A State-independent Interaction between Ligand and a Conserved Arginine Residue in Cyclic Nucleotide-gated Channels Reveals a Functional Polarity of the Cyclic Nucleotide Binding Site

Tibbs, Gareth R.; Liu, David T.; Leypold, Bradley G.; Siegelbaum, Steven A.

doi:10.1074/jbc.273.8.4497

Cited by 62 publications

(65 citation statements)

References 44 publications

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“…The ligand-induced movement of the C-helix is widely thought to initiate the conformational changes that lead to opening of the channel pore, but the structural evidence in support of this hypothesis is equivocal (10,(24)(25)(26)(27)(28)(29). The crystal structure of the HCN2 carboxyl-terminal region in the absence of ligand shows little difference from the cyclic nucleotide-bound structure (12).…”

mentioning

confidence: 93%

Double electron–electron resonance reveals cAMP-induced conformational change in HCN channels

Puljung¹,

DeBerg

Zagotta³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Binding of 3′,5′-cyclic adenosine monophosphate (cAMP) to hyperpolarization-activated cyclic nucleotide-gated (HCN) ion channels regulates their gating. cAMP binds to a conserved intracellular cyclic nucleotide-binding domain (CNBD) in the channel, increasing the rate and extent of activation of the channel and shifting activation to less hyperpolarized voltages. The structural mechanism underlying this regulation, however, is unknown. We used double electron-electron resonance (DEER) spectroscopy to directly map the conformational ensembles of the CNBD in the absence and presence of cAMP. Site-directed, double-cysteine mutants in a soluble CNBD fragment were spin-labeled, and interspin label distance distributions were determined using DEER. We found motions of up to 10 Å induced by the binding of cAMP. In addition, the distributions were narrower in the presence of cAMP. Continuouswave electron paramagnetic resonance studies revealed changes in mobility associated with cAMP binding, indicating less conformational heterogeneity in the cAMP-bound state. From the measured DEER distributions, we constructed a coarse-grained elastic-network structural model of the cAMP-induced conformational transition. We find that binding of cAMP triggers a reorientation of several helices within the CNBD, including the C-helix closest to the cAMP-binding site. These results provide a basis for understanding how the binding of cAMP is coupled to channel opening in HCN and related channels.hyperpolarization-activated ion channels | allosteric regulation

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mentioning

confidence: 93%

Double electron–electron resonance reveals cAMP-induced conformational change in HCN channels

Puljung¹,

DeBerg

Zagotta³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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“…Similarly, the putative ligand contact position is defined as bCNGA1 Asp 604 and homologous positions in other BDs. New X chimeras were constructed by substitution of the BD in the chimera ROON-S2 previously studied (21,22); new RO chimeras were constructed by BD substitution in the chimera RO133 previously studied (13,21,(23)(24)(25). X-bA1 and RO-bA1 in this work are synonymous with ROON-S2 and RO133, respectively.…”

Section: Methodsmentioning

confidence: 99%

Distinct Structural Determinants of Efficacy and Sensitivity in the Ligand-binding Domain of Cyclic Nucleotide-gated Channels

Young

Krougliak

2004

Journal of Biological Chemistry

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Cyclic nucleotide-gated (CNG) channels open in response to direct binding of cyclic nucleotide messengers. Every subunit in a tetrameric CNG channel contains a cytoplasmic ligand-binding domain (BD) that includes a ␤-roll (flanked by short helices) and a single C-terminal helix called the C-helix that was previously found to control efficacy (maximal open probability) and selectivity for cGMP versus cAMP. We constructed a series of chimeric CNG channel subunits, each containing a distinct BD sequence (chosen from among six phylogenetically divergent isoforms) fused to an invariant non-BD sequence. We assayed these "BD substitution" chimeras as homomeric CNG channels in Xenopus oocytes to compare their functions and found that the most efficient activation by both cAMP and cGMP derived from the BD of the catfish CNGA4 olfactory modulatory subunit (fCNGA4). We then tested the effects of replacing subregions of the bovine CNGA1 BD with corresponding fCNGA4 sequence and hence identified parts of the fCNGA4 BD producing efficient activation. For instance, replacing either the "hinge" that connects the roll and C-helix subdomains or the BD sequence N-terminal to the hinge greatly enhanced cAMP efficacy. Replacing the "loop-␤8" region (the C-terminal end of the ␤-roll) improved agonist sensitivity for cGMP selectively over cAMP. Our results thus identify multiple BD elements outside the C-helix that control selective ligand interaction and channel gating steps by distinct mechanisms. This suggests that the purine ring of the cyclic nucleotide may interact with both the ␤-roll and the C-helix at different points in the mechanism. Cyclic nucleotide-gated (CNG)1 channels conduct mono-and divalent cations upon activation by the direct binding of the cytoplasmic messengers cAMP and cGMP. These channels are widespread in the nervous system and in a variety of other tissues, and most notably they are essential signaling components in visual and olfactory transduction, where their activation leads both to changes in membrane potential and to the influx of calcium into the cytoplasm (reviewed in Refs. 1 and 2). Functional CNG channels are tetramers (homomeric or heteromeric) of homologous subunits; vertebrates contain a family of six paralogous CNG channel subunit genes in two phylogenetic subfamilies (3), CNGA and CNGB. Distinct combinations of these paralogues are expressed in each tissue type to produce CNG channels whose response parameters are presumably adapted to the physiological requirements of the tissue; these parameters include sensitivity and efficacy (maximal ligandgated open probability) for cAMP and cGMP and selectivity for one agonist over the other. Thus, CNG channels hold promise as targets for tissue-specific pharmacological regulation of signaling through cyclic nucleotide-dependent, electrical, and calcium-dependent pathways. It is therefore important to understand how CNG channel function is determined by the sequences of individual subunits and more generally how structural elements in the channel work t...

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“…Mutations of the Arg residue to Lys or Trp in PKA (54,55), to several different residues, including Ala, in CAP (52,53,56), and to Gln in MlotiK1 channels (57) abolished cAMP binding. Mutation of the Arg residue to Ala in MlotiK1 and HCN2 channels, and to neutral and negatively charged residues in CNGA1 channels drastically decreased apparent cyclic nucleotide binding affinity (51,58,59).…”

Section: The Residues Crucial For Cyclic Nucleotide Binding Are Absenmentioning

confidence: 99%

Absence of Direct Cyclic Nucleotide Modulation of mEAG1 and hERG1 Channels Revealed with Fluorescence and Electrophysiological Methods

Brelidze

Carlson

Zagotta

2009

Journal of Biological Chemistry

122

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Similar to CNG and HCN channels, EAG and ERG channels contain a cyclic nucleotide binding domain (CNBD) in their C terminus. While cyclic nucleotides have been shown to facilitate opening of CNG and HCN channels, their effect on EAG and ERG channels is less clear. Here we explored cyclic nucleotide binding and modulation of mEAG1 and hERG1 channels with fluorescence and electrophysiology. Binding of cyclic nucleotides to the isolated CNBD of mEAG1 and hERG1 channels was examined with two independent fluorescence-based methods: changes in tryptophan fluorescence and fluorescence of an analog of cAMP, 8-NBD-cAMP. As a positive control for cyclic nucleotide binding we used changes in the fluorescence of the isolated CNBD of mHCN2 channels. Our results indicated that cyclic nucleotides do not bind to the isolated CNBD domain of mEAG1 channels and bind with low affinity (K d > 51 M) to the isolated CNBD of hERG1 channels. Consistent with the results on the isolated CNBD, application of cyclic nucleotides to inside-out patches did not affect currents recorded from mEAG1 channels. Surprisingly, despite its low affinity binding to the isolated CNBD, cAMP also had no effect on currents from hERG1 channels even at high concentrations. Our results indicate that cyclic nucleotides do not directly modulate mEAG1 and hERG1 channels. Further studies are necessary to determine if the CNBD in the EAG family of K ؉ channels might harbor a binding site for a ligand yet to be uncovered.The EAG family of K ϩ channels comprises ether-à-go-go (EAG), 2 EAG-related gene (ERG), and EAG-like (ELK) K ϩ channel subfamilies (1) with diverse tissue expression patterns and physiological functions (reviewed in Ref.2). mEAG channels are overexpressed in tumor tissues (3, 4), where they are involved in regulation of tumor progression (5, 6). Inhibition of the EAG channel expression by RNAi interference (7), application of channel blockers (8, 9), and monoclonal antibody that selectively inhibits currents from EAG channels (10) decreased cell proliferation in tumor tissues. ERG channels are best known for their function in the heart. Because of their unique physiological properties, fast inactivation, and slow deactivation, ERG channels are major contributors to the repolarization phase of the cardiac action potential (11)(12)(13)(14). Mutations in the ERG channels and administration of ERG channel blockers, such as class III antiarrhythmic drugs, cause long QT syndrome, a potentially lethal cardiac arrhythmia characterized by a prolonged cardiac action potential (15)(16)(17)(18)(19). In addition to their role in cardiac excitability, ERG channels also regulate proliferation of tumor cells (20 -22). The physiological role of ELK channels is not well understood, however, early reports suggest their possible involvement in the regulation of neuronal excitability (23). K ϩ channels in the EAG family are structurally related to the cyclic nucleotide-gated (CNG) and hyperpolarization-activated cyclic nucleotide-modulated (HCN) K ϩ channels (1, 24). All...

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A State-independent Interaction between Ligand and a Conserved Arginine Residue in Cyclic Nucleotide-gated Channels Reveals a Functional Polarity of the Cyclic Nucleotide Binding Site

Cited by 62 publications

References 44 publications

Double electron–electron resonance reveals cAMP-induced conformational change in HCN channels

Double electron–electron resonance reveals cAMP-induced conformational change in HCN channels

Distinct Structural Determinants of Efficacy and Sensitivity in the Ligand-binding Domain of Cyclic Nucleotide-gated Channels

Absence of Direct Cyclic Nucleotide Modulation of mEAG1 and hERG1 Channels Revealed with Fluorescence and Electrophysiological Methods

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