Ofer Wiser

FUNCTIONAL INTERACTION OF SYNTAXIN AND SNAP-25 WITH VOLTAGE-SENSITIVE L- AND N-TYPE CA2+ CHANNELS

We have used an electrophysiological assay to investigate the functional interaction of syntaxin 1A and SNAP‐25 with the class C, L‐type, and the class B, N‐type, voltage‐sensitive calcium channels. Co‐expression of syntaxin 1A with the pore‐forming subunits of the L‐ and N‐type channels in Xenopus oocytes generates a dramatic inhibition of inward currents (>60%) and modifies the rate of inactivation (tau) and steady‐state voltage dependence of inactivation. Syntaxin 1–267, which lacks the transmembrane region (TMR), and syntaxin 2 do not modify channel properties, suggesting that the syntaxin 1A interaction site resides predominantly in the TMR. Co‐expression of SNAP‐25 significantly modifies the gating properties of L‐ and N‐type channels and displays modest inhibition of current amplitude. Syntaxin 1A and SNAP‐25 combined restore the syntaxin‐inhibited N‐type inward current but not the reduced rate of inactivation. Hence, a distinct interaction of a putative syntaxin 1A‐SNAP‐25 complex with the channel is apparent, consistent with the formation of a synaptosomal SNAP receptors (SNAREs) complex. The in vivo functional reconstitution: (i) establishes the proximity of the SNAREs to calcium channels; (ii) provides new insight into a potential regulatory role for the two SNAREs in controlling calcium influx through N‐ and L‐type channels; and (iii) may suggest a pivotal role for calcium channels in the secretion process.

Oncogenic potential of TASK3 (Kcnk9) depends on K+ channel function

TASK3 gene (Kcnk9) is amplified and overexpressed in several types of human carcinomas. In this report, we demonstrate that a point mutation (G95E) within the consensus K+ filter of TASK3 not only abolished TASK3 potassium channel activity but also abrogated its oncogenic functions, including proliferation in low serum, resistance to apoptosis, and promotion of tumor growth. Furthermore, we provide evidence that TASK3G95E is a dominant-negative mutation, because coexpression of the wild-type and the mutant TASK3 resulted in inhibition of K+ current of wild-type TASK3 and its tumorigenicity in nude mice. These results establish a direct link between the potassium channel activity of TASK3 and its oncogenic functions and imply that blockers for this potassium channel may have therapeutic potential for the treatment of cancers.

G protein-activated inwardly rectifying potassium channels mediate depotentiation of long-term potentiation

Excitatory synapses in the brain undergo activity-dependent changes in the strength of synaptic transmission. Such synaptic plasticity as exemplified by long-term potentiation (LTP) is considered a cellular correlate of learning and memory. The presence of G protein-activated inwardly rectifying K+ (GIRK) channels near excitatory synapses on dendritic spines suggests their possible involvement in synaptic plasticity. However, whether activity-dependent regulation of GIRK channels affects excitatory synaptic plasticity is unknown. In a companion article we have reported activity-dependent regulation of GIRK channel density in cultured hippocampal neurons that requires activity of NMDA receptors (NMDAR) and protein phosphatase-1 (PP1) and takes place within 15 min. In this study, we performed whole-cell recordings of cultured hippocampal neurons and found that NMDAR activation increases basal GIRK current and GIRK channel activation mediated by adenosine A1 receptors, but not GABAB receptors. Given the similar involvement of NMDARs, adenosine A1 receptors, and PP1 in depotentiation of LTP caused by low-frequency stimulation that immediately follows LTP-inducing high-frequency stimulation, we wondered whether NMDAR-induced increase in GIRK channel surface density and current may contribute to the molecular mechanisms underlying this specific depotentiation. Remarkably, GIRK2 null mutation or GIRK channel blockade abolishes depotentiation of LTP, demonstrating that GIRK channels are critical for depotentiation, one form of excitatory synaptic plasticity.

Synaptotagmin restores kinetic properties of a syntaxin‐associated N‐type voltage sensitive calcium channel

© 1997 Federation of European Biochemical Societies.

The α2/δ subunit of voltage sensitive Ca2+ channels is a single transmembrane extracellular protein which is involved in regulated secretion

The membrane topology of α2/δ subunit was investigated utilizing electrophysiological functional assay and specific anti‐α2 antibodies. (a) cRNA encoding a deleted α2/δ subunit was coinjected with α1C subunit of the L‐type calcium channel into Xenopus oocytes. The truncated form, lacking the third putative TM domain (α2/δΔTMIII), failed to amplify the expressed inward currents, normally induced by α 1c coinjected with intact α2/δ subunit. Western blot analysis of α2/δΔTMIII shows the appearance of a degraded α2 protein and no expression of the full‐size two‐TM truncated‐protein. The improper processing of α2/δΔTMIII suggests that the α2/δ is a single TM domain protein and the TM region is positioned at the δ subunit. (b) External application of anti‐α2 antibodies, prepared for an epitope within the alternatively spliced and ‘intracellular’ region, inhibits depolarization induced secretion in PC12, further supporting an external location of the α2 subunit and establishing δ subunit as the only membrane anchor for the extracellular α2 subunit.

Modulation of Basal and Receptor-Induced GIRK Potassium Channel Activity and Neuronal Excitability by the Mammalian PINS Homolog LGN

G protein-activated inwardly rectifying potassium (GIRK) channels mediate slow synaptic inhibition and control neuronal excitability. It is unknown whether GIRK channels are subject to regulation by guanine dissociation inhibitor (GDI) proteins like LGN, a mammalian homolog of Drosophila Partner of Inscuteable (mPINS). Here we report that LGN increases basal GIRK current but reduces GIRK activation by metabotropic transmitter receptors coupled to Gi or Go, but not Gs. Moreover, expression of its N-terminal, TPR-containing protein interaction domains mimics the effects of LGN in mammalian cells, probably by releasing sequestered endogenous LGN. In hippocampal neurons, expression of LGN, or LGN fragments that mimic or enhance LGN activity, hyperpolarizes the resting potential due to increased basal GIRK activity and reduces excitability. Using Lenti virus for LGN RNAi to reduce endogenous LGN levels in hippocampal neurons, we further show an essential role of LGN for maintaining basal GIRK channel activity and for harnessing neuronal excitability.

The voltage-gated Ca2+ channel is the Ca2+ sensor of fast neurotransmitter release

Previously it demonstrated that in the absence of Ca2+ entry, evoked secretion occurs neither by membrane depolarization, induction of [Ca2+]i rise, nor by both combined (Ashery, U., Weiss, C., Sela, D., Spira, M. E., and Atlas, D. (1993). Receptors Channels1:217–220.). These studies designate Ca2+ entry as opposed to [Ca2+]i rise, essential for exocytosis. It led us to propose that the channel acts as the Ca2+ sensor and modulates secretion through a physical and functional contact with the synaptic proteins. This view was supported by protein–protein interactions reconstituted in the Xenopus oocytes expression system and release experiments in pancreatic cells (Barg, S., Ma, X., Elliasson, L., Galvanovskis, J., Gopel, S. O., Obermuller, S., Platzer, J., Renstrom, E., Trus, M., Atlas, D., Streissnig, G., and Rorsman, P. (2001). Biophys. J.; Wiser, O., Bennett, M. K., and Atlas, D. (1996). EMBO J.15:4100–4110; Wiser, O., Trus, M., Hernandez, A., Renström, E., Barg, S., Rorsman, P., and Atlas, D. (1999). Proc. Natl. Acad. Sci. U.S.A.96:248–253). The kinetics of Cav1.2 (Lc-type) and Cav2.2 (N-type) Ca2+ channels were modified in oocytes injected with cRNA encoding syntaxin 1A and SNAP-25. Conserved cysteines (Cys271, Cys272) within the syntaxin 1A transmembrane domain are essential. Synaptotagmin I, a vesicle-associated protein, accelerated the activation kinetics indicating Cav2.2 coupling to the vesicle. The unique modifications of Cav1.2 and Cav2.2 kinetics by syntaxin 1A, SNAP-25, and synaptotagmin combined implied excitosome formation, a primed fusion complex of the channel with synaptic proteins. The Cav1.2 cytosolic domain Lc753–893, acted as a dominant negative modulator, competitively inhibiting insulin release of channel-associated vesicles (CAV), the readily releasable pool of vesicles (RRP) in islet cells. A molecular mechanism is offered to explain fast secretion of vesicles tethered to SNAREs-associated Ca2+ channel. The tight arrangement facilitates the propagation of conformational changes induced during depolarization and Ca2+-binding at the channel, to the SNAREs to trigger secretion. The results imply a rapid Ca2+-dependent CAV (RRP) release, initiated by the binding of Ca2+ to the channel, upstream to intracellular Ca2+ sensor thus establishing the Ca2+ channel as the Ca2+ sensor of neurotransmitter release.

The transmembrane domain of syntaxin 1A negatively regulates voltage-sensitive Ca2+ channels

Syntaxin 1A has a pronounced inhibitory effect on the activation kinetics and current amplitude of voltage-gated Ca(2+) channels. This study explores the molecular basis of syntaxin interaction with N- and Lc-type Ca(2+) channels by way of functional assays of channel gating in a Xenopus oocytes expression system. A chimera of syntaxin 1A and syntaxin 2 in which the transmembrane domain of syntaxin 2 replaced the transmembrane of syntaxin 1A (Sx1-2), significantly reduced the rate of activation of N- and Lc-channels. This shows a similar effect to that demonstrated by syntaxin 1A, though the current was not inhibited. The major sequence differences at the transmembrane of the syntaxin isoforms are that the two highly conserved cysteines Cys 271 and Cys 272 in syntaxin 1A correspond to the valines Val 272 and Val 273 in syntaxin 2 transmembrane. Mutating either cysteines in Sx1-1 (syntaxin 1A) to valines, did not affect modulation of the channel while a double mutant C271/272V was unable to regulate inward current. Transfer of these two cysteines to the transmembrane of syntaxin 2 by mutating Val 272 and Val 273 to Cys 272 and Cys 273 led to channel inhibition. When cleaved by botulinum toxin, the syntaxin 1A fragments, amino acids 1-253 and 254-288, which includes the transmembrane domain, were both unable to inhibit current amplitude but retained the ability to modify the activation kinetics of the channel. A full-length syntaxin 1A and the integrity of the two cysteines within the transmembrane are crucial for coordinating Ca(2+) entry through the N- and Lc-channels. These results suggest that upon membrane depolarization, the voltage-gated N- and Lc-type Ca(2+)-channels signal the exocytotic machinery by interacting with syntaxin 1A at the transmembrane and the cytosolic domains. Cleavage with botulinum toxin disrupts the coupling of the N- and Lc-type channels with syntaxin 1A and abolishes exocytosis, supporting the hypothesis that these channels actively participate in Ca(2+) regulated secretion.

Ionic dependence of Ca2+ channel modulation by syntaxin 1A

Alteration of the kinetic properties of voltage-gated Ca2+ channels, Cav1.2 (Lc-type), Cav2.2 (N type), and Cav2.3 (R type), by syntaxin 1A (Syn1A) and synaptotagmin could modulate exocytosis. We tested how switching divalent charge carriers from Ca2+ to Sr2+ and Ba2+ affected Syn1A and synaptotagmin modulation of Ca2+-channel activation. Syn1A accelerated Cav1.2 activation if Ca2+ was the charge carrier; and by substituting for Ba2+, Syn1A slowed Cav1.2 activation. Syn1A also significantly accelerated Cav2.3 activation in Ca2+ and marginally in Ba2+. Synaptotagmin, on the other hand, increased the rate of activation of Cav2.3 and Cav2.2 in all permeating ions tested. The Syn1A-channel interaction, unlike the synaptotagmin-channel interaction, proved significantly more sensitive to the type of permeating ion. It is well established that exocytosis is affected by switching the charge carriers. Based on the present results, we suggest that the channel-Syn1A interaction could respond to the conformational changes induced within the channel during membrane depolarization and divalent ion binding. These changes could partially account for the charge specificity of synaptic transmission as well as for the fast signaling between the Ca2+ source and the fusion apparatus of channel-associated-vesicles (CAV). Furthermore, propagation of conformational changes induced by the divalent ions appear to affect the concerted interaction of the channel with the fusion/docking machinery upstream to free Ca2+ buildup and/or binding to a cytosolic Ca2+ sensor. These results raise the intriguing possibility that the channel is the Ca2+ sensor in the process of fast neurotransmitter release.

G-Protein Regulation of Channels

Publisher Summary This chapter discusses modulation of channels due to their direct interaction with G proteins and focuses on the G-protein-gated inward rectifying potassium channels Kir3 (GIRK), and the voltage-gated calcium channels. GIRK channels have low basal activity, and are activated by GPCR, due to their direct binding to the βγ subunit of the G protein. Stimulation of G-protein-coupled receptor (GPCR) facilitates GTP exchange for GDP to Gα, leading to dissociation of Gα-GTP from the Gβγ dimer and regulation of their effectors. Measurements of ions that flow through the open channel pore by electrophysiological methods enable direct determination of the activity of a single channel protein at millisecond resolution in vivo . There are numerous examples for modulation of channel activity by indirect means involving phosphorylation, second messengers, and regulators of G-protein activity such as RGS proteins.