Ion channel gene expression in human lung, skin, and cord blood-derived mast cells

Immunoglobulin E (IgE)-dependent activation of human mast cells (HMC) is characterized by an influx of extracellular calcium (Ca(2+)), which is essential for subsequent release of preformed (granule-derived) mediators and newly generated autacoids and cytokines. In addition, flow of ions such as K(+) and Cl(-) is likely to play an important role in mast cell activation, proliferation, and chemotaxis through their effect on membrane potential and thus Ca(2+) influx. It is therefore important to identify these critical molecular effectors of HMC function. In this study, we have used high-density oligonucleotide probe arrays to characterize for the first time the profile of ion channel gene expression in human lung, skin, and cord blood-derived mast cells. These cells express mRNA for inwardly rectifying and Ca(2+)-activated K(+) channels, voltage-dependent Na(+) and Ca(2+) channels, purinergic P2X channels, transient receptor potential channels, and voltage-dependent and intracellular Cl(-) channels. IgE-dependent activation had little effect on ion channel expression, but distinct differences for some channels were observed between the different mast cell phenotypes, which may contribute to the mechanism of functional mast cell heterogeneity.

Regulation of beta-amyloid precursor protein and inositol 1,4,5-trisphosphate receptor gene expression during differentiation of a human neuronal cell line

Retinoic acid-induced differentiation of SH-SY5Y human neuroblastoma cells results in the development of extensive neurite processes as well as changes in cell body morphology toward a neuronal phenotype. The authors have examined concurrent regulation of beta-amyloid precursor protein (APP) and inositol 1,4,5-trisphosphate receptor (insP(3)R) gene expression in SY5Y cells during neuronal differentiation. Of the multiple APP mRNA transcripts expressed in this cell line, retinoic acid treatment significantly increased the expression of APP(695) transcript while the level of total APP remained unchanged. In the same time course, neuronal differentiation decreased the expression of insP(3)R at both the mRNA and protein levels. These findings demonstrate an inverse relationship between APP and insP(3)R gene expression during neuronal differentiation of SH-SY5Y cells and suggest a possible change in intracellular calcium homeostasis.

Nature and expression of dihydropyridine-sensitive and -insensitive calcium currents in hair cells of frog semicircular canals

Ca(2+) currents in hair cells of the frog crista ampullaris were studied using the whole-cell patch-clamp technique. Currents were recorded in situ from hair cells in peripheral, intermediate and central regions of the sensory epithelium. Two types of Ca(2+) currents were found: a partially inactivating current that was expressed by nearly all central cells and by about 65% of intermediate and peripheral cells, and a sustained current expressed by the remaining cell population. The mean Ca(2+) current amplitude was larger in intermediate cells than in central or peripheral cells. The two types of Ca(2+) currents were composed of two components: a large, nifedipine-sensitive (NS) current and a small, nifedipine-insensitive (NI) current. The latter was resistant to SNX-482, omega-conotoxin MVIIC and omega-agatoxin IVA and to omega-conotoxin GVIA, antagonists of R, P/Q and N-type Ca(2+) channels. The amplitude of NS and NI currents varied among peripheral cells, where the current density gradually increased from the beginning of the region toward its end. No significant variation of Ca(2+) current density was detected in hair cells of either intermediate or central regions. These results demonstrate the presence of regional and intraregional variations in the expression of L and non-L Ca(2+) channels in the frog crista ampullaris. Finally, immunocytochemical investigations revealed the presence of Ca(2+) channel subunits of the alpha(1D) type and the unexpected expression of alpha(1B)-subunits.

Single channel function of inositol 1,4,5-trisphosphate receptor type-1 and -2 isoform domain-swap chimeras

The InsP3R proteins have three recognized domains, the InsP3-binding, regulatory/coupling, and channel domains (Mignery, G.A., and T.C. Südhof. 1990. EMBO J. 9:3893-3898). The InsP3 binding domain and the channel-forming domain are at opposite ends of the protein. Ligand regulation of the channel must involve communication between these different regions of the protein. This communication likely involves the interceding sequence (i.e., the regulatory/coupling domain). The single channel functional attributes of the full-length recombinant type-1, -2, and -3 InsP3R channels have been defined. Here, two type-1/type-2 InsP3R regulatory/coupling domain chimeras were created and their single channel function defined. One chimera (1-2-1) contained the type-2 regulatory/coupling domain in a type-1 backbone. The other chimera (2-1-2) contained the type-1 regulatory/coupling domain in a type-2 backbone. These chimeric proteins were expressed in COS cells, isolated, and then reconstituted in proteoliposomes. The proteoliposomes were incorporated into artificial planar lipid bilayers and the single-channel function of the chimeras defined. The chimeras had permeation properties like that of wild-type channels. The ligand regulatory properties of the chimeras were altered. The InsP3 and Ca2+ regulation had some unique features but also had features in common with wild-type channels. These results suggest that different independent structural determinants govern InsP3R permeation and ligand regulation. It also suggests that ligand regulation is a multideterminant process that involves several different regions of the protein. This study also demonstrates that a chimera approach can be applied to define InsP3R structure-function.

Temporal alterations in voltage gated Ca2+ channel immunoreactivities in the gerbil hippocampus following ischemic insults

In the present study, temporal changes of voltage-gated Ca(2+) channel (VGCC) immunoreactivities were evaluated in the gerbil hippocampus following ischemia. P/Q-type VGCC immunoreactivity was elevated in the hippocampus in the 3 h post-ischemic group. In the 30 min post-ischemic group, N-type VGCC immunoreactivity began to increase only in the CA1 region. L-type (alpha1C) VGCC immunoreactivity was significantly increased in the 12 h post-ischemic group. L-type (alpha1D) VGCC immunoreactivity began to increase in the CA1 region in the 30 min post-ischemic group and peaked in the 12 h post-ischemic group. These findings suggest that the altered VGCC immunoreactivities following ischemia may play an important role in the ischemic neuronal injury.

Expression profiles of three isoforms of inositol 1,4,5-trisphosphate receptor in brown adipose tissue of the rat

The thermogenic function of brown adipose tissue (BAT) is known to be mainly regulated by a signal transduction cascade via beta-adrenoceptor. However, recent studies indicated that the alpha-adrenoceptor and its downstream signal transduction cascade, causing elevation of the cellular Ca(2+) level, are also important for the regulation of this function of BAT. In the present study, expression profiles of 3 isoforms of the inositol 1,4,5-trisphosphate (IP(3)) receptor, known as one of the major components of the machinery regulating the intracellular Ca(2+) concentration in the BAT of rats, were investigated by Northern analysis. Of these three IP(3) receptor isoforms, the type 2 one was found to be the most abundant of the three in BAT. Furthermore, when rats were exposed to the cold, under which condition the thermogenic function of BAT is known to be stimulated, the expression levels of types 1 and 2 isoforms of IP(3) receptor were remarkably elevated. The results of Western analysis supported the predominant expression of the type 2 isoform in BAT. However, different from the results of Northern analysis, the expression levels of types 1 and 2 isoforms of IP(3) receptor protein in BAT were not influenced by exposure of the animals to the cold.

Expression of voltage-gated Ca2+ channel subtypes in cultured astrocytes

Transient intracellular [Ca(2+)] increases in astrocytes from influx and/or release from internal stores can release glutamate and thereby modulate synaptic transmission in adjacent neurons. Electrophysiological studies have shown that cultured astrocytes express voltage-dependent Ca(2+) channels but their molecular identities have remained unexplored. We therefore performed RT-PCR analysis with primers directed to different voltage-gated Ca(2+) channel alpha(1) subunits. In primary cultures of astrocytes, we detected mRNA transcripts for the alpha(1B) (N-type), alpha(1C) (L-type), alpha(1D) (L-type), alpha(1E) (R-type), and alpha(1G) (T-type), but not alpha(1A) (P/Q-type), voltage-gated Ca(2+) channels. We then used antibodies against all of the Ca(2+) channel subunits to confirm protein expression, via Western blots, and localization by means of immunocytochemistry. In Western blot analysis, we observed immunoreactive bands corresponding to the appropriate alpha(1) subunit proteins. Western blots showed an expression pattern similar to PCR results in that we detected proteins for the alpha(1B) (N-type), alpha(1C) (L-type), alpha(1D) (L-type), alpha(1E) (R-type), and alpha(1G) (T-type), but not alpha(1A) (P/Q-type). Using immunocytochemistry, we observed Ca(2+) channel expression for these subunits in punctate clusters on plasma membrane of GFAP-expressing astrocytes. These results confirm that cultured astrocytes express corresponding proteins to several high- and low-threshold Ca(2+) channels but not alpha(1A) (P/Q-type). Overall, our data indicate that astrocytes express multiple types of voltage-gated Ca(2+) channels, hinting at a complex regulation of Ca(2+) homeostasis in glial cells.

Down-regulation of voltage-gated Ca2+ channels by neuronal calcium sensor-1 is beta subunit-specific

Neuronal Ca(2+) sensor protein-1 (NCS-1) is a member of the Ca(2+) binding protein family, with three functional Ca(2+) binding EF-hands and an N-terminal myristoylation site. NCS-1 is expressed in brain and heart during embryonic and postnatal development. In neurons, NCS-1 facilitates neurotransmitter release, but both inhibition and facilitation of the Ca(2+) current amplitude have been reported. In heart, NCS-1 co-immunoprecipitates with K(+) channels and modulates their activity, but the potential effects of NCS-1 on cardiac Ca(2+) channels have not been investigated. To directly assess the effect of NCS-1 on the various types of Ca(2+) channels we have co-expressed NCS-1 in Xenopus oocytes, with Ca(V)1.2, Ca(V)2.1, and Ca(V)2.2 Ca(2+) channels, using various subunit combinations. The major effect of NCS-1 was to decrease Ca(2+) current amplitude, recorded with the three different types of alpha(1) subunit. When expressed with Ca(V)2.1, the depression of Ca(2+) current amplitude induced by NCS-1 was dependent upon the identity of the beta subunit expressed, with no block recorded without beta subunit or with the beta(3) subunit. Current-voltage and inactivation curves were also slightly modified and displayed a different specificity toward the beta subunits. Taken together, these data suggest that NCS-1 is able to modulate cardiac and neuronal voltage-gated Ca(2+) channels in a beta subunit specific manner.

Selective phosphorylation of the IP3R-I in vivo by cGMP-dependent protein kinase in smooth muscle

This study examined the expression of inositol 1,4,5-trisphosphate (IP(3)) receptor (IP(3)R) types and PKG isoforms in isolated gastric smooth muscle cells and determined the ability of PKG and PKA to phosphorylate IP(3)Rs and inhibit IP(3)-dependent Ca(2+) release, which mediates the initial phase of agonist-induced contraction. PKG-Ialpha and PKG-Ibeta were expressed in gastric smooth muscle cells, together with IP(3)-R-associated cG-kinase substrate, a protein that couples PKG-Ibeta to IP(3)R-I. IP(3)R-I and IP(3)R-III were also expressed, but only IP(3)R-I was phosphorylated by PKA and PKG in vitro and exclusively by PKG in vivo. Sequential phosphorylation by PKA and by PKG-Ialpha in vitro showed that PKA phosphorylated the same site as PKG (presumably S(1755)) and an additional PKA-specific site (S(1589)). In intact muscle cells, agents that activated PKG or both PKG and PKA induced IP(3)R-I phosphorylation that was reversed by the PKG inhibitor (8R,9S,11s)-(-)-9-methoxy-carbamyl-8-methyl-2,3,9,10-tetrahydro-8,11-epoxy-1H,8H,1H,-2,7b,11a-trizadizo-benzo9(a,g)cycloocta(c,d,e)-trinden-1-one. Agents that activated PKA induced IP(3)R-I phosphorylation in permeabilized but not intact muscle cells, implying that PKA does not gain access to IP(3)R-I in intact muscle cells. The pattern of IP(3)R-I phosphorylation in vivo and in vitro was more consistent with phosphorylation by PKG-Ialpha. Phosphorylation of IP(3)R-I in microsomes by PKG, PKA, or a combination of PKG and PKA inhibited IP(3)-induced Ca(2+) release to the same extent, implying that inhibition was mediated by phosphorylation of the PKG-specific site. We conclude that IP(3)R-I is selectively phosphorylated by PKG-I in intact smooth muscle resulting in inhibition of IP(3)-dependent Ca(2+) release.

Intestinal calcium absorption: Molecular vitamin D mediated mechanisms

Rickets and hyperparathyroidism caused by a defective Vitamin D receptor (VDR) can be prevented in humans and animals by high calcium intake, suggesting that intestinal calcium absorption is critical for 1,25(OH)(2) vitamin D [1,25-(OH)(2)D(3)] action on calcium homeostasis. We assessed the rate of serum (45)Ca accumulation within 10 min after oral gavage in two strains of VDR-knock out (KO) mice (Leuven and Tokyo KO) and observed a threefold lower area under the curve in both KO-strains. Moreover, we evaluated the expression of intestinal candidate genes, belonging to a new class of calcium channels (TRPV), involved in transcellular calcium transport. The calcium transport protein ECaC2 was more abundantly expressed at mRNA level than ECaC1 in duodenum, but both were considerably reduced (ECaC2 > 90%, ECaC1 > 60%) in the two VDR-KO strains on a normal calcium diet. Calbindin-D(9K) expression was only significantly decreased in the Tokyo KO, whereas PMCA(1b) expression was normal in both VDR-KOs. In Leuven wild type mice, a high calcium diet inhibited (> 90%), and 1,25(OH)(2)D(3) or low calcium diet induced (sixfold) duodenal ECaC2 expression and, to a lesser degree, ECaC1 and calbindin-D(9K) expression. In Leuven KO mice, however, high or low calcium intake decreased calbindin-D(9K) and PMCA(1b) expression, whereas both ECaC mRNA expressions remained consistently low on any diet. These results suggest that the expression of the novel duodenal epithelial calcium channels (in particular ECaC2 or TRPV6) is strongly vitamin D dependent and that calcium influx, probably interacting with calbindin-D(9K), should be considered as a rate-limiting step in the process of vitamin D dependent active calcium absorption.

Human skeletal muscle calcium channel alpha1S is expressed in the basal ganglia: distinctive expression pattern among L-type Ca2+ channels

Voltage-gated calcium channels (VGCCs) are essential molecules for neuronal function. VGCCs consist of five subunits, alpha1, alpha2, beta, gamma, and delta. Among the ten subtypes of the alpha1 subunit (alpha1A-I and S), expression of alpha1S was previously believed to be restricted to the skeletal muscle. We report here, however, that alpha1S is also expressed in human and rat central nervous system. First, we performed PCR screening for VGCC alpha1 subunits in human nervous system using degenerate primers, and identified alpha1S as well as all the eight alpha1 subunits with previously described expression. Intriguingly, alpha1S was selectively localized to the basal ganglia, particularly the caudate nucleus. In situ hybridization showed that alpha1S was expressed in medium-sized caudate neurons. Quantitative analysis using real time RT-PCR revealed a distinct pattern of alpha1S expression among L-type calcium channels. Furthermore, RT-PCR using laser-mediated manipulation of single cells suggested that human alpha1S was coexpressed with ryanodine receptors (RYRs) in GABAergic neurons. Our results suggest the potential relevance of alpha1S to dopaminergic signal transduction and calcium-induced calcium release in caudate neurons.

Injury type-specific calcium channel alpha 2 delta-1 subunit up-regulation in rat neuropathic pain models correlates with antiallodynic effects of gabapentin

The calcium channel alpha2delta-1 subunit is a structural subunit important for functional calcium channel assembly. In vitro studies have shown that this subunit is the binding site for gabapentin, an anticonvulsant that exerts antihyperalgesic effects by unknown mechanisms. Increased expression of this subunit in the spinal cord and dorsal root ganglia (DRG) has been suggested to play a role in enhanced nociceptive responses of spinal nerve-injured rats to innocuous mechanical stimulation (allodynia). To investigate whether a common mechanism underlies allodynic states derived from different etiologies, and if so, whether similar alpha2delta-1 subunit up-regulation correlates with these allodynic states, we compared DRG and spinal cord alpha2delta-1 subunit levels and gabapentin sensitivity in allodynic rats with mechanical nerve injuries (sciatic nerve chronic constriction injury, spinal nerve transection, or ligation), a metabolic disorder (diabetes), or chemical neuropathy (vincristine neurotoxicity). Our data indicated that even though allodynia occurred in all types of nerve injury investigated, DRG and/or spinal cord alpha2delta-1 subunit up-regulation and gabapentin sensitivity only coexisted in the mechanical and diabetic neuropathies. Thus, induction of the alpha2delta-1 subunit in the DRG and spinal cord is likely regulated by factors that are specific for individual neuropathies and may contribute to gabapentin-sensitive allodynia. However, the calcium channel alpha2delta-1 subunit is not the sole molecular change that uniformly characterizes the neuropathic pain states.

Anx7 is required for nutritional control of gene expression in mouse pancreatic islets of Langerhans

BACKGROUND

Gene expression in islets of Langerhans is profoundly sensitive to glucose and other nutrients. Islets of Langerhans in the Anx7(+/-) knockout mouse exhibit a profound reduction in ITPR3 protein expression, defective intracellular calcium signaling, and defective insulin secretion. Additional data presented here also show that mRNA for ITPR3 is virtually undetectable in isolated Anx7(+/-) islets. IP3Receptor type 3 (ITPR3) expression in islets of Langerhans is closely regulated by secretory stimuli, and it has been suggested that the level of the ITPR3 expression controls the ability of the islets to respond to nutritional signals. We report that although control islets respond to glucose in vitro by a transient increment in ITPR3 mRNA, the islets from the Anx7(+/-) mouse remain low. We therefore hypothesized that the Anx7/IP3 Receptor(3)/Ca(2+) signaling pathway plays a role in beta cell responses to glucose, and that in the absence of the Anx7/ITPR3 signaling system, the islets would be unable to discriminate between fed or fasted states in vivo.

MATERIALS AND METHODS

To test this hypothesis, we subjected Anx7(+/-) and control mice to either food and water ad libidum or to an overnight fast with access to water only. We then isolated the respective islets and compared nutrient-dependent changes in global gene expression under the four conditions using genome-based microarray technology.

RESULTS

Anx7 protein expression in these islets is only about 50% of control levels in normal littermate controls, and IPTR3 message and protein are virtually zero. cDNA microarray analyses show that in control animals gene expression is significantly affected by the fasting state. Many of the affected genes have historical relevance to development and differentiation of islets. These include preproglucagon, APOJ, cadherin2, phosphoglucoisomerase, oncostatin M, PAX6, HGF, and cytokeratin 18. However, there are also many other nutritionally sensitive genes in control islets that are principally associated with cell division and DNA repair. The latter genes have not specifically been associated with islet physiology in the past. By contrast, Anx7(+/-) mouse islets exhibit a greatly reduced ability to discriminate genomically between fed and fasted states for all classes of identified genes. Many of the validated genes are specific to islets in comparison to liver tissue examined. Real-time quantitative RT-PCR analysis of islets from Anx7 heterozygous mice and littermate controls revealed remarkable down-regulation in PTEN, Glut-2, PDX-1, IGF-1, and Neuro D1 expression, but not in liver.

CONCLUSIONS

We conclude that reduced gene dosage in the Anx7(+/-) islet, with concomitant loss of ITPR3 expression and consequent defects in Ca(2+) signaling, may substantially contribute to the mechanism of the loss of genomic discrimination, in vivo, between the fed and fasted states. We believe that the requirement for complete Anx7 gene dosage and IPTR3 expression in islets of Langerhans will prove to be of fundamental importance for understanding the mechanism of nutritional sensing in health and disease.

Comparison of ion-channel subunit expression in canine cardiac Purkinje fibers and ventricular muscle

Although Purkinje fibers (PFs) play an important role in cardiac electrophysiology, almost nothing is known about the expression of ion-channel subunits in PFs. We applied competitive reverse transcription-polymerase chain reaction, Western blotting, and immunocytochemistry to compare the expression of ion-channel subunit mRNA and protein in canine PFs versus ventricular muscle (VM). For transient outward current-related subunits, Kv4.2 was not detected, and Kv1.4 expression was extremely low. Kv4.3 expression was of the same order for VM and PFs. The tetraethylammonium chloride-sensitive subunit Kv3.4 was expressed much more strongly in PFs than in VM, and Kv channel-interacting protein transcript expression was 25-fold stronger in VM than in PFs. For delayed rectifiers, ERG and KvLQT1 expression was lower in PFs at both mRNA and protein levels. Although minK transcripts were more numerous in PFs, minK protein was significantly more strongly expressed in VM. L-type Ca2+ current alpha-subunit (Ca(V)1.2) and Na+-Ca2+ exchanger proteins were more strongly expressed in VM than in PFs. For T-type Ca2+ current, Ca(V)3.1, Ca(V)3.2, and Ca(V)3.3 transcripts were all more strongly expressed in PFs. For the nonselective cation current, hyperpolarization-activated cation channel 1 (HCN1) expression was subquantifiable, HCN2 transcript expression was comparable in PFs and VM, and HCN4 mRNA expression was strong in PFs but below the detection threshold in VM. HCN2 and HCN4 protein expression was much stronger in PFs than in VM. We conclude that ion-channel subunit expression in PFs differs from that in VM in ways that are consistent with, and shed light on the molecular basis of, well-recognized fundamental PF ionic properties.

Alternate splicing in the cytosolic II-III loop and the carboxy terminus of human E-type voltage-gated Ca(2+) channels: electrophysiological characterization of isoforms

There is growing evidence that Ca(v)2.3 (alpha1E, E-type) transcripts may encode the ion-conducting subunit of a subclass of R-type Ca(2+) channels, a heterogeneous group of channels by definition resistant to blockers of L-, N-, and P/Q-type Ca(2+) channels. To understand whether splice variation of Ca(v)2.3 contributes to the divergence of R-type channels, individual variants of Ca(v)2.3 were constructed and expressed in HEK-293 cells. With Ba(2+) as charge carrier, the tested biophysical properties were similar. In Ca(2+), the inactivation time course was slower and the recovery from short-term inactivation was faster; however, this occurred only in variants containing a 19-amino-acid-long insertion, which is typical for neuronal Ca(v)2.3 Ca(2+) channel subunits. This different Ca(2+) sensitivity is not responsible for the major differences between various R-type channels, and future studies might clarify its importance for in vivo synaptic or dendritic integration and the reasons for its loss in endocrine Ca(v)2.3 splice variants.

Atrial fibrillation: the tip of the iceberg

Atrial fibrillation (AF) usually results from profound alterations of the functional properties and structure of the atrial myocardium. For instance, at the cellular level AF is associated with a marked shortening of the action potential (AP) also seen in dilated atria in sinus rhythm. Drastic down-regulation of the I-type Ca2+ current that activates during the plateau phase is one of the main mechanisms responsible for this AP shortening. The down-regulation could be due to a variety of mechanisms including decreased channel expression and alteration of their camp-dependent phosphorylation. There are also alterations of repolarizing currents such as the transient outward potassium current or acetylcholinegated-inward rectifier potassium current. The electrical remodeling of diseased atria is most often associated with severe tissular and cellular alterations including: fibrosis, myocyte dystrophy with myolysis and dedifferentiation, apoptosis and gap junction disorganization. These abnormalities could result from a common and non specific adaptive response to changes in the working conditions of the atrial myocardium. The main goal of research in this field is now to link up the various abnormalities observed during AF and to determine their respective roles in atrial vulnerability to arrhythmia.

Calcium uptake and calcium transporter expression by trophoblast cells from human term placenta

Placental transfer of maternal calcium (Ca(2+)) is a crucial step for fetal development although the biochemical mechanisms responsible for this process are largely unknown. This process is carried out in vivo by the placental syncytiotrophoblast layer. The aim of this study was to define the membrane gates responsible for the syncytiotrophoblast Ca(2+) entry, the first step in transplacental transfer. We have investigated the basal Ca(2+) uptake by primary culture of human term placenta syncytiotrophoblast. Kinetic studies revealed an active extracellular Ca(2+) uptake by cultured human syncytiotrophoblast. We demonstrated by Northern blot the presence of transcript for calcium transporter type 1 (CaT1) in cultured human syncytiotrophoblast and CaT1 expression was further confirmed by reverse transcription polymerase chain reaction (RT-PCR). In addition, the expression of calcium transporter type 2 (CaT2) was revealed by RT-PCR in cultured human syncytiotrophoblast. It has been reported that the activity of this family of Ca(2+) channels is voltage-independent, and is not sensitive to L-type Ca(2+) channels agonist and antagonist. Interestingly, modulation of membrane potential by extracellular high potassium concentration and valinomycin had no effect on the basal Ca(2+) uptake of human syncytiotrophoblast. Moreover, the addition of L-type Ca(2+) channel modulators (Bay K 8644 and nitrendipine) to the incubation medium had also no effect on the basal Ca(2+) uptake, suggesting that the process is mainly voltage-independent and does not involved L-type Ca(2+) channels. On the other hand, we observed that two known blockers of CaT-mediated Ca(2+) transport, namely extracellular magnesium (Mg(2+)) and ruthenium red, dose-dependently inhibited Ca(2+) uptake by cultured human syncytiotrophoblast. Therefore, our results suggest that basal Ca(2+) uptake of human syncytiotrophoblast may be assured by CaT1 and CaT2.

Identification of the calcium channel alpha 1E (Ca(v)2.3) isoform expressed in atrial myocytes

Antisense oligonucleotides targeting the calcium channel alpha 1E (Ca(v)2.3) subunit significantly inhibit the insulin-like growth factor-1 (IGF-1)-stimulated increase in low voltage-activated (LVA) (T-type) calcium current in cultured rat atrial myocytes [Proc. Natl. Acad. Sci. U.S.A. 94(1997) 14936]. As part of a continuing effort to understand the regulation of LVA current expression in the heart, we have identified the specific alpha 1E isoform that is expressed in atrial tissue. Through reverse transcription-polymerase chain reaction (RT-PCR), nine overlapping partial clones spanning the entire coding region of the cardiac alpha 1E mRNA were obtained. The predominate isoform in atrial tissue was identified and found to be highly homologous to the alpha 1E isoform previously isolated from kidney and the islets of Langerhans [Eur. J. Biochem. 257(1998) 274]. The expression of alpha 1E in the heart occurs specifically in cardiac myocytes and not in smooth muscle or fibroblasts as demonstrated by RT-PCR performed on isolated atrial myocytes and by in situ hybridization.

Astrocytes in adult rat brain express type 2 inositol 1,4,5-trisphosphate receptors

Astrocytes respond to neuronal activity by propagating Ca(2+) waves elicited through the inositol 1,4,5-trisphosphate pathway. We have previously shown that wave propagation is supported by specialized Ca(2+) release sites, where a number of proteins, including inositol 1,4,5-trisphosphate receptors (IP(3)R), occur together in patches. The specific IP(3)R isoform expressed by astrocytes in situ in rat brain is unknown. In the present report, we use isoform-specific antibodies to localize immunohistochemically the IP(3)R subtype expressed in astrocytes in rat brain sections. Astrocytes were identified using antibodies against the astrocyte-specific markers, S-100 beta, or GFAP. Dual indirect immunohistochemistry showed that astrocytes in all regions of adult rat brain express only IP(3)R2. High-resolution analysis showed that hippocampal astrocytes are endowed with a highly branched network of processes that bear fine hair-like extensions containing punctate patches of IP(3)R2 staining in intimate contact with synapses. Such an organization is reminiscent of signaling microdomains found in cultured glial cells. Similarly, Bergmann glial cell processes in the cerebellum also contained fine hair-like processes containing IP(3)R2 staining. The IP(3)R2-containing fine terminal branches of astrocyte processes in both brain regions were found juxtaposed to presynaptic terminals containing synaptophysin as well as PSD 95-containing postsynaptic densities. Corpus callosum astrocytes had an elongated morphology with IP(3)R2 studded processes extending along fiber tracts. Our data suggest that PLC-mediated Ca(2+) signaling in astrocytes in rat brain occurs predominantly through IP(3)R2 ion channels. Furthermore, the anatomical arrangement of the terminal astrocytic branches containing IP(3)R2 ensheathing synapses is ideal for supporting glial monitoring of neuronal activity.

Novel functional properties of Ca(2+) channel beta subunits revealed by their expression in adult rat heart cells

Recombinant adenoviruses were used to overexpress green fluorescent protein (GFP)-fused auxiliary Ca(2+) channel beta subunits (beta(1)-beta(4)) in cultured adult rat heart cells, to explore new dimensions of beta subunit functions in vivo. Distinct beta-GFP subunits distributed differentially between the surface sarcolemma, transverse elements, and nucleus in single heart cells. All beta-GFP subunits increased the native cardiac whole-cell L-type Ca(2+) channel current density, but produced distinctive effects on channel inactivation kinetics. The degree of enhancement of whole-cell current density was non-uniform between beta subunits, with a rank order of potency beta(2a) approximately equal to beta(4) > beta(1b) > beta(3). For each beta subunit, the increase in L-type current density was accompanied by a correlative increase in the maximal gating charge (Q(max)) moved with depolarization. However, beta subunits produced characteristic effects on single L-type channel gating, resulting in divergent effects on channel open probability (P(o)). Quantitative analysis and modelling of single-channel data provided a kinetic signature for each channel type. Spurred on by ambiguities regarding the molecular identity of the actual endogenous cardiac L-type channel beta subunit, we cloned a new rat beta(2) splice variant, beta(2b), from heart using 5' rapid amplification of cDNA ends (RACE) PCR. By contrast with beta(2a), expression of beta(2b) in heart cells yielded channels with a microscopic gating signature virtually identical to that of native unmodified channels. Our results provide novel insights into beta subunit functions that are unattainable in traditional heterologous expression studies, and also provide new perspectives on the molecular identity of the beta subunit component of cardiac L-type Ca(2+) channels. Overall, the work establishes a powerful experimental paradigm to explore novel functions of ion channel subunits in their native environments.

The role of endogenous human Trp4 in regulating carbachol-induced calcium oscillations in HEK-293 cells

We utilized 2-aminoethyoxydiphenyl borane, an agent that blocks store-operated Ca(2+) entry, as well as an antisense approach to characterize endogenous Ca(2+) entry pathways in HEK-293 cells. The thapsigargin- and carbachol-induced, but not the 1-oleolyl-2-acytyl-sn-glycerol (OAG)-induced, entry was blocked by 2-aminoethyoxydiphenyl borane. Both reverse transcriptase-PCR and Western blot analyses demonstrated endogenous expression for HTRP1, HTRP3, and HTRP4 and specific suppression of mRNA levels and Trp protein levels in cells stably expressing antisense constructs. Expression of HTRP4 antisense inhibited 35% of the carbachol (CCh)-stimulated Ba(2+) entry and 46% of the OAG-stimulated Sr(2+) entry but in contrast had no effect on the thapsigargin-stimulated Ba(2+) or Sr(2+) entry. HTRP3 antisense reduced, while HTRP1 antisense had no effect on, OAG-induced Sr(2+) entry. Of greater importance, HTRP4 antisense expression, but not HTRP3 antisense expression, blocked the sustained Ca(2+) oscillations produced by low doses of CCh (15 microm), arguing that receptor-stimulated rather than store-operated channels are involved in these sustained oscillations. HTRP4 antisense also inhibited 75% of the arachidonic acid-induced Ca(2+) entry. In summary, these data suggest that HTRP4 proteins in HEK-293 cells, differing from HTRP3 and HTRP1 proteins, do not serve as functional subunits of store-operated channels but do function as subunits for CCh- and OAG-stimulated channels. Furthermore, evidence is provided for the first time for the involvement of a Trp isoform (HTRP4) in the formation of the channel responsible for both arachidonic acid-induced Ca(2+) entry and the Ca(2+) entry needed to sustain long term Ca(2+) oscillations induced by low doses of carbachol.

Identification and characterization of a calcium channel gamma subunit expressed in differentiating neurons and myoblasts

Transient elevations of intracellular calcium (calcium transients) play critical roles in many developmental processes, including differentiation. Although the factors that regulate calcium transients are not clearly defined, calcium influx may be controlled by molecules interacting with calcium channels, including channel regulatory subunits. Here, we describe the chick gamma4 regulatory subunit (CACNG4), the first such subunit to be characterized in early development. CACNG4 is expressed early in the cranial neural plate, and later in the cranial and dorsal root ganglia; importantly, the timing of this later expression correlates precisely with the onset of neuronal differentiation. CACNG4 expression is also observed in nonneuronal tissues undergoing differentiation, specifically the myotome and a subpopulation of differentiating myoblasts in the limb bud. Finally, within the distal cranial ganglia, we show that CACNG4 is expressed in placode-derived cells (prospective neurons), but also, surprisingly, in neural crest-derived cells, previously shown to form only glia in this location; contrary to these previous results, we find that neural crest cells can form neurons in the distal ganglia. Given the proposed role of CACNG4 in modulating calcium channels and its expression in differentiating cells, we suggest that CACNG4 may promote differentiation via regulation of intracellular calcium levels.

Gabapentin-mediated inhibition of voltage-activated Ca2+ channel currents in cultured sensory neurones is dependent on culture conditions and channel subunit expression

We have used the whole cell patch clamp method and fura-2 fluorescence imaging to study the actions of gabapentin (1-(aminoethyl) cyclohexane acetic acid) on voltage-activated Ca(2+) entry into neonatal cultured dorsal root ganglion (DRG) neurones and differentiated F-11 (embryonic rat DRG x neuroblastoma hybrid) cells. Gabapentin (2.5 microM) in contrast to GABA (10 microM) did not influence resting membrane potential or input resistance. In current clamp mode gabapentin failed to influence the properties of evoked single action potentials but did reduce the duration of action potentials prolonged by Ba(2+). Gabapentin attenuated high voltage-activated Ca(2+) channel currents in a dose- and voltage- dependent manner in DRG neurones and reduced Ca(2+) influx evoked by K(+) depolarisation in differentiated F-11 cells loaded with fura-2. The sensitivity of DRG neurones to gabapentin was not changed by the GABA(B) receptor antagonist saclofen but pertussis toxin pre-treatment reduced the inhibitory effects of gabapentin. Experiments following pre-treatment of DRG neurones with a PKA-activator and a PKA-inhibitor implicated change in phosphorylation state as a mechanism, which influenced gabapentin action. Sp- and Rp-analogues of cAMP significantly increased or decreased gabapentin-mediated inhibition of voltage-activated Ca(2+) channel currents. Culture conditions used to maintain DRG neurones and passage number of differentiated F-11 cells also influenced the sensitivity of Ca(2+) channels to gabapentin. We analysed the Ca(2+) channel subunits expressed in populations of DRG neurones and F-11 cells that responded to gabapentin had low sensitivity to gabapentin or were insensitive to gabapentin, by Quantitative TaqMan PCR. The data obtained from this analysis suggested that the relative abundance of the Ca(2+) channel beta(2) and alpha(2)delta subunit expressed was a key determinant of gabapentin sensitivity of both cultured DRG neurones and differentiated F-11 cells. In conclusion, gabapentin inhibited part of the high voltage-activated Ca(2+) current in neonatal rat cultured DRG neurones via a mechanism that was independent of GABA receptor activation, but was sensitive to pertussis toxin. Gabapentin responses identified in this study implicated Ca(2+) channel beta(2) subunit type as critically important to drug sensitivity and interactions with alpha(1) and alpha(2)delta subunits may be implicated in antihyperalgesic therapeutic action for this compound.

A novel Xenopus oocyte expression system based on cytoplasmic coinjection of T7-driven plasmids and purified T7-RNA polymerase

The Xenopus laevis South African frog oocyte is a well suited and widely used system for protein biochemistry and functional studies. So far, two methods are commonly in use for the expression of exogenous proteins in this system. Investigators have the choice between cytoplasmic injections of in vitro synthesized cRNA or nuclear injections of cDNA. Here, we describe a new method for ion channel expression in oocytes, which consists of a coinjection of T7-driven cDNA and T7-RNA polymerase directly into the cytoplasm. This technique uses very limited amounts of purified enzyme and is also applicable to SP6 polymerase. Commercially available polymerases can also conveniently substitute for self-purified enzymes. The technique can be used for electrophysiological and biochemical analysis. In particular, high level expressions have been achieved for potassium (Shaker B, Kv1.2 and Kv1.3) and sodium (P mu 1.2) channels, and we also demonstrate efficient metabolic labeling of the calcium channel auxiliary beta 3 subunit. The properties of the channels expressed by this technique are indistinguishable from those of the channels expressed by classical methods. Expression of multi-subunit proteins was also achieved illustrating that the technique can be used for structure-function analyses. Moreover, this novel expression technique avoids many drawbacks of the two former techniques. It clearly bypasses the costly and time-consuming step of cRNA synthesis in vitro, prevents delicate cRNA manipulation and is easier to perform and more reliable than nuclear injection. Finally, it does not affect cell survival rate. These data indicate that the T7-RNA polymerase expression technique could be widely used in the future for the expression of exogenous proteins in the Xenopus oocyte system.

Suppression of ATP-induced Cl(-)secretion by enhanced expression of epithelial Na(+)channels in mouse endometrial epithelium

We have studied the effect of enhanced expression of epithelial Na(+)channels (ENaC) on the ATP-induced Cl(-)secretion in the mouse epithelium using short-circuit current (I(SC)) and RT-PCR techniques. The amiloride sensitivity of basal current (I(b)) across the cultured endometrial epithelia was found to vary with the magnitude of the I(b), the higher the I(b)the greater its sensitivity to amiloride, indicating possible elevation of ENaC. However, the magnitude of ATP-induced I(SC), previously demonstrated to be mediated by Ca(2+)-activated chloride channel (CaCC), decreased as the amiloride sensitivity of the I(b)increased, suggesting a possible inhibitory effect of elevated expression of ENaC on ATP-mediated chloride secretion. The Matrigel treatment for culturing the endometrial epithelia affected the amiloride sensitivity of the I(b)as well as the ATP-induced I(SC)reversedly. Competitive RT-PCR demonstrated that the expression of both ENaC gamma subunits and CaCC was enhanced in Matrigel-treated cultures. However, the observed reduction in the ATP-induced or CaCC-mediated I(SC)could not be explained by the CaCC expression pattern. These data suggest that inhibition of CaCC function is due to enhanced ENaC expression. Therefore, in addition to interacting with CFTR, ENaC also appears to interact with CaCC in the mouse endometrial epithelium. Physiologically the present findings indicate that enhanced expression of ENaC leads to suppression of other Cl(-)channels, such as CFTR and CaCC, thereby preconditioning the endometrium in favour of overall salt and water absorption as observed during embryo implantation.