Differential expression of T-type calcium channels in P/Q-type calcium channel mutant mice with ataxia and absence epilepsy

Mutations in P/Q-type calcium channels generate common phenotypes in mice and humans, which are characterized by ataxia, paroxysmal dyskinesia, and absence seizures. Subsequent functional changes of T-type calcium channels in thalamus are observed in P/Q-type calcium channel mutant mice and these changes play important roles in generation of absence seizures. However, the changes in T-type calcium channel function and/or expression in the cerebellum, which may be related to movement disorders, are still unknown. The leaner mouse exhibits severe ataxia, paroxysmal dyskinesia, and absence epilepsy due to a P/Q-type calcium channel mutation. We investigated changes in T-type calcium channel expression in the leaner mouse thalamus and cerebellum using quantitative real-time polymerase chain reaction (qRT-PCR) and quantitative in situ hybridization histochemistry (ISHH). qRT-PCR analysis showed no change in T-type calcium channel alpha 1G subunit (Cav3.1) expression in the leaner thalamus, but a significant decrease in alpha 1G expression in the whole leaner mouse cerebellum. Interestingly, quantitative ISHH revealed differential changes in alpha 1G expression in the leaner cerebellum, where the granule cell layer showed decreased alpha 1G expression while Purkinje cells showed increased alpha 1G expression. To confirm these observations, the granule cell layer and the Purkinje cell layer were laser capture microdissected separately, then analyzed with qRT-PCR. Similar to the observation obtained by ISHH, the leaner granule cell layer showed decreased alpha 1G expression and the leaner Purkinje cell layer showed increased alpha 1G expression. These results suggest that differential expression of T-type calcium channels in the leaner cerebellum may be involved in the observed movement disorders.     

Decreased calretinin expression in cerebellar granule cells in the leaner mouse

We investigated calretinin expression in cerebellar granule cells of 30-day-old leaner mice to understand possible changes in calcium homeostasis due to the calcium channel mutation that these mice carry. Quantitative in situ hybridization histochemistry showed decreased calretinin mRNA expression in the leaner cerebellum. Immunohistochemical staining also revealed decreased calretinin immunoreactivity in the leaner cerebellum. To exclude the effect of granule cell loss that occurs in the leaner mouse when comparing cerebellar calretinin expression, the number of granule cells per unit area in the cerebellum was compared to the wild-type cerebellum. Granule cell counts per unit area of cerebellum revealed similar numbers of granule cells present in wild-type and leaner mice. Laser capture microdissection (LCM) was employed to obtain an equal number of granule cells from wild-type and leaner mice. Western blot analysis with LCM-procured cerebellar granule cells showed decreased calretinin expression in leaner granule cells. These results indicate that there is an absolute decrease in calretinin expression in leaner granule cells even when granule cell loss is taken into account. Decreased calretinin expression in leaner granule cells may contribute to altered calcium buffering capacity. This alteration could be an adaptive change due to the calcium channel dysfunction, and may result in abnormal neuronal excitability and gene expression.     

Changes in TRPC channel expression during postnatal development of cerebellar neurons

In the brain, classical (canonical) transient receptor potential (TRPC) channels are thought to be involved in different aspects of neuronal development. We investigated the developmental expression profile of TRPC channels in rat cerebellum during the first 6 weeks after birth. TRPC3 expression is significantly up-regulated whereas TRPC4 and TRPC6 expression are significantly down-regulated over this period of time. TRPC3 expression is mainly found on Purkinje cells and their dendrites, suggesting that the increase in TRPC3 expression reflects development of the dendritic tree of Purkinje cells. TRPC4 expression was restricted to granule and their precursor cells. TRPC6 expression is found on Purkinje cell bodies, on mature granule cells in the internal granule cell layer (but not their precursors) and interneurons in the molecular layer. The decrease in TRPC4 expression suggests that it is required for proper granule cell development whereas the decrease in TRPC6 expression is presumably correlated with interneuron development. Moreover, we demonstrate the presence of functional TRPC channels on Purkinje cell dendrites that are activated following stimulation of metabotropic glutamate receptors. Our results reveal cell-specific expression patterns for different TRPC proteins and suggest that developmental changes in TRPC protein expression may be required for proper postnatal cerebellar development.     

Elevated P/Q type (alpha1A) and L2 type (alpha1D) Purkinje cell voltage-gated calcium channels in the cerebella of seizure prone gerbils

Differences in expression of N-methyl-D-aspartate (NMDA) receptor and voltage gated Ca2+ channels (VGCC) in the gerbil cerebellum were investigated to identify routes of Ca2+ influx that may be involved in Purkinje cell damage. Immunodensities of NR1 and NR2A/B were the same in seizure resistant (SR) and seizure sensitive (SS) gerbils. However, both P/Q type (alpha1A) and L2 type (alpha1D) VGCC levels were higher in the Purkinje cells of SS gerbils than in those of SR gerbils, whereas N type (alpha1B) and L1 type (alpha1C) VGCC levels were similar in the two groups. Our findings suggest that increases in P/Q type (alpha1A) and L2 type (alpha1D) VGCC are implicated in the degeneration of Purkinje cells in SS gerbils.     

RGS8 expression in developing cerebellar Purkinje cells

The regulators of G protein signaling (RGS) proteins modulate heterotrimeric G protein signaling. RGS8 belongs to B/R4 subfamily of RGS proteins and is specifically expressed in Purkinje cells of adult cerebellum. Here, to examine the expression of RGS8 mRNA in developing cerebellum, we performed in situ hybridization. Apparent signals for expression of RGS8 mRNA were first detected on day 9 after birth, then RGS8 mRNA expression in Purkinje cells increased up to day 21, and its levels decreased to some extent in adult Purkinje cells. We also studied the expression of RGS7, which is expressed in Golgi cells in the granule cell layer of adult cerebellum. The expression of RGS7 mRNA was recognized in 7 day neonatal cerebellum. When examined with anti-RGS8 antibody, the RGS8 protein was already excluded from nucleus on day 9, and was distributed in cell body and dendrites in differentiating Purkinje cells of 14 day neonates.     

T‐type calcium channel blockers inhibit autophagy and promote apoptosis of malignant melanoma cells

We have recently reported that human melanoma cells express a variety of voltage‐gated calcium (Ca²⁺) channel types, including low‐voltage‐activated T‐type channels that play a significant role in melanoma cell cycle progression. Here, we challenged melanoma metastatic cells with T‐type channel blockers of clinical use and found a dual effect on cell viability: (i) a reduction in the proliferation rate, through a halt in the progression to the G₁‐S phase; and (ii) a promotion of cell death that was partially dependent on the activation of caspases. An in‐depth analysis of the death process showed that the apoptotic pathway is preceded by endoplasmic reticulum stress and the subsequent inhibition of the basal macroautophagy which is active in these cells. The effects of pharmacological blockers on Ca²⁺ homeostasis, autophagy, and cell death were mimicked by T‐type channel gene silencing. These results provide the basis for a new pharmacological and/or gene silencing approach toward tackling melanoma metastasis.     

Spatiotemporal expression and functional implication of CXCL14 in the developing mice cerebellum

Cerebellar granule neurons migrate from the external granule cell layer (EGL) to the internal granule cell layer (IGL) during postnatal morphogenesis. This migration process through 4 different layers is a complex mechanism which is highly regulated by many secreted proteins. Although chemokines are well-known peptides that trigger cell migration, but with the exception of CXCL12, which is responsible for prenatal EGL formation, their functions have not been thoroughly studied in granule cell migration. In the present study, we examined cerebellar CXCL14 expression in neonatal and adult mice. CXCL14 mRNA was expressed at high levels in adult mouse cerebellum, but the protein was not detected. Nevertheless, Western blotting analysis revealed transient expression of CXCL14 in the cerebellum in early postnatal days (P1, P8), prior to the completion of granule cell migration. Looking at the distribution of CXCL14 by immunohistochemistry revealed a strong immune reactivity at the level of the Purkinje cell layer and molecular layer which was absent in the adult cerebellum. In functional assays, CXCL14 stimulated transwell migration of cultured granule cells and enhanced the spreading rate of neurons from EGL microexplants. Taken together, these results revealed the transient expression of CXCL14 by Purkinje cells in the developing cerebellum and demonstrate the ability of the chemokine to stimulate granule cell migration, suggesting that it must be involved in the postnatal maturation of the cerebellum.     

Contribution of the neural cell recognition molecule NB‐3 to synapse formation between parallel fibers and Purkinje cells in mouse

The neural cell recognition molecule NB‐3, also referred to as contactin‐6, is expressed prominently in the developing nervous system after birth and its deficiency has been shown to cause impairment in motor coordination. Here, we investigated the contribution of NB‐3 to cerebellar development, focusing on lobule 3 where NB‐3 was expressed in granule cells but not in Purkinje cells. In the developing molecular layer, the neural cell recognition molecules TAG‐1, L1, and NB‐3 formed distinct expression zones from the external granule cell layer to the internal granule cell layer (IGL), respectively. The NB‐3‐immunoreactive zone did not overlap with TAG‐1‐immunoreactive zone. By contrast, the L1‐immunoreactive zone overlapped with both the TAG‐1‐ and NB‐3‐immunoreactive zones. NB‐3‐positive puncta overlapped with vesicular glutamate transporter 1, a presynaptic marker and were apposed close to metabotropic glutamate receptor 1A, a postsynaptic marker, indicating that NB‐3 is localized presynaptically at glutamatergic synapses between parallel fibers and Purkinje cells. In NB‐3 knockout mice, L1 immunoreactive signals were increased in the IGL at postnatal day (P) 5, suggesting the increase in the number of immature granule cells of the IGL. In addition, the density of parallel fiber synaptic terminals was reduced in NB‐3 knockout mice relative to wild‐type mice at P5 to P10. In parallel with these findings, caspase‐dependent cell death was significantly increased in the NB‐ 3‐deficient cerebellum at P15. Collectively, our results indicate that NB‐3 deficiency affects synapse formation during postnatal cerebellar development. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

Differential modulation of N‐type calcium channels by µ‐opioid receptors in oxytocinergic versus vasopressinergic neurohypophysial terminals

Opioids modulate the electrical activity of magnocellular neurons (MCN) and inhibit neuropeptide release at their terminals in the neurohypophysis. We have previously shown that µ‐opioid receptor (MOR) activation induces a stronger inhibition of oxytocin (OT) than vasopressin (AVP) release from isolated MCN terminals. This higher sensitivity of OT release is due, at least in part, to the selective targeting of R‐type calcium channels. We now describe the underlying basis for AVP's weaker inhibition by MOR activation and provide a more complete explanation of the complicated effects on neuropeptide release. We found that N‐type calcium channels in AVP terminals are differentially modulated by MOR; enhanced at lower concentrations but increasingly inhibited at higher concentrations of agonists. On the other hand, N‐type calcium channels in OT terminals were always inhibited. The response pattern in co‐labeled terminals was analogous to that observed in AVP‐containing terminals. Changes in intracellular calcium concentration and neuropeptide release corroborated these results as they showed a similar pattern of enhancement and inhibition in AVP terminals contrasting with solely inhibitory responses in OT terminals to MOR agonists. We established that fast translocation of Ca²⁺ channels to the plasma membrane was not mediating current increments and thus, changes in channel kinetic properties are most likely involved. Finally, we reveal a distinct Ca‐channel β‐subunit expression between each type of nerve endings that could explain some of the differences in responses to MOR activation. These results help advance our understanding of the complex modulatory mechanisms utilized by MORs in regulating presynaptic neuropeptide release. J. Cell. Physiol. 225: 276–288, 2010. © 2010 Wiley‐Liss, Inc.     

Calcium‐induced calcium release from intracellular stores is developmentally regulated in primary cultures of cerebellar granule neurons

The properties of depolarization‐evoked calcium transients are known to change during the maturation of dissociated cerebellar granule neuron cultures. Here, we assessed the role of the calcium‐induced calcium release (CICR) mechanism in granule neuron maturation. Both depletion of intracellular calcium stores and the pharmacological blockade of CICR significantly reduced depolarization stimulated calcium transients in young but not older (≥1 week) cultures. This functional decrease in the CICR signaling component was associated with the reduction of ryanodine receptor (RyR) immunoreactivity during granule neuron maturation both in culture and in the intact cerebellum. These observations are consistent with the idea that changes in RyR expression result in functional changes in calcium signaling transients during normal neuronal development in the intact mammalian cerebellum as well as in reduced neuronal cultures. Pharmacological disruption of CICR during neuron differentiation in vitro resulted in dose‐dependent changes in survival, GAP‐43 expression, and the acquisition of the glutamatergic neurotransmitter phenotype. Together, these results indicate that CICR function plays a physiologically relevant role in regulating early granule neuron differentiation in vitro and is likely to play a role in cerebellar maturation. © 2000 John Wiley & Sons, Inc. J Neurobiol 42: 134–147, 2000     

Voltage‐sensitive calcium currents and their role in regulating phrenic motoneuron electrical excitability during the perinatal period

This study examined the ontogeny of voltage‐sensitive calcium conductances in rat phrenic motoneurons (PMNs) and their role in regulating electrical excitability during the perinatal period. Specifically, we studied the period spanning from embryonic day (E)16 through postnatal day (P)1, when PMNs undergo fundamental transformation in their morphology, passive properties, ionic channel composition, synaptic inputs, and electrical excitability. Low voltage‐activated (LVA) and high voltage‐activated (HVA) conductances were measured using whole cell patch recordings utilizing a cervical slice‐phrenic nerve preparation from perinatal rats. Changes between E16 and P0–1 included the following: an ≈2‐fold increase in the density of total calcium conductances, an ≈2‐fold decrease in the density of LVA calcium conductances, and an ≈3‐fold increase in the density of HVA conductances. The elevated expression of T‐type calcium channels during the embryonic period lengthened the action potential and enhanced electrical excitability as evidenced by a hyperpolarization‐evoked rebound depolarization. The reduction of LVA current density coupled to the presence of a hyperpolarizing outward A‐type potassium current had a critical effect in diminishing the rebound depolarization in neonatal PMNs. The increase in HVA current density was concomitant with the emergence of a calcium‐dependent “hump‐like” afterdepolarization (ADP) and burst‐like firing. Neonatal PMNs develop a prominent medium‐duration afterhyperpolarization (mAHP) as the result of coupling between N‐type calcium channels and small conductance, calcium‐activated potassium channels. These data demonstrate that changes in calcium channel expression contribute to the maturation of PMN electrophysiological properties during the time from the commencement of fetal inspiratory drive to the onset of continuous breathing at birth. © 2001 John Wiley & Sons, Inc. J Neurobiol 46: 231–248, 2001     

The calcium‐sensing receptor and integrins modulate cerebellar granule cell precursor differentiation and migration

In the developing cerebellum granule cell precursors (GCPs) proliferate in the external granule cell layer before differentiating and migrating to the inner granule cell layer. Aberrant GCP proliferation leads to medulloblastoma, the most prevalent form of childhood brain cancer. Here, we demonstrate that the calcium‐sensing receptor (CaSR), a homodimeric G‐protein coupled receptor, functions in conjunction with cell adhesion proteins, the integrins, to enhance GCP migration and cell homing by promoting GCP differentiation. During the second postnatal week a robust peak in CaSR expression was observed in GCPs; reciprocal immunoprecipitation experiments conducted during this period established that the CaSR and β1 integrins are present together in a macromolecular protein complex. Analysis of cell‐surface proteins demonstrated that activation of the CaSR by positive allosteric modulators promoted plasma membrane expression of β1 integrins via ERK2 and AKT phosphorylation and resulted in increased GCP migration toward an extracellular matrix protein. The results of in vivo experiments whereby CaSR modulators were injected i.c.v. revealed that CaSR activation promoted radial migration of GCPs by enhancing GCP differentiation, and conversely, a CaSR inhibitor disrupted GCP differentiation and promoted GCP proliferation. Our results demonstrate that an ion‐sensing G‐protein coupled receptor acts to promote neuronal differentiation and homing during cerebellar maturation. These findings together with those of others also suggest that CaSR/integrin complexes act to transduce extracellular calcium signals into cellular movement, and may function in this capacity as a universal cell migration/homing complex in the developing brain. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 375–389, 2016     

Gating deficiency in a familial hemiplegic migraine type 1 mutant P/Q-type calcium channel

Familial hemiplegic migraine type 1 (FHM1) arises from missense mutations in the gene encoding alpha1A, the pore-forming subunit of P/Q-type calcium channels. The nature of the channel disorder is fundamental to the disease, yet is not well understood. We studied how the most prevalent FHM1 mutation, a threonine to methionine substitution at position 666 (TM), affects both ionic current and gating current associated with channel activation, a previously unexplored feature of P/Q channels. Whole-cell currents were measured in HEK293 cells expressing channels containing either wild-type (WT) or TM alpha1A. Calcium currents were significantly smaller in cells expressing TM channels, consistent with previous reports. In contrast, surface expression of TM channels, measured by immunostaining against an extracellular epitope, was not decreased, and Western blots demonstrated that TM alpha1A subunits were expressed as full-length proteins. WT and TM gating currents were isolated by replacing Ca2+ with the nonpermeant cation La3+. The gating currents generated by the mutant channels were one-third that of WT, a deficiency sufficient to account for the observed attenuation in calcium current; the remaining gating current was no different in kinetics or voltage dependence. Thus, the decreased calcium influx seen with TM channels can be attributed to a reduced number of channels available to undergo the voltage-dependent conformational changes needed for channel opening, not to fewer channel proteins expressed on the cell surface. This identification of an intrinsic defect in FHM1 mutant channels helps explain their impact on neurotransmission when they occupy type-specific slots for P/Q channels at central nerve terminals.     

Immunolocalization of the acid-sensing ion channel 2a in the rat cerebellum

The acid-sensing ion channels (ASICs) are members of the DEG/ENaC superfamily of Na+ channels. Acid-gated cation currents have been detected in neurons from multiple regions of the brain including the cerebellum, but little is known about their molecular identity and function. Recently, one of ASICs (ASIC1a) was implicated in synaptic plasticity. In this study we examined the subcellular distribution of ASIC2a in rat cerebellum by immunostaining and confocal microscopy. Monoclonal antibodies for labeling of defined brain structures, for example, astroglia, Purkinje cell dendrites, nuclei, and presynaptic terminals were used for colocalization analyses. In the gray matter, the anti-ASIC2a antibody intensively stained dendrite branches of Purkinje cells evenly distributed throughout the entire molecular layer (ML). In the granule cell layer (GL), anti-ASIC2a antibody stained synaptic glomeruli. Neuronal localization of ASIC2a was confirmed by lack of co-staining with glial fibrillary acidic protein. Anti-ASIC2a staining in the ML colocalized with metabotropic glutamate receptor 1alpha (mGluR1alpha) in Purkinje cell dendrites and dendritic spines. Both proteins, mGluR1alpha and ASIC2a, were enriched in a crude synaptic membrane fraction prepared from cerebellum, suggesting synaptic expression of these proteins. Dual staining with anti-syntaxin 1A and anti-ASIC2a antibodies demonstrates characteristic complementary distribution of two proteins in both ML and GL. Because syntaxin 1A localized in presynaptic membranes and synaptic vesicles, complementary distribution with ASIC2a suggests postsynaptic localization of ASIC2a in these structures. This study shows specific localization of ASIC2a in both Purkinje and granule cell dendrites of the cerebellum and enrichment of ASIC2a in a crude cerebellar synaptic membrane fraction. The study is the first report of synaptic localization of ASIC2a in the CNS. The synaptic localization of ASIC2a in the cerebellum makes this channel a candidate for a role in motor coordination and learning.     

Cellular Distribution of Gangliosides in the Developing Mouse Cerebellum: Analysis Using the Staggerer Mutant

The distribution of cerebellar gangliosides was studied in staggerer (sg/sg) mutant mice, where the majority of granule cells die after completing their migration across the molecular layer. In addition, the external granule cell layer in sg/sg mice persists longer than in normal mice. Moreover, in the sg/sg cerebellum, Purkinje cells are significantly reduced in number, and almost none have tertiary branchlet spines. The loss of Purkinje cells and granule cells in sg/sg mice is accompanied by an early-onset reactive gliosis that continues through adulthood. By correlating changes in ganglioside composition with the well-documented histological events of cerebellar development in normal and sg/sg mice, we obtained strong evidence for a nonrandom cellular distribution of gangliosides. The sharpest reduction in the GD1a content of sg/sg cerebellum occurred after 15 days of age, coincident with granule cell loss. GT1a, on the other hand, was significantly reduced from 15 through 150 days in the sg/sg mice. GD3 is a major ganglioside of the undifferentiated granule cell, but it becomes rapidly displaced by the more complex gangliosides with the onset of granule cell maturation. In the sg/sg mice, GD3 persisted at abnormally high levels from 15 to 28 days and then accumulated through adulthood. These findings, and those from other cerebellar mouse mutants, suggest that GD1a is enriched in granule cells and that GT1a is enriched in Purkinje cells. Our findings also suggest that GT1a is more concentrated in branchlet spines than in other regions of the Purkinje cell membrane. GT1b appears to be enriched in both granule cells and Purkinje cells, whereas GM1 appears to be enriched in myelin. Furthermore, the apparent persistence of the embryonic ganglioside GD3 in sg/sg mice results from an early-onset reactive gliosis, together with a partial retardation in granule cell maturation. The accumulation of GD3 beyond 28 days reflects the continued accretion of GD3 in reactive glia.     

Expression of dihydropyridine-sensitive brain calcium channels in the rat central nervous system.

We have localized dihydropyridine (DHP-sensitive calcium channels in rat brain by in situ hybridization and immunohistochemistry. The mRNA for the dihydropyridine-sensitive calcium channel alpha 1 subunit (DHPR-B) is prominently localized in neuronal cells in the olfactory bulb, dentate gyrus, hippocampus, arcuate nucleus, paraventricular nucleus, ventromedial nucleus, cerebral cortex, superior colliculus and the cerebellar Purkinje cell layer. Strong expression of DHPR-B mRNA was also found in the pituitary and pineal glands. DHP-sensitive calcium channel alpha 1 subunit distribution has also been examined immunohistochemically with polyclonal antibodies raised against synthetic peptides specific for the DHPR-B alpha 1 subunit protein. The results from immunohistochemistry were in good agreement with those from in situ hybridization. Thus, regional distribution and localization of DHPR-B mRNA and alpha 1 subunit protein in rat brain suggest that this type of DHP-sensitive brain calcium channel may play an important role in excitation-secretion coupling functions in the neuroendocrine system.     

Effects of voltage‐gated calcium channel subunit genes on calcium influx in cultured C. elegans mechanosensory neurons

Voltage‐gated calcium channels (VGCCs) serve as a critical link between electrical signaling and diverse cellular processes in neurons. We have exploited recent advances in genetically encoded calcium sensors and in culture techniques to investigate how the VGCC α₁ subunit EGL‐19 and α₂/δ subunit UNC‐36 affect the functional properties of C. elegans mechanosensory neurons. Using the protein‐based optical indicator cameleon, we recorded calcium transients from cultured mechanosensory neurons in response to transient depolarization. We observed that in these cultured cells, calcium transients induced by extracellular potassium were significantly reduced by a reduction‐of‐function mutation in egl‐19 and significantly reduced by L‐type calcium channel inhibitors; thus, a main source of touch neuron calcium transients appeared to be influx of extracellular calcium through L‐type channels. Transients did not depend directly on intracellular calcium stores, although a store‐independent 2‐APB and gadolinium‐sensitive calcium flux was detected. The transients were also significantly reduced by mutations in unc‐36, which encodes the main neuronal α₂/δ subunit in C. elegans. Interestingly, while egl‐19 mutations resulted in similar reductions in calcium influx at all stimulus strengths, unc‐36 mutations preferentially affected responses to smaller depolarizations. These experiments suggest a central role for EGL‐19 and UNC‐36 in excitability and functional activity of the mechanosensory neurons. © 2006 Wiley Periodicals, Inc. J Neurobiol, 2006     

Kv8.1, a new neuronal potassium channel subunit with specific inhibitory properties towards Shab and Shaw channels.

Outward rectifier K+ channels have a characteristic structure with six transmembrane segments and one pore region. A new member of this family of transmembrane proteins has been cloned and called Kv8.1. Kv8.1 is essentially present in the brain where it is located mainly in layers II, IV and VI of the cerebral cortex, in hippocampus, in CA1-CA4 pyramidal cell layer as well in granule cells of the dentate gyrus, in the granule cell layer and in the Purkinje cell layer of the cerebellum. The Kv8.1 gene is in the 8q22.3-8q24.1 region of the human genome. Although Kv8.1 has the hallmarks of functional subunits of outward rectifier K+ channels, injection of its cRNA in Xenopus oocytes does not produce K+ currents. However Kv8.1 abolishes the functional expression of members of the Kv2 and Kv3 subfamilies, suggesting that the functional role of Kv8.1 might be to inhibit the function of a particular class of outward rectifier K+ channel types. Immunoprecipitation studies have demonstrated that inhibition occurs by formation of heteropolymeric channels, and results obtained with Kv8.1 chimeras have indicated that association of Kv8.1 with other types of subunits is via its N-terminal domain.