T-type current modulation by the actin-binding protein Kelch-like 1.

We report a novel form of modulation of T-type calcium currents carried out by the neuronal actin-binding protein (ABP) Kelch-like 1 (KLHL1). KLHL1 is a constitutive neuronal ABP localized to the soma and dendritic arbors; its genetic elimination in Purkinje neurons leads to dendritic atrophy and motor insufficiency. KLHL1 participates in neurite outgrowth and upregulates voltage-gated P/Q-type calcium channel function; here we investigated KLHL1's role as a modulator of low-voltage-gated calcium channels and determined the molecular mechanism of this modulation with electrophysiology and biochemistry. Coexpression of KLHL1 with Ca(V)3.1 or Ca(V)3.2 (alpha(1G) or alpha(1H) subunits) caused increases in T-type current density (35%) and calcium influx (75-83%) when carried out by alpha(1H) but not by alpha(1G). The association between KLHL1 and alpha(1H) was determined by immunoprecipitation and immunolocalization in brain membrane fractions and in vitro in HEK-293 cells. Noise analysis showed that neither alpha(1H) single-channel conductance nor open probability was altered by KLHL1, yet a significant increase in channel number was detected and further corroborated by Western blot analysis. KLHL1 also induced an increase in alpha(1H) current deactivation time (tau(deactivation)). Interestingly, the majority of KLHL1's effects were eliminated when the actin-binding motif (kelch) was removed, with the exception of the calcium influx increase during action potentials, indicating that KLHL1 interacts with alpha(1H) and actin and selectively regulates alpha(1H) function by increasing the number of alpha(1H) channels. This constitutes a novel regulatory mechanism of T-type calcium currents and supports the role of KLHL1 in the modulation of cellular excitability.

A mutant of TTX-resistant cardiac sodium channels with TTX-sensitive properties.

The cardiac sodium channel alpha subunit (RHI) is less sensitive to tetrodotoxin (TTX) and saxitoxin (STX) and more sensitive to cadmium than brain and skeletal muscle (microliter) isoforms. An RHI mutant, with Tyr substituted for Cys at position 374 (as in microliter) confers three properties of TTX-sensitive channels: (i) greater sensitivity to TTX (730-fold); (ii) lower sensitivity to cadmium (28-fold); and (iii) altered additional block by toxin upon repetitive stimulation. Thus, the primary determinant of high-affinity TTX-STX binding is a critical aromatic residue at position 374, and the interaction may take place possibly through an ionized hydrogen bond. This finding requires revision of the sodium channel pore structure that has been previously suggested by homology with the potassium channel.

Identification of the t-type calcium channel (Ca(v)3.1d) in developing mouse heart.

During cardiac development, there is a reciprocal relationship between cardiac morphogenesis and force production (contractility). In the early embryonic myocardium, the sarcoplasmic reticulum is poorly developed, and plasma membrane calcium (Ca(2+)) channels are critical for maintaining both contractility and excitability. In the present study, we identified the Ca(V)3.1d mRNA expressed in embryonic day 14 (E14) mouse heart. Ca(V)3.1d is a splice variant of the alpha1G, T-type Ca(2+) channel. Immunohistochemical localization showed expression of alpha1G Ca(2+) channels in E14 myocardium, and staining of isolated ventricular myocytes revealed membrane localization of the alpha1G channels. Dihydropyridine-resistant inward Ba(2+) or Ca(2+) currents were present in all fetal ventricular myocytes tested. Regardless of charge carrier, inward current inactivated with sustained depolarization and mirrored steady-state inactivation voltage dependence of the alpha1G channel expressed in human embryonic kidney-293 cells. Ni(2+) blockade discriminates among T-type Ca(2+) channel isoforms and is a relatively selective blocker of T-type channels over other cardiac plasma membrane Ca(2+) handling proteins. We demonstrate that 100 micromol/L Ni(2+) partially blocked alpha1G currents under physiological external Ca(2+). We conclude that alpha1G T-type Ca(2+) channels are functional in midgestational fetal myocardium.

Cloning of a novel four repeat protein related to voltage-gated sodium and calcium channels.

Cloning has led to the discovery of more ion channels than predicted by functional studies, yet there remain channels that have not been cloned. We report the cloning of a novel protein that contains the four domain structure found in voltage-gated Ca2+ and Na+ channels. Phylogenetic relationships suggested that the protein might have diverged from an ancestral four repeat channel before the divergence of Ca2+ and Na+ channels. Northern blot analysis showed that mRNA transcripts encoding the protein are expressed predominantly in the brain, moderately in the heart, and weakly in the pancreas. Despite extensive expression attempts, currents from the putative channel were not detected. Based on its sequence, we propose that the novel protein might be a voltage-activated cation channel with unique gating properties.

Functional expression of the rat heart I Na+ channel isoform. Demonstration of properties characteristic of native cardiac Na+ channels.

We describe the expression of functional Na+ channels in Xenopus oocytes injected with cRNA transcribed from the rat heart I cDNA clone. The expressed rat heart I Na+ currents show kinetic properties and resistance to tetrodotoxin and saxitoxin which are characteristic of native cardiac Na+ currents. The primary amino acid sequence of the rat heart I alpha-subunit is therefore sufficient for expression of tetrodotoxin resistance, and the rat heart I clone is likely to account for the tetrodotoxin-resistant phenotype of cardiac and denervated skeletal muscle.

Molecular cloning and functional expression of Ca(v)3.1c, a T-type calcium channel from human brain.

Low voltage-activated T-type calcium channels are encoded by a family of at least three genes, with additional diversity created by alternative splicing. This study describes the cloning of the human brain alpha1G, which is a novel isoform, Ca(v)3.1c. Comparison of this sequence to genomic sequences deposited in the GenBank allowed us to identify the intron/exon boundaries of the human CACNA1G gene. A full-length cDNA was constructed, then used to generate a stably-transfected mammalian cell line. The resulting currents were analyzed for their voltage- and time-dependent properties. These properties identify this gene as encoding a T-type Ca(2+) channel.

Expression of Egr-1 in the brain of sleep deprived rats.

In previous research, rats subjected to prolonged sleep deprivation have shown disturbances of thermoregulation, hormonal and metabolic changes in apparent response to the thermoregulatory problems, lesions on the tail and paws, and eventual death. To search for alterations of functional activity in brain, the expression of the immediate early gene Egr-1 was examined by immunocytochemistry and Northern blotting in rats subjected to total sleep deprivation (TSD) for 10 days. Controls included yoked stimulus-control (TSC) rats, surgically implanted but otherwise undisturbed control rats, and unoperated control rats. Photographs of immunoreacted coronal sections from four sets of rats were ranked blindly for 25 brain regions. TSD rats showed tendencies for regionally specific increases in Egr-1-like immunoreactivity in dorsal raphe, lateral habenula, superior colliculus, and ventral periaqueductal grey. However, most regions showed no differences in Egr-1-like immunoreactivity between TSD and control rats. Neither was there a difference in whole brain Egr-1 mRNA by Northern blot in two additional sets of rats. Thus, this study, like previous studies of brain histology, amines, adrenoceptors, and glucose utilization, does not provide positive support for the hypothesis that sleep protects the central nervous system against massive global damage, fatigue, or dysfunction.

Molecular characterization of two members of the T-type calcium channel family.

In this chapter we review our recent studies on the cloning of two novel cDNAs (alpha 1G and alpha 1H), and present electrophysiological evidence that they encode low voltage-activated, T-type calcium channels (CavT.1 and CavT.2, respectively). The nucleotide sequences of these T channels are very different from high voltage-activated Ca2+ channels, which explains why they were not cloned earlier using homology-based strategies. We used a bioinformatic approach, cloning the first fragment in silico. We then used this fragment to screen human heart and rat brain lambda gt10 libraries, leading to the cloning of two full-length cDNAs derived from distinct genes (CACNA1G and CACNA1H). The deduced amino acid sequences of the T channels (alpha 1G and alpha 1H) are also very different from previously cloned Ca2+ and Na+ channels; however, there are regions of structural similarity. For example, the T channels also contain four repeats, and within each repeat there are six putative membrane-spanning regions and a pore loop. Expression of these cloned channels in either Xenopus oocytes or HEK-293 cells leads to the formation of typical T-type currents. As observed for native T currents, these channels activate at potentials near the resting membrane potential, inactivate rapidly, deactivate slowly, and have a tiny single-channel conductance. The currents generated by alpha 1G and alpha 1H are nearly identical in terms of their voltage dependence and kinetics. We present preliminary evidence that nickel may serve as a valuable tool in discriminating between these subtypes.

Kelch-like 1 protein upregulates T-type currents by an actin-F dependent increase in α(1H) channels via the recycling endosome.

The neuronal protein Kelch-like 1 (KLHL1) is a novel actin-binding protein that modulates neuronal structure and function. KLHL1 knockout mice exhibit dendritic atrophy in cerebellar Purkinje neurons and motor dysfunction. Interestingly, KLHL1 upregulates high and low voltage-gated calcium currents (Ca(V)2.1 and Ca(V)3.2) and interacts with their respective principal subunits, α(1A) and α(1H). We reported the mechanism of enhanced Ca(V)3.2 (α(1H)) current density (and calcium influx) by KLHL1 is due to an increase in channel number (N) that requires the binding of actin. In this report we further elucidate the role of the actin cytoskeleton in this process using pharmacological tools to disrupt or stabilize actin filaments and to prevent protein trafficking and vesicle recycling. Disruption of the cytoskeleton did not affect the basal activity of α(1H), but did eliminate its modulation by KLHL1. In contrast, actin-F stabilization on its own increased basal α(1H) activity similar to KLHL1 but without synergy in its presence, suggesting KLHL1 requires actin-polymerization to increase α(1H) currents. Noise analysis revealed that actin polymerization induced an increase in N and P(o), in contrast to increased N in the presence of KLHL1. Interestingly, pharmacological or genetic disruption of endosomal recycling eliminated the increase in channel number by KLHL1 demonstrating this effect occurs via enhanced α(1H) re-insertion through the recycling endosome. Our findings afford insight on a novel mechanism of T-type channel modulation that could have overall functional implications for T-type channel function in the brain.

Identification of a T-type Ca(2+) channel isoform in murine atrial myocytes (AT-1 cells)

Calcium channels are important targets for therapeutics, but their molecular diversity complicates characterization of these channels in native heart cells. In this study, we identify a new splice variant of a low-voltage activated, or T-type Ca(2+), channel in murine atrial myocytes. To date, alpha1G and alpha1H are the only 2 T-type Ca(2+) channel isoforms found in cardiovascular tissue. We compared alpha1G and alpha1H channel current heterologously expressed in HEK 293 cells with T-type current from the murine atrial tumor cell, AT-1. AT-1 cell T-type current (I(T)) has the same voltage dependence of activation and inactivation as alpha1G and alpha1H. The cloned T-type channels and AT-1 T-type current share similar kinetics of macroscopic inactivation and deactivation. The kinetics of recovery from inactivation of T-type currents serves as an electrophysiological signature for T-channel isoform. alpha1G and AT-1 I(T) have a similar recovery from inactivation time course that is faster than that for alpha1H. In all cases, T-type current recovers with a biexponential time course, and the relative amplitude of fast and slow time courses explains the slower alpha1H recovery kinetics, rather than differences in the time constants of the individual transitions. Thus, the T-type channels may be an important contributor to automaticity in heart cells, and molecular diversity is reflected in the pathway of recovery from inactivation.

Arachidonic acid modulation of alpha1H, a cloned human T-type calcium channel.

Arachidonic acid (AA) and the products of its metabolism are central mediators of changes in cellular excitability. We show that the recently cloned and expressed T-type or low-voltage-activated Ca channel, alpha1H, is modulated by external AA. AA (10 microM) causes a slow, time-dependent attenuation of alpha1H current. At a holding potential of -80 mV, 10 microM AA reduces peak inward alpha1H current by 15% in 15 min and 70% in 30 min and shifts the steady-state inactivation curve -25 mV. AA inhibition was not affected by applying the cyclooxygenase inhibitor indomethacin or the lipoxygenase inhibitor nordihydroguaiaretic acid. The epoxygenase inhibitor octadecynoic acid partially antagonized AA attenuation of alpha1H. The epoxygenase metabolite epoxyeicosatrienoic acid (8,9-EET) mimicked the inhibitory effect of AA on alpha1H peak current. A protein kinase C (PKC)-specific inhibitor (peptide fragment 19-36) only partially antagonized the AA-induced reduction of peak alpha1H current and the shift of the steady-state inactivation curve but had no effect on 8,9-EET-induced attenuation of current. In contrast, PKA has no role in the modulation of alpha1H. These results suggest that AA attenuation and shift of alpha1H may be mediated directly by AA. The heterologous expression of T-type Ca channels allows us to study for the first time properties of this important class of ion channel in isolation. There is a significant overlap of the steady-state activation and inactivation curves, which implies a substantial window current. The selective shift of the steady-state inactivation curve by AA reduces peak Ca current and eliminates the window current. We conclude that AA may partly mediate physiological effects such as vasodilatation via the attenuation of T-type Ca channel current and the elimination of a T-type channel steady window current.

Full reversal of Pb++ block of L-type Ca++ channels requires treatment with heavy metal antidotes.

The mechanisms of Pb++ block and unblock of L-type Ca++ channel currents were measured using ventricular myocytes or the cloned channel. The cloned channel was expressed in either Xenopus laevis oocytes or human embryonic kidney cells (HEK 293, stable transfectants). The threshold for Pb++ block was 1 nM, and the apparent IC50 value was 152 nM in oocytes and 169 nM in HEK 293 cells. Pb++ block was dependent on the composition of the external recording solution but not dependent on the subunit composition of the channel. Pb++ block was voltage dependent, with little block observed at negative test potentials using low concentrations of Pb++. Strong depolarizations (>+100 mV) reversed Pb++ block, allowing measurement of reblock kinetics. Reblock was fast (tau = 11 msec), as measured during a +20-mV test pulse. Simple washout did not completely reverse Pb++ block, especially after exposure to concentrations of >100 nM. Full recovery could only be observed after treatment with heavy metal antidotes such as meso-2,3-dimercaptosuccinic acid, 2,3-dimercapto-1-propanesulfonic acid and EDTA. These results suggest that Pb++ blocks voltage-gated Ca++ channels by two mechanisms and that full reversal of lead block requires chelator treatment.

Nickel block of three cloned T-type calcium channels: low concentrations selectively block alpha1H.

Nickel has been proposed to be a selective blocker of low-voltage-activated, T-type calcium channels. However, studies on cloned high-voltage-activated Ca(2+) channels indicated that some subtypes, such as alpha1E, are also blocked by low micromolar concentrations of NiCl(2). There are considerable differences in the sensitivity to Ni(2+) among native T-type currents, leading to the hypothesis that there may be more than one T-type channel. We confirmed part of this hypothesis by cloning three novel Ca(2+) channels, alpha1G, H, and I, whose currents are nearly identical to the biophysical properties of native T-type channels. In this study we examined the nickel block of these cloned T-type channels expressed in both Xenopus oocytes and HEK-293 cells (10 mM Ba(2+)). Only alpha1H currents were sensitive to low micromolar concentrations (IC(50) = 13 microM). Much higher concentrations were required to half-block alpha1I (216 microM) and alpha1G currents (250 microM). Nickel block varied with the test potential, with less block at potentials above -30 mV. Outward currents through the T channels were blocked even less. We show that depolarizations can unblock the channel and that this can occur in the absence of permeating ions. We conclude that Ni(2+) is only a selective blocker of alpha1H currents and that the concentrations required to block alpha1G and alpha1I will also affect high-voltage-activated calcium currents.

Differential distribution of three members of a gene family encoding low voltage-activated (T-type) calcium channels.

Low voltage-activated (T-type) calcium currents are observed in many central and peripheral neurons and display distinct physiological and functional properties. Using in situ hybridization, we have localized central and peripheral nervous system expression of three transcripts (alpha1G, alpha1H, and alpha1I) of the T-type calcium channel family (CaVT). Each mRNA demonstrated a unique distribution, and expression of the three genes was largely complementary. We found high levels of expression of these transcripts in regions associated with prominent T-type currents, including inferior olivary and thalamic relay neurons (which expressed alpha1G), sensory ganglia, pituitary, and dentate gyrus granule neurons (alpha1H), and thalamic reticular neurons (alpha1I and alpha1H). Other regions of high expression included the Purkinje cell layer of the cerebellum, the bed nucleus of the stria terminalis, the claustrum (alpha1G), the olfactory tubercles (alpha1H and alpha1I), and the subthalamic nucleus (alpha1I and alpha1G). Some neurons expressed high levels of all three genes, including hippocampal pyramidal neurons and olfactory granule cells. Many brain regions showed a predominance of labeling for alpha1G, including the amygdala, cerebral cortex, rostral hypothalamus, brainstem, and spinal cord. Exceptions included the basal ganglia, which showed more prominent labeling for alpha1H and alpha1I, and the olfactory bulb, the hippocampus, and the caudal hypothalamus, which showed more even levels of all three transcripts. Our results are consistent with the hypothesis that differential gene expression underlies pharmacological and physiological heterogeneity observed in neuronal T-type calcium currents, and they provide a molecular basis for the study of T-type channels in particular neurons.

Muscle-specific regulation of a transfected rabbit myosin heavy chain beta gene promoter.

We have examined the transcriptional regulation of the rabbit myosin heavy chain (HC) beta gene by using DNA-mediated transfection experiments. To analyze the activity of the myosin HC beta promoter in a myogenic background, cultured myoblasts from 12-day-old chick embryonic breast muscle were transfected with a chimeric gene containing 781 base pairs of the promoter region fused to the gene for chloramphenicol acetyltransferase (CAT). As indicated by the transient expression of chloramphenicol acetyltransferase, the activity of the promoter in myoblast cultures increased at least 32-fold following differentiation and was selectively inhibited when myogenesis was blocked with 5-bromodeoxyuridine. Furthermore, RNase protection experiments showed that the in vivo myosin HC beta transcriptional initiation (or cap) site was utilized in the transfected skeletal muscle cells and also that the regulation of the exogenous promoter was similar to the induction of the endogenous skeletal alpha-actin gene. The results indicated that the exogenous promoter is regulated in a tissue- and stage-specific manner. By creating progressive 5' deletions of the promoter, we showed that only the region extending -294 base pairs upstream from the cap site is necessary for the muscle-specific expression. Linker-scanner mutagenesis of this region indicated that the positive regulation in differentiated skeletal muscle is mediated by at least two distinct elements within the 5'-flanking region of the myosin HC beta gene.

Molecular cloning of a putative tetrodotoxin-resistant rat heart Na+ channel isoform.

Voltage-gated Na+ channels in mammalian heart differ from those in nerve and skeletal muscle. One major difference is that tetrodotoxin (TTX)-resistant cardiac Na+ channels are blocked by 1-10 microM TTX, whereas TTX-sensitive nerve Na+ channels are blocked by nanomolar TTX concentrations. We constructed a cDNA library from 6-day-old rat hearts, where only low-affinity [3H]saxitoxin receptors, corresponding to TTX-resistant Na+ channels, were detected. We isolated several overlapping cDNA clones encompassing 7542 nucleotides and encoding the entire alpha subunit of a cardiac-specific Na+ channel isoform (designated rat heart I) as well as several rat brain I Na+ channel cDNA clones. The derived amino acid sequence of rat heart I was highly homologous to, but distinct from, previous Na+ channel clones. RNase protection studies showed that the corresponding mRNA species is abundant in newborn and adult rat hearts, but not detectable in brain or innervated skeletal muscle. The same mRNA species appears upon denervation of skeletal muscle, likely accounting for expression of new TTX-resistant Na+ channels. Thus, this cardiac-specific Na+ channel clone appears to encode a distinct TTX-resistant isoform and is another member of the mammalian Na+ channel multigene family, found in newborn heart and denervated skeletal muscles.

Mibefradil block of cloned T-type calcium channels.

Mibefradil is a tetralol derivative chemically distinct from other calcium channel antagonists. It is a very effective antihypertensive agent that is thought to achieve its action via a higher affinity block for low-voltage-activated (T) than for high-voltage-activated (L) calcium channels. Estimates of affinity using Ba(2+) as the charge carrier have predicted a 10- to 15-fold preference of mibefradil for T channels over L channels. However, T channel IC(50) values are reported to be approximately 1 microM, which is much higher than expected for clinical efficacy because relevant blood levels of this drug are approximately 50 nM. We compared the affinity for mibefradil of the newly cloned T channel isoforms, alpha1G, alpha1H, and alpha1I with an L channel, alpha1C. In 10 mM Ba(2+), mibefradil blocked in the micromolar range and with 12- to 13-fold greater affinity for T channels than for L channels (approximately 1 microM versus 13 microM). When 2 mM Ca(2+) was used as the charge carrier, the drug was more efficacious; the IC(50) for alpha1G shifted to 270 nM and for alpha1H shifted to 140 nM, 4.5- and 9-fold higher affinity than in 10 mM Ba. The data are consistent with the idea that mibefradil competes for its binding site on the channel with the permeant species and that Ba(2+) is a more effective competitor than Ca(2+). Raising temperature to 35 degrees C reduced affinity (IC(50) 792 nM). Reducing channel availability to half increased affinity ( approximately 70 nM). This profile of mibefradil affinity makes these channels good candidates for the physiological target of this antihypertensive agent.

The effect of alpha2-delta and other accessory subunits on expression and properties of the calcium channel alpha1G.

1. The effect has been examined of the accessory alpha2-delta and beta subunits on the properties of alpha1G currents expressed in monkey COS-7 cells and Xenopus oocytes. 2. In immunocytochemical experiments, the co-expression of alpha2-delta increased plasma membrane localization of expressed alpha1G and conversely, the heterologous expression of alpha1G increased immunostaining for endogenous alpha2-delta, suggesting an interaction between the two subunits. 3. Heterologous expression of alpha2-delta together with alpha1G in COS-7 cells increased the amplitude of expressed alpha1G currents by about 2-fold. This finding was confirmed in the Xenopus oocyte expression system. The truncated delta construct did not increase alpha1G current amplitude, or increase its plasma membrane expression. This indicates that it is the exofacial alpha2 domain that is involved in the enhancement by alpha2-delta. 4. Beta1b also produced an increase of functional expression of alpha1G, either in the absence or the presence of heterologously expressed alpha2-delta, whereas the other beta subunits had much smaller effects. 5. None of the accessory subunits had any marked influence on the voltage dependence or kinetics of the expressed alpha1G currents. These results therefore suggest that alpha2-delta and beta1b interact with alpha1G to increase trafficking of, or stabilize, functional alpha1G channels expressed at the plasma membrane.

Cloning and expression of a novel member of the low voltage-activated T-type calcium channel family.

Low voltage-activated Ca2+ channels play important roles in pacing neuronal firing and producing network oscillations, such as those that occur during sleep and epilepsy. Here we describe the cloning and expression of the third member of the T-type family, alpha1I or CavT.3, from rat brain. Northern analysis indicated that it is predominantly expressed in brain. Expression of the cloned channel in either Xenopus oocytes or stably transfected human embryonic kidney-293 cells revealed novel gating properties. We compared these electrophysiological properties to those of the cloned T-type channels alpha1G and alpha1H and to the high voltage-activated channels formed by alpha1Ebeta3. The alpha1I channels opened after small depolarizations of the membrane similar to alpha1G and alpha1H but at more depolarized potentials. The kinetics of activation and inactivation were dramatically slower, which allows the channel to act as a Ca2+ injector. In oocytes, the kinetics were even slower, suggesting that components of the expression system modulate its gating properties. Steady-state inactivation occurred at higher potentials than any of the other T channels, endowing the channel with a substantial window current. The alpha1I channel could still be classified as T-type by virtue of its criss-crossing kinetics, its slow deactivation (tail current), and its small (11 pS) conductance in 110 mM Ba2+ solutions. Based on its brain distribution and novel gating properties, we suggest that alpha1I plays important roles in determining the electroresponsiveness of neurons, and hence, may be a novel drug target.