Marcela S. Nadal

Molecular Diversity of K+ Channels

ABSTRACT: K+ channel principal subunits are by far the largest and most diverse of the ion channels. This diversity originates partly from the large number of genes coding for K+ channel principal subunits, but also from other processes such as alternative splicing, generating multiple mRNA transcripts from a single gene, heteromeric assembly of different principal subunits, as well as possible RNA editing and posttranslational modifications. In this chapter, we attempt to give an overview (mostly in tabular format) of the different genes coding for K+ channel principal and accessory subunits and their genealogical relationships. We discuss the possible correlation of different principal subunits with native K+ channels, the biophysical and pharmacological properties of channels formed when principal subunits are expressed in heterologous expression systems, and their patterns of tissue expression. In addition, we devote a section to describing how diversity of K+ channels can be conferred by heteromultimer formation, accessory subunits, alternative splicing, RNA editing and posttranslational modifications. We trust that this collection of facts will be of use to those attempting to compare the properties of new subunits to the properties of others already known or to those interested in a comparison between native channels and cloned candidates.

Contributions of Kv3 Channels to Neuronal Excitability

ABSTRACT: Four mammalian Kv3 genes have been identified, each of which generates, by alternative splicing, multiple protein products differing in their C‐terminal sequence. Products of the Kv3.1 and Kv3.2 genes express similar delayed‐rectifier type currents in heterologous expression systems, while Kv3.3 and Kv3.4 proteins express A‐type currents. All Kv3 currents activate relatively fast at voltages more positive than −10 mV, and deactivate very fast. The distribution of Kv3 mRNAs in the rodent CNS was studied by in situ hybridization, and the localization of Kv3.1 and Kv3.2 proteins has been studied by immunohistochemistry. Most Kv3.2 mRNAs (∼90%) are present in thalamic‐relay neurons throughout the dorsal thalamus. The protein is expressed mainly in the axons and terminals of these neurons. Kv3.2 channels are thought to be important for thalamocortical signal transmission. Kv3.1 and Kv3.2 proteins are coexpressed in some neuronal populations such as in fast‐spiking interneurons of the cortex and hippocampus, and neurons in the globus pallidus. Coprecipitation studies suggest that in these cells the two types of protein form heteromeric channels. Kv3 proteins appear to mediate, in native neurons, similar currents to those seen in heterologous expression systems. The activation voltage and fast deactivation rates are believed to allow these channels to help repolarize action potentials fast without affecting the threshold for action potential generation. The fast deactivating current generates a quickly recovering afterhyperpolarization, thus maximizing the rate of recovery of Na+ channel inactivation without contributing to an increase in the duration of the refractory period. These properties are believed to contribute to the ability of neurons to fire at high frequencies and to help regulate the fidelity of synaptic transmission. Experimental evidence has now become available showing that Kv3.1‐Kv3.2 channels play critical roles in the generation of fast‐spiking properties in cortical GABAergic interneurons.

DPP10 Modulates Kv4-mediated A-type Potassium Channels

A new member of a family of proteins characterized by structural similarity to dipeptidyl peptidase (DPP) IV known as DPP10 was recently identified and linked to asthma susceptibility; however, the cellular functions of DPP10 are thus far unknown. DPP10 is highly homologous to subfamily member DPPX, which we previously reported as a modulator of Kv4-mediated A-type potassium channels (Nadal, M. S., Ozaita, A., Amarillo, Y., Vega-Saenz de Miera, E., Ma, Y., Mo, W., Goldberg, E. M., Misumi, Y., Ikehara, Y., Neubert, T. A., and Rudy, B. (2003) Neuron. 37, 449–461). We studied the ability of DPP10 protein to modulate the properties of Kv4.2 channels in heterologous expression systems. We found DPP10 activity to be nearly identical to DPPX activity and significantly different from DPPIV activity. DPPX and DPP10 facilitated Kv4.2 protein trafficking to the cell membrane, increased A-type current magnitude, and modified the voltage dependence and kinetic properties of the current such that they resembled the properties of A-type currents recorded in neurons in the central nervous system. Using in situ hybridization, we found DPP10 to be prominently expressed in brain neuronal populations that also express Kv4 subunits. Furthermore, DPP10 was detected in immunoprecipitated Kv4.2 channel complexes from rat brain membranes, confirming the association of DPP10 proteins with native Kv4.2 channels. These experiments suggest that DPP10 contributes to the molecular composition of A-type currents in the central nervous system. To dissect the structural determinants of these integral accessory proteins, we constructed chimeras of DPPX, DPP10, and DPPIV lacking the extracellular domain. Chimeras of DPPX and DPP10, but not DPPIV, were able to modulate the properties of Kv4.2 channels, highlighting the importance of the intracellular and transmembrane domains in this activity.

Kv4 Accessory Protein DPPX (DPP6) is a Critical Regulator of Membrane Excitability in Hippocampal CA1 Pyramidal Neurons

A-type K+ currents have unique kinetic and voltage-dependent properties that allow them to finely tune synaptic integration, action potential (AP) shape and firing patterns. In hippocampal CA1 pyramidal neurons, Kv4 channels make up the majority of the somatodendritic A-type current. Studies in heterologous expression systems have shown that Kv4 channels interact with transmembrane dipeptidyl-peptidase-like proteins (DPPLs) to regulate the surface trafficking and biophysical properties of Kv4 channels. To investigate the influence of DPPLs in a native system, we conducted voltage-clamp experiments in patches from CA1 pyramidal neurons expressing short-interfering RNA (siRNA) targeting the DPPL variant known to be expressed in hippocampal pyramidal neurons, DPPX (siDPPX). In accordance with heterologous studies, we found that DPPX downregulation in neurons resulted in depolarizing shifts of the steady-state inactivation and activation curves, a shallower conductance-voltage slope, slowed inactivation, and a delayed recovery from inactivation for A-type currents. We carried out current-clamp experiments to determine the physiological effect of the A-type current modifications by DPPX. Neurons expressing siDPPX exhibited a surprisingly large reduction in subthreshold excitability as measured by a decrease in input resistance, delayed time to AP onset, and an increased AP threshold. Suprathreshold DPPX downregulation resulted in slower AP rise and weaker repolarization. Computer simulations supported our experimental results and demonstrated how DPPX remodeling of A-channel properties can result in opposing sub- and suprathreshold effects on excitability. The Kv4 auxiliary subunit DPPX thus acts to increase neuronal responsiveness and enhance signal precision by advancing AP initiation and accelerating both the rise and repolarization of APs.

DPP6 localization in brain supports function as a Kv4 channel associated protein

The gene encoding the dipeptidyl peptidase-like protein DPP6 (also known as DPPX) has been associated with human neural disease. However, until recently no function had been found for this protein. It has been proposed that DPP6 is an auxiliary subunit of neuronal Kv4 K+ channels, the ion channels responsible for the somato-dendritic A-type K+ current, an ionic current with crucial roles in the regulation of firing frequency, dendritic integration and synaptic plasticity. This view has been supported mainly by studies showing that DPP6 is necessary to generate channels with biophysical properties resembling the native channels in some neurons. However, independent evidence that DPP6 is a component of neuronal Kv4 channels in the brain, and whether this protein has other functions in the CNS is still lacking. We generated antibodies to DPP6 proteins to compare their distribution in brain with that of the Kv4 pore-forming subunits. DPP6 proteins were prominently expressed in neuronal populations expressing Kv4.2 proteins and both types of protein were enriched in the dendrites of these cells, strongly supporting the hypothesis that DPP6 is an associated protein of Kv4 channels in brain neurons. The observed similarity in the cellular and subcellular patterns of expression of both proteins suggests that this is the main function of DPP6 in brain. However, we also found that DPP6 antibodies intensely labeled the hippocampal mossy fiber axons, which lack Kv4 proteins, suggesting that DPP6 proteins may have additional, Kv4-unrelated functions.

Differential characterization of three alternative spliced isoforms of DPPX

Transient subthreshold-activating somato-dendritic A-type K(+) currents (I(SA)s) have fundamental roles in neuronal function. They cause delayed excitation, influence spike repolarization, modulate the frequency of repetitive firing, and have important roles in signal processing in dendrites. We previously reported that DPPX proteins are key components of the channels mediating these currents (Kv4 channels) (Nadal, M.S., Ozaita, A., Amarillo, Y., Vega-Saenz, E., Ma, Y., Mo, W., Goldberg, E.M., Misumi, Y., Ikehara, Y., Neubert, T.A., Rudy, B., 2003. The CD26-related dipeptidyl aminopeptidase-like protein DPPX is a critical component of neuronal A-type K+ channels. Neuron 37, 449-461). The DPPX gene encodes alternatively spliced transcripts that generate single-spanning transmembrane proteins with a short, divergent intracellular domain and a large extracellular domain. We characterized the modulatory effects on Kv4.2-mediated currents and the rat brain distribution of three splice variants of the DPPX subfamily of proteins. These three splice isoforms--DPPX-S, DPPX-L, and DPPX-K--are expressed in adult rat brain and modify the voltage dependence and kinetic properties of Kv4.2 channels expressed in Xenopus oocytes. Analysis of a deletion mutant that lacks the variable N-terminus showed that the N-terminus is not necessary for the modulation of Kv4 channels. Using in situ hybridization analysis, we found that the three splice variants are prominently expressed in brain regions where Kv4 subunits are also expressed. DPPX-K and DPPX-S mRNAs have a widespread distribution, whereas DPPX-L transcripts are concentrated in few specific areas of the rat brain. The emerging diversity of DPPX splice variants, differing only in the N-terminus of the protein, opens up intriguing possibilities for the modulation of Kv4 channels.

The effects of Shaker beta-subunits on the human lymphocyte K+ channel Kv1.3.

The activation of T-lymphocytes is dependent upon, and accompanied by, an increase in voltage-gated K+ conductance. Kv1.3, a Shaker family K+ channel protein, appears to play an essential role in the activation of peripheral human T cells. Although Kv1.3-mediated K+ currents increase markedly during the activation process in mice, and to a lesser degree in humans, Kv1.3 mRNA levels in these organisms do not, indicating post-transcriptional regulation. In other tissues Shaker K+ channel proteins physically associate with cytoplasmic β-subunits (Kvβ1–3). Recently it has been shown that Kvβ1 and Kvβ2 are expressed in mouse T cells and that they are up-regulated during mitogen-stimulated activation. In this study, we show that the human Kvβ subunits substantially increase K+ current amplitudes when coexpressed with their Kv1.3 counterpart, and that unlike in mouse, protein levels of human Kvβ2 remain constant upon activation. Differences in Kvβ2 expression between mice and humans may explain the differential K+ conductance increases which accompany T-cell proliferation in these organisms.

Evidence for the presence of a novel Kv4‐mediated A‐type K+ channel‐modifying factor

1 Subthreshold‐operating transient (A‐type) K+ currents (ISAs) are important in regulating neuronal firing frequency and in the modulation of incoming signals in dendrites. It is now known that Kv4 proteins are the principal, or pore‐forming, subunits of the channels mediating ISAs. In addition, accessory subunits of Kv4 channels have also been identified. These either have no effect or slow down the inactivation kinetics of Kv4 channels. However, in many neuronal populations the ISA is faster, not slower, than the current generated by channels containing only Kv4 proteins. 2 Evidence is presented for the presence in rat cerebellar mRNA of transcripts encoding a molecular factor, termed KAF, that accelerates the kinetics of Kv4 channels. Size‐fractionation of cerebellar mRNA in sucrose gradients separated the high molecular weight mRNAs (4–7 kb) encoding KAF from the low molecular weight ones (1.5–3 kb) encoding factors that slow down the inactivation kinetics of Kv4 channels. The latter were identified as KChIPs using anti‐KChIP antisense oligonucleotides. 3 Both anti‐KChIP and anti‐Kv4 antisense oligonucleotides failed to eliminate KAFs activity from the high molecular weight mRNA fraction, thus suggesting that KAF might be a novel subunit(s) that can contribute to generating native ISA channel diversity. 4 The time course of the currents expressed by KAF‐modified Kv4 channels resembles more closely the time course of the native ISA in cerebellar granule cells.

Modulation of Kv3 potassium channels expressed in CHO cells by a nitric oxide-activated phosphatase

1 Voltage‐gated K+ channels containing Kv3 subunits play specific roles in the repolarization of action potentials. Kv3 channels are expressed in selective populations of CNS neurons and are thought to be important in facilitating sustained and/or repetitive high frequency firing. Regulation of the activity of Kv3 channels by neurotransmitters could have profound effects on the repetitive firing characteristics of those neurons. 2 Kv3 channels are found in several neuronal populations in the CNS that express nitric oxide synthases (NOSs). We therefore investigated whether Kv3 channels are modulated by the signalling gas nitric oxide (NO). 3 We found that Kv3.1 and Kv3.2 currents are potentially suppressed by D‐NONOate and other NO donors. The effects of NO on these currents are mediated by the activation of guanylyl cyclase (GC), since they are prevented by Methylene Blue, an inhibitor of GC, and by ODQ, a specific inhibitor of the soluble form of GC. Moreover, application of 8‐Br‐cGMP, a permeant analogue of cGMP, also blocked Kv3.1 and Kv3.2 currents. 4 KT5283, a cGMP‐dependent protein kinase (PKG) blocker, prevented the inhibition of Kv3.1 and Kv3.2 currents by D‐NONOate and 8‐Br‐cGMP. This indicates that activation of PKG as a result of the increase in intracellular cGMP levels produced by D‐NONOate or 8‐Br‐cGMP is necessary for channel block. 5 Although the effects of NO on Kv3.1 and Kv3.2 channels require PKG activity, two observations suggest that they are not mediated by phosphorylation of channel proteins: (a) the reagents affect both Kv3.2 and Kv3.1 channels, although only Kv3.2 proteins have a putative PKA‐PKG phosphorylation site, and (b) mutation of the PKA‐PKG phosphorylation site in Kv3.2 does not interfere with the effects of NO or cGMP. 6 The inhibitory effects of NO and cGMP on Kv3.1 and Kv3.2 currents appear to be mediated by the activation of serine‐threonine phosphatase, since they are blocked by low doses of okadaic acid. Furthermore, direct intracellular application of the catalytic subunit of protein phosphatase 2A inhibited Kv3.2 currents, indicating that activity of PKG‐induced phosphatase is necessary and sufficient to inhibit these channels. 7 The results suggest that basal phosphorylation of Kv3 channel proteins is required for proper channel function. Activation of phosphatases via NO or other signals that increase cGMP might be a potent mechanism to regulate Kv3 channel activity in neurons.

The dipeptidyl-peptidase-like-protein DPP6 determines the unitary conductance of neuronal Kv4.2 channels

The neuronal subthreshold-operating A-type K+ current regulates electrical excitability, spike timing, and synaptic integration and plasticity. The Kv4 channels underlying this current have been implicated in epilepsy, regulation of dopamine release, and pain plasticity. However, the unitary conductance (γ) of neuronal somatodendritic A-type K+ channels composed of Kv4 pore-forming subunits is larger (∼7.5 pS) than that of Kv4 channels expressed singly in heterologous cells (∼4 pS). Here, we examined the putative novel contribution of the dipeptidyl-peptidase-like protein-6 DPP6-S to the γ of native [cerebellar granule neuron (CGN)] and reconstituted Kv4.2 channels. Coexpression of Kv4.2 proteins with DPP6-S was sufficient to match the γ of native CGN channels; and CGN Kv4 channels from dpp6 knock-out mice yielded a γ indistinguishable from that of Kv4.2 channels expressed singly. Moreover, suggesting electrostatic interactions, charge neutralization mutations of two N-terminal acidic residues in DPP6-S eliminated the increase in γ. Therefore, DPP6-S, as a membrane protein extrinsic to the pore domain, is necessary and sufficient to explain a fundamental difference between native and recombinant Kv4 channels. These observations may help to understand the molecular basis of neurological disorders correlated with recently identified human mutations in the dpp6 gene.