotonergic dorsal raphe cooperate toward CO2/acid-induced arousal. Their interactions and molecular mechanisms of H(+)/CO2-induced activation are relevant for the understanding and treatment of respiratory and metabolic disorders related to sleep-waking such as obstructive sleep apnea and sudden infant death syndrome.

Proton- and ammonium-sensing by histaminergic neurons controlling wakefulness

The histaminergic neurons in the tuberomamillary nucleus (TMN) of the posterior hypothalamus are involved in the control of arousal. These neurons are sensitive to hypercapnia as has been shown in experiments examining c-Fos expression, a marker for increased neuronal activity. We investigated the mechanisms through which TMN neurons respond to changes in extracellular levels of acid/CO₂. Recordings in rat brain slices revealed that acidification within the physiological range (pH from 7.4 to 7.0), as well as ammonium chloride (5 mM), excite histaminergic neurons. This excitation is significantly reduced by antagonists of type I metabotropic glutamate receptors and abolished by benzamil, an antagonist of acid-sensing ion channels (ASICs) and Na⁺/Ca²⁺ exchanger, or by ouabain which blocks Na⁺/K⁺ ATPase. We detected variable combinations of 4 known types of ASICs in single TMN neurons, and observed activation of ASICs in single dissociated TMN neurons only at pH lower than 7.0. Thus, glutamate, which is known to be released by glial cells and orexinergic neurons, amplifies the acid/CO₂-induced activation of TMN neurons. This amplification demands the coordinated function of metabotropic glutamate receptors, Na⁺/Ca²⁺ exchanger and Na⁺/K⁺ ATPase. We also developed a novel HDC-Cre transgenic reporter mouse line in which histaminergic TMN neurons can be visualized. In contrast to the rat, the mouse histaminergic neurons lacked the pH 7.0-induced excitation and displayed only a minimal response to the mGluR I agonist DHPG (0.5 μM). On the other hand, ammonium-induced excitation was similar in mouse and rat. These results are relevant for the understanding of the neuronal mechanisms controlling acid/CO₂-induced arousal in hepatic encephalopathy and obstructive sleep apnoea. Moreover, the new HDC-Cre mouse model will be a useful tool for studying the physiological and pathophysiological roles of the histaminergic system.

The bile steroid chenodeoxycholate is a potent antagonist at NMDA and GABA(A) receptors

The bile steroids (BS) cholic acid and chenodeoxycholic acid are produced in hepatocytes and in the brain. Nothing is known about neuronal actions of BS. Deficiency in a 27-hydroxylase enzyme coincides with reduced production of chenodeoxycholic acid (CDCA) and a relative increase in cholic acid in an inherited lipid storage disease, cerebrotendinous xanthomatosis, characterized by neurological dysfunctions, which can be treated by dietary CDCA. We have examined the modulation of hypothalamic network activity by nine common BS. Cholate and CDCA significantly reduced the firing of hypothalamic neurons and synchronized network activity with CDCA being nearly 10 times more potent. The synthetic BS dehydrocholate synchronized the activity without affecting the firing rate. Gabazine, a GABA(A) receptor antagonist, occluded synchronization by BS. Whole-cell patch clamp recordings revealed a block of NMDA- and GABA(A)-receptors by BS. Potencies of nine common BS differed between NMDA and GABA(A) receptors, however in both cases they correlated with BS affinities for albumin but not with their lipophilicity, supporting a direct action at ligand gated ion channels. GABAergic synaptic currents displayed a faster decay under BS. Our data provide new insight into extrahepatic functions of BS revealing their neuroactive potential.

Histamine in the nervous system

Histamine is a transmitter in the nervous system and a signaling molecule in the gut, the skin, and the immune system. Histaminergic neurons in mammalian brain are located exclusively in the tuberomamillary nucleus of the posterior hypothalamus and send their axons all over the central nervous system. Active solely during waking, they maintain wakefulness and attention. Three of the four known histamine receptors and binding to glutamate NMDA receptors serve multiple functions in the brain, particularly control of excitability and plasticity. H1 and H2 receptor-mediated actions are mostly excitatory; H3 receptors act as inhibitory auto- and heteroreceptors. Mutual interactions with other transmitter systems form a network that links basic homeostatic and higher brain functions, including sleep-wake regulation, circadian and feeding rhythms, immunity, learning, and memory in health and disease.

Na+/Ca2+ exchangers: three mammalian gene families control Ca2+ transport

Mammalian Na+/Ca2+ exchangers are members of three branches of a much larger family of transport proteins [the CaCA (Ca2+/cation antiporter) superfamily] whose main role is to provide control of Ca2+ flux across the plasma membranes or intracellular compartments. Since cytosolic levels of Ca2+ are much lower than those found extracellularly or in sequestered stores, the major function of Na+/Ca2+ exchangers is to extrude Ca2+ from the cytoplasm. The exchangers are, however, fully reversible and thus, under special conditions of subcellular localization and compartmentalized ion gradients, Na+/Ca2+ exchangers may allow Ca2+ entry and may play more specialized roles in Ca2+ movement between compartments. The NCX (Na+/Ca2+ exchanger) [SLC (solute carrier) 8] branch of Na+/Ca2+ exchangers comprises three members: NCX1 has been most extensively studied, and is broadly expressed with particular abundance in heart, brain and kidney, NCX2 is expressed in brain, and NCX3 is expressed in brain and skeletal muscle. The NCX proteins subserve a variety of roles, depending upon the site of expression. These include cardiac excitation-contraction coupling, neuronal signalling and Ca2+ reabsorption in the kidney. The NCKX (Na2+/Ca2+-K+ exchanger) (SLC24) branch of Na+/Ca2+ exchangers transport K+ and Ca2+ in exchange for Na+, and comprises five members: NCKX1 is expressed in retinal rod photoreceptors, NCKX2 is expressed in cone photoreceptors and in neurons throughout the brain, NCKX3 and NCKX4 are abundant in brain, but have a broader tissue distribution, and NCKX5 is expressed in skin, retinal epithelium and brain. The NCKX proteins probably play a particularly prominent role in regulating Ca2+ flux in environments which experience wide and frequent fluctuations in Na+ concentration. Until recently, the range of functions that NCKX proteins play was generally underappreciated. This situation is now changing rapidly as evidence emerges for roles including photoreceptor adaptation, synaptic plasticity and skin pigmentation. The CCX (Ca2+/cation exchanger) branch has only one mammalian member, NCKX6 or NCLX (Na+/Ca2+-Li+ exchanger), whose physiological function remains unclear, despite a broad pattern of expression.

Glutamate-induced calcium transients in rat neurons of the dorsal motor nucleus of the vagus

The dorsal motor nucleus of the vagus (DMNV) integrates peripheral and central signals and sends efferent output to the gastrointestinal system. Glutamate, the major excitatory neurotransmitter of the central nervous system, causes increases in intracellular calcium in DMNV neurons. The mechanisms by which glutamate activates calcium signaling in the DMNV were examined. DMNV neurons were isolated from neonatal rat brainstem using microdissection and enzymatic digestion. Exposure to glutamate caused intracellular Ca(2+) increments in greater than 80% of cells. Removal of extracellular Ca(2+) abolished intracellular Ca(2+) transients. Kynurenic acid, a nonspecific glutamate receptor antagonist, abolished intracellular Ca(2+) transients. Exposure to glutamate while blocking AMPA receptors with GYKI 52466 abolished the Ca(2+) response. Exposure to (S)AMPA, an AMPA receptor agonist, caused intracellular Ca(2+) increments in 97% of cells. Activation and antagonism of NMDA and kainate receptors produced no changes compared to control experiments. NiCl, a nonspecific Ca(2+) channel blocker, abolished intracellular Ca(2+) transients. Blocking T-type Ca(2+) channels with mibefradil abolished the Ca(2+) response in 76% of cells. Blockade of L-type and N-type Ca(2+) channels did not affect the Ca(2+) response. Glutamate mediates intracellular Ca(2+) currents in DMNV neurons via the AMPA receptor and T-type Ca(2+) channels, allowing influx of extracellular Ca(2+).

Editing of AMPA and Serotonin 2C Receptors in Individual Central Neurons, Controlling Wakefulness

(1) Pre-mRNA editing of serotonin 2C (5-HT2c) and glutamate (Glu) receptors (R) influences higher brain functions and pathological states such as epilepsy, amyotrophic lateral sclerosis, and depression. Adenosine deaminases acting on RNA (ADAR1-3) convert adenosine to inosine on synthetic RNAs, analogous to 5-HT2cR and GluR. The order of editing as well as mechanisms controlling editing in native neurons is unknown. (2) With single-cell RT-PCR we investigated the co-expression of ADAR genes with GluR and 5-HT2cR and determined the editing status at known sites in the hypothalamic tuberomamillary nucleus, a major center for wakefulness and arousal. (3) The most frequently expressed enzymes were ADAR1, followed by ADAR2. The Q/R site of GluR2 was always fully edited. Editing at the R/G site in the GluR2 (but not GluR4) subunit was co-ordinated with ADAR expression: maximal editing was found in neurons expressing both ADAR2 splice variants of the deaminase domain and lacking ADAR3. (4) Editing of the 5-HT2cR did not correlate with ADAR expression. The 5-HT2cR mRNA was always edited at A, in the majority of cells at B sites and variably edited at E, C and D sites. A negative correlation was found between editing of C and D sites. The GluR4 R/G site editing was homogeneous within individuals: it was fully edited in all neurons obtained from 12 rats and under-edited in six neurons obtained from three rats. (5) We conclude that GluR2 R/G editing is controlled at the level of ADAR2 and therefore this enzyme may be a target for pharmacotherapy. On the other hand, further factors/enzymes besides ADAR must control or influence 5-HT2cR and GluR pre-mRNA editing in native neurons; our data indicate that these factors vary between individuals and could be predictors of psychiatric disease.

Different cation sensitivities and binding site domains of Na+-Ca2+-K+ and Na+-Ca2+ exchangers

We examined inhibitory effects of external multivalent cations Ni(2+), Co(2+), Cd(2+), La(3+), Mg(2+), and Mn(2+) on reverse-mode exchange of the K(+)-dependent Na(+)/Ca(2+) exchanger NCKX2 and the K(+)-independent exchanger NCX1 expressed in CCL-39 cells by measuring the rate of Ca(2+) uptake with radioisotope tracer and electrophysiological techniques. The apparent affinities for block of Ca(2+) uptake by multivalent cations was higher in NCKX2 than NCX1, and the rank order of inhibitory potencies among these cations was different. Additional experiments also showed that external Li(+) stimulated reverse-mode exchange by NCX1, but not NCKX2 in the presence of 5 mM K(+). Thus, both exchangers exhibited differential sensitivities to not only K(+) but also many other external cations. We attempted to locate the putative binding sites within the alpha motifs for multivalent cations by site-directed mutagenesis experiments. The cation affinities of NCKX2 were altered by mutations of amino acid residues in the alpha-1 motif, but not by mutations in the alpha-2 motif. These results contrast with those for NCX1 where mutations in both alpha-1 and alpha-2 motifs have been shown previously to affect cation affinities. Susceptibility tests with sulfhydryl alkylating agents suggested that the alpha-1 and alpha-2 motifs are situated extracellularly and intracellularly, respectively, in both exchangers. A topological model is proposed in which the extracellular-facing alpha-1 motif forms an external cation binding site that includes key residues N203, G207C, and I209 in NCKX2, while both alpha-1 and alpha-2 motifs together form the binding sites in NCX1.