Your search keyword '"Shizhen Wang"' showing total 5 results

1. Conformational changes at cytoplasmic intersubunit interactions control Kir channel gating.

Author

Shizhen Wang, Borschel, William F., Heyman, Sarah, Hsu, Phillip, and Nichols, Colin G.

Subjects

*POTASSIUM channels, *PROTEIN-protein interactions, *CONFORMATIONAL analysis, *MEMBRANE proteins, *BIOLOGICAL interfaces

Abstract

The defining structural feature of inward-rectifier potassium (Kir) channels is the unique Kir cytoplasmic domain. Recently we showed that salt bridges located at the cytoplasmic domain subunit interfaces (CD-Is) of eukaryotic Kir channels control channel gating via stability of a novel inactivated closed state. The cytoplasmic domains of prokaryotic and eukaryotic Kir channels show similar conformational rearrangements to the common gating ligand, phosphatidylinositol bisphosphate (PIP2), although these exhibit opposite coupling to opening and closing transitions. In Kir2.1, mutation of one of these CD-I salt bridge residues (R204A) reduces apparent PIP2 sensitivity of channel activity, and here we show that Ala or Cys substitutions of the functionally equivalent residue (Arg-165) in the prokaryotic Kir channel KirBac1.1 also significantly decrease sensitivity of the channel to PIP2 (by 5-30-fold). To further understand the structural basis of CD-I control of Kir channel gating, we examined the effect of the R165A mutation on PIP2-induced changes in channel function and conformation. Single-channel analyses indicated that the R165A mutation disrupts the characteristic long interburst closed state of reconstituted KirBac1.1 in giant liposomes, resulting in a higher open probability due to more frequent opening bursts. Intramolecular FRET measurements indicate that, relative to wild-type channels, the R165A mutation results in splaying of the cytoplasmic domains away from the central axis and that PIP2 essentially induces opposite motions of the major β-sheet in this channel mutant. We conclude that the removal of stabilizing CD-I salt bridges results in a collapsed state of the Kir domain. [ABSTRACT FROM AUTHOR]

Published

2017

2. Domain Organization of the ATP-sensitive Potassium Channel Complex Examined by Fluorescence Resonance Energy Transfer.

Author

Shizhen Wang, Makhina, Elena N., Masia, Ricard, Hyrc, Krzysztof L., Formanack, Mary Lynn, and Nichols, Colin G.

Subjects

*ADENOSINE triphosphate, *POTASSIUM channels regulation, *FLUORESCENCE resonance energy transfer, *REGULATION of cell metabolism, *TETRAMERS (Oligomers), *TRYPSIN

Abstract

KATP channels link cell metabolism to excitability in many cells. They are formed as tetramers of Kir6.2 subunits, each associated with a SUR1 subunit. We used mutant GFP-based FRET to assess domain organization in channel complexes. Fulllength Kir6.2 subunits were linked to YFP or cyan fluorescent protein (CFP) at N or C termini, and all such constructs, including double-tagged YFP-Kir6.2-CFP (Y6.2C), formed functional KATP channels. In intact COSm6 cells, background emission of YFP excited by 430-nm light was ~ 6%, but the Y6.2C construct expressed alone exhibited an apparent FRET efficiency of ~ 25%, confirmed by trypsin digestion, with or without SUR1 co-expression. Similar FRET efficiency was detected in mixtures of CFP- and YFP-tagged full-length Kir6.2 subunits and transmembrane domain only constructs, when tagged at the C termini but not at the N termini. The FRET-reported Kir6.2 tetramer domain organization was qualitatively consistent with Kir channel crystal structures: C termini and M2 domains are centrally located relative to N termini and M1 domains, respectively. Additional FRET analyses were performed on cells in which tagged full-length Kir6.2 and tagged SUR1 constructs were co-expressed. These analyses further revealed that 1) NBD1 of SUR1 is closer to theCterminus of Kir6.2 than to theN terminus; 2) the Kir6.2 cytoplasmic domain is not essential for complexation with SUR1; and 3) the N-terminal half of SUR1 can complex with itself in the absence of either the C-terminal half or Kir6.2. [ABSTRACT FROM AUTHOR]

Published

2013

3. Differential Roles of Blocking Ions in KirBac1.1 Tetramer Stability.

Author

Shizhen Wang, Alimi, Yewande, Tong, Ailing, Nichols, Colin G., and Enkvetchakul, Decha

Subjects

*POTASSIUM channels, *TETRAMERS (Oligomers), *MONOMERS, *GENETIC mutation, *ACTIVE biological transport

Abstract

Potassium channels are tetrameric proteins that mediate K[sup+]-selective transmembrane diffusion. For KcsA, tetramer stability depends on interactions between permeant ions and the channel pore. We have examined the role of pore blockers on the tetramer stability of KirBac1.1. In 150 mM KCl, purified Kir- Bac1.1 protein migrates as a monomer (∼40 kDa) on SDSPAGE. Addition of Ba[sup2+] (K[sub1/2] ∼ 50 μM) prior to loading results in an additional tetramer band (∼160 kDa). Mutation A109C, at a residue located near the expected Ba[sup2+]-binding site, decreased tetramer stabilization by Ba[sup2+] (K[sub1/2] ∼ 300 μM), whereas I131C, located nearby, stabilized tetramers in the absence of Ba[sup2+]. Neither mutation affected Ba[sup2+] block of channel activity (using [sup86]Rb[sup+] flux assay). In contrast to Ba[sup2+], Mg[sup2+] had no effect on tetramer stability (even though Mg[sup2+] was a potent blocker). Many studies have shown Cd[sup2+] block of [sup2+] channels as a result of cysteine substitution of cavity-lining M2 (S6) residues, with the implicit interpretation that coordination of a single ion by cysteine side chains along the central axis effectively blocks the pore. We examined blocking and tetramer-stabilizing effects of Cd[sup2+] on KirBac1.1 with cysteine substitutions in M2. Cd[sup2+] block potency followed an α-helical pattern consistent with the crystal structure. Significantly, Cd[sup2+] strongly stabilized tetramers of I138C, located in the center of the inner cavity. This stabilization was additive with the effect of Ba[sup2+], consistent with both ions simultaneously occupying the channel: Ba[sup2+] at the selectivity filter entrance and Cd[sup2+] coordinated by I138C side chains in the inner cavity. [ABSTRACT FROM AUTHOR]

Published

2009

4. Arachidonic acid reverses cholesterol and zinc inhibition of human voltage-gated proton channels.

Author

Shuo Han, Applewhite, Sarah, DeCata, Jenna, Jones, Samuel, Cummings, John, and Shizhen Wang

Subjects

*VOLTAGE-gated ion channels, *ARACHIDONIC acid, *CHOLESTEROL, *PHOSPHOLIPASE A2, *PROTONS, *ION channels

Abstract

Unlike other members of the voltage-gated ion channel superfamily, voltage-gated proton (Hv) channels are solely composed of voltage sensor domains without separate ionconducting pores. Due to their unique dependence on both voltage and transmembrane pH gradients, Hv channels normally open to mediate proton efflux. Multiple cellular ligands were also found to regulate the function of Hv channels, including Zn2+, cholesterol, polyunsaturated arachidonic acid, and albumin. Our previous work showed that Zn2+ and cholesterol inhibit the human voltage-gated proton channel (hHv1) by stabilizing its S4 segment at resting state conformations. Released from phospholipids by phospholipase A2 in cells upon infection or injury, arachidonic acid regulates the function of many ion channels, including hHv1. In the present work, we examined the effects of arachidonic acid on purified hHv1 channels using liposome flux assays and revealed underlying structural mechanisms using single-molecule FRET. Our data indicated that arachidonic acid strongly activates hHv1 channels by promoting transitions of the S4 segment toward opening or "preopening" conformations. Moreover, we found that arachidonic acid even activates hHv1 channels inhibited by Zn2+ and cholesterol, providing a biophysical mechanism to activate hHv1 channels in nonexcitable cells upon infection or injury. [ABSTRACT FROM AUTHOR]

Published

2023

5. Voltage sensor dynamics of a bacterial voltage-gated sodium channel NavAb reveal three conformational states.

Author

Shuo Han, Vance, Joshua, Jones, Samuel, DeCata, Jenna, Tran, Kimberly, Cummings, John, and Shizhen Wang

Subjects

*VOLTAGE-gated ion channels, *SODIUM channels, *VOLTAGE, *LOCAL anesthetics, *DETECTORS

Abstract

High-resolution structures of voltage-gated sodium channels (Nav) were first obtained from a prokaryotic ortholog NavAb, which provided important mechanistic insights into Na+ selectivity and voltage gating. Unlike eukaryotic Navs, the NavAb channel is formed by four identical subunits, but its ion selectivity and pharmacological profiles are very similar to eukaryotic Navs. Recently, the structures of the NavAb voltage sensor at resting and activated states were obtained by cryo-EM, but its intermediate states and transition dynamics remain unclear. In the present work, we used liposome flux assays to show that purified NavAb proteins were functional to conduct both H+ and Na+ and were blocked by the local anesthetic lidocaine. Additionally, we examined the real-time conformational dynamics of the NavAb voltage sensor using single-molecule FRET. Our single-molecule FRET measurements on the tandem NavAb channel labeled with Cy3/5 FRET fluorophore pair revealed spontaneous transitions of the NavAb S4 segment among three conformational states, which fitted well with the kinetic model developed for the S4 segment of the human voltage-gated proton channel hHv1. Interestingly, even under strong activating voltage, the NavAb S4 segment seems to adopt a conformational distribution similar to that of the hHv1 S4 segment at a deep resting state. The conformational behaviors of the NavAb voltage sensor under different voltages need to be further examined to understand the mechanisms of voltage sensing and gating in the canonical voltage-gated ion channel superfamily. [ABSTRACT FROM AUTHOR]

Published

2023