TRPC1 regulates calcium‐activated chloride channels in salivary gland cells

Calcium‐activated chloride channel (CaCC) plays an important role in modulating epithelial secretion. It has been suggested that in salivary tissues, sustained fluid secretion is dependent on Ca²⁺ influx that activates ion channels such as CaCC to initiate Cl^? efflux. However direct evidence as well as the molecular identity of the Ca²⁺ channel responsible for activating CaCC in salivary tissues is not yet identified. Here we provide evidence that in human salivary cells, an outward rectifying Cl^? current was activated by increasing [Ca²⁺]_i, which was inhibited by the addition of pharmacological agents niflumic acid (NFA), an antagonist of CaCC, or T16Ainh‐A01, a specific TMEM16a inhibitor. Addition of thapsigargin (Tg), that induces store‐depletion and activates TRPC1‐mediated Ca²⁺ entry, potentiated the Cl^? current, which was inhibited by the addition of a non‐specific TRPC channel blocker SKF96365 or removal of external Ca²⁺. Stimulation with Tg also increased plasma membrane expression of TMEM16a protein, which was also dependent on Ca²⁺ entry. Importantly, in salivary cells, TRPC1 silencing, but not that of TRPC3, inhibited CaCC especially upon store depletion. Moreover, primary acinar cells isolated from submandibular gland also showed outward rectifying Cl^? currents upon increasing [Ca²⁺]_i. These Cl^? currents were again potentiated with the addition of Tg, but inhibited in the presence of T16Ainh‐A01. Finally, acinar cells isolated from the submandibular glands of TRPC1 knockout mice showed significant inhibition of the outward Cl^? currents without decreasing TMEM16a expression. Together the data suggests that Ca²⁺ entry via the TRPC1 channels is essential for the activation of CaCC. J. Cell. Physiol. 9999: 2848–2856, 2015. © 2015 Wiley Periodicals, Inc.

     

Calmodulin-dependent activation and inactivation of anoctamin calcium-gated chloride channels

Calcium-dependent chloride channels serve critical functions in diverse biological systems. Driven by cellular calcium signals, the channels codetermine excitatory processes and promote solute transport. The anoctamin (ANO) family of membrane proteins encodes three calcium-activated chloride channels, named ANO 1 (also TMEM16A), ANO 2 (also TMEM16B), and ANO 6 (also TMEM16F). Here we examined how ANO 1 and ANO 2 interact with Ca²⁺/calmodulin using nonstationary current analysis during channel activation. We identified a putative calmodulin-binding domain in the N-terminal region of the channel proteins that is involved in channel activation. Binding studies with peptides indicated that this domain, a regulatory calmodulin-binding motif (RCBM), provides two distinct modes of interaction with Ca²⁺/calmodulin, one at submicromolar Ca²⁺ concentrations and one in the micromolar Ca²⁺ range. Functional, structural, and pharmacological data support the concept that calmodulin serves as a calcium sensor that is stably associated with the RCBM domain and regulates the activation of ANO 1 and ANO 2 channels. Moreover, the predominant splice variant of ANO 2 in the brain exhibits Ca²⁺/calmodulin-dependent inactivation, a loss of channel activity within 30 s. This property may curtail ANO 2 activity during persistent Ca²⁺ signals in neurons. Mutagenesis data indicated that the RCBM domain is also involved in ANO 2 inactivation, and that inactivation is suppressed in the retinal ANO 2 splice variant. These results advance the understanding of Ca²⁺ regulation in anoctamin Cl⁻ channels and its significance for the physiological function that anoctamin channels subserve in neurons and other cell types.     

Presynaptic Localization and Possible Function of Calcium-Activated Chloride Channel Anoctamin 1 in the Mammalian Retina

Calcium (Ca²⁺)-activated chloride (Cl⁻) channels (CaCCs) play a role in the modulation of action potentials and synaptic responses in the somatodendritic regions of central neurons. In the vertebrate retina, large Ca²⁺-activated Cl⁻ currents (I_Cl(Ca)) regulate synaptic transmission at photoreceptor terminals; however, the molecular identity of CaCCs that mediate I_Cl(Ca) remains unclear. The transmembrane protein, TMEM16A, also called anoctamin 1 (ANO1), has been recently validated as a CaCC and is widely expressed in various secretory epithelia and nervous tissues. Despite the fact that tmem16a was first cloned in the retina, there is little information on its cellular localization and function in the mammalian retina. In this study, we found that ANO1 was abundantly expressed as puncta in 2 synaptic layers. More specifically, ANO1 immunoreactivity was observed in the presynaptic terminals of various retinal neurons, including photoreceptors. I_Cl(Ca) was first detected in dissociated rod bipolar cells expressing ANO1. I_Cl(Ca) was abolished by treatment with the Ca²⁺ channel blocker Co²⁺, the L-type Ca²⁺ channel blocker nifedipine, and the Cl⁻ channel blockers 5-nitro-2-(3-phenylpropylamino) benzoic acid (NPPB) and niflumic acid (NFA). More specifically, a recently discovered ANO1-selective inhibitor, T16A_inh-A01, and a neutralizing antibody against ANO1 inhibited I_Cl(Ca) in rod bipolar cells. Under a current-clamping mode, the suppression of I_Cl(Ca) by using NPPB and T16A_inh-A01 caused a prolonged Ca²⁺ spike-like depolarization evoked by current injection in dissociated rod bipolar cells. These results suggest that ANO1 confers I_Cl(Ca) in retinal neurons and acts as an intrinsic regulator of the presynaptic membrane potential during synaptic transmission.     

Synthesis and evaluation of 18F-hexafluorophosphate as a novel PET probe for imaging of sodium/iodide symporter in a murine C6-glioma tumor model

Noninvasive imaging of iodide uptake via the sodium/iodide symporter (NIS) has received great interest for evaluation of thyroid cancer and reporter imaging of NIS-expressing viral therapies. In this study, we investigate ¹⁸F-labeled hexafluorophosphate (HFP or PF₆^?) as a high-affinity iodide analog for NIS imaging. ¹⁸F-HFP was synthesized by radiofluorination of phosphorus pentafluoride·N-methylpyrrolidine complex and evaluated in human NIS (hNIS)-expressing C6 glioma cells and a C6 glioma xenograft mouse model. ¹⁸F-HFP was obtained in radiochemical yield of 10?±?5%, radiochemical purity of >96% and specific radioactivity of 604?±?18?MBq/µmol. Specific uptake of ¹⁸F-HFP and high affinity of ¹⁹F-HFP were observed in hNIS+ C6-glioma cells. PET imaging showed robust uptake of ¹⁸F-HFP in NIS-expressing tissues (thyroid, stomach, and hNIS+ C6 glioma xenografts), and the uptake of ¹⁸F-HFP was blocked by NaClO₄ pretreatment. Specific accumulation in hNIS-expressing xenograft (hNIS+) was observed relative to isogenic control tumor (hNIS?). Clearance of ¹⁸F-HFP was predominantly through renal excretion. The biodistribution showed consistent results with PET imaging. Minimal bone uptake was observed over 2?h period post-injection, indicating excellent in vivo stability of ¹⁸F-HFP. Although improvement in specific radioactivity is desirable, the results indicate that ¹⁸F-HFP is a promising candidate radiotracer for further evaluation for NIS imaging.     

Chronic exposure to stress hormones alters the subtype of store‐operated channels expressed in H19‐7 hippocampal neuronal cells

Differentiating H19‐7 hippocampal precursor cells up‐regulate (～4.3‐fold) store‐operated channel (SOC) activity; relatively linear current‐voltage curves indicate an I_SOC subtype of SOC. In differentiated H19‐7 neurons, the majority of agonist (arginine vasopressin, AVP)‐stimulated Ca²⁺ entry occurs via SOCs, based on 2‐aminoethyldiphenylborinate (2‐APB) inhibition data and the observation that transient receptor potential C1 (TRPC1) channel knock down cells show a dramatic reduction of thapsigargin‐stimulated store‐operated Ca²⁺ entry (SOCE) and inhibition of AVP‐stimulated Ca²⁺ entry. Treatment of H19‐7 cells with the rat stress hormone corticosterone during differentiation induces a significant increase in AVP‐stimulated Ca²⁺ entry, which is virtually eliminated by 2‐APB, suggesting a corticosterone‐induced increase of SOCE. Corticosterone also enhances AVP‐stimulated Mn²⁺ entry, confirming an elevated Ca²⁺ entry pathway, rather than a decreased Ca²⁺ extrusion. When corticosterone addition is delayed until after H19‐7 cells have fully differentiated, it still elevates SOCE. In corticosterone‐treated H19‐7 cells, the knock down of TRPC1 no longer blocks thapsigargin‐stimulated Ca²⁺ entry suggesting that the subtype of SOCs expressed in H19‐7 cells is altered by corticosterone treatment. Electrophysiological studies demonstrate that store‐operated currents in corticosterone‐treated H19‐7 cells exhibit a highly inward rectifying current‐voltage curve consistent with an I_CRAC subtype of SOCs. Consistent with this finding is the observation that corticosterone treatment of H19‐7 cells increases the expression of the I_CRAC channel subunit Orai1. Thus, the subtype of SOCs expressed in H19‐7 hippocampal neurons can be altered from I_SOC to I_CRAC by chronic treatment with stress hormones. J. Cell. Physiol. 228: 1332–1343, 2013. © 2012 Wiley Periodicals, Inc.     

Anoctamin Calcium-Activated Chloride Channels May Modulate Inhibitory Transmission in the Cerebellar Cortex

Calcium-activated chloride channels of the anoctamin (alias TMEM16) protein family fulfill critical functions in epithelial fluid transport, smooth muscle contraction and sensory signal processing. Little is known, however, about their contribution to information processing in the central nervous system. Here we examined the recent finding that a calcium-dependent chloride conductance impacts on GABAergic synaptic inhibition in Purkinje cells of the cerebellum. We asked whether anoctamin channels may underlie this chloride conductance. We identified two anoctamin channel proteins, ANO1 and ANO2, in the cerebellar cortex. ANO1 was expressed in inhibitory interneurons of the molecular layer and the granule cell layer. Both channels were expressed in Purkinje cells but, while ANO1 appeared to be retained in the cell body, ANO2 was targeted to the dendritic tree. Functional studies confirmed that ANO2 was involved in a calcium-dependent mode of ionic plasticity that reduces the efficacy of GABAergic synapses. ANO2 channels attenuated GABAergic transmission by increasing the postsynaptic chloride concentration, hence reducing the driving force for chloride influx. Our data suggest that ANO2 channels are involved in a Ca²⁺-dependent regulation of synaptic weight in GABAergic inhibition. Thus, in balance with the chloride extrusion mechanism via the co-transporter KCC2, ANO2 appears to regulate ionic plasticity in the cerebellum.     

A Coding Variant of ANO10, Affecting Volume Regulation of Macrophages,Is Associated with Borrelia Seropositivity

In a first genome-wide association study (GWAS) approach to anti-Borrelia seropositivity, we identified two significant single nucleotide polymorphisms (SNPs) (rs17850869, P = 4.17E-09; rs41289586, P = 7.18E-08). Both markers, located on chromosomes 16 and 3, respectively, are within or close to genes previously connected to spinocerebellar ataxia. The risk SNP rs41289586 represents a missense variant (R263H) of anoctamin 10 (ANO10), a member of a protein family encoding Cl⁻ channels and phospholipid scram-blases. ANO10 augments volume-regulated Cl⁻ currents (I_Hypo) in Xenopus oocytes, HEK293 cells, lymphocytes and macrophages and controls volume regulation by enhancing regulatory volume decrease (RVD). ANO10 supports migration of macrophages and phagocytosis of spirochetes. The R263H variant is inhibitory on I_Hypo, RVD and intracellular Ca²⁺ signals, which may delay spirochete clearance, thereby sensitizing adaptive immunity. Our data demonstrate for the first time that ANO10 has a central role in innate immune defense against Borrelia infection.     

A nonradioactive iodide uptake assay for sodium iodide symporter function

The standard assay for sodium iodide symporter (NIS) function is based on the measurement of radioiodide uptake (¹²⁵I) in NIS-expressing cells. However, cost and safety issues have limited the method from being used widely. Here we describe a simple spectrophotometric assay for the determination of iodide accumulation in rat thyroid-derived cells (FRTL5) based on the catalytic effect of iodide on the reduction of yellow cerium(IV) to colorless cerium(III) in the presence of arsenious acid (Sandell-Kolthoff reaction). The assay is fast and highly reproducible with a Z′ factor of 0.70. This procedure allows the screening of more than 800 samples per day and can easily be adapted to robotic systems for high-throughput screening of NIS function modulators. Using this method, the potency of several known inhibitors of NIS function was evaluated in a single day with high accuracy and reliability. Measured IC₅₀ values were essentially identical to those determined using Na¹²⁵I.     

Expression and Function of Epithelial Anoctamins

The calcium-activated chloride channel anoctamin1 (ANO1; TMEM16A) is fundamental for the function of epithelial organs. Mice lacking ANO1 expression exhibit transport defects and a pathology similar to cystic fibrosis. They also show a general defect of epithelial electrolyte transport. Here we analyzed expression of all ten members (ANO1–ANO10) in a broad range of murine tissues and detected predominant expression of ANO1, 6, 7, 8, 9, 10 in epithelial tissues, while ANO2, 3, 4, 5 are common in neuronal and muscle tissues. When expressed in Fisher Rat Thyroid (FTR) cells, all ANO proteins localized to the plasma membrane but only ANO1, 2, 6, and 7 produced Ca²⁺-activated Cl⁻ conductance, as analyzed by ATP-induced iodide quenching of YFP fluorescence. In contrast ANO9 and ANO10 suppressed baseline Cl⁻ conductance and coexpression of ANO9 with ANO1 inhibited ANO1 activity. Patch clamping of ANO-expressing FRT cells indicated that apart from ANO1 also ANO6 and 10 produced chloride currents, albeit with very different Ca²⁺ sensitivity and activation time. We conclude that each tissue expresses a set of anoctamins that form cell- and tissue-specific Ca²⁺-dependent Cl⁻ channels.     

House dust mite extract activates apical Cl− channels through protease‐activated receptor 2 in human airway epithelia

Adequate fluid secretion from airway mucosa is essential for maintaining mucociliary clearance, and fluid hypersecretion is a prominent feature of inflammatory airway diseases such as allergic rhinitis. House dust mite extract (HDM) has been reported to activate protease‐activated receptors (PARs), which play various roles in airway epithelia. However, the role of HDM in regulating ion transporters and fluid secretion has not been investigated. We examined the effect of HDM on ion transport in human primary nasal epithelial cells. The Ca²⁺‐sensitive dye Fura2‐AM was used to determine intracellular Ca²⁺ concentration ([Ca²⁺]_i) by means of spectrofluorometry in human normal nasal epithelial cells (NHNE). Short‐circuit current (Isc) was measured using Ussing chambers. Fluid secretion from porcine airway mucosa was observed by optical measurement. HDM extract (10 µg/Ml) effectively cleaved the PAR‐2 peptide and induced an increase of [Ca²⁺]_i that was abolished by desensitization with trypsin, but not with thrombin. Apical application of HDM‐induced Isc sensitive to both a cystic fibrosis transmembrane conductance regulator (CFTR) inhibitor and a Ca²⁺‐activated Cl^? channel (CaCC) inhibitor. HDM extract also stimulated fluid secretion from porcine airway mucosa. HDM extract activated PAR‐2 and apical Cl^? secretion via CaCC and CFTR, and HDM‐induced fluid secretion in porcine airway mucosa. Our results suggest a role for PAR‐2 in mucociliary clearance and fluid hypersecretion of airway mucosa in response to air‐borne allergens such as HDM. J. Cell. Biochem. 109: 1254–1263, 2010. © 2010 Wiley‐Liss, Inc.     

Functional organization of TRPC-Ca channels and regulation of calcium microdomains

TRP family of proteins are components of unique cation channels that are activated in response to diverse stimuli ranging from growth factor and neurotransmitter stimulation of plasma membrane receptors to a variety of chemical and sensory signals. This review will focus on members of the TRPC sub-family (TRPC1–TRPC7) which currently appear to be the strongest candidates for the enigmatic Ca²⁺ influx channels that are activated in response to stimulation of plasma membrane receptors which result in phosphatidyl inositol-(4,5)-bisphosphate (PIP₂) hydrolysis, generation of IP₃ and DAG, and IP₃-induced Ca²⁺ release from the intracellular Ca²⁺ store via inositol trisphosphate receptor (IP₃R). Homomeric or selective heteromeric interactions between TRPC monomers generate distinct channels that contribute to store-operated as well as store-independent Ca²⁺ entry mechanisms. The former is regulated by the emptying/refilling of internal Ca²⁺ store(s) while the latter depends on PIP₂ hydrolysis (due to changes in PIP₂ per se or an increase in diacylglycerol, DAG). Although the exact physiological function of TRPC channels and how they are regulated has not yet been conclusively established, it is clear that a variety of cellular functions are controlled by Ca²⁺ entry via these channels. Thus, it is critical to understand how cells coordinate the regulation of diverse TRPC channels to elicit specific physiological functions. It is now well established that segregation of TRPC channels mediated by interactions with signaling and scaffolding proteins, determines their localization and regulation in functionally distinct cellular domains. Furthermore, both protein and lipid components of intracellular and plasma membranes contribute to the organization of these microdomains. Such organization serves as a platform for the generation of spatially and temporally dictated [Ca²⁺]_i signals which are critical for precise control of downstream cellular functions.     

Involvement of TRP channels in the signal transduction of bradykinin in human osteoblasts

Bradykinin (BK), a mediator of pain and inflammation, is involved in bone metabolism. We have previously reported that BK increased the synthesis of interleukin-6 and prostaglandin E₂ via phosphorylation of ERK1/2 in human osteoblasts, SaM-1. In the present study, we investigated the signal transduction pathway of BK focusing on intracellular Ca²⁺ kinetics in SaM-1 cells. Bath-applied BK increased intracellular Ca²⁺ concentration through the activation of B₂ receptors. Removal of extracellular Ca²⁺ attenuated the effects of BK. Additionally, thapsigargin, endoplasmic reticulum Ca²⁺ pump inhibitor, completely inhibited BK-induced increase of intracellular Ca²⁺. These results suggested that bath-applied BK activated store-operated Ca²⁺ channels (SOCCs) following Ca²⁺ store depletion via B₂ receptor. Although the molecular components of SOCCs have yet to be conclusively identified in all cell types, recent studies demonstrated that transient receptor potential canonical (TRPC) channels are candidates for them. TRPC1, TRPC3, TRPC4 and TRPC6 were expressed in SaM-1 cells and inhibitors of TRP channel, 2-aminoethoxydiphenyl borate, GdCl₃, LaCl₃ and flufenamic acid, inhibited the effects of BK. These findings suggested that BK activated SOCCs and induced Ca²⁺ influx via B₂ receptor in human osteoblasts. Molecular components of the SOCCs are suggested to be TRPC channels.     

Focus on TRP channels in cystic fibrosis

The Transient Receptor Potential (TRP) protein superfamily is a group of cation channels expressed in various cell types and involved in respiratory diseases such as cystic fibrosis (CF), the genetic disease caused by CF Transmembrane conductance Regulator (CFTR) mutations. In human airway epithelial cells, there is growing evidence for a functional link between CFTR and TRP channels. TRP channels contribute to transmitting extracellular signals into the cells and, in an indirect manner, to CFTR activity via a Ca²⁺ rise signaling. Indeed, mutated CFTR-epithelial cells are characterized by an increased Ca²⁺ influx and, on the opposite, by a decreased of magnesium influx, both being mediated by TRP channels. This increasing cellular Ca²⁺ triggers the activation of calcium-activated chloride channels (CaCC) or CFTR itself, via adenylyl cyclase, PKA and tyrosine kinases activation, but also leads to an exaltation of the inflammatory response. Another shortcoming in mutated CFTR-epithelial cells is a [Mg²⁺]_i decrease, associated with impaired TRPM7 functioning. This deregulation has to be taken into consideration in CF physiopathology, as Mg²⁺ is required for ATP hydrolysis and CFTR activity. The modulation of druggable TRP channels could supplement CF therapy either an anti-inflammatory drug or for CFTR potentiation, according to the balance between exacerbation and respite phases. The present paper focus on TRPA1, TRPC6, TRPM7, TRPV2, TRPV4, TRPV6 and ORAI 1, the proteins identified, for now, as dysfunctional channels, in CF cells.     

TRPC1 protein forms only one type of native store-operated channels in HEK293 cells

TRPC1 is a major component of store-operated calcium entry in many cell types. In our previous studies, three types of endogenous store-operated calcium channels have been described in HEK293 cells, but it remained unknown which of these channels are composed of TRPC1 proteins. Here, this issue has been addressed by performing single-channel analysis in HEK293 cells transfected with anti-TRPC1 siRNA (siTPRC1) or a TPRC1-encoding plasmid. The results show that thapsigargin-or agonist-induced calcium influx is significantly attenuated in siTRPC1-transfected HEK293 cells. TRPC1 knockdown by siRNA results in the disappearance of store-operated I_max channels, while the properties of I_min and I_NS channels are unaffected. In HEK293 cells with overexpressed TRPC1 protein, the unitary current–voltage relationship of exogenous TRPC1 channels is almost linear, with a slope conductance of about 17 pS. The extrapolated reversal potential of expressed TRPC1 channels is +30 mV. Therefore, the main electrophysiological and regulatory properties of expressed TRPC1 and native I_max channels are identical. Moreover, TRPC1 overexpression in HEK293 cells results in an increased number of store-operated I_max channels. All these data allow us to conclude that TRPC1 protein forms native store-operated I_max channels but is not an essential subunit for other store-operated channel types in HEK293 cells.     

Agonist-activated Ca2+ influx and Ca2+ -dependent Cl- channels in Xenopus ovarian follicular cells: functional heterogeneity within the cell monolayer

Xenopus follicles are endowed with specific receptors for ATP, ACh, and AII, transmitters proposed as follicular modulators of gamete growth and maturation in several species. Here, we studied ion‐current responses elicited by stimulation of these receptors and their activation mechanisms using the voltage‐clamp technique. All agonists elicited Cl^? currents that depended on coupling between oocyte and follicular cells and on an increase in intracellular Ca²⁺ concentration ([Ca²⁺]_i), but they differed in their activation mechanisms and in the localization of the molecules involved. Both ATP and ACh generated fast Cl^? (F_Cl) currents, while AII activated an oscillatory response; a robust Ca²⁺ influx linked specifically to F_Cl activation elicited an inward current (I_iw,Ca) which was carried mainly by Cl^? ions, through channels with a sequence of permeability of SCN^? > I^? > Br^? > Cl^?. Like F_Cl, I_iw,Ca was not dependent on oocyte [Ca²⁺]_i; instead both were eliminated by preventing [Ca²⁺]_i increase in the follicular cells, and also by U73122 and 2‐APB, drugs that inhibit the phospolipase C (PLC) pathway. The results indicated that F_Cl and I_iw,Ca were produced by the expected, PLC‐stimulated Ca²⁺‐release and Ca²⁺‐influx, respectively, and by the opening of I_Cl(Ca) channels located in the follicular cells. Given their pharmacological characteristics and behavior in conditions of divalent cation deprivation, Ca²⁺‐influx appeared to be driven through store‐operated, calcium‐like channels. The AII response, which is also known to require PLC activation, did not activate I_iw,Ca and was strictly dependent on oocyte [Ca²⁺]_i increase; thus, ATP and ACh receptors seem to be expressed in a population of follicular cells different from that expressing AII receptors, which were coupled to the oocyte through distinct gap‐junction channels. J. Cell. Physiol. 227: 3457–3470, 2012. © 2011 Wiley Periodicals, Inc.     

Na+/I− Symporter and Type 3 Iodothyronine Deiodinase Gene Expression in Amniotic Membrane and Placenta and Its Relationship to Maternal Thyroid Hormones

Placental type 3 iodothyronine deiodinase (D3) potentially protects the fetus from the elevated maternal thyroid hormones. Na⁺/I^? symporter (NIS) is a plasma membrane glycoprotein, which mediates active iodide uptake. Our objectives were to establish the distribution of NIS and D3 gene expressions in the placenta and the amniotic membrane and to investigate the relationship between placental D3 and NIS gene expressions and maternal iodine, selenium, and thyroid hormone status. Thyroid hormones, urinary iodine concentration (UIC), and selenium levels were measured in 49 healthy term pregnant women. NIS and D3 gene expressions were studied with the total mRNA RT-PCR method in tissues from maternal placenta (n?=?49), fetal placenta (n?=?9), and amniotic membrane (n?=?9). NIS and D3 gene expressions were shown in the fetal and maternal sides of the placenta and amniotic membrane. Mean blood selenium level was 66?±?26.5 μg/l, and median UIC was 143 μg/l. We could not demonstrate any statistically significant relationship of spot UIC and blood selenium with NIS and D3 expression (p?>?0.05). Positive correlations were found between NIS and thyroxine-binding globulin (TBG) (r?=?0.3, p?=?0.042) and between D3 and preoperative glucose levels (r?=?0.4, p?=?0.006). D3 and NIS genes are expressed in term placenta and amniotic membrane; thus, in addition to placenta, amniotic membrane contributes to regulation of maternofetal iodine and thyroid hormone transmission. Further studies are needed to clarify the relationship between maternal glucose levels and placental D3 expression and between TBG and placental NIS expression.     

Local Ca²+ entry via Orai1 regulates plasma membrane recruitment of TRPC1 and controls cytosolic Ca²+ signals required for specific cell functions

Store-operated Ca²⁺ entry (SOCE) has been associated with two types of channels: CRAC channels that require Orai1 and STIM1 and SOC channels that involve TRPC1, Orai1, and STIM1. While TRPC1 significantly contributes to SOCE and SOC channel activity, abrogation of Orai1 function eliminates SOCE and activation of TRPC1. The critical role of Orai1 in activation of TRPC1-SOC channels following Ca²⁺ store depletion has not yet been established. Herein we report that TRPC1 and Orai1 are components of distinct channels. We show that TRPC1/Orai1/STIM1-dependent I_SOC, activated in response to Ca²⁺ store depletion, is composed of TRPC1/STIM1-mediated non-selective cation current and Orai1/STIM1-mediated I_CRAC; the latter is detected when TRPC1 function is suppressed by expression of shTRPC1 or a STIM1 mutant that lacks TRPC1 gating, STIM1(⁶⁸⁴EE⁶⁸⁵). In addition to gating TRPC1 and Orai1, STIM1 mediates the recruitment and association of the channels within ER/PM junctional domains, a critical step in TRPC1 activation. Importantly, we show that Ca²⁺ entry via Orai1 triggers plasma membrane insertion of TRPC1, which is prevented by blocking SOCE with 1 µM Gd³⁺, removal of extracellular Ca²⁺, knockdown of Orai1, or expression of dominant negative mutant Orai1 lacking a functional pore, Orai1-E106Q. In cells expressing another pore mutant of Orai1, Orai1-E106D, TRPC1 trafficking is supported in Ca²⁺-containing, but not Ca²⁺-free, medium. Consistent with this, I_CRAC is activated in cells pretreated with thapsigargin in Ca²⁺-free medium while I_SOC is activated in cells pretreated in Ca²⁺-containing medium. Significantly, TRPC1 function is required for sustained K_Ca activity and contributes to NFκB activation while Orai1 is sufficient for NFAT activation. Together, these findings reveal an as-yet unidentified function for Orai1 that explains the critical requirement of the channel in the activation of TRPC1 following Ca²⁺ store depletion. We suggest that coordinated regulation of the surface expression of TRPC1 by Orai1 and gating by STIM1 provides a mechanism for rapidly modulating and maintaining SOCE-generated Ca²⁺ signals. By recruiting ion channels and other signaling pathways, Orai1 and STIM1 concertedly impact a variety of critical cell functions that are initiated by SOCE.     

Activation and Inhibition of TMEM16A Calcium-Activated Chloride Channels

Calcium-activated chloride channels (CaCC) encoded by family members of transmembrane proteins of unknown function 16 (TMEM16) have recently been intensely studied for functional properties as well as their physiological roles as chloride channels in various tissues. One technical hurdle in studying these channels is the well-known channel rundown that frequently impairs the precision of electrophysiological measurements for the channels. Using experimental protocols that employ fast-solution exchange, we circumvented the problem of channel rundown by normalizing the Ca²⁺-induced current to the maximally-activated current obtained within a time period in which the channel rundown was negligible. We characterized the activation of the TMEM16A-encoded CaCC (also called ANO1) by Ca²⁺, Sr²⁺, and Ba²⁺, and discovered that Mg²⁺ competes with Ca²⁺ in binding to the divalent-cation binding site without activating the channel. We also studied the permeability of the ANO1 pore for various anions and found that the anion occupancy in the pore–as revealed by the permeability ratios of these anions–appeared to be inversely correlated with the apparent affinity of the ANO1 inhibition by niflumic acid (NFA). On the other hand, the NFA inhibition was neither affected by the degree of the channel activation nor influenced by the types of divalent cations used for the channel activation. These results suggest that the NFA inhibition of ANO1 is likely mediated by altering the pore function but not through changing the channel gating. Our study provides a precise characterization of ANO1 and documents factors that can affect divalent cation activation and NFA inhibition of ANO1.     

Current view on regulation of voltage‐gated sodium channels by calcium and auxiliary proteins

In cardiac and skeletal myocytes, and in most neurons, the opening of voltage‐gated Na⁺ channels (Na_V channels) triggers action potentials, a process that is regulated via the interactions of the channels’ intercellular C‐termini with auxiliary proteins and/or Ca²⁺. The molecular and structural details for how Ca²⁺ and/or auxiliary proteins modulate Na_V channel function, however, have eluded a concise mechanistic explanation and details have been shrouded for the last decade behind controversy about whether Ca²⁺ acts directly upon the Na_V channel or through interacting proteins, such as the Ca²⁺ binding protein calmodulin (CaM). Here, we review recent advances in defining the structure of Na_V intracellular C‐termini and associated proteins such as CaM or fibroblast growth factor homologous factors (FHFs) to reveal new insights into how Ca²⁺ affects Na_V function, and how altered Ca²⁺‐dependent or FHF‐mediated regulation of Na_V channels is perturbed in various disease states through mutations that disrupt CaM or FHF interaction.