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A novel ion conducting route besides the central pore in an inherited mutant of G-protein-gated inwardly rectifying K+ channel

I-Shan Chen1, I-Shan Chen2, I-Shan Chen3, Jodene Eldstrom4, David Fedida4, Yoshihiro Kubo2, Yoshihiro Kubo1 
National Institutes of Natural Sciences, Japan1, Graduate University for Advanced Studies2, Wakayama Medical University3, University of British Columbia4
19 Aug 2021-bioRxiv (Cold Spring Harbor Laboratory)-
TL;DR: In this article, the authors investigated the mechanisms underlying the abnormal ion selectivity of inherited GIRK mutants and showed that the mechanism underlying the loss of K+ selectivity induced by this inherited mutation involves formation of a novel ion permeation pathway besides the selectivity filter pathway.
Abstract: G-protein-gated inwardly rectifying K+ (GIRK; Kir3.x) channels play important physiological roles in various organs. Some of the disease-associated mutations of GIRK channels are known to induce loss of K+ selectivity but their structural changes remain unclear. In this study, we investigated the mechanisms underlying the abnormal ion selectivity of inherited GIRK mutants. By the two-electrode voltage-clamp analysis of GIRK mutants heterologously expressed in Xenopus oocytes, we observed that Kir3.2 G156S permeates Li+ better than Rb+, while T154del or L173R of Kir3.2 and T158A of Kir3.4 permeate Rb+ better than Li+, suggesting a unique conformational change in the G156S mutant. Applications of blockers of the selectivity filter (SF) pathway, Ba2+ or Tertiapin-Q (TPN-Q), remarkably increased the Li+-selectivity of Kir3.2 G156S but did not alter those of the other mutants. In single-channel recordings of Kir3.2 G156S expressed in mouse fibroblasts, two types of events were observed, one attributable to a TPN-Q sensitive K+ current and the second a TPN-Q resistant Li+ current. The results show that a novel Li+ permeable and blocker-resistant pathway exists in G156S in addition to the SF pathway. Mutations in the pore helix (PH), S148F and T151A, also induced high Li+ permeation. Our results demonstrate that the mechanism underlying the loss of K+ selectivity of Kir3.2 G156S involves formation of a novel ion permeation pathway besides the SF pathway, which allows permeation of various species of cations. Significance Statement Kir3.2 G156S is a Na+-permeable inherited mutant which causes neurological disorders in mammals. The structural changes underlying the loss of K+ selectivity induced by this inherited mutation remain unknown. Here we show evidences revealing a novel mechanism underlying the abnormal ion selectivity that Kir3.2 G156S has two ion permeation pathways, the conventional SF route which permeates K+ predominantly and a novel route which permeates Li+ and Na+ preferentially. This provides us with information for the design of new effective drugs for disease treatment at the early stages, which can selectively block only the novel cation permeation pathway.

Summary (3 min read)

Jump to: [Introduction][Different disease associated mutations of GIRK channels show diverse ion selectivity][Effect of TPN-Q on the ion selectivity of Kir3.2 G156S][Activation effect of Gβγ and Ivermectin on Kir3.2 G156S][Single-channel recordings of Kir3.2 G156S show two types of ion conducting events][Discussion][Mutagenesis and cRNA preparations][Oocyte preparations][Two-electrode voltage-clamp recordings][Single-channel recordings] and [Reagents]

Introduction

  • These amino acid residues are conserved among GIRK subtypes.
  • The structural changes induced by mutations at different regions of the channel which alter the ion selectivity still remain to be elucidated.
  • No further experimental data have been provided to support these hypotheses.

Different disease associated mutations of GIRK channels show diverse ion selectivity

  • To characterize the ion selectivity changes of GIRK channels induced by inherited mutations, the authors constructed these mutants using mouse Kir3.2 or rat Kir3.4 channels .
  • In the case of GIRK channels which show strong rectification, however, the reversal potential is significantly affected by even a small leak current which hinders accurate analysis of PX / PK.
  • The information the authors present in this study to compare the ion selectivity is the profile of sequence of current amplitudes which reflects the extent of the permeation of various ions.
  • Since the homotetramers of the Kir3.4 SF mutant G151R showed very small currents from all extracellular cations, ion permeation could not be compared because of contamination from endogenous currents .
  • A previous study suggested that this may be relevant to the eliminated hydrogen bonds of Thr158 with Pro128, Cys129 and Lys160, which are conserved among GIRK subtypes (Choi et al., 2011) .

Effect of TPN-Q on the ion selectivity of Kir3.2 G156S

  • To further clarify whether a novel ion permeation pathway besides the conventional SF route does exist in Kir3.2 G156S, the authors examined the effect of another pore blocker which binds to the GIRK channel at a different position than Ba 2+ .
  • Here the authors used Tertiapin-Q (TPN-Q) known to specifically block Kir1.1 and GIRK channels by capping the SF pore from the extracellular side (Doupnik, Parra, & Guida, 2015; Patel, Kuyucak, & Doupnik, 2020) .
  • Taken together, when the SF pathway was blocked by TPN-Q, a high PLi/PK was observed presumably due to the novel ion permeation route.

Activation effect of Gβγ and Ivermectin on Kir3.2 G156S

  • Previous studies showed that heteromeric channels comprised of Kir3.2 G156S and Kir3.1 are insensitive to Gβγ-stimulation (Navarro et al., 1996) .
  • Here the authors examined whether homomeric channels of Kir3.2 G156S are also insensitive to the Gβγstimulation by coexpressing Kir3.2 G156S with the muscarinic M2 receptor (M2R).
  • Applications of 10 μM IVM induced the current increase in both the Kir3.2 WT and G156S mutant.
  • This shows that the limited response of the G156S mutant to ACh stimulation is not due to the high basal activity reaching a saturation level, since IVM can further increase the current amplitude.
  • Taken together, the G156S mutation may induce a conformational change that occurs not only in the SF region but also in the structural components which play roles in the Gβγ-coupling-channel activation linkage.

Single-channel recordings of Kir3.2 G156S show two types of ion conducting events

  • When 400 nM TPN-Q was added to the pipette solution, these events with a relatively large current amplitude were largely absent and replaced by infrequently observed events with a very small current amplitude (< 0.2 pA) .
  • Occasional amplifier resets were unavoidable during these long recordings due to the need to reset the headstage output periodically as part of the capacitive feedback system used to achieve low noise recordings .
  • 5a. Inclusion of 400 nM TPN-Q in the pipette did not apparently change the activity and the amplitude of Li + current , showing that the major events caused by Li + influx through Kir3.2 G156S were not blocked by TPN-Q .
  • These results demonstrate that two types of ion conducting events are present in the same recording of Kir3.2 G156S.
  • This supports that a novel ion permeation pathway in addition to the SF route is formed by the G156S mutation in the Kir3.2 channel.

Discussion

  • This novel ion permeation route is similar to a side entry pathway for Na + permeation through the sodium potassium (NaK) channel (Roy et al., 2021; Shi et al., 2018) .
  • The sequence of ion preference of the G156R and L173R mutants (Rb + , Cs + -preferable permeation) fits to I -IV of the Eisenman sequence, suggesting that the modified SF pathway is a weak-field-strength site type, where the site-interaction energy is less than the hydration energy (Eisenman, 1962; Hille, 2001) .
  • Further detailed analysis was not performed due to the difficulty of the precise estimation of the small current amplitudes of fast gating events.
  • In conclusion, their results reveal the presence of a novel ion permeation pathway besides the SF route in Kir3.2 G156S.
  • The design of drugs that selectively block the novel cation permeation route alone to eliminate the abnormal cation fluxes may have the potential to develop a novel treatment for Kir disorders such as for KPLBS patients with the Kir3.2 G154S mutation (corresponding to mouse G156S) at an early stage of life.

Mutagenesis and cRNA preparations

  • The authors constructed mutants of Kir3.2 and Kir3.4 and prepared their cRNA as described previously (Chen et al., 2019) .
  • By PCR using PfuUltra II Fusion HS DNA Polymerase kit (Agilent technologies, Santa Clara, CA, USA) and the primers (Supplementary Table 1 ), the authors introduced point mutations in mouse Kir3.2 (GenBank accession no.: AF040051) or rat Kir3.4 (GenBank no.: L35771) which were confirmed by DNA sequencing.
  • Their cDNA were linearized by restriction enzymes, and the complementary RNA were transcribed by the mMessage T3 or T7 mMachine Kit (Ambion, Austin, TX, USA).

Oocyte preparations

  • The authors purchased adult female Xenopus laevis from Hamamatsu Seibutsu Kyouzai (Hamamatsu, Japan).
  • Isolation of oocytes from the frogs were performed as described previously (Chen et al., 2019) .
  • After removing the follicles, each oocyte was injected with 50 nl of cRNA solution and then incubated in frog Ringer's solution with 0.1% penicillin-streptomycin (Sigma-Aldrich) at 17°C.
  • The oocytes were used for twoelectrode voltage-clamp recordings 1-5 days after the injection of cRNA.

Two-electrode voltage-clamp recordings

  • Glass electrodes for two-electrode voltage-clamp recordings had a resistance of 0.2-0.5 MΩ when filled with a pipette solution containing 3 M potassium acetate and 10 mM KCl.
  • To evaluate the ion selectivity, the KCl was replaced by LiCl, NaCl, RbCl, CsCl, methylammonium-Cl, tetramethylammonium-Cl, tetraethylammonium-Cl, or NMDG-Cl, one at a time.
  • Data were recorded by an oocyte clamp amplifier OC-725C (Warner instruments, Holliston, MA, USA), a digital converter Digidata 1440 (Molecular devices, San Jose, CA, USA), and pCLAMP 10 software (Molecular devices).
  • Compounds were applied to the extracellular solution and perfused the oocytes in a recording chamber.

Single-channel recordings

  • Cell-attached recordings were carried out using ltk-mouse fibroblast cells as previously described (Eldstrom, Wang, Werry, Wong, & Fedida, 2015; Murray et al., 2016; Westhoff, Eldstrom, Murray, Thompson, & Fedida, 2019) .
  • Briefly, cells were transfected using Lipofectamine 2000 (Invitrogen, Carlsbad, CA, USA) as per the manufactures protocol, with DNA ratios of 1:0.8 of Kir3.2 G156S:GFP in micrograms.

Reagents

  • Tertiapin-Q (TPN-Q) was purchased from Abcam (Cambridge, UK) or Bio-Techne Canada (Toronto, Canada).
  • ACh, Ivermectin (IVM), and the other reagents were purchased from Sigma-Aldrich (St. Louis, USA), unless otherwise specified.
  • TPN-Q and ACh were dissolved in distilled water, and IVM was dissolved in DMSO.
  • These reagents were diluted to a final concentration in the extracellular solution and the solvent concentration was ≤ 0.3%.

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1
A novel ion conducting route besides the central pore in an 1
inherited mutant of G-protein-gated inwardly rectifying K
+
channel 2
3
I-Shan Chen
abc
*, Jodene Eldstrom
d
, David Fedida
d
, and Yoshihiro Kubo
ab
* 4
5
a
Division of Biophysics and Neurobiology, Department of Molecular and Cellular 6
Physiology, National Institute for Physiological Sciences, National Institutes of 7
Natural Sciences, Okazaki 444-8585, Japan 8
b
Department of Physiological Sciences, School of Life Science, SOKENDAI (The 9
Graduate University for Advanced Studies), Hayama 240-0193, Japan 10
c
Department of Pharmacology, School of Medicine, Wakayama Medical University, 11
Wakayama 641-8509, Japan 12
d
Department of Anesthesiology, Pharmacology and Therapeutics, University of 13
British Columbia, Vancouver, British Columbia, V6T 1Z3, Canada 14
15
*Corresponding authors: I-Shan Chen, Yoshihiro Kubo 16
Email: chenis@wakayama-med.ac.jp; ykubo@nips.ac.jp 17
18
ORCIDs: I-S. C.: 0000-0003-3204-3921; J. E.: 0000-0002-7684-175X; 19
D. F.: 0000-0001-6797-5185; Y. K.: 0000-0001-6707-0837 20
21
Preprint: bioRxiv, DOI: https://doi.org/10.1101/2021.08.18.456735 22
23
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted September 11, 2021. ; https://doi.org/10.1101/2021.08.18.456735doi: bioRxiv preprint
2
Abstract
24
G-protein-gated inwardly rectifying K
+
(GIRK; Kir3.x) channels play important 25
physiological roles in various organs. Some of the disease-associated mutations of 26
GIRK channels are known to induce loss of K
+
selectivity but their structural changes 27
remain unclear. In this study, we investigated the mechanisms underlying the 28
abnormal ion selectivity of inherited GIRK mutants. By the two-electrode voltage-29
clamp analysis of GIRK mutants heterologously expressed in Xenopus oocytes, we 30
observed that Kir3.2 G156S permeates Li
+
better than Rb
+
, while T154del or L173R 31
of Kir3.2 and T158A of Kir3.4 permeate Rb
+
better than Li
+
, suggesting a unique 32
conformational change in the G156S mutant. Applications of blockers of the 33
selectivity filter (SF) pathway, Ba
2+
or Tertiapin-Q (TPN-Q), remarkably increased the 34
Li
+
-selectivity of Kir3.2 G156S but did not alter those of the other mutants. In single-35
channel recordings of Kir3.2 G156S expressed in mouse fibroblasts, two types of 36
events were observed, one attributable to a TPN-Q sensitive K
+
current and the 37
second a TPN-Q resistant Li
+
current. The results show that a novel Li
+
permeable 38
and blocker-resistant pathway exists in G156S in addition to the SF pathway. 39
Mutations in the pore helix (PH), S148F and T151A, also induced high Li
+
40
permeation. Our results demonstrate that the mechanism underlying the loss of K
+
41
selectivity of Kir3.2 G156S involves formation of a novel ion permeation pathway 42
besides the SF pathway, which allows permeation of various species of cations. 43
44
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted September 11, 2021. ; https://doi.org/10.1101/2021.08.18.456735doi: bioRxiv preprint
3
Introduction 45
G-protein-gated inwardly rectifying K
+
(GIRK) channels are stimulated by the 46
activation of G-protein-coupled receptors (GPCRs) to regulate heartbeat, neuronal 47
excitability and hormone secretion (Hibino et al., 2010). There are four types of GIRK 48
subunits (Kir3.1, Kir3.2, Kir3.3, and Kir3.4) which form homotetramers of Kir3.2 or 49
heterotetramers of multiple combinations in different tissues (Hibino et al., 2010; 50
Krapivinsky et al., 1995; Kubo, Reuveny, Slesinger, Jan, & Jan, 1993; Lesage et al., 51
1994), and gene mutations encoded by GIRK channels have been found to cause 52
diseases in some patients (Zangerl-Plessl, Qile, Bloothooft, Stary-Weinzinger, & van 53
der Heyden, 2019). For example, deletion of Thr152, or mutations of Gly154 to Ser or 54
Leu171 to Arg in the human Kir3.2 channel (encoded by KCNJ6), cause Keppen-55
Lubinsky syndrome (KPLBS) or KPLBS-like disorder (Horvath et al., 2018; Masotti et 56
al., 2015), and G151R, T158A or L168R mutations in the human Kir3.4 channel 57
(encoded by KCNJ5) cause aldosterone-producing adenomas (APA) (Boulkroun et 58
al., 2012; Choi et al., 2011). These amino acid residues are conserved among GIRK 59
subtypes. Some of the inherited mutations of these residues have been reported to 60
cause loss of K
+
selectivity, resulting in disorder of cell function and cell death (Choi 61
et al., 2011; Horvath et al., 2018; Navarro et al., 1996; Scholl et al., 2012; Slesinger 62
et al., 1996). 63
K
+
selectivity is achieved by a highly conserved amino acid sequence TV(I)GYG 64
which forms the selectivity filter (SF) in K
+
channels (Zagotta, 2006). Mutations in the 65
SF sequence of K
+
channels alter ion selectivity (Heginbotham, Lu, Abramson, & 66
MacKinnon, 1994). An ion pair, conserved in the Kir channel family, a glutamic acid 67
located in the pore helix (PH) and an arginine located in the extracellular loop behind 68
the SF, is known to contribute to stabilization of the pore structure and maintaining 69
ion selectivity (Yang, Yu, Jan, & Jan, 1997). Mutations of other residues in the PH, 70
such as Ser148 or Glu152 of mouse Kir3.2, also impair the K
+
selectivity (Chen et al., 71
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted September 11, 2021. ; https://doi.org/10.1101/2021.08.18.456735doi: bioRxiv preprint
4
2019; Yi, Lin, Jan, & Jan, 2001). Mutations located in transmembrane domains (TMs) 72
outside the SF also alter ion selectivity and residues located at the central cavity can 73
also influence the ion selectivity through interaction with the permeating ions (Bichet, 74
Grabe, Jan, & Jan, 2006; Bichet et al., 2004; Matamoros & Nichols, 2021; Yi et al., 75
2001). Structures of various types of K
+
channel have been identified by Cryo-EM 76
and X-ray crystallography (Long, Campbell, & Mackinnon, 2005; Miller & Long, 2012; 77
W. Wang & MacKinnon, 2017; Whorton & MacKinnon, 2011). However, the structural 78
changes induced by mutations at different regions of the channel which alter the ion 79
selectivity still remain to be elucidated. 80
Previous studies using homology modeling have predicted structural changes to 81
GIRK channels induced by disease associated mutations as follows: (A) mutations in 82
the SF (human Kir3.2 T152del or Kir3.2 G154S) impair the stabilization of K
+
83
interaction with the backbone of the SF (Masotti et al., 2015); (B) the L171R mutation 84
in the TM2 of human Kir3.2 limits the SF movement by the formation of a hydrogen 85
bond with Glu148 in the PH (Horvath et al., 2018), while the L168R mutation at the 86
corresponding position of human Kir3.4 is relevant to the interaction with the side 87
chain of Tyr of the GYG motif in the SF (Choi et al., 2011); (C) the T158A mutation in 88
the extracellular loop of human Kir3.4 weakens the stability of the structure by 89
eliminating the hydrogen bonds between the extracellular loop, PH, and TM1 (Choi et 90
al., 2011). However, no further experimental data have been provided to support 91
these hypotheses. 92
In the present study, we investigated the mechanisms underlying the abnormal ion 93
selectivity of these inherited mutations in Kir3.2 and Kir3.4 channels by introducing 94
mutations at the corresponding positions in mouse Kir3.2 or rat Kir3.4. Using 95
electrophysiological recordings in Xenopus oocytes, we demonstrate that most of 96
these mutations induce a conformational change which allows increased permeation 97
of Rb
+
or Cs
+
, while the G156S mutation of the Kir3.2 channel (corresponding to 98
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted September 11, 2021. ; https://doi.org/10.1101/2021.08.18.456735doi: bioRxiv preprint
5
human Kir3.2 G154S) induces a different conformational change which allows better 99
permeation of Li
+
or Na
+
over Rb
+
or Cs
+
. Applications of pore blockers of GIRK 100
channels increase the Li
+
-selectivity of Kir3.2 G156S but do not influence that of the 101
other mutants. Single-channel recordings of the G156S mutant in mouse fibroblasts 102
show that two types of ion conducting events, which respectively reflect K
+
current via 103
the SF pathway and Li
+
current via a novel ion permeation pathway, exist in the same 104
recording. Mutations of amino acid residues located in the PH behind the SF also 105
gave rise to the Li
+
-permeable pathway outside of the SF route. Our results reveal a 106
novel mechanism underlying the loss of K
+
-selectivity of Kir3.2 G156S that involves 107
formation of a novel ion permeation pathway in addition to the conventional SF route. 108
109
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted September 11, 2021. ; https://doi.org/10.1101/2021.08.18.456735doi: bioRxiv preprint
Citations
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Journal ArticleDOI
A selectivity filter mutation provides insights into gating regulation of a K+ channel

[...]

Theres Friesacher, Haritha P. Reddy, Harald Bernsteiner, J. Carlo Combista, Boris Shalomov, Amal Kanti Bera, Eva-Maria Zangerl-Plessl, Nathan Dascal, Anna Stary-Weinzinger 
11 Apr 2022-Communications biology
TL;DR: In this article , the effect of a selectivity filter mutation on GIRK2 structure and function was investigated and an allosteric connection between the SF and a crucial activator binding site was identified.
Abstract: Abstract G-protein coupled inwardly rectifying potassium (GIRK) channels are key players in inhibitory neurotransmission in heart and brain. We conducted molecular dynamics simulations to investigate the effect of a selectivity filter (SF) mutation, G154S, on GIRK2 structure and function. We observe mutation-induced loss of selectivity, changes in ion occupancy and altered filter geometry. Unexpectedly, we reveal aberrant SF dynamics in the mutant to be correlated with motions in the binding site of the channel activator Gβγ. This coupling is corroborated by electrophysiological experiments, revealing that GIRK2 wt activation by Gβγ reduces the affinity of Ba 2+ block. We further present a functional characterization of the human GIRK2 G154S mutant validating our computational findings. This study identifies an allosteric connection between the SF and a crucial activator binding site. This allosteric gating mechanism may also apply to other potassium channels that are modulated by accessory proteins.

2 citations

Journal ArticleDOI
CL-705G: a novel chemical Kir6.2-specific KATP channel opener

[...]

Ivan A. Gando, Manuel Becerra Flores, I-Shan Chen, Hua-Qian Yang, Tomoe Y. Nakamura, Tim Cardozo, William A. Coetzee 
20 Jun 2023-Frontiers in Pharmacology
TL;DR: In this article , the authors used 3D models of the Kir6.2/SUR homotetramers based on existing cryo-EM structures of channels in both the open and closed states to identify a potential agonist binding pocket in a functionally critical area of the channel.
Abstract: Background: KATP channels have diverse roles, including regulation of insulin secretion and blood flow, and protection against biological stress responses and are excellent therapeutic targets. Different subclasses of KATP channels exist in various tissue types due to the unique assemblies of specific pore-forming (Kir6.x) and accessory (SURx) subunits. The majority of pharmacological openers and blockers act by binding to SURx and are poorly selective against the various KATP channel subclasses. Methods and Results: We used 3D models of the Kir6.2/SUR homotetramers based on existing cryo-EM structures of channels in both the open and closed states to identify a potential agonist binding pocket in a functionally critical area of the channel. Computational docking screens of this pocket with the Chembridge Core chemical library of 492,000 drug-like compounds yielded 15 top-ranked “hits”, which were tested for activity against KATP channels using patch clamping and thallium (Tl+) flux assays with a Kir6.2/SUR2A HEK-293 stable cell line. Several of the compounds increased Tl+ fluxes. One of them (CL-705G) opened Kir6.2/SUR2A channels with a similar potency as pinacidil (EC50 of 9 µM and 11 μM, respectively). Remarkably, compound CL-705G had no or minimal effects on other Kir channels, including Kir6.1/SUR2B, Kir2.1, or Kir3.1/Kir3.4 channels, or Na+ currents of TE671 medulloblastoma cells. CL-705G activated Kir6.2Δ36 in the presence of SUR2A, but not when expressed by itself. CL-705G activated Kir6.2/SUR2A channels even after PIP2 depletion. The compound has cardioprotective effects in a cellular model of pharmacological preconditioning. It also partially rescued activity of the gating-defective Kir6.2-R301C mutant that is associated with congenital hyperinsulinism. Conclusion: CL-705G is a new Kir6.2 opener with little cross-reactivity with other channels tested, including the structurally similar Kir6.1. This, to our knowledge, is the first Kir-specific channel opener.
Posted ContentDOI
A self-inactivating invertebrate opsin with resistance to retinal depletion optically drives biased signaling toward Gβγ-dependent ion channel modulation

[...]

Hisao Tsukamoto, Yoshihiro Kubo
06 Jan 2023-bioRxiv
TL;DR: In this paper , a self-inactivating invertebrate opsin, Platynereis c-opsin1, drives biased signaling for Gβγ-dependent GIRK channel activation in a light-dependent manner.
Abstract: Animal opsins, light-sensitive G protein-coupled receptors (GPCRs), have been utilized for optogenetic tools to control G protein-dependent signaling pathways. Upon G protein activation, the Ga and Gβγ subunits drive different intracellular signaling pathways, leading to complex cellular responses. For some purposes, Ga-, Gβγ-dependent signaling needs to be separately modulated, but these responses are simultaneously evoked due to the 1:1 stoichiometry of Ga and Gβγ. Nevertheless, we show temporal activation of G protein using a self-inactivating invertebrate opsin, Platynereis c-opsin1, drives biased signaling for Gβγ-dependent GIRK channel activation in a light-dependent manner by utilizing the kinetic difference between Gβγ-dependent and Ga-dependent responses. The opsin-induced transient Gi/o activation preferably causes activation of the kinetically-fast Gβγ-dependent GIRK channels rather than slower Gi/oα-dependent adenylyl cyclase inhibition. Although similar Gβγ-biased signaling properties were observed in a selfinactivating vertebrate visual pigment, Platynereis c-opsin1 needs fewer retinal molecules to evoke cellular responses. Furthermore, the Gβγ-biased signaling properties of Platynereis c-opsinl are enhanced by genetically fused with RGS8 protein which accelerates G protein inactivation. The self-inactivating invertebrate opsin and its RGS8-fusion protein can function as optical control tools biased for Gβγ-dependent ion channel modulation.
References
More filters
Journal ArticleDOI
A novel current pathway parallel to the central pore in a mutant voltage gated potassium channel

[...]

Sylvia Prütting1, Stephan Grissmer1
University of Ulm1
03 Jun 2011-Journal of Biological Chemistry
TL;DR: It is hypothesize that the hKv1.3_V388C mutation in the P-region generated a channel with two ion-conducting pathways, one, the α-pore allowing K+ flux in the presence of K+, and the second pathway, the σ- pore, functionally similar but physically distinct from the ω-pathway.

7 citations

Journal ArticleDOI
Driving force-dependent block by internal Ba2+ on the Kir2.1 channel: Mechanistic insight into inward rectification

[...]

Chi-Pan Hsieh1, Chung-Chin Kuo2, Chiung-Wei Huang2
Memorial Hospital of South Bend1, National Taiwan University2
01 Jul 2015-Biophysical Chemistry
TL;DR: It is shown that the driving force and thus the K(+) ion flux significantly influenced the apparent affinity of the block by internal Ba(2+), and changed steeply near the equilibrium point, either in the presence or absence of the transmembrane electrical field.

6 citations

Journal ArticleDOI
Observation of σ-pore currents in mutant hKv1.2_V370C potassium channels.

[...]

Pavel Tyutyaev1, Stephan Grissmer1
University of Ulm1
20 Apr 2017-PLOS ONE
TL;DR: In this paper, the σ-pore currents were observed in the S6-S6 interface gap of the V388C channel in the HKv1.3 channel.
Abstract: Current through the σ-pore was first detected in hKv1.3_V388C channels, where the V388C mutation in hKv1.3 channels opened a new pathway (σ-pore) behind the central α-pore. Typical for this mutant channel was inward current at potentials more negative than -100 mV when the central α-pore was closed. The α-pore blockers such as TEA+ and peptide toxins (CTX, MTX) could not reduce current through the σ-pore of hKv1.3_V388C channels. This new pathway would proceed in parallel to the α-pore in the S6-S6 interface gap. To see whether this phenomenon is restricted to hKv1.3 channels we mutated hKv1.2 at the homologue position (hKv1.2_V370C). By overexpression of hKv1.2_V370C mutant channels in COS-7 cells we could show typical σ-currents. The electrophysiological properties of the σ-pore in hKv1.3_V388C and hKv1.2_V370C mutant channels were similar. The σ-pore of hKv1.2_V370C channels was most permeable to Na+ and Li+ whereas Cl- and protons did not influence current through the σ-pore. Tetraethylammonium (TEA+), charybdotoxin (CTX) and maurotoxin (MTX), known α-pore blockers, could not reduce current through the σ-pore of hKv1.2_V370C channels. Taken together we conclude that the observation of σ-pore currents is not restricted to Kv1.3 potassium channels but can also be observed in a closely related potassium channel. This finding could have implications in the treatment of different ion channel diseases linked to mutations of the respective channels in regions close to homologue position investigated by us.

3 citations

Journal ArticleDOI
Characterization of the σ-Pore in Mutant hKv1.3 Potassium Channels.

[...]

Pavel Tyutyaev, Stephan Grissmer
01 Jan 2018-Cellular Physiology and Biochemistry
TL;DR: It is concluded that the σ-pore exists in hKv1.3_V388C channel and that amino acid position 392 and 395 (Shaker position 442 and 445) line the ρ-pores in the tetrameric hKV1.
Abstract: BACKGROUND/AIMS The replacement of the amino acid valine at position 388 (Shaker position 438) in hKv1.3 channels or at the homologue position 370 in hKv1.2 channels resulted in a channel with two different ion conducting pathways: One pathway was the central, potassium-selective α-pore, that was sensitive to block by peptide toxins (CTX or KTX in the hKv1.3_V388C channel and CTX or MTX in the hKv1.2_V370C channel). The other pathway (σ-pore) was behind the central α-pore creating an inward current at potentials more negative than -100 mV, a potential range where the central α-pore was closed. In addition, current through the σ-pore could not be reduced by CTX, KTX or MTX in the hKv1.3_V388C or the hKv1.2_V370C channel, respectively. METHODS For a more detailed characterization of the σ-pore, we created a trimer consisting of three hKv1.3_V388C α-subunits linked together and characterized current through this trimeric hKv1.3_V388C channel. Additionally, we determined which amino acids line the σ-pore in the tetrameric hKv1.3_V388C channel by replacing single amino acids in the tetrameric hKv1.3_V388C mutant channel that could be involved in σ-pore formation. RESULTS Overexpression of the trimeric hKv1.3_V388C channel in COS-7 cells yielded typical σ-pore currents at potentials more negative than -100 mV similar to what was observed for the tetrameric hKv1.3_V388C channel. Electrophysiological properties of the trimeric and tetrameric channel were similar: currents could be observed at potentials more negative than -100 mV, were not carried by protons or chloride ions, and could not be reduced by peptide toxins (CTX, MTX) or TEA. The σ-pore was mostly permeable to Na+ and Li+. In addition, in our site-directed mutagenesis experiments, we created a number of new double mutant channels in the tetrameric hKv1.3_V388C background channel. Two of these tetrameric double mutant channels (hKv1.3_V388C_T392Y and hKv1.3_V388C_Y395W) did not show currents through the σ-pore. CONCLUSIONS From our experiments with the trimeric hKv1.3_V388C channel we conclude that the σ-pore exists in hKv1.3_V388C channels independently of the α-pore. From our site-directed mutagenesis experiments in the tetrameric hKv1.3_V388C channel we conclude that amino acid position 392 and 395 (Shaker position 442 and 445) line the σ-pore.

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