Marcel Crest

Selective Blocking of Voltage-Gated K+ Channels Improves Experimental Autoimmune Encephalomyelitis and Inhibits T Cell Activation

Kaliotoxin (KTX), a blocker of voltage-gated potassium channels (Kv), is highly selective for Kv1.1 and Kv1.3. First, Kv1.3 is expressed by T lymphocytes. Blockers of Kv1.3 inhibit T lymphocyte activation. Second, Kv1.1 is found in paranodal regions of axons in the central nervous system. Kv blockers improve the impaired neuronal conduction of demyelinated axons in vitro and potentiate the synaptic transmission. Therefore, we investigated the therapeutic properties of KTX via its immunosuppressive and symptomatic neurological effects, using experimental autoimmune encephalomyelitis (EAE), an animal model for multiple sclerosis. The T line cells used to induce adoptive EAE were myelin basic protein (MBP)-specific, constitutively contained mRNA for Kv1.3. and expressed Kv1.3. These channels were shown to be blocked by KTX. Activation is a crucial step for MBP T cells to become encephalitogenic. The addition of KTX during Ag-T cell activation led to a great reduction in the MBP T cell proliferative response, in the production of IL-2 and TNF, and in Ca2+ influx. Furthermore, the addition of KTX during T cell activation in vitro led a decreased encephalitogenicity of MBP T cells. Moreover, KTX injected into Lewis rats impaired T cell function such as the delayed-type hypersensitivity. Lastly, the administration of this blocker of neuronal and lymphocyte channels to Lewis rats improved the symptoms of EAE. We conclude that KTX is a potent immunosuppressive agent with beneficial effects on the neurological symptoms of EAE.

Gating of the polycystin ion channel signaling complex in neurons and kidney cells

Mutations in either polycystin‐2 (PC2) or polycystin‐1 (PC1) proteins cause severe, potentially lethal, kidney disorders and multiple extrarenal (including brain) disease phenotypes. PC2, a member of the transient receptor potential channel superfamily, and PC1, an orphan membrane receptor of largely unknown function, are thought to be part of a common signaling pathway. Here, we show that in rat sympathetic neurons and kidney cells, coassembly of full‐length PC1 with PC2 forms a plasmalemmal ion channel signaling complex in which PC1 stimulation simultaneously activates PC2 ion channels and Gi/o‐proteins. PC2 activation occurs through a structural rearrangement of PC1, independent of G‐protein activation. Thus, PC1 acts as a prototypical membrane receptor that concordantly regulates PC2 channels and G‐proteins, a bimodal mechanism that may account for the multifunctional roles of polycystin proteins in fundamental cellular processes of various cell types.

Pharmacological dissection and distribution of NaN/Nav1.9, T-type Ca2+ currents, and mechanically activated cation currents in different populations of DRG neurons.

Low voltage–activated (LVA) T-type Ca2+ (ICaT) and NaN/Nav1.9 currents regulate DRG neurons by setting the threshold for the action potential. Although alterations in these channels have been implicated in a variety of pathological pain states, their roles in processing sensory information remain poorly understood. Here, we carried out a detailed characterization of LVA currents in DRG neurons by using a method for better separation of NaN/Nav1.9 and ICaT currents. NaN/Nav1.9 was inhibited by inorganic ICa blockers as follows (IC50, μM): La3+ (46) > Cd2+ (233) > Ni2+ (892) and by mibefradil, a non-dihydropyridine ICaT antagonist. Amiloride, however, a preferential Cav3.2 channel blocker, had no effects on NaN/Nav1.9 current. Using these discriminative tools, we showed that NaN/Nav1.9, Cav3.2, and amiloride- and Ni2+-resistant ICaT (AR-ICaT) contribute differentially to LVA currents in distinct sensory cell populations. NaN/Nav1.9 carried LVA currents into type-I (CI) and type-II (CII) small nociceptors and medium-Aδ–like nociceptive cells but not in low-threshold mechanoreceptors, including putative Down-hair (D-hair) and Aα/β cells. Cav3.2 predominated in CII-nociceptors and in putative D-hair cells. AR-ICaT was restricted to CII-nociceptors, putative D-hair cells, and Aα/β-like cells. These cell types distinguished by their current-signature displayed different types of mechanosensitive channels. CI- and CII-nociceptors displayed amiloride-sensitive high-threshold mechanical currents with slow or no adaptation, respectively. Putative D-hair and Aα/β-like cells had low-threshold mechanical currents, which were distinguished by their adapting kinetics and sensitivity to amiloride. Thus, subspecialized DRG cells express specific combinations of LVA and mechanosensitive channels, which are likely to play a key role in shaping responses of DRG neurons transmitting different sensory modalities.

The versatile nature of the calcium‐permeable cation channel TRPP2

TRPP2 is a member of the transient receptor potential (TRP) superfamily of cation channels, which is mutated in autosomal dominant polycystic kidney disease (ADPKD). TRPP2 is thought to function with polycystin 1—a large integral protein—as part of a multiprotein complex involved in transducing Ca2+‐dependent information. TRPP2 has been implicated in various biological functions including cell proliferation, sperm fertilization, mating behaviour, mechanosensation and asymmetric gene expression. Although its function as a Ca2+‐permeable cation channel is well established, its precise role in the plasma membrane, the endoplasmic reticulum and the cilium is controversial. Recent studies suggest that TRPP2 function is highly dependent on the subcellular compartment of expression, and is regulated by many interactions with adaptor proteins. This review summarizes the most pertinent evidence about the properties of TRPP2 channels, focusing on the compartment‐specific functions of mammalian TRPP2.

Kv3.1b Is a Novel Component of CNS Nodes

We herein demonstrate that Kv3.1b subunits are present at nodes of Ranvier in the CNS of both rats and mice. Kv3.1b colocalizes with voltage-gated Na+ channels in a subset of nodes in the spinal cord, particularly those of large myelinated axons. Kv3.1b is abundantly expressed in the gray matter of the spinal cord, but does not colocalize with Na+ channels in initial segments. In the PNS, few nodes are Kv3.1b-positive. During the development of the CNS, Kv3.1b clustering at nodes occurs later than that of Na+ channels, but precedes the juxtaparanodal clustering of Kv1.2. Moreover, in myelin-deficient rats, which have severe CNS dysmyelination, node-like clusters of Kv3.1b and Na+ channels are observed even in regions devoid of oligodendrocytes. Ankyrin G coimmunoprecipitates Kv3.1b in vivo, indicating that these two proteins may interact in the CNS at nodes. 4-Aminopyridine, a K+ channel blocker, broadened the compound action potential recorded from adult rat optic nerve and spinal cord, but not from the sciatic nerve. These effects were also observed in Kv3.1-deficient mice. In conclusion, Kv3.1b is the first K+ channel subunit to be identified in CNS nodes; but Kv3.1b does not account for the effects of 4-aminopyridine on central myelinated tracts.

Maurotoxin, a four disulfide bridge toxin from Scorpio maurus venom: purification, structure and action on potassium channels.

A new toxin acting on K+ channels, maurotoxin (MTX), has been purified to homogeneity from the venom of the chactoid scorpion Scorpio maurus. MTX is a basic single chain 34 amino acid residue polypeptide, amidated at its C terminal, and crosslinked by four disulfide bridges. It shows 29–68% sequence identity with other K+ channel toxins, and presents an original disulfide pattern, the last two half‐cystine residues (31–34) being connected. Although the first three disulfide bonds have not been defined experimentally, modelling based on the structure of charybdotoxin favored two combinations out of six, one of which has two bridges (3–24 and 9–29) in common with the general motif of scorpion toxins. The last bridge would connect residues 13 and 19. MTX inhibits the binding to rat brain synaptosomal membranes of both [125I]apamin, a SKCa channel blocker (IC50 5 nM), and [125I]kaliotoxin, a Kv channel blocker (IC50 30 pM). MTX blocks the Kv1.1, Kv1.2 and Kv1.3 currents expressed in Xenopus oocytes with IC50 of 45, 0.8 and 180 nM, respectively. MTX represents a member of a new class of short toxins with 4 disulfide bridges, active on voltage‐dependent K+ channel and also competing with apamin for binding to its receptor.

Functional organization of PLC signaling microdomains in neurons

Our understanding of receptor transduction systems has grown impressively in recent years as a result of intense efforts to characterize signaling molecules and cascades in neurons. A large body of evidence has recently accrued regarding the fast and effective signal transfer that occurs during phosphoinositide signaling. In particular, dissection of the Drosophila phototransduction pathway has enabled a greater understanding of the molecular organization of phospholipase C (PLC) signaling. Supramolecular complexes organize the correct repertoires of receptors, enzymes and ion channels into individual signaling pathways. Such mechanisms involve localization of signaling molecules to sites of action by scaffold and anchoring proteins, ensuring speed and specificity of signal transduction events. However, not all PLC signals nucleate around scaffold proteins, although mechanisms for selectivity and discrimination remain. This article reviews recent advances on the molecular organization and functional consequences of PLC signaling domains, which link membrane receptors to ion channels, including TRP and KCNQ channels.

Colocalization of active KCa channels and Ca2+ channels within Ca2+ Domains in helix neurons

Large conductance Ca(2+)-activated K+ channels (KCa channels) have to be colocalized with Ca2+ channels to be involved in nerve cell firing regulation. KCa channels were detected in cell-attached patches performed in voltage-clamped Helix neurons. This technique allowed Ca2+ entry to occur either within or around the patch. We observed that the submembrane Ca2+ diffusion was sufficiently limited to prevent the KCa channels from being opened by remote Ca2+ entry. The KCa channels located in areas devoid of Ca2+ channels remained quiescent during cell firing. These crypto channels were detected following either patch excision or intracellular Ca2+ injection. These data provide direct evidence for the existence of functional Ca2+ domains in a nonspecialized neural membrane.

Large conductance Ca(2+)-activated K+ channels are involved in both spike shaping and firing regulation in Helix neurones.

1. The role of BK‐type calcium‐dependent K+ channels (K+Ca) in cell firing regulation was evaluated by performing whole‐cell voltage clamp and patch clamp experiments on the U cell neurones in the snail Helix pomatia. These cells were selected because most of the repolarizing K+ current flowed through K+Ca channels. 2. U cells generated overshooting Ca(2+)‐dependent spikes in Na(+)‐free saline. In response to prolonged depolarizing current, they fired a limited number of spikes of decreasing amplitude, and behaved like fast‐adapting or phasic neurones. 3. Under voltage clamp conditions, the K+Ca current had a slow onset at voltages that induced small Ca2+ entries. By manipulating the Ca2+ entry (either with appropriate voltage programmes or by changing the Ca2+ content of the bath), the K+Ca channel opening was found to be rate limited by the Ca2+ binding step and not by the voltage‐dependent conformational change to the open state. 4. Despite the slow activation rate observed in voltage‐clamped cells, 25‐30% of the available K+Ca current was found to be active during isolated spikes. These data were based on patch clamp, spike‐like voltage clamp and hybrid current clamp‐voltage clamp experiments. 5. The fact that spikes led the slowly rising K+Ca current to shift into a fast activating mode was accounted for by the large surge of Ca2+ current concomitant with spike upstroke. The early calcium surge resulted in local increases in cytosolic calcium, which speeded up the binding of calcium ions to the closed K+Ca channels. From changes in the null Ca2+ current voltage, it was calculated that the submembrane [Ca2+]i increase to 50‐80 microM during the spike. 6. Due to their fast voltage dependence, K+Ca channels appeared to play no role in shaping the interspike trajectory. 7. Even in the fast activating mode, the K+Ca current had a finite rate of rise and was not involved in repolarizing short duration Na(+‐dependent action potentials. The current became more and more active, however, when voltage‐gated K+ channels were progressively inactivated during firing. 8. The fast adaptation exhibited by U cells upon sustained depolarization was not paralleled by a recruitment of K+Ca channels because of the cumulative Ca2+ entries. During a spike burst, the K+Ca current progressively overlapped the depolarizing Ca2+ current, which ultimately stopped the firing. The early opening of K+Ca channels was ascribed to residual Ca2+ accumulation that kept part of the channels in the Ca(2+)‐bound state ready to be opened quickly by cell depolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Expression and localization of the Nav1.9 sodium channel in enteric neurons and in trigeminal sensory endings: implication for intestinal reflex function and orofacial pain.

The Nav1.9 sodium channel is expressed in nociceptive DRG neurons where it contributes to spontaneous pain behavior after peripheral inflammation. Here, we used a newly developed antibody to investigate the distribution of Nav1.9 in rat and mouse trigeminal ganglion (TG) nerve endings and in enteric nervous system (ENS). In TGs, Nav1.9 was expressed in the soma of small- and medium-sized, peripherin-positive neurons. Nav1.9 was present along trigeminal afferent fibers and at terminals in lip skin and dental pulp. In the ENS, Nav1.9 was detected within the soma and proximal axons of sensory, Dogiel type II, myenteric and submucosal neurons. Immunological data were correlated with the detection of persistent TTX-resistant Na(+) currents sharing similar properties in DRG, TG and myenteric neurons. Collectively, our data support a potential role of Nav1.9 in the transmission of trigeminal pain and the regulation of intestinal reflexes. Nav1.9 might therefore constitute a molecular target for therapeutic treatments of orofacial pain and gastrointestinal syndromes.