Jean-Charles Hoda

Alpha7 neuronal nicotinic acetylcholine receptors are negatively regulated by tyrosine phosphorylation and Src-family kinases.

Nicotine, a component of tobacco, is highly addictive but possesses beneficial properties such as cognitive improvements and memory maintenance. Involved in these processes is the neuronal nicotinic acetylcholine receptor (nAChR) α7, whose activation triggers depolarization, intracellular signaling cascades, and synaptic plasticity underlying addiction and cognition. It is therefore important to investigate intracellular mechanisms by which a cell regulates α7 nAChR activity. We have examined the role of phosphorylation by combining molecular biology, biochemistry, and electrophysiology in SH-SY5Y neuroblastoma cells, Xenopus oocytes, rat hippocampal interneurons, and neurons from the supraoptic nucleus, and we found tyrosine phosphorylation of α7 nAChRs. Tyrosine kinase inhibition by genistein decreased α7 nAChR phosphorylation but strongly increased acetylcholine-evoked currents, whereas tyrosine phosphatase inhibition by pervanadate produced opposite effects. Src-family kinases (SFKs) directly interacted with the cytoplasmic loop of α7 nAChRs and phosphorylated the receptors at the plasma membrane. SFK inhibition by PP2 [4-amino-5-(4-chlorophenyl)-7-(t-butyl)pyrazolo[3,4-d]pyrimidine] or SU6656 (2,3-dihydro-N,N-dimethyl-2-oxo-3-[(4,5,6,7-tetrahydro-1H-indol-2-yl)methylene]-1H-indole-5-sulfonamide) increased α7 nAChR-mediated responses, whereas expression of active Src reduced α7 nAChR activity. Mutant α7 nAChRs lacking cytoplasmic loop tyrosine residues because of alanine replacement of Tyr-386 and Tyr-442 were more active than wild-type receptors and insensitive to kinase or phosphatase inhibition. Because the amount of surface α7 receptors was not affected by kinase or phosphatase inhibitors, these data show that functional properties of α7 nAChRs depend on the tyrosine phosphorylation status of the receptor and are the result of a balance between SFKs and tyrosine phosphatases. These findings reveal novel regulatory mechanisms that may help to understand nicotinic receptor-dependent plasticity, addiction, and pathology.

Expression and 1,4-dihydropyridine-binding properties of brain L-type calcium channel isoforms.

The L-type calcium channel (LTCC) isoforms Cav1.2 and Cav1.3 display similar 1,4-dihydropyridine (DHP) binding properties and are both expressed in mammalian brain. Recent work implicates Cav1.3 channels as interesting drug targets, but no isoform-selective modulators exist. It is also unknown to what extent Cav1.1 and Cav1.4 contribute to L-type-specific DHP binding activity in brain. To address this question and to determine whether DHPs can discriminate between Cav1.2 and Cav1.3 binding pockets, we combined radioreceptor assays and quantitative polymerase chain reaction (qPCR). We bred double mutants (Cav-DM) from mice expressing mutant Cav1.2 channels [Cav1.2DHP(-/-)] lacking high affinity for DHPs and from Cav1.3 knockouts [Cav1.3(-/-)]. (+)-[3H]isradipine binding to Cav1.2DHP(-/-) and Cav-DM brains was reduced to 15.1 and 4.4% of wild type, respectively, indicating that Cav1.3 accounts for 10.7% of brain LTCCs. qPCR revealed that Cav1.1 and Cav1.4 α1 subunits comprised 0.08% of the LTCC transcripts in mouse whole brain, suggesting that they cannot account for the residual binding. Instead, this could be explained by low-affinity binding (127-fold Kd increase) to the mutated Cav1.2 channels. Inhibition of (+)-[3H]isradipine binding to Cav1.2DHP(-/-) (predominantly Cav1.3) and wild-type (predominantly Cav1.2) brain membranes by unlabeled DHPs revealed a 3- to 4-fold selectivity of nitrendipine and nifedipine for the Cav1.2 binding pocket, a finding further confirmed with heterologously expressed channels. This suggests that small differences in their binding pockets may allow development of isoform-selective modulators for LTCCs and that, because of their very low expression, Cav1.1 and Cav1.4 are unlikely to serve as drug targets to treat CNS diseases.

C-terminal modulator controls Ca2+-dependent gating of Cav1.4 L-type Ca2+ channels

Tonic neurotransmitter release at sensory cell ribbon synapses is mediated by calcium (Ca2+) influx through L-type voltage-gated Ca2+ channels. This tonic release requires the channels to inactivate slower than in other tissues. Cav1.4 L-type voltage-gated Ca2+ channels (LTCCs) are found at high densities in photoreceptor terminals, and α1 subunit mutations cause human congenital stationary night blindness type-2 (CSNB2). Cav1.4 voltage-dependent inactivation is slow and Ca2+-dependent inactivation (CDI) is absent. We show that removal of the last 55 or 122 (C122) C-terminal amino acid residues of the human α1 subunit restores calmodulin-dependent CDI and shifts voltage of half-maximal activation to more negative potentials. The C terminus must therefore form part of a mechanism that prevents calmodulin-dependent CDI of Cav1.4 and controls voltage-dependent activation. Fluorescence resonance energy transfer experiments in living cells revealed binding of C122 to C-terminal motifs mediating CDI in other Ca2+ channels. The absence of this modulatory mechanism in the CSNB2 truncation mutant K1591X underlines its importance for normal retinal function in humans.

Modulation of voltage- and Ca2+-dependent gating of CaV1.3 L-type calcium channels by alternative splicing of a C-terminal regulatory domain.

Low voltage activation of CaV1.3 L-type Ca2+ channels controls excitability in sensory cells and central neurons as well as sinoatrial node pacemaking. CaV1.3-mediated pacemaking determines neuronal vulnerability of dopaminergic striatal neurons affected in Parkinson disease. We have previously found that in CaV1.4 L-type Ca2+ channels, activation, voltage, and calcium-dependent inactivation are controlled by an intrinsic distal C-terminal modulator. Because alternative splicing in the CaV1.3 α1 subunit C terminus gives rise to a long (CaV1.342) and a short form (CaV1.342A), we investigated if a C-terminal modulatory mechanism also controls CaV1.3 gating. The biophysical properties of both splice variants were compared after heterologous expression together with β3 and α2δ1 subunits in HEK-293 cells. Activation of calcium current through CaV1.342A channels was more pronounced at negative voltages, and inactivation was faster because of enhanced calcium-dependent inactivation. By investigating several CaV1.3 channel truncations, we restricted the modulator activity to the last 116 amino acids of the C terminus. The resulting CaV1.3ΔC116 channels showed gating properties similar to CaV1.342A that were reverted by co-expression of the corresponding C-terminal peptide C116. Fluorescence resonance energy transfer experiments confirmed an intramolecular protein interaction in the C terminus of CaV1.3 channels that also modulates calmodulin binding. These experiments revealed a novel mechanism of channel modulation enabling cells to tightly control CaV1.3 channel activity by alternative splicing. The absence of the C-terminal modulator in short splice forms facilitates CaV1.3 channel activation at lower voltages expected to favor CaV1.3 activity at threshold voltages as required for modulation of neuronal firing behavior and sinoatrial node pacemaking.

Congenital Stationary Night Blindness Type 2 Mutations S229P, G369D, L1068P, and W1440X Alter Channel Gating or Functional Expression of Cav1.4 L-type Ca2+ Channels

Mutations in the CACNA1F gene (voltage-dependent L-type calcium channel α1F subunit) encoding retinal Cav1.4 L-type Ca2+ channels cause X-linked recessive congenital stationary night blindness type 2 (CSNB2). Many of them are predicted to yield nonfunctional channels. Complete loss of Cav1.4 function is therefore regarded as a pathogenetic mechanism for the impaired signaling from photoreceptors to second-order retinal neurons. We investigated the functional consequences of CSNB2 missense mutations S229P, G369D, and L1068P and the C-terminal truncation mutant W1440X. After expression in Xenopus laevis oocytes or human embryonic kidney tsA-201 cells, inward Ca2+ current (ICa) and inward Ba2+ current (IBa) could be recorded from mutations G369D and L1068P. G369D shifted the half-maximal voltage for channel activation (V0.5,act) significantly to more negative potentials (>11 mV), slowed inactivation, and removed Ca2+-dependent inactivation. The L1068P mutant yielded currents only in the presence of the channel activator BayK8644. Currents (IBa) inactivated faster than wild type (WT) and recovered more slowly from inactivation (IBa and ICa). No channel activity could be measured for mutants S229P and W1440X after oocyte expression. No W1440X α1 protein was detected after expression in tsA-201 cells, whereas S229P (as well as G369D and L1068P) α1 subunits were expressed at levels indistinguishable from WT (n = 3). Our data provide unequivocal evidence that CSNB2 missense mutations can induce severe changes in Cav1.4 function, which may decrease (L1068P and S229P) or even increase (G369D) channel activity. The lower activation range of G369D can explain the reduced dynamic range of photoreceptor signaling. Moreover, we demonstrate that loss of channel function of one (L1068P) CSNB2 mutation can be rescued by a Ca2+ channel activator.

Human Nocturnal Frontal Lobe Epilepsy: Pharmocogenomic Profiles of Pathogenic Nicotinic Acetylcholine Receptor β-Subunit Mutations outside the Ion Channel Pore

Certain mutations in specific parts of the neuronal nicotinic acetylcholine receptor (nAChR) subunit genes CHRNA4, CHRNB2, and probably CHRNA2, can cause autosomal dominant nocturnal frontal lobe epilepsy (ADNFLE). All but one of the known causative mutations are located in the second transmembrane region (TM2), which serves as the major ion poreforming domain of the receptor. Functional characterization of these ADNFLE mutations has shown that although each mutant exhibits specific properties, they all confer a gain of function with increased sensitivity to acetylcholine. In this work, we characterize the second and third ADNFLE-associated mutations that are external to TM2 but affect different amino acid residues within the third transmembrane region (TM3). The two new CHRNB2 mutations were identified in three families of Turkish Cypriot, Scottish, and English origin. These TM3 mutations elicit the same gain of function pathomechanism as observed for the TM2 mutations with enhanced acetylcholine sensitivity, despite their unusual localization within the gene. Electrophysiological experiments, including single channel measurements, revealed that incorporation of these new mutant subunits does not affect the conductance of the ionic pore but increases the probability of opening. Determination of the sensitivity to nicotine for nAChRs carrying mutations in TM2 and TM3 showed clear differences in the direction and the extent to which the window current for nicotine sensitivity was shifted for individual mutations, indicating differences in pharmacogenomic properties that are not readily correlated with increased ACh affinity.

Pleiotropic functional effects of the first epilepsy-associated mutation in the human CHRNA2 gene.

Autosomal dominant nocturnal frontal lobe epilepsy (ADNFLE) can be caused by mutations in the neuronal nicotinic acetylcholine receptor (nAChR) subunit genes CHRNA4 and CHRNB2. Recently, a point mutation (α2‐I279N) associated with sleep‐related epilepsy has been described in a third nAChR gene, CHRNA2. We demonstrate here that α2‐I279N can be co‐expressed with the major structural subunit CHRNB2. α2‐I279N causes a marked gain‐of‐function effect and displays a distinct biopharmacological profile, including markedly reduced inhibition by carbamazepine and increased nicotine sensitivity.

Effects of congenital stationary night blindness type 2 mutations R508Q and L1364H on Cav1.4 L-type Ca2+ channel function and expression

At least 48 mutations in the CACNA1F gene encoding retinal Cav1.4 L‐type Ca2+ channels have been linked to X‐linked recessive congenital stationary night blindness type 2 (CSNB2). A large number of these are missense mutations encoding full‐length α1‐subunits that can potentially form functional channels. We have previously shown that such missense mutations can confer their phenotype by different pathological mechanisms, such as complete lack of α1 subunit protein expression or dramatic changes in channel gating. Here we investigated the functional consequences of CSNB2 missense mutations R508Q and L1364H. We found no (R508Q) or only minor (L1364H) changes in the gating properties of both mutants after heterologous expression in Xenopus laevis oocytes (at 20°C). However, both mutants resulted in altered expression density of Cav1.4 currents. When expressed in the mammalian cell line tsA‐201, the current amplitude of L1364H channels was reduced when cells were grown at 30°C and both mutations affected total α1 protein expression. This effect was temperature dependent. Our data provide evidence that, in contrast to previously characterized CSNB2 missense mutations, the clinical phenotype of R508Q and L1364H is unlikely to be explained by changes in channel gating. Instead, these mutations affect the protein expression of Cav1.4 Ca2+ channels.

Opposite Effects of a Single IIIS5 Mutation on Phenylalkylamine and Dihydropyridine Interaction with L-type Ca2+ Channels

Replacement of L-type Ca2+ channel α1 subunit residue Thr-1066 in segment IIIS5 by a tyrosine residue conserved in the corresponding positions of non-L-type Ca2+ channels eliminates high dihydropyridine sensitivity through a steric mechanism. To determine the effects of this mutation on phenylalkylamine interaction, we exploited the availability of Cav1.2DHP–/– mice containing the T1066Y mutation. In contrast to dihydropyridines, increased protein-dependent binding of the phenylalkylamine (–)-[3H]devapamil occurred to Cav1.2DHP–/– mouse brain microsomes. This effect could be attributed to an at least 2-fold increase in affinity as determined by saturation analysis and binding inhibition experiments. The latter also revealed a higher affinity for (–)-verapamil but not for (–)-gallopamil. The mutation caused a pronounced slowing of (–)-[3H]devapamil dissociation, indicating a stabilization of the drug-channel complex. The increased affinity of mutant channels was also evident in functional studies after heterologous expression of wild type and T1066Y channels in Xenopus laevis oocytes. 100 μm (–)-verapamil inhibited a significantly larger fraction of Ba2+ inward current through mutant than through WT channels. Our results provide evidence that phenylalkylamines also interact with the IIIS5 helix and that the geometry of the IIIS5 helix affects the access and/or binding of different chemical classes of Ca2+ channel blockers to their overlapping binding domains. Mutation of Thr-1066 to a non-L-type tyrosine residue can be exploited to differentially affect phenylalkylamine and dihydropyridine binding to L-type Ca2+ channels.

The nicotinic acetylcholine receptor alpha 4 subunit contains a functionally relevant SNP Haplotype

BackgroundNon-coding single nucleotide polymorphisms within the nicotinic acetylcholine receptor alpha 4 subunit gene (CHRNA4) are robustly associated with various neurological and behavioral phenotypes including schizophrenia, cognition and smoking. The most commonly associated polymorphisms are located in exon 5 and segregate as part of a haplotype. So far it is unknown if this haplotype is indeed functional, or if the observed associations are an indirect effect caused by linkage disequilibrium with not yet identified adjacent functional variants. We therefore analyzed the functional relevance of the exon 5 haplotype alleles.ResultsUsing voltage clamp experiments we were able to show that the CHRNA4 haplotype alleles differ with respect to their functional effects on receptor sensitivity including reversal of receptor sensitivity between low and high acetylcholine concentrations. The results indicate that underlying mechanisms might include differences in codon usage bias and changes in mRNA stability.ConclusionsOur data demonstrate that the complementary alleles of the CHRNA4 exon 5 haplotype are functionally relevant, and might therefore be causative for the above mentioned associations.