Subunit configuration of heteromeric cone cyclic nucleotide-gated channels

Cone photoreceptor cyclic nucleotide-gated (CNG) channels are thought to be tetrameric assemblies of CNGB3 (B3) and CNGA3 (A3) subunits. We have used functional and biochemical approaches to investigate the stoichiometry and arrangement of these subunits in recombinant channels. First, tandem dimers of linked subunits were used to constrain the order of CNGB3 and CNGA3 subunits; the properties of channels formed by B3/B3+A3/A3 dimers, or A3/B3+B3/A3 dimers, closely resembled those of channels arising from B3+A3 monomers. Functional markers in B3/B3 (or A3/A3) dimers confirmed that both B3 subunits (and both A3 subunits) gained membership into the pore-forming tetramer and that like subunits were positioned adjacent to each other. Second, chemical crosslinking and co-immunoprecipitation studies using epitope-tagged monomer subunits both demonstrated the presence of two CNGB3 subunits in cone channels. Together, these data support a preferred subunit arrangement for cone CNG channels (B3-B3-A3-A3) that is distinct from the 3A:1B configuration of rod channels.     

Ligand-binding domain subregions contributing to bimodal agonism in cyclic nucleotide-gated channels

Cyclic nucleotide-gated (CNG) channels bind cGMP or cAMP in a cytoplasmic ligand-binding domain (BD), and this binding typically increases channel open probability (P(o)) without inducing desensitization. However, the catfish CNGA2 (fCNGA2) subtype exhibits bimodal agonism, whereby steady-state P(o) increases with initial cGMP-binding events ("pro" action) up to a maximum of 0.4, but decreases with subsequent cGMP-binding events ("con" action) occurring at concentrations >3 mM. We sought to clarify if low pro-action efficacy was either necessary or sufficient for con action to operate. To find BD residues responsible for con action or low pro-action efficacy or both, we constructed chimeric CNG channels: subregions of the fCNGA2 BD were substituted with corresponding sequence from the rat CNGA4 BD, which does not support con action. Constructs were expressed in frog oocytes and tested by patch clamp of cell-free membranes. For nearly all BD elements, we found at least one construct where replacing that element preserved robust con action, with a ratio of steady-state conductances, g((10 mM cGMP))/g((3 mM cGMP)) < 0.75. When all of the BD sequence C terminal of strand β6 was replaced, g((10 mM cGMP))/g((3 mM cGMP)) was increased to 0.95 ± 0.05 (n = 7). However, this apparent attenuation of con action could be explained by an increase in the efficacy of pro action for all agonists, controlled by a conserved "phosphate-binding cassette" motif that contacts ligand; this produces high P(o) values that are less sensitive to shifts in gating equilibrium. In contrast, substituting a single valine in the N-terminal helix αA abolished con action (g((30 mM cGMP))/g((3 mM cGMP)) increased to 1.26 ± 0.24; n = 7) without large increases in pro-action efficacy. Our work dissociates the two functional features of low pro-action efficacy and con action, and moreover identifies a separate structural determinant for each.     

Structural basis for ligand selectivity of heteromeric olfactory cyclic nucleotide-gated channels

In vertebrate olfactory receptors, cAMP produced by odorants opens cyclic nucleotide-gated (CNG) channels, which allow Ca(2+) entry and depolarization of the cell. These CNG channels are composed of alpha subunits and at least two types of beta subunits that are required for increased cAMP selectivity. We studied the molecular basis for the altered cAMP selectivity produced by one of the beta subunits (CNG5, CNCalpha4, OCNC2) using cloned rat olfactory CNG channels expressed in Xenopus oocytes. Compared with alpha subunit homomultimers (alpha channels), channels composed of alpha and beta subunits (alpha+beta channels) were half-activated (K(1/2)) by eightfold less cAMP and fivefold less cIMP, but similar concentrations of cGMP. The K(1/2) values for heteromultimers of the alpha subunit and a chimeric beta subunit with the alpha subunit cyclic nucleotide-binding region (CNBR) (alpha+beta-CNBRalpha channels) were restored to near the values for alpha channels. Furthermore, a single residue in the CNBR could account for the altered ligand selectivity. Mutation of the methionine residue at position 475 in the beta subunit to a glutamic acid as in the alpha subunit (beta-M475E) reverted the K(1/2,cAMP)/K(1/2,cGMP) and K(1/2, cIMP)/K(1/2,cGMP) ratios of alpha+beta-M475E channels to be very similar to those of alpha channels. In addition, comparison of alpha+beta-CNBRalpha channels with alpha+beta-M475E channels suggests that the CNBR of the beta subunit contains amino acid differences at positions other than 475 that produce an increase in the apparent affinity for each ligand. Like the wild-type beta subunit, the chimeric beta/alpha subunits conferred a shallow slope to the dose-response curves, increased voltage dependence, and caused desensitization. In addition, as for alpha+beta channels, block of alpha+betaCNBRalpha channels by internal Mg(2+) was not steeply voltage-dependent (zdelta approximately 1e(-)) as compared to block of alpha channels (zdelta 2.7e(-)). Thus, the ligand-independent effects localize outside of the CNBR. We propose a molecular model to explain how the beta subunit alters ligand selectivity of the heteromeric channels.     

Regulation of cyclic nucleotide-gated channels

Cyclic nucleotide-gated (CNG) channels are found in several cell types, and are best studied in photoreceptors and olfactory sensory neurons. There, CNG channels are gated by the second messengers of the visual and olfactory signalling cascades, cGMP and cAMP respectively, and operate as transduction channels generating the stimulus-induced receptor potentials. In visual and olfactory sensory cells CNG channels conduct cationic currents. Calcium can contribute a large fraction of this current, and calcium influx serves a modulatory role in CNG-channel mediated signal transduction. There have been recent developments in our understanding of how the regulation of CNG channels contributes to the physiological properties of photoreceptors and olfactory sensory cells, and in particular on the role of calcium-mediated feedback.     

Molecular mechanisms of cyclic nucleotide-gated channels

Cyclic nucleotide-gated (CNG) channels are highly specialized to carry out their unique role in cell signaling. Significant progress has been made in the last several years determining the molecular mechanisms for these specializations. The activation of the channels begins with the binding of cyclic nucleotide to a domain in the carboxyl terminal region. This binding, in turn, produces an induced fit of the protein that involves a movement of the C-helix portion of the binding domain. The induced fit of the binding domain is coupled to an allosteric conformational change that opens the channel pore. The pore is formed primarily from the sequence between the S5 and S6 segments. A single glutamic acid in the pore represents the binding site for multiple monovalent cations, the blocking site for external divalent cations, and the site for the effect of protons on permeation.     

Dissecting intersubunit contacts in cyclic nucleotide-gated ion channels

In cyclic nucleotide-gated (CNG) ion channels, binding of cGMP or cAMP drives a conformational change that leads to opening of an ion-conducting pore. One region implicated in the coupling of ligand binding to opening of the pore is the C linker region. Here, we used crosslinking of endogenous cysteines to study interregion proximity. We demonstrate that an individual amino acid--C481--in the C linker region of each of two neighboring subunits can form a disulfide bond. Further, using tandem dimers, we show that a disulfide bond between C35 in the N-terminal region and C481 in the C linker region can form either within a subunit or between subunits. From our data on proximity between individual amino acids and previous studies, a picture emerges of the C linker as a potential dimerization interface.     

Ca2+ permeation in cyclic nucleotide-gated channels.

Cyclic nucleotide-gated (CNG) channels conduct Na+, K+ and Ca2+ currents under the control of cGMP and cAMP. Activation of CNG channels leads to depolarization of the membrane voltage and to a concomitant increase of the cytosolic Ca2+ concentration. Several polypeptides were identified that constitute principal and modulatory subunits of CNG channels in both neurons and non-excitable cells, co-assembling to form a variety of heteromeric proteins with distinct biophysical properties. Since the contribution of each channel type to Ca2+ signaling depends on its specific Ca2+ conductance, it is necessary to analyze Ca2+ permeation for each individual channel type. We have analyzed Ca2+ permeation in all principal subunits of vertebrates and for a principal subunit from Drosophila melanogaster. We measured the fractional Ca2+ current over the physiological range of Ca2+ concentrations and found that Ca2+ permeation is determined by subunit composition and modulated by membrane voltage and extracellular pH. Ca2+ permeation is controlled by the Ca2+-binding affinity of the intrapore cation-binding site, which varies profoundly between members of the CNG channel family, and gives rise to a surprising diversity in the ability to generate Ca2+ signals.     

Electrophysiological analysis of cloned cyclic nucleotide-gated ion channels

Electrophysiological studies were conducted on the cloned plant cyclic nucleotide-gated ion channels AtCNGC2 and AtCNGC1 from Arabidopsis, and NtCBP4 from tobacco (Nicotiana tobacum). The nucleotide coding sequences for these proteins were expressed in Xenopus laevis oocytes or HEK 293 cells. Channel characteristics were evaluated using voltage clamp analysis of currents in the presence of cAMP. AtCNGC2 was demonstrated to conduct K(+) and other monovalent cations, but exclude Na(+); this conductivity profile is unique for any ion channel not possessing the amino acid sequence found in the selectivity filter of K(+)-selective ion channels. Application of cAMP evoked currents in membrane patches of oocytes injected with AtCNGC2 cRNA. Direct activation of the channel by cyclic nucleotide, demonstrated by application of cyclic nucleotide to patches of membranes expressing such channels, is a hallmark characteristic of this ion channel family. Voltage clamp studies (two-electrode configuration) demonstrated that AtCNGC1 and NtCBP4 are also cyclic nucleotide-gated channels. Addition of a lipophilic analog of cAMP to the perfusion bath of oocytes injected with NtCBP4 and AtCNGC1 cRNAs induced inward rectified, noninactivating K(+) currents.     

Expression of plant cyclic nucleotide-gated cation channels in yeast

The functional properties of inwardly conducting plant cyclic nucleotide-gated cation channels (CNGCs) have not been thoroughly characterized due in part to the recalcitrance of their functional expression in heterologous systems. Here, K+ uptake-deficient mutants of yeast (trk1,2) and Escherichia coli (LB650), as well as the Ca2+-uptake yeast mutant mid1,cch1, were used for functional characterization of Arabidopsis thaliana CNGCs, with the aim of identifying some of the cultural and physiological conditions that impact on plant CNGC function in heterologous systems. Use of the Ca2+-uptake yeast mutant provided the first evidence consistent with Ca2+ conduction by the A. thaliana CNGC AtCNGC1. Expression of AtCNGC1 in LB650 demonstrated that mutants of Escherichia coli (which has no endogenous calmodulin) can also be used to study functional properties of CNGCs. Expression of AtCNGC2 and AtCNGC4 enhanced growth of trk1,2 in the presence of hygromycin; AtCNGC1 has less of an effect. Deletion of the AtCNGC1 calmodulin-binding domain enhanced growth of trk1,2 at low external K+ but not of LB650, suggesting that yeast calmodulin may bind to, and down-regulate this plant channel. In vitro binding studies confirmed this physical interaction. Northern analysis, green fluorescent protein:AtCNGC1 fusion protein expression, as well as an antibody raised against a portion of AtCNGC1, were used to monitor expression of AtCNGC1 and deletion constructs of the channel in the heterologous systems. In the presence of the activating ligand cAMP, expression of the AtCNGC1 channel with the calmodulin-binding domain deleted increased intracellular [K+] of trk1,2. Trk1,2 is hypersensitive to the toxic cations spermine, tetramethylamine, and NH4+. These compounds, as well as amiloride, inhibited trk1,2 growth and thereby improved the efficacy of this yeast mutant as a heterologous expression system for CNGCs. In addition to characterizing mutants of yeast and E. coli as assay systems for plant CNGCs, work presented in this report demonstrates, for the first time, that a plant CNGC can retain ion channel function despite (partial) deletion of its calmodulin-binding domain and that yeast calmodulin can bind to and possibly down-regulate a plant CNGC.     

Stoichiometry and assembly of olfactory cyclic nucleotide-gated channels

Native ion channels are precisely tuned to their physiological role in neuronal signaling. This tuning frequently involves the controlled assembly of heteromeric channels comprising multiple types of subunits. Cyclic nucleotide-gated (CNG) channels of olfactory neurons are tetramers and require three types of subunits, CNGA2, CNGA4, and CNGB1b, to exhibit properties necessary for olfactory transduction. Using fluorescently tagged subunits and fluorescence resonance energy transfer (FRET), we find the subunit composition of heteromeric olfactory channels in the surface membrane is fixed, with 2:1:1 CNGA2:CNGA4:CNGB1b. Furthermore, when expressed individually with CNGA2, CNGA4 and CNGB1b subunits were still present in only a single copy and, when expressed alone, did not self-assemble. These results suggest that the precise assembly of heteromeric olfactory channels results from a mechanism where CNGA4 and CNGB1b subunits have a high affinity for CNGA2 but not for self-assembly, precluding more than one CNGA4 or CNGB1b subunit in the channel complex.     

Gating rearrangements in cyclic nucleotide-gated channels revealed by patch-clamp fluorometry

Site-specific fluorescence recordings have shown great promise in understanding conformational changes in signaling proteins. The reported applications on ion channels have been limited to extracellular sites in whole oocyte preparations. We are now able to directly monitor gating movements of the intracellular domains of cyclic nucleotide-gated channels using simultaneous site-specific fluorescence recording and patchclamp current recording from inside-out patches. Fluorescence signals were reliably observed when fluorophore was covalently attached to a site between the cyclic nucleotide-binding domain and the pore. While iodide, an anionic quencher, has a higher quenching efficiency in the channel's closed state, thallium ion, a cationic quencher, has a higher quenching efficiency in the open state. The state and charge dependence of quenching suggests movements of charged or dipolar residues near the fluorophore during CNG channel activation.     

Molecular rearrangements in the ligand-binding domain of cyclic nucleotide-gated channels

Cyclic nucleotide-gated (CNG) channels are activated in response to the direct binding of cyclic nucleotides to an intracellular domain. This domain is thought to contain a beta roll and two alpha helices, designated the B and C helices. To probe the conformational changes occurring in the ligand-binding domain during channel activation, we used the substituted cysteine accessibility method (SCAM). We found that a residue in the beta roll, C505, is more accessible in unliganded channels than in liganded channels, whereas a residue in the C helix, G597C, is more accessible in closed channels than in open channels. These results support a molecular mechanism for channel activation in which the ligand initially binds to the beta roll, followed by an opening allosteric transition involving the relative movement of the C helix toward the beta roll.     

cGMP and cyclic nucleotide-gated channels participate in mouse sperm capacitation

During capacitation of mammalian sperm intracellular [Ca(2+)] and cyclic nucleotides increase, suggesting that CNG channels play a role in the physiology of sperm. Here we study the effect of capacitation, 8Br-cAMP (8-bromoadenosine 3',5'-cyclic monophosphate) and 8Br-cGMP (8-bromoguanosine 3',5'-cyclic monophosphate) on the macroscopic ionic currents of mouse sperm, finding the existence of different populations of sperm, in terms of the recorded current and its response to cyclic nucleotides. Our results show that capacitation and cyclic nucleotides increase the ionic current, having a differential sensitivity to cGMP (cyclic guanosine monophosphate) and cAMP (cyclic adenosine monophosphate). Using a specific inhibitor we determine the contribution of CNG channels to macroscopic current and capacitation.     

Influence of permeant ions on gating in cyclic nucleotide-gated channels

Cyclic nucleotide-gated channels are key components in the transduction of visual and olfactory signals where their role is to respond to changes in the intracellular concentration of cyclic nucleotides. Although these channels poorly select between physiologically relevant monovalent cations, the gating by cyclic nucleotide is different in the presence of Na(+) or K(+) ions. This property was investigated using rod cyclic nucleotide-gated channels formed by expressing the subunit 1 (or alpha) in HEK293 cells. In the presence of K(+) as the permeant ion, the affinity for cGMP is higher than the affinity measured in the presence of Na(+). At the single channel level, subsaturating concentrations of cGMP show that the main effect of the permeant K(+) ions is to prolong the time channels remain open without major changes in the shut time distribution. In addition, the maximal open probability was higher when K(+) was the permeant ion (0.99 for K(+) vs. 0.95 for Na(+)) due to an increase in the apparent mean open time. Similarly, in the presence of saturating concentrations of cAMP, known to bind but unable to efficiently open the channel, permeant K(+) ions also prolong the time channels visit the open state. Together, these results suggest that permeant ions alter the stability of the open conformation by influencing of the O-->C transition.     

Modification of cyclic nucleotide-gated ion channels by ultraviolet light

We irradiated cyclic nucleotide-gated ion channels in situ with ultraviolet light to probe the role of aromatic residues in ion channel function. UV light reduced the current through excised membrane patches from Xenopus oocytes expressing the alpha subunit of bovine retinal cyclic nucleotide-gated channels irreversibly, a result consistent with permanent covalent modification of channel amino acids by UV light. The magnitude of the current reduction depended only on the total photon dose delivered to the patches, and not on the intensity of the exciting light, indicating that the functionally important photochemical modification(s) occurred from an excited state reached by a one-photon absorption process. The wavelength dependence of the channels' UV light sensitivity (the action spectrum) was quantitatively consistent with the absorption spectrum of tryptophan, with a small component at long wavelengths, possibly due to cystine absorption. This spectral analysis suggests that UV light reduced the currents at most wavelengths studied by modifying one or more "target" tryptophans in the channels. Comparison of the channels' action spectrum to the absorption spectrum of tryptophan in various solvents suggests that the UV light targets are in a water-like chemical environment. Experiments on mutant channels indicated that the UV light sensitivity of wild-type channels was not conferred exclusively by any one of the 10 tryptophan residues in a subunit. The similarity in the dose dependences of channel current reduction and tryptophan photolysis in solution suggests that photochemical modification of a small number of tryptophan targets in the channels is sufficient to decrease the currents.     

Mechanism of allosteric modulation of rod cyclic nucleotide-gated channels

The cyclic nucleotide-gated (CNG) channel of retinal rod photoreceptor cells is an allosteric protein whose activation is coupled to a conformational change in the ligand-binding site. The bovine rod CNG channel can be activated by a number of different agonists, including cGMP, cIMP, and cAMP. These agonists span three orders of magnitude in their equilibrium constants for the allosteric transition. We recorded single-channel currents at saturating cyclic nucleotide concentrations from the bovine rod CNG channel expressed in Xenopus oocytes as homomultimers of alpha subunits. The median open probability was 0.93 for cGMP, 0.47 for cIMP, and 0.01 for cAMP. The channels opened to a single conductance level of 26-30 pS at +80 mV. Using signal processing methods based on hidden Markov models, we determined that two closed and one open states are required to explain the gating at saturating ligand concentrations. We determined the maximum likelihood rate constants for two gating schemes containing two closed (denoted C) and one open (denoted O) states. For the C left and right arrow C left and right arrow O scheme, all rate constants were dependent on cyclic nucleotide. For the C left and right arrow O left and right arrow C scheme, the rate constants for only one of the transitions were cyclic nucleotide dependent. The opening rate constant was fastest for cGMP, intermediate for cIMP, and slowest for cAMP, while the closing rate constant was fastest for cAMP, intermediate for cIMP, and slowest for cGMP. We propose that interactions between the purine ring of the cyclic nucleotide and the binding domain are partially formed at the time of the transition state for the allosteric transition and serve to reduce the transition state energy and stabilize the activated conformation of the channel. When 1 microM Ni2+ was applied in addition to cyclic nucleotide, the open time increased markedly, and the closed time decreased slightly. The interactions between H420 and Ni2+ occur primarily after the transition state for the allosteric transition.