Tau inhibits mitochondrial calcium efflux and makes neurons vulnerable to calcium-induced cell death

Aggregation or phosphorylation of the microtubule-associated protein tau is the pathological hallmark in a number of diseases termed tauopathies, which include the most common neurodegenerative disorder, Alzheimer’s disease; or frontotemporal dementia, linked to mutations in the gene MAPT encoding tau. Although misfolded tau has strong familial and histopathological (as in intracellular tangles) association with neurodegenerative disorders, the cellular mechanism of tau-induced pathology remains to be controversial. Here we studied the effect of tau on the cytosolic and mitochondrial calcium homeostasis using primary cortical cultures treated with the protein and iPSC-derived neurons bearing the 10 + 16 MAPT mutation linked to frontotemporal dementia. We found that incubation of the primary cortical co-cultures of neurons and astrocytes with tau induced spontaneous Ca²⁺ oscillations in the neurons, which were also observed in iPSC-neurons with the 10 + 16 MAPT mutation. Importantly, tau inhibited mitochondrial calcium efflux via the mitochondrial Na⁺/Ca²⁺ exchanger (NCLX) in both neurons and astrocytes. This inhibition led to mitochondrial depolarisation in response to physiological and pathological calcium stimuli and made these cells vulnerable to calcium-induced caspase 3 activation and cell death. Thus, inhibition of the mitochondrial NCLX in neurons with misfolded or mutated tau can be involved in the mechanism of neurodegeneration.     

The up-regulation of voltage-gated sodium channels subtypes coincides with an increased sodium current in hippocampal neuronal culture model

Voltage-gated sodium channels (VGSC) have been linked to inherited forms of epilepsy. The expression and biophysical properties of VGSC in the hippocampal neuronal culture model have not been clarified. In order to evaluate mechanisms of epileptogenesis that are related to VGSC, we examined the expression and function of VGSC in the hippocampal neuronal culture model in vitro and spontaneously epileptic rats (SER) in vivo. Our data showed that the peak amplitude of transient, rapidly-inactivating Na⁺ current (I_Na,T) in model neurons was significantly increased compared with control neurons, and the activation curve was shifted to the negative potentials in model neurons in whole cell recording by patch–clamp. In addition, channel activity of persistent, non-inactivating Na⁺ current (I_Na,P) was obviously increased in the hippocampal neuronal culture model as judged by single-channel patch–clamp recording. Furthermore, VGSC subtypes Na_V1.1, Na_V1.2 and Na_V1.3 were up-regulated at the protein expression level in model neurons and SER as assessed by Western blotting. Four subtypes of VGSC proteins in SER were clearly present throughout the hippocampus, including CA1, CA3 and dentate gyrus regions, and neurons expressing VGSC immunoreactivity were also detected in hippocampal neuronal culture model by immunofluorescence. These findings suggested that the up-regulation of voltage-gated sodium channels subtypes in neurons coincided with an increased sodium current in the hippocampal neuronal culture model, providing a possible explanation for the observed seizure discharge and enhanced excitability in epilepsy.     

Tumorigenicity Studies of Induced Pluripotent Stem Cell (iPSC)-Derived Retinal Pigment Epithelium (RPE) for the Treatment of Age-Related Macular Degeneration

Basic studies of human pluripotential stem cells have advanced rapidly and stem cell products are now seeing therapeutic applications. However, questions remain regarding the tumorigenic potential of such cells. Here, we report the tumorigenic potential of induced pluripotent stem cell (iPSC)-derived retinal pigment epithelium (RPE) for the treatment of wet-type, age-related macular degeneration (AMD). First, immunodeficient mouse strains (nude, SCID, NOD-SCID and NOG) were tested for HeLa cells’ tumor-forming capacity by transplanting various cell doses subcutaneously with or without Matrigel. The 50% Tumor Producing Dose (TPD₅₀ value) is the minimal dose of transplanted cells that generated tumors in 50% of animals. For HeLa cells, the TPD₅₀ was the lowest when cells were embedded in Matrigel and transplanted into NOG mice (TPD₅₀ = 10^1.1, n = 75). The TPD₅₀ for undifferentiated iPSCs transplanted subcutaneously to NOG mice in Matrigel was 10^2.12; (n = 30). Based on these experiments, 1×10⁶ iPSC-derived RPE were transplanted subcutaneously with Matrigel, and no tumor was found during 15 months of monitoring (n = 65). Next, to model clinical application, we assessed the tumor-forming potential of HeLa cells and iPSC 201B7 cells following subretinal transplantation of nude rats. The TPD₅₀ for iPSCs was 10^4.73 (n = 20) and for HeLa cells 10^1.32 (n = 37) respectively. Next, the tumorigenicity of iPSC-derived RPE was tested in the subretinal space of nude rats by transplanting 0.8–1.5×10⁴ iPSC-derived RPE in a collagen-lined (1 mm×1 mm) sheet. No tumor was found with iPSC-derived RPE sheets during 6–12 months of monitoring (n = 26). Considering the number of rodents used, the monitoring period, the sensitivity of detecting tumors via subcutaneous and subretinal administration routes and the incidence of tumor formation from the iPSC-derived RPE, we conclude that the tumorigenic potential of the iPSC-derived RPE was negligible.     

TPEN,a Specific Zn<Superscript>2+</Superscript> Chelator,Inhibits Sodium Dithionite and Glucose Deprivation (SDGD)-Induced Neuronal Death by Modulating Apoptosis,Glutamate Signaling,and Voltage-Gated K<Superscript>+</Superscript> and Na<Superscript>+</Superscript> Channels

Hypoxia–ischemia-induced neuronal death is an important pathophysiological process that accompanies ischemic stroke and represents a major challenge in preventing ischemic stroke. To elucidate factors related to and a potential preventative mechanism of hypoxia–ischemia-induced neuronal death, primary neurons were exposed to sodium dithionite and glucose deprivation (SDGD) to mimic hypoxic–ischemic conditions. The effects of N,N,N′,N′-tetrakis (2-pyridylmethyl) ethylenediamine (TPEN), a specific Zn²⁺-chelating agent, on SDGD-induced neuronal death, glutamate signaling (including the free glutamate concentration and expression of α-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) receptor (GluR2) and N-methyl-d-aspartate (NMDA) receptor subunits (NR2B), and voltage-dependent K⁺ and Na⁺ channel currents were also investigated. Our results demonstrated that TPEN significantly suppressed increases in cell death, apoptosis, neuronal glutamate release into the culture medium, NR2B protein expression, and I _K as well as decreased GluR2 protein expression and Na⁺ channel activity in primary cultured neurons exposed to SDGD. These results suggest that TPEN could inhibit SDGD-induced neuronal death by modulating apoptosis, glutamate signaling (via ligand-gated channels such as AMPA and NMDA receptors), and voltage-gated K⁺ and Na⁺ channels in neurons. Hence, Zn²⁺ chelation might be a promising approach for counteracting the neuronal loss caused by transient global ischemia. Moreover, TPEN could represent a potential cell-targeted therapy.     

A Time Course Analysis of the Electrophysiological Properties of Neurons Differentiated from Human Induced Pluripotent Stem Cells (iPSCs)

Many protocols have been designed to differentiate human embryonic stem cells (ESCs) and human induced pluripotent stem cells (iPSCs) into neurons. Despite the relevance of electrophysiological properties for proper neuronal function, little is known about the evolution over time of important neuronal electrophysiological parameters in iPSC-derived neurons. Yet, understanding the development of basic electrophysiological characteristics of iPSC-derived neurons is critical for evaluating their usefulness in basic and translational research. Therefore, we analyzed the basic electrophysiological parameters of forebrain neurons differentiated from human iPSCs, from day 31 to day 55 after the initiation of neuronal differentiation. We assayed the developmental progression of various properties, including resting membrane potential, action potential, sodium and potassium channel currents, somatic calcium transients and synaptic activity. During the maturation of iPSC-derived neurons, the resting membrane potential became more negative, the expression of voltage-gated sodium channels increased, the membrane became capable of generating action potentials following adequate depolarization and, at day 48–55, 50% of the cells were capable of firing action potentials in response to a prolonged depolarizing current step, of which 30% produced multiple action potentials. The percentage of cells exhibiting miniature excitatory post-synaptic currents increased over time with a significant increase in their frequency and amplitude. These changes were associated with an increase of Ca²⁺ transient frequency. Co-culturing iPSC-derived neurons with mouse glial cells enhanced the development of electrophysiological parameters as compared to pure iPSC-derived neuronal cultures. This study demonstrates the importance of properly evaluating the electrophysiological status of the newly generated neurons when using stem cell technology, as electrophysiological properties of iPSC-derived neurons mature over time.     

A novel neuronal organoid model mimicking glioblastoma (GBM) features from induced pluripotent stem cells (iPSC)

BackgroundCurrent experimental models using either human or mouse cell lines, are not representative of the complex features of GBM. In particular, there is no model to study patient-derived iPSCs to generate a GBM model. Overexpression of c-met gene is one of the molecular features of GBM leading to increased signaling via STAT3 phosphorylation. We generated an iPSC line from a patient with c-met mutation and we asked whether we could use it to generate neuronal-like organoids mimicking features of GBM.MethodsWe have generated iPSC-aggregates differentiating towards organoids. We analyzed them by gene expression profiling, immunostaining and transmission electronic microscopy analyses (TEM).ResultsHerein we describe that c-met-mutated iPSC aggregates spontaneously differentiate into dopaminergic neurons more rapidly than control iPSC aggregates in culture. Gene expression profiling of c-met-mutated iPSC aggregates at day +90 showed neuronal- and GBM-related genes, reproducing a genomic network described in primary human GBM. Comparative TEM analyses confirmed the enrichment of these structures in intermediate filaments and abnormal cilia, a feature described in human GBM. The c-met-mutated iPSC-derived organoids, as compared to controls expressed high levels of glial fibrillary acidic protein (GFAP), which is a typical marker of human GBM, as well as high levels of phospho-MET and phospho-STAT3. The use of temozolomide (TMZ) showed a preferential cytotoxicity of this drug in c-met-mutated neuronal-like organoids.General significanceThis study shows the feasibility of generating “off-the shelf” neuronal-like organoid model mimicking GBM using c-met-mutated iPSC aggregates and its potential future use in research.     

Channel Properties of Nax Expressed in Neurons

Na_x is a sodium-concentration ([Na⁺])-sensitive Na channel with a gating threshold of ~150 mM for extracellular [Na⁺] ([Na⁺]_o) in vitro. We previously reported that Na_x was preferentially expressed in the glial cells of sensory circumventricular organs including the subfornical organ, and was involved in [Na⁺] sensing for the control of salt-intake behavior. Although Na_x was also suggested to be expressed in the neurons of some brain regions including the amygdala and cerebral cortex, the channel properties of Na_x have not yet been adequately characterized in neurons. We herein verified that Na_x was expressed in neurons in the lateral amygdala of mice using an antibody that was newly generated against mouse Na_x. To investigate the channel properties of Na_x expressed in neurons, we established an inducible cell line of Na_x using the mouse neuroblastoma cell line, Neuro-2a, which is endogenously devoid of the expression of Na_x. Functional analyses of this cell line revealed that the [Na⁺]-sensitivity of Na_x in neuronal cells was similar to that expressed in glial cells. The cation selectivity sequence of the Na_x channel in cations was revealed to be Na⁺ ≈ Li⁺ > Rb⁺ > Cs⁺ for the first time. Furthermore, we demonstrated that Na_x bound to postsynaptic density protein 95 (PSD95) through its PSD95/Disc-large/ZO-1 (PDZ)-binding motif at the C-terminus in neurons. The interaction between Na_x and PSD95 may be involved in promoting the surface expression of Na_x channels because the depletion of endogenous PSD95 resulted in a decrease in Na_x at the plasma membrane. These results indicated, for the first time, that Na_x functions as a [Na⁺]-sensitive Na channel in neurons as well as in glial cells.     

Qualitative and Quantitative Comparison of the Proteome of Erythroid Cells Differentiated from Human iPSCs and Adult Erythroid Cells by Multiplex TMT Labelling and NanoLC-MS/MS

Induced pluripotent stem cells (iPSC) are an attractive progenitor source for the generation of in vitro blood products. However, before iPSC-derived erythroid cells can be considered for therapeutic use their similarity to adult erythroid cells must be confirmed. We have analysed the proteome of erythroid cells differentiated from the iPSC fibroblast derived line (C19) and showed they express hallmark RBC proteins, including all those of the ankyrin and 4.1R complex. We next compared the proteome of erythroid cells differentiated from three iPSC lines (C19, OCE1, OPM2) with that of adult and cord blood progenitors. Of the 1989 proteins quantified <3% differed in level by 2-fold or more between the different iPSC-derived erythroid cells. When compared to adult cells, 11% of proteins differed in level by 2-fold or more, falling to 1.9% if a 5-fold threshold was imposed to accommodate slight inter-cell line erythropoietic developmental variation. Notably, the level of >30 hallmark erythroid proteins was consistent between the iPSC lines and adult cells. In addition, a sub-population (10–15%) of iPSC erythroid cells in each of the iPSC lines completed enucleation. Aberrant expression of some cytoskeleton proteins may contribute to the failure of the majority of the cells to enucleate since we detected some alterations in cytoskeletal protein abundance. In conclusion, the proteome of erythroid cells differentiated from iPSC lines is very similar to that of normal adult erythroid cells, but further work to improve the induction of erythroid cells in existing iPSC lines or to generate novel erythroid cell lines is required before iPSC-derived red cells can be considered suitable for transfusion therapy.     

Riluzole suppresses postinhibitory rebound in an excitatory motor neuron of the medicinal leech

Postinhibitory rebound (PIR) is an intrinsic property often exhibited by neurons involved in generating rhythmic motor behaviors. Cell DE-3, a dorsal excitatory motor neuron in the medicinal leech exhibits PIR responses that persist for several seconds following the offset of hyperpolarizing stimuli and are suppressed in reduced Na⁺ solutions or by Ca²⁺ channel blockers. The long duration and Na⁺ dependence of PIR suggest a possible role for persistent Na⁺ current (I _NaP). In vertebrate neurons, the neuroprotective agent riluzole can produce a selective block of I _NaP. This study demonstrates that riluzole inhibits cell DE-3 PIR in a concentration- and Ca²⁺-dependent manner. In 1.8 mM Ca²⁺ solution, 50–100 µM riluzole selectively blocked the late phase of PIR, an effect similar to that of the neuromodulator serotonin. However, 200 µM riluzole blocked both the early and late phases of PIR. Increasing extracellular Ca²⁺ to 10 mM strengthened PIR, but high riluzole concentrations continued to suppress both phases of PIR. These results indicate that riluzole may suppress PIR via a nonspecific inhibition of Ca²⁺ conductances and suggest that a Ca²⁺-activated nonspecific current (I _CAN), rather than I _NaP, may underlie the Na⁺-dependent component of PIR.     

Characterization of Na+-Dependent Phosphate Uptake in Cultured Fetal Rat Cortical Neurons

Abstract: Our laboratory has recently cloned and expressed a brain- and neuron-specific Na⁺-dependent inorganic phosphate (P_i) cotransporter that is constitutively expressed in neurons of the rat cerebral cortex, hippocampus, and cerebellum. We have now characterized Na⁺-dependent ³²P_i cotransport in cultured fetal rat cortical neurons, where >90% of saturable P_i uptake is Na⁺-dependent. Saturable, Na⁺-dependent ³²P_i uptake was first observed in primary cultures of cortical neurons at 7 days in vitro (DIV) and was maximal at 12 DIV. Na⁺-dependent P_i transport was optimal at physiological temperature (37°C) and pH (7.0–7.5), with apparent K_m values for P_i and Na⁺ of 54 ± 12.7 µM and 35 ± 4.2 mM, respectively. A reduction in extracellular Ca²⁺ markedly reduced (>60%) Na⁺-dependent P_i uptake, with a threshold for maximal P_i import of 1–2.5 mM CaCl₂. Primary cultures of fetal cortical neurons incubated in medium where equimolar concentrations of choline were substituted for Na⁺ had lower levels of ATP and ADP and higher levels of AMP than did those incubated in the presence of Na⁺. Furthermore, a substantial fraction of the ³²P_i cotransported with Na⁺ was concentrated in the adenine nucleotides. Inhibitors of oxidative metabolism, such as rotenone, oligomycin, or dinitrophenol, dramatically decreased Na⁺-dependent P_i import rates. These data establish the presence of a Na⁺-dependent P_i cotransport system in neurons of the CNS, demonstrate the Ca²⁺-dependent nature of ³²P_i uptake, and suggest that the neuronal Na⁺-dependent P_i cotransporter may import P_i required for the production of high-energy compounds vital to neuronal metabolism.     

Comparative effects of sodium pyrithione evoked intracellular calcium elevation in rodent and primate ventral horn motor neurons

Oral administration of sodium pyrithione (NaP) causes hindlimb weakness in rodents, but not in primates. Previous work using Aplysia neurons has demonstrated that NaP produces a persistent influx of Ca²⁺ ions across the plasma membrane. To determine whether this also occurs in mammalian neurons and whether this could underlie the inter-species difference between rodents and primates, we have tested the effects of NaP on intracellular Ca²⁺ levels ([Ca²⁺]_i) in rat and monkey motor neurons in vitro. Motor neurons present in spinal cord slices from rhesus monkey embryos (E37 and 56) and from rat E16 were dissected and cultured on glass coverslips. Following 2 weeks (rhesus) or 2-3 days (rat) in culture, neurons were loaded with fura-PE3/AM, and examined for [Ca²⁺]_i changes in response to NaP. Rhesus motor neurons were identified by immunostaining for Islet-1 (MN specific antigen) and neuron specific enolase (NSE). Motor neurons from both species exhibited dose-dependent NaP-evoked increases in [Ca²⁺]_i However, the dose-response curve for the Rhesus motor neurons was significantly shifted to the right of the rat dose-response curve, whereas the overall amplitude of the Ca²⁺ rise was similar in both species. As shown previously for the Aplysia neurons, the action of NaP is attenuated by SKF 96365, an inhibitor of store-operated calcium entry. In contrast the action of NaP is unaffected by nifedipine and tetrodotoxin, blockers of voltage-dependent Ca²⁺ and Na⁺ channels, respectively, or by ouabain, an inhibitor of the plasma membrane Na⁺/K⁺ ATPase. Our results indicate that the NaP-induced increase in [Ca²⁺]_i is conserved across species and suggest that the toxicological sensitivity of rodent over primate to pyrithione could be due to the enhanced sensitivity of rodent motor neurons to NaP-evoked intracellular Ca²⁺ elevation.     

Prolonged Intracellular Na+ Dynamics Govern Electrical Activity in Accessory Olfactory Bulb Mitral Cells

Persistent activity has been reported in many brain areas and is hypothesized to mediate working memory and emotional brain states and to rely upon network or biophysical feedback. Here, we demonstrate a novel mechanism by which persistent neuronal activity can be generated without feedback, relying instead on the slow removal of Na⁺ from neurons following bursts of activity. We show that mitral cells in the accessory olfactory bulb (AOB), which plays a major role in mammalian social behavior, may respond to a brief sensory stimulation with persistent firing. By combining electrical recordings, Ca²⁺ and Na⁺ imaging, and realistic computational modeling, we explored the mechanisms underlying the persistent activity in AOB mitral cells. We found that the exceptionally slow inward current that underlies this activity is governed by prolonged dynamics of intracellular Na⁺ ([Na⁺]_i), which affects neuronal electrical activity via several pathways. Specifically, elevated dendritic [Na⁺]_i reverses the Na⁺-Ca²⁺ exchanger activity, thus modifying the [Ca²⁺]_i set-point. This process, which relies on ubiquitous membrane mechanisms, is likely to play a role in other neuronal types in various brain regions.     

A Specific and Essential Role for Na,K-ATPase α3 in Neurons Co-expressing α1 and α3

Most neurons co-express two catalytic isoforms of Na,K-ATPase, the ubiquitous α1, and the more selectively expressed α3. Although neurological syndromes are associated with α3 mutations, the specific role of this isoform is not completely understood. Here, we used electrophysiological and Na⁺ imaging techniques to study the role of α3 in central nervous system neurons expressing both isoforms. Under basal conditions, selective inhibition of α3 using a low concentration of the cardiac glycoside, ouabain, resulted in a modest increase in intracellular Na⁺ concentration ([Na⁺]_i) accompanied by membrane potential depolarization. When neurons were challenged with a large rapid increase in [Na⁺]_i, similar to what could be expected following suprathreshold neuronal activity, selective inhibition of α3 almost completely abolished the capacity to restore [Na⁺]_i in soma and dendrite. Recordings of Na,K-ATPase specific current supported the notion that when [Na⁺]_i is elevated in the neuron, α3 is the predominant isoform responsible for rapid extrusion of Na⁺. Low concentrations of ouabain were also found to disrupt cortical network oscillations, providing further support for the importance of α3 function in the central nervous system. The α isoforms express a well conserved protein kinase A consensus site, which is structurally associated with an Na⁺ binding site. Following activation of protein kinase A, both the α3-dependent current and restoration of dendritic [Na⁺]_i were significantly attenuated, indicating that α3 is a target for phosphorylation and may participate in short term regulation of neuronal function.     

Involvement of the Na+/Ca2+ exchanger isoform 1 (NCX1) in Neuronal Growth Factor (NGF)-induced Neuronal Differentiation through Ca2+-dependent Akt Phosphorylation

NGF induces neuronal differentiation by modulating [Ca²⁺]_i. However, the role of the three isoforms of the main Ca²⁺-extruding system, the Na⁺/Ca²⁺ exchanger (NCX), in NGF-induced differentiation remains unexplored. We investigated whether NCX1, NCX2, and NCX3 isoforms could play a relevant role in neuronal differentiation through the modulation of [Ca²⁺]_i and the Akt pathway. NGF caused progressive neurite elongation; a significant increase of the well known marker of growth cones, GAP-43; and an enhancement of endoplasmic reticulum (ER) Ca²⁺ content and of Akt phosphorylation through an early activation of ERK1/2. Interestingly, during NGF-induced differentiation, the NCX1 protein level increased, NCX3 decreased, and NCX2 remained unaffected. At the same time, NCX total activity increased. Moreover, NCX1 colocalized and coimmunoprecipitated with GAP-43, and NCX1 silencing prevented NGF-induced effects on GAP-43 expression, Akt phosphorylation, and neurite outgrowth. On the other hand, the overexpression of its neuronal splicing isoform, NCX1.4, even in the absence of NGF, induced an increase in Akt phosphorylation and GAP-43 protein expression. Interestingly, tetrodotoxin-sensitive Na⁺ currents and 1,3-benzenedicarboxylic acid, 4,4′-[1,4,10-trioxa-7,13-diazacyclopentadecane-7,13-diylbis(5-methoxy-6,12-benzofurandiyl)]bis-, tetrakis[(acetyloxy)methyl] ester-detected [Na⁺]_i significantly increased in cells overexpressing NCX1.4 as well as ER Ca²⁺ content. This latter effect was prevented by tetrodotoxin. Furthermore, either the [Ca²⁺]_i chelator(1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid) (BAPTA-AM) or the PI3K inhibitor LY 294002 prevented Akt phosphorylation and GAP-43 protein expression rise in NCX1.4 overexpressing cells. Moreover, in primary cortical neurons, NCX1 silencing prevented Akt phosphorylation, GAP-43 and MAP2 overexpression, and neurite elongation. Collectively, these data show that NCX1 participates in neuronal differentiation through the modulation of ER Ca²⁺ content and PI3K signaling.     

Multiple Cation Channels Mediate Increases in Intracellular Calcium Induced by the Volatile Irritant, Trans-2-Pentenal in Rat Trigeminal Neurons

Trans-2-Pentenal (pentenal), an α,β-unsaturated aldehyde, induces increases in [Ca²⁺]_i in cultured neonatal rat trigeminal ganglion (TG) neurons. Since all pentenal-sensitive neurons responded to a specific TRPA1 agonist, allyl isothiocyanate (AITC) and neurons from TRPA1 knockouts failed to respond to pentenal, TRPA1 appears to be sole initial transduction site for pentenal-evoked trigeminal response, as reported for the structurally related irritant, acrolein. Furthermore, because the neuronal sensitivity to pentenal is strictly dependent upon the presence of extracellular Na⁺/Ca²⁺, as we showed previously, we investigated which types of voltage-gated sodium/calcium channels (VGSCs/VGCCs) are involved in pentenal-induced [Ca²⁺]_i increases as a downstream mechanisms. The application of tetrodotoxin (TTX) significantly suppressed the pentenal-induced increase in [Ca²⁺]_i in a portion of TG neurons, suggesting that TTX-sensitive (TTXs) VGSCs contribute to the pentenal response in those neurons. Diltiazem and ω-agatoxin IVA, antagonists of L- and P/Q-type VGCCs, respectively, both caused significant reductions of the pentenal-induced responses. ω-Conotoxin GVIA, on the other hand, caused only a small decrease in the size of pentenal-induced [Ca²⁺]_i rise. These indicate that both L- and P/Q-type VGCCs are involved in the increase in [Ca²⁺]_i produced by pentenal, while N-type calcium channels play only a minor role. This study demonstrates that TTXs VGSCs, L- and P/Q-type VGCCs play a significant role in the pentenal-induced trigeminal neuronal responses as downstream mechanisms following TRPA1 activation.     

Relationship between Intracellular Na+ Concentration and Reduced Na+ Affinity in Na+,K+-ATPase Mutants Causing Neurological Disease

The neurological disorders familial hemiplegic migraine type 2 (FHM2), alternating hemiplegia of childhood (AHC), and rapid-onset dystonia parkinsonism (RDP) are caused by mutations of Na⁺,K⁺-ATPase α₂ and α₃ isoforms, expressed in glial and neuronal cells, respectively. Although these disorders are distinct, they overlap in phenotypical presentation. Two Na⁺,K⁺-ATPase mutations, extending the C terminus by either 28 residues (“+28” mutation) or an extra tyrosine (“+Y”), are associated with FHM2 and RDP, respectively. We describe here functional consequences of these and other neurological disease mutations as well as an extension of the C terminus only by a single alanine. The dependence of the mutational effects on the specific α isoform in which the mutation is introduced was furthermore studied. At the cellular level we have characterized the C-terminal extension mutants and other mutants, addressing the question to what extent they cause a change of the intracellular Na⁺ and K⁺ concentrations ([Na⁺]_i and [K⁺]_i) in COS cells. C-terminal extension mutants generally showed dramatically reduced Na⁺ affinity without disturbance of K⁺ binding, as did other RDP mutants. No phosphorylation from ATP was observed for the +28 mutation of α₂ despite a high expression level. A significant rise of [Na⁺]_i and reduction of [K⁺]_i was detected in cells expressing mutants with reduced Na⁺ affinity and did not require a concomitant reduction of the maximal catalytic turnover rate or expression level. Moreover, two mutations that increase Na⁺ affinity were found to reduce [Na⁺]_i. It is concluded that the Na⁺ affinity of the Na⁺,K⁺-ATPase is an important determinant of [Na⁺]_i.     

Properties of Calmodulin Binding to NaV1.2 IQ Motif and Its Autism-Associated Mutation R1902C

Voltage-gated sodium channels (VGSCs) are fundamental to the initiation and propagation of action potentials in excitable cells. Ca²⁺/calmodulin (CaM) binds to VGSC type II (Na_V1.2) isoleucine and glutamine (IQ) motif. An autism-associated mutation in Na_V1.2 IQ motif, Arg1902Cys (R1902C), has been reported to affect the combination between CaM and the IQ motif compared to that of the wild type IQ motif. However, the detailed properties for the Ca²⁺-regulated binding of CaM to Na_V1.2 IQ (1901Lys-1927Lys, IQ_wt) and mutant IQ motif (IQ_R1902C) remains unclear. Here, the binding ability of CaM and CaM's constituent proteins including N- and C lobe to the IQ motif of Na_V1.2 and its mutant was investigated by protein pull-down experiments. We discovered that the combination between CaM and the IQ motif was U-shaped with the highest at [Ca²⁺] ≈ free and the lowest at 100 nM [Ca²⁺]. In the IQ_R1902C mutant, Ca²⁺-dependence of CaM binding was nearly lost. Consequently, the binding of CaM to IQ_R1902C at 100 and 500 nM [Ca²⁺] was increased compared to that of IQ_wt. Both N- and C lobe of CaM could bind with Na_V1.2 IQ motif and IQ_R1902C mutant, with the major effect of C lobe. Furthermore, CaMKII had no impact on the binding between CaM and Na_V1.2 IQ motif. This research offers novel insight to the regulation of Na_V1.2 IQ_wt and IQ_R1902C motif, an autism-associated mutation, by CaM.