David Gomez-Varela

Monoclonal Antibody Blockade of the Human Eag1 Potassium Channel Function Exerts Antitumor Activity

The potassium channel ether à go-go has been directly linked to cellular proliferation and transformation, although its physiologic role(s) are as of yet unknown. The specific blockade of human Eag1 (hEag1) may not only allow the dissection of the role of the channel in distinct physiologic processes, but because of the implication of hEag1 in tumor biology, it may also offer an opportunity for the treatment of cancer. However, members of the potassium channel superfamily are structurally very similar to one another, and it has been notoriously difficult to obtain specific blockers for any given channel. Here, we describe and validate the first rational design of a monoclonal antibody that selectively inhibits a potassium current in intact cells. Specifically blocking hEag1 function using this antibody inhibits tumor cell growth both in vitro and in vivo. Our data provide a proof of concept that enables the generation of functional antagonistic monoclonal antibodies against ion channels with therapeutic potential. The particular antibody described here, as well as the technique developed to make additional functional antibodies to Eag1, makes it possible to evaluate the potential of the channel as a target for cancer therapy.

Modulation of human erg K+ channel gating by activation of a G protein‐coupled receptor and protein kinase C

1 Modulation of the human ether‐à‐go‐go‐related gene (HERG) K+ channel was studied in two‐electrode voltage‐clamped Xenopus oocytes co‐expressing the channel protein and the thyrotropin‐releasing hormone (TRH) receptor. 2 Addition of TRH caused clear modifications of HERG channel gating kinetics. These variations consisted of an acceleration of deactivation, as shown by a faster decay of hyperpolarization‐induced tail currents, and a slower time course of activation, measured using an envelope of tails protocol. The voltage dependence for activation was also shifted by nearly 20 mV in the depolarizing direction. Neither the inactivation nor the inactivation recovery rates were altered by TRH. 3 The alterations in activation gating parameters induced by TRH were demonstrated in a direct way by looking at the increased outward K+ currents elicited in extracellular solutions in which K+ was replaced by Cs+. 4 The effects of TRH were mimicked by direct pharmacological activation of protein kinase C (PKC) with β‐phorbol 12‐myristate, 13‐acetate (PMA). The TRH‐induced effects were antagonized by GF109203X, a highly specific inhibitor of PKC that also abolished the PMA‐dependent regulation of the channels. 5 It is concluded that a PKC‐dependent pathway links G protein‐coupled receptors that activate phospholipase C to modulation of HERG channel gating. This provides a mechanism for the physiological regulation of cardiac function by phospholipase C‐activating receptors, and for modulation of adenohypophysial neurosecretion in response to TRH.

Differential effects of amino-terminal distal and proximal domains in the regulation of human erg K(+) channel gating.

The participation of amino-terminal domains in human ether-a-go-go (eag)-related gene (HERG) K(+) channel gating was studied using deleted channel variants expressed in Xenopus oocytes. Selective deletion of the HERG-specific sequence (HERG Delta138-373) located between the conserved initial amino terminus (the eag or PAS domain) and the first transmembrane helix accelerates channel activation and shifts its voltage dependence to hyperpolarized values. However, deactivation time constants from fully activated states and channel inactivation remain almost unaltered after the deletion. The deletion effects are equally manifested in channel variants lacking inactivation. The characteristics of constructs lacking only about half of the HERG-specific domain (Delta223-373) or a short stretch of 19 residues (Delta355-373) suggest that the role of this domain is not related exclusively to its length, but also to the presence of specific sequences near the channel core. Deletion-induced effects are partially reversed by the additional elimination of the eag domain. Thus the particular combination of HERG-specific and eag domains determines two important HERG features: the slow activation essential for neuronal spike-frequency adaptation and maintenance of the cardiac action potential plateau, and the slow deactivation contributing to HERG inward rectification.

Lateral Mobility of Nicotinic Acetylcholine Receptors on Neurons Is Determined by Receptor Composition, Local Domain, and Cell Type

The lateral mobility of surface receptors can define the signaling properties of a synapse and rapidly change synaptic function. Here we use single-particle tracking with Quantum Dots to follow nicotinic acetylcholine receptors (nAChRs) on the surface of chick ciliary ganglion neurons in culture. We find that both heteropentameric α3-containing receptors (α3*-nAChRs) and homopentameric α7-containing receptors (α7-nAChRs) access synaptic domains by lateral diffusion. They have comparable mobilities and display Brownian motion in extrasynaptic space but are constrained and move more slowly in synaptic space. The two receptor types differ in the nature of their synaptic restraints. Disruption of lipid rafts, PDZ-containing scaffolds, and actin filaments each increase the mobility of α7-nAChRs in synaptic space while collapse of microtubules has no effect. The opposite is seen for α3*-nAChRs where synaptic mobility is increased only by microtubule collapse and not the other manipulations. Other differences are found for regulation of α3*-nAChR and α7-nAChR mobilities in extrasynaptic space. Most striking are effects on the immobile populations of α7-nAChRs and α3*-nAChRs. Disruption of either lipid rafts or PDZ scaffolds renders half of the immobile α3*-nAChRs mobile without changing the proportion of immobile α7-nAChRs. Similar results were obtained with chick sympathetic ganglion neurons, though regulation of receptor mobility differed in at least one respect from that seen with ciliary ganglion neurons. Control of nAChR lateral mobility, therefore, is determined by mechanisms that are domain specific, receptor subtype dependent, and cell-type constrained. The outcome is a system that could tailor nicotinic signaling capabilities to specific needs of individual locations.

Characterization of Eag1 Channel Lateral Mobility in Rat Hippocampal Cultures by Single-Particle-Tracking with Quantum Dots

Voltage-gated ion channels are main players involved in fast synaptic events. However, only slow intracellular mechanisms have so far been described for controlling their localization as real-time visualization of endogenous voltage-gated channels at high temporal and spatial resolution has not been achieved yet. Using a specific extracellular antibody and quantum dots we reveal and characterize lateral mobility as a faster mechanism to dynamically control the number of endogenous ether-a-go-go (Eag)1 ion channels inside synapses. We visualize Eag1 entering and leaving synapses by lateral diffusion in the plasma membrane of rat hippocampal neurons. Mathematical analysis of their trajectories revealed how the motion of Eag1 gets restricted when the channels diffuse into the synapse, suggesting molecular interactions between Eag1 and synaptic components. In contrast, Eag1 channels switch to Brownian movement when they exit synapses and diffuse into extrasynaptic membranes. Furthermore, we demonstrate that the mobility of Eag1 channels is specifically regulated inside synapses by actin filaments, microtubules and electrical activity. In summary, using single-particle-tracking techniques with quantum dots nanocrystals, our study shows for the first time the lateral diffusion of an endogenous voltage-gated ion channel in neurons. The location-dependent constraints imposed by cytoskeletal elements together with the regulatory role of electrical activity strongly suggest a pivotal role for the mobility of voltage-gated ion channels in synaptic activity.

A novel mechanism for nicotinic potentiation of glutamatergic synapses

Selective strengthening of specific glutamatergic synapses in the mammalian hippocampus is critical for encoding new memories. This is most commonly achieved by input-specific Hebbian-type plasticity involving glutamate-dependent coincident presynaptic and postsynaptic depolarization. Our results demonstrate a novel mechanism by which nicotinic signaling, independently of coincident fast glutamatergic transmission, increases synaptic strength in the hippocampus. Electrophysiological recordings from rat hippocampal neurons in culture revealed that 1–3 h of exposure to 1 μm nicotine, even with action potentials being blocked, produced increases in both the frequency and amplitude of miniature EPSCs. Possible mechanisms were analyzed both in mouse organotypic slice culture and in rat cell culture by inducing the cells to express super-ecliptic pHluorin-tagged GluA1-containing AMPA receptors, which fluoresce only on the cell surface. Pharmacological and genetic manipulation of the cells, in combination with fluorescence-recovery-after-photobleaching experiments, revealed that nicotine, acting through α7-containing nicotinic acetylcholine receptors on the postsynaptic neuron, induces the stabilization and accumulation of GluA1-containing AMPA receptors on dendritic spines. The process relies on intracellular calcium signaling, PDZ [postsynaptic density-95 (PSD-95)/Discs large (Dlg)/zona occludens-1 (ZO-1)] interactions with members of the PSD-95 family, and lateral diffusion of the GluA1 receptors on the cell surface. These findings define a new avenue by which nicotinic signaling modulates synaptic mechanisms thought to subserve learning and memory.

Influence of amino-terminal structures on kinetic transitions between several closed and open states in human erg K+ channels

Gating kinetics of human ether-a-go-go (eag)-related gene (HERG) K+ channel expressed in Xenopus oocytes was studied using non-inactivating channel variants carrying different structural modifications in the amino terminus. A kinetics model was elaborated to describe the behavior of full-length channels, that includes at least three open states besides the three closed states previously proposed. Deletion of the HERG-specific proximal domain (HERG D138-373) accelerated all individual forward transitions between closed states. Whereas relatively large amplitude depolarizations were required to drive full-length HERG channels to more distal open states, these were reached more easily in channels without proximal domain. Alteration of the initial eag/PAS domain by introduction of a short amino-acid sequence at the beginning of the amino terminus did not alter transitions between closed states, but prevented the channels from reaching the farthest open states that determine slower deactivation rates. This indicates that the presence of specific amino-terminal structures can be correlated with the occurrence of distinctive molecular transitions. It also demonstrates that both proximal and eag/PAS domains in the amino terminus contribute to set the gating characteristics of HERG channels.

PMCA2 via PSD-95 Controls Calcium Signaling by α7-Containing Nicotinic Acetylcholine Receptors on Aspiny Interneurons

Local control of calcium concentration within neurons is critical for signaling and regulation of synaptic communication in neural circuits. How local control can be achieved in the absence of physical compartmentalization is poorly understood. Challenging examples are provided by nicotinic acetylcholine receptors that contain α7 nicotinic receptor subunits (α7-nAChRs). These receptors are highly permeable to calcium and are concentrated on aspiny dendrites of interneurons, which lack obvious physical compartments for constraining calcium diffusion. Using functional proteomics on rat brain, we show that α7-nAChRs are associated with plasma membrane calcium-ATPase pump isoform 2 (PMCA2). Analysis of α7-nAChR function in hippocampal interneurons in culture shows that PMCA2 activity limits the duration of calcium elevations produced by the receptors. Unexpectedly, PMCA2 inhibition triggers rapid calcium-dependent loss of α7-nAChR clusters. This extreme regulatory response is mediated by CaMKII, involves proteasome activity, depends on the second intracellular loop of α7-nAChR subunits, and is specific in that it does not alter two other classes of calcium-permeable ionotropic receptors on the same neurons. A critical link is provided by the scaffold protein PSD-95 (postsynaptic density-95), which is associated with α7-nAChRs and constrains their mobility as revealed by single-particle tracking on neurons. The PSD-95 link is required for PMCA2-mediated removal of α7-nAChR clusters. This three-component combination of PMCA2, PSD-95, and α7-nAChR offers a novel mechanism for tight control of calcium dynamics in neurons.

Relevance of the proximal domain in the amino‐terminus of HERG channels for regulation by a phospholipase C‐coupled hormone receptor

We used Xenopus oocytes co‐expressing thyrotropin‐releasing hormone (TRH) receptors and human ether‐a‐go‐go‐related gene (HERG) K+ channel variants carrying different amino‐terminal modifications to check the relevance of the proximal domain for hormonal regulation of the channel. Deletion of the whole proximal domain (Δ138–373) eliminates TRH‐induced modifications in activation and deactivation parameters. TRH effects on activation are also suppressed with channels lacking the second half of the proximal domain or only residues 326–373. However, normal responses to TRH are obtained with Δ346–373 channels. Thus, whereas residues 326–345 are required for the hormonal modulation of HERG activation, different proximal domain sequences contribute to set HERG gating characteristics and its regulation by TRH.

Annexin A2 regulates TRPA1-dependent nociception.

The transient receptor potential A1 (TRPA1) channel is essential for vertebrate pain. Even though TRPA1 activation by ligands has been studied extensively, the molecular machinery regulating TRPA1 is only poorly understood. Using an unbiased proteomics-based approach we uncovered the physical association of Annexin A2 (AnxA2) with native TRPA1 in mouse sensory neurons. AnxA2 is enriched in a subpopulation of sensory neurons and coexpressed with TRPA1. Furthermore, we observe an increase of TRPA1 membrane levels in cultured sensory neurons from AnxA2-deficient mice. This is reflected by our calcium imaging experiments revealing higher responsiveness upon TRPA1 activation in AnxA2-deficient neurons. In vivo these findings are associated with enhanced nocifensive behaviors specifically in TRPA1-dependent paradigms of acute and inflammatory pain, while heat and mechanical sensitivity as well as TRPV1-mediated pain are preserved in AnxA2-deficient mice. Our results support a model whereby AnxA2 limits the availability of TRPA1 channels to regulate nociceptive signaling in vertebrates.