scholarly journals A Xenopus oocyte model system to study action potentials

2018 ◽  
Vol 150 (11) ◽  
pp. 1583-1593 ◽  
Author(s):  
Aaron Corbin-Leftwich ◽  
Hannah E. Small ◽  
Helen H. Robinson ◽  
Carlos A. Villalba-Galea ◽  
Linda M. Boland
Keyword(s):  
Action Potentials ◽  
Subcellular Location ◽  
Model System ◽  
K Channel ◽  
Functional Coupling ◽  
Xenopus Laevis Oocytes ◽  
Excitable Cells ◽  
Voltage Gated ◽  
Channel Expression ◽  
Electrical Signaling

Action potentials (APs) are the functional units of fast electrical signaling in excitable cells. The upstroke and downstroke of an AP is generated by the competing and asynchronous action of Na+- and K+-selective voltage-gated conductances. Although a mixture of voltage-gated channels has been long recognized to contribute to the generation and temporal characteristics of the AP, understanding how each of these proteins function and are regulated during electrical signaling remains the subject of intense research. AP properties vary among different cellular types because of the expression diversity, subcellular location, and modulation of ion channels. These complexities, in addition to the functional coupling of these proteins by membrane potential, make it challenging to understand the roles of different channels in initiating and “temporally shaping” the AP. Here, to address this problem, we focus our efforts on finding conditions that allow reliable AP recordings from Xenopus laevis oocytes coexpressing Na+ and K+ channels. As a proof of principle, we show how the expression of a variety of K+ channel subtypes can modulate excitability in this minimal model system. This approach raises the prospect of studies on the modulation of APs by pharmacological or biological means with a controlled background of Na+ and K+ channel expression.

scholarly journals Action potentials in Xenopus oocytes triggered by blue light

2020 ◽  
Vol 152 (5) ◽  
Author(s):  
Florian Walther ◽  
Dominic Feind ◽  
Christian vom Dahl ◽  
Christoph Emanuel Müller ◽  
Taulant Kukaj ◽  
...  
Keyword(s):  
Membrane Potential ◽  
Action Potential ◽  
Blue Light ◽  
Action Potentials ◽  
Xenopus Oocytes ◽  
Na Channel ◽  
Xenopus Laevis Oocytes ◽  
Na Channels ◽  
Excitable Cells ◽  
Voltage Gated

Voltage-gated sodium (Na+) channels are responsible for the fast upstroke of the action potential of excitable cells. The different α subunits of Na+ channels respond to brief membrane depolarizations above a threshold level by undergoing conformational changes that result in the opening of the pore and a subsequent inward flux of Na+. Physiologically, these initial membrane depolarizations are caused by other ion channels that are activated by a variety of stimuli such as mechanical stretch, temperature changes, and various ligands. In the present study, we developed an optogenetic approach to activate Na+ channels and elicit action potentials in Xenopus laevis oocytes. All recordings were performed by the two-microelectrode technique. We first coupled channelrhodopsin-2 (ChR2), a light-sensitive ion channel of the green alga Chlamydomonas reinhardtii, to the auxiliary β1 subunit of voltage-gated Na+ channels. The resulting fusion construct, β1-ChR2, retained the ability to modulate Na+ channel kinetics and generate photosensitive inward currents. Stimulation of Xenopus oocytes coexpressing the skeletal muscle Na+ channel Nav1.4 and β1-ChR2 with 25-ms lasting blue-light pulses resulted in rapid alterations of the membrane potential strongly resembling typical action potentials of excitable cells. Blocking Nav1.4 with tetrodotoxin prevented the fast upstroke and the reversal of the membrane potential. Coexpression of the voltage-gated K+ channel Kv2.1 facilitated action potential repolarization considerably. Light-induced action potentials were also obtained by coexpressing β1-ChR2 with either the neuronal Na+ channel Nav1.2 or the cardiac-specific isoform Nav1.5. Potential applications of this novel optogenetic tool are discussed.

scholarly journals Tuning voltage-gated channel activity and cellular excitability with a sphingomyelinase

2013 ◽  
Vol 142 (4) ◽  
pp. 367-380 ◽  
Author(s):  
David J. Combs ◽  
Hyeon-Gyu Shin ◽  
Yanping Xu ◽  
Yajamana Ramu ◽  
Zhe Lu
Keyword(s):  
Membrane Potential ◽  
Mammalian Cells ◽  
Resting Membrane Potential ◽  
Xenopus Laevis Oocytes ◽  
Channel Activity ◽  
Excitable Cells ◽  
Voltage Sensors ◽  
Voltage Gated ◽  
Activated State ◽  
Gated Channel

Voltage-gated ion channels generate action potentials in excitable cells and help set the resting membrane potential in nonexcitable cells like lymphocytes. It has been difficult to investigate what kinds of phospholipids interact with these membrane proteins in their native environments and what functional impacts such interactions create. This problem might be circumvented if we could modify specific lipid types in situ. Using certain voltage-gated K+ (KV) channels heterologously expressed in Xenopus laevis oocytes as a model, our group has shown previously that sphingomyelinase (SMase) D may serve this purpose. SMase D is known to remove the choline group from sphingomyelin, a phospholipid primarily present in the outer leaflet of plasma membranes. This SMase D action lowers the energy required for voltage sensors of a KV channel to enter the activated state, causing a hyperpolarizing shift of the Q-V and G-V curves and thus activating them at more hyperpolarized potentials. Here, we find that this SMase D effect vanishes after removing most of the voltage-sensor paddle sequence, a finding supporting the notion that SMase D modification of sphingomyelin molecules alters these lipids’ interactions with voltage sensors. Then, using SMase D to probe lipid–channel interactions, we find that SMase D not only similarly stimulates voltage-gated Na+ (NaV) and Ca2+ channels but also markedly slows NaV channel inactivation. However, the latter effect is not observed in tested mammalian cells, an observation highlighting the profound impact of the membrane environment on channel function. Finally, we directly demonstrate that SMase D stimulates both native KV1.3 in nonexcitable human T lymphocytes at their typical resting membrane potential and native NaV channels in excitable cells, such that it shifts the action potential threshold in the hyperpolarized direction. These proof-of-concept studies illustrate that the voltage-gated channel activity in both excitable and nonexcitable cells can be tuned by enzymatically modifying lipid head groups.

scholarly journals Studies of Conorfamide-Sr3 on Human Voltage-Gated Kv1 Potassium Channel Subtypes

Marine Drugs ◽  
2020 ◽  
Vol 18 (8) ◽  
pp. 425
Author(s):  
Estuardo López-Vera ◽  
Luis Martínez-Hernández ◽  
Manuel B. Aguilar ◽  
Elisa Carrillo ◽  
Joanna Gajewiak
Keyword(s):  
Action Potentials ◽  
Inhibitory Concentration ◽  
Molecular Probe ◽  
K Channel ◽  
Dependent Effect ◽  
K Channels ◽  
Voltage Gated ◽  
Pancreatic Cells ◽  
Genes Encoding ◽  
Voltage Gated Ion Channels

Recently, Conorfamide-Sr3 (CNF-Sr3) was isolated from the venom of Conus spurius and was demonstrated to have an inhibitory concentration-dependent effect on the Shaker K+ channel. The voltage-gated potassium channels play critical functions on cellular signaling, from the regeneration of action potentials in neurons to the regulation of insulin secretion in pancreatic cells, among others. In mammals, there are at least 40 genes encoding voltage-gated K+ channels and the process of expression of some of them may include alternative splicing. Given the enormous variety of these channels and the proven use of conotoxins as tools to distinguish different ligand- and voltage-gated ion channels, in this work, we explored the possible effect of CNF-Sr3 on four human voltage-gated K+ channel subtypes homologous to the Shaker channel. CNF-Sr3 showed a 10 times higher affinity for the Kv1.6 subtype with respect to Kv1.3 (IC50 = 2.7 and 24 μM, respectively) and no significant effect on Kv1.4 and Kv1.5 at 10 µM. Thus, CNF-Sr3 might become a novel molecular probe to study diverse aspects of human Kv1.3 and Kv1.6 channels.

scholarly journals Impaired voltage-gated K+channel expression in brain during experimental cancer cachexia

FEBS Letters ◽  
2003 ◽  
Vol 536 (1-3) ◽  
pp. 45-50 ◽  
Author(s):  
Mireia Coma ◽  
Rubén Vicente ◽  
Silvia Busquets ◽  
Neus Carbó ◽  
Michael M Tamkun ◽  
...  
Keyword(s):  
Cancer Cachexia ◽  
K Channel ◽  
Voltage Gated ◽  
Experimental Cancer ◽  
Channel Expression

scholarly journals Shaker-related voltage-gated K+channel expression and vasomotor function in human coronary resistance arteries

2018 ◽  
Vol 25 (1) ◽  
pp. e12431 ◽  
Author(s):  
Yoshinori Nishijima ◽  
Ankush Korishettar ◽  
Dawid S. Chabowski ◽  
Sheng Cao ◽  
Xiaodong Zheng ◽  
...  
Keyword(s):  
K Channel ◽  
Coronary Resistance ◽  
Resistance Arteries ◽  
Voltage Gated ◽  
Vasomotor Function ◽  
Channel Expression

scholarly journals Coupling between Voltage Sensors and Activation Gate in Voltage-gated K+ Channels

2002 ◽  
Vol 120 (5) ◽  
pp. 663-676 ◽  
Author(s):  
Zhe Lu ◽  
Angela M. Klem ◽  
Yajamana Ramu
Keyword(s):  
Electrical Signal ◽  
K Channel ◽  
Coupling Mechanism ◽  
Excitable Cells ◽  
Voltage Sensing ◽  
K Channels ◽  
Voltage Sensors ◽  
Voltage Gated ◽  
Transmembrane Segments ◽  
Activation Gate

Current through voltage-gated K+ channels underlies the action potential encoding the electrical signal in excitable cells. The four subunits of a voltage-gated K+ channel each have six transmembrane segments (S1–S6), whereas some other K+ channels, such as eukaryotic inward rectifier K+ channels and the prokaryotic KcsA channel, have only two transmembrane segments (M1 and M2). A voltage-gated K+ channel is formed by an ion-pore module (S5–S6, equivalent to M1–M2) and the surrounding voltage-sensing modules. The S4 segments are the primary voltage sensors while the intracellular activation gate is located near the COOH-terminal end of S6, although the coupling mechanism between them remains unknown. In the present study, we found that two short, complementary sequences in voltage-gated K+ channels are essential for coupling the voltage sensors to the intracellular activation gate. One sequence is the so called S4–S5 linker distal to the voltage-sensing S4, while the other is around the COOH-terminal end of S6, a region containing the actual gate-forming residues.

scholarly journals Functions of Presynaptic Voltage-gated Calcium Channels

Function ◽  
2020 ◽  
Vol 2 (1) ◽  
Author(s):  
Annette C Dolphin
Keyword(s):  
Calcium Channels ◽  
Neurotransmitter Release ◽  
Action Potentials ◽  
Voltage Dependence ◽  
Kinetic Properties ◽  
Excitable Cells ◽  
Single Action ◽  
Voltage Gated ◽  
Voltage Gated Calcium Channels ◽  
Vesicular Release

Abstract Voltage-gated calcium channels are the principal conduits for depolarization-mediated Ca2+ entry into excitable cells. In this review, the biophysical properties of the relevant members of this family of channels, those that are present in presynaptic terminals, will be discussed in relation to their function in mediating neurotransmitter release. Voltage-gated calcium channels have properties that ensure they are specialized for particular roles, for example, differences in their activation voltage threshold, their various kinetic properties, and their voltage-dependence of inactivation. All these attributes play into the ability of the various voltage-gated calcium channels to participate in different patterns of presynaptic vesicular release. These include synaptic transmission resulting from single action potentials, and longer-term changes mediated by bursts or trains of action potentials, as well as release resulting from graded changes in membrane potential in specialized sensory synapses.

scholarly journals Intrinsic Gating Behavior of Voltage-Gated Sodium Channels Predetermines Regulation by Auxiliary β-subunits

2021 ◽  
Author(s):  
Niklas Brake ◽  
Adamo S Mancino ◽  
Yuhao Yan ◽  
Takushi Shimomura ◽  
Heika Silveira ◽  
...  
Keyword(s):  
Excitable Cells ◽  
Voltage Sensing ◽  
Auxiliary Subunits ◽  
Voltage Gated ◽  
Closed State ◽  
Channel Function ◽  
Voltage Gated Sodium Channels ◽  
Nav Channels ◽  
Regulatory Effects ◽  
Electrical Signaling

AbstractVoltage-gated sodium (Nav) channels mediate rapid millisecond electrical signaling in excitable cells. Auxiliary subunits, β1-β4, are thought to regulate Nav channel function through covalent and/or polar interactions with the channel’ s voltage-sensing domains. How these interactions translate into the diverse and variable regulatory effects of β-subunits remains unclear. Here, we find that the intrinsic movement order of the voltage-sensing domains during channel gating is unexpectedly variable across Nav channel isoforms. This movement order dictates the channel’ s propensity for closed-state inactivation, which in turn modulates the actions of β1 and β3. We show that the differential regulation of skeletal muscle, cardiac, and neuronal Nav channels is explained by their variable levels of closed-state inactivation. Together, this study provides a unified mechanism for the regulation of all Nav channel isoforms by β1 and β3, which explains how the fixed structural interactions of auxiliary subunits can paradoxically exert variable effects on channel function.

scholarly journals Structural basis of ion permeation gating in Slo2.1 K+ channels

2013 ◽  
Vol 142 (5) ◽  
pp. 523-542 ◽  
Author(s):  
Priyanka Garg ◽  
Alison Gardner ◽  
Vivek Garg ◽  
Michael C. Sanguinetti
Keyword(s):  
Selectivity Filter ◽  
Structural Basis ◽  
K Channel ◽  
Xenopus Laevis Oocytes ◽  
Ion Permeation ◽  
Channel Activation ◽  
K Channels ◽  
Voltage Gated ◽  
Channel Function ◽  
Activation Gate

The activation gate of ion channels controls the transmembrane flux of permeant ions. In voltage-gated K+ channels, the aperture formed by the S6 bundle crossing can widen to open or narrow to close the ion permeation pathway, whereas the selectivity filter gates ion flux in cyclic-nucleotide gated (CNG) and Slo1 channels. Here we explore the structural basis of the activation gate for Slo2.1, a weakly voltage-dependent K+ channel that is activated by intracellular Na+ and Cl−. Slo2.1 channels were heterologously expressed in Xenopus laevis oocytes and activated by elevated [NaCl]i or extracellular application of niflumic acid. In contrast to other voltage-gated channels, Slo2.1 was blocked by verapamil in an activation-independent manner, implying that the S6 bundle crossing does not gate the access of verapamil to its central cavity binding site. The structural basis of Slo2.1 activation was probed by Ala scanning mutagenesis of the S6 segment and by mutation of selected residues in the pore helix and S5 segment. Mutation to Ala of three S6 residues caused reduced trafficking of channels to the cell surface and partial (K256A, I263A, Q273A) or complete loss (E275A) of channel function. P271A Slo2.1 channels trafficked normally, but were nonfunctional. Further mutagenesis and intragenic rescue by second site mutations suggest that Pro271 and Glu275 maintain the inner pore in an open configuration by preventing formation of a tight S6 bundle crossing. Mutation of several residues in S6 and S5 predicted by homology modeling to contact residues in the pore helix induced a gain of channel function. Substitution of the pore helix residue Phe240 with polar residues induced constitutive channel activation. Together these findings suggest that (1) the selectivity filter and not the bundle crossing gates ion permeation and (2) dynamic coupling between the pore helix and the S5 and S6 segments mediates Slo2.1 channel activation.

KCNA10: a novel ion channel functionally related to both voltage-gated potassium and CNG cation channels

2000 ◽  
Vol 278 (6) ◽  
pp. F1013-F1021 ◽  
Author(s):  
Rainer Lang ◽  
George Lee ◽  
Weimin Liu ◽  
Shulan Tian ◽  
Hamid Rafi ◽  
...  
Keyword(s):  
Single Channel ◽  
Reversal Potential ◽  
Amino Acid Identity ◽  
Cation Channels ◽  
K Channel ◽  
Xenopus Laevis Oocytes ◽  
Selectivity Ratio ◽  
Channel Blockers ◽  
Voltage Gated ◽  
Single Channel Currents

Our laboratory previously cloned a novel rabbit gene ( Kcn1), expressed in kidney, heart, and aorta, and predicted to encode a protein with 58% amino acid identity with the K channel Shaker Kv1.3 (Yao X et al. Proc Natl Acad Sci USA 92: 11711–11715, 1995). Because Kcn1 did not express well (peak current in Xenopus laevis oocytes of 0.3 μA at +60 mV), the human homolog (KCNA10) was isolated, and its expression was optimized in oocytes. KCNA10 mediates voltage-gated K+currents that exhibit minimal steady-state inactivation. Ensemble currents of 5–10 μA at +40 mV were consistently recorded from injected oocytes. Channels are closed at the holding potential of −80 mV but are progressively activated by depolarizations more positive than −30 mV, with half-activation at +3.5 ± 2.5 mV. The channel displays an unusual inhibitor profile because, in addition to being blocked by classical K channel blockers (barium tetraethylammonium and 4-aminopyridine), it is also sensitive to inhibitors of cyclic nucleotide-gated (CNG) cation channels (verapamil and pimozide). Tail-current analysis shows a reversal potential shift of 47 mV/decade change in K concentration, indicating a K-to-Na selectivity ratio of at least 15:1. The phorbol ester phorbol 12-myristate 13-acetate, an activator of protein kinase C, inhibited whole cell current by 42%. Analysis of single-channel currents reveals a conductance of ∼11 pS. We conclude KCNA10 is a novel human voltage-gated K channel with features common to both K-selective and CNG cation channels. Given its distribution in renal blood vessels and heart, we speculate that KCNA10 may be involved in regulating the tone of renal vascular smooth muscle and may also participate in the cardiac action potential.

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