Structural basis of ligand activation in a cyclic nucleotide regulated potassium channel

Structural insights into conformational changes of a cyclic nucleotide-binding domain in solution from Mesorhizobium loti K1 channel

Cyclic nucleotide-sensitive ion channels, known as HCN and CNG channels, are activated by binding of ligands to a domain (CNBD) located on the cytoplasmic side of the channel. The underlying mechanisms are not well understood. To elucidate the gating mechanism, structures of both the ligand-free and -bound CNBD are required. Several crystal structures of the CNBD from HCN2 and a bacterial CNG channel (MloK1) have been solved. However, for HCN2, the cAMP-free and -bound state did not reveal substantial structural rearrangements. For MloK1, structural information for the cAMP-free state has only been gained from mutant CNBDs. Moreover, in the crystal, the CNBD molecules form an interface between dimers, proposed to be important for allosteric channel gating. Here, we have determined the solution structure by NMR spectroscopy of the cAMP-free wild-type CNBD of MloK1. A comparison of the solution structure of cAMP-free and -bound states reveals large conformational rearrangement on ligand binding. The two structures provide insights on a unique set of conformational events that accompany gating within the ligand-binding site.

Mechanistic insight into human ether-à-go-go-related gene (hERG) K+ channel deactivation gating from the solution structure of the EAG domain

Human ether-à-go-go-related gene (hERG) K⁺ channels have a critical role in cardiac repolarization. hERG channels close (deactivate) very slowly, and this is vital for regulating the time course and amplitude of repolarizing current during the cardiac action potential. Accelerated deactivation is one mechanism by which inherited mutations cause long QT syndrome and potentially lethal arrhythmias. hERG deactivation is highly dependent upon an intact EAG domain (the first 135 amino acids of the N terminus). Importantly, deletion of residues 2–26 accelerates deactivation to a similar extent as removing the entire EAG domain. These and other experiments suggest the first 26 residues (NT1–26) contain structural elements required to slow deactivation by stabilizing the open conformation of the pore. Residues 26–135 form a Per-Arnt-Sim domain, but a structure for NT1–26 has not been forthcoming, and little is known about its site of interaction on the channel. In this study, we present an NMR structure for the entire EAG domain, which reveals that NT1–26 is structurally independent from the Per-Arnt-Sim domain and contains a stable amphipathic helix with one face being positively charged. Mutagenesis and electrophysiological studies indicate that neutralizing basic residues and breaking the amphipathic helix dramatically accelerate deactivation. Furthermore, scanning mutagenesis and molecular modeling studies of the cyclic nucleotide binding domain suggest that negatively charged patches on its cytoplasmic surface form an interface with the NT1–26 domain. We propose a model in which NT1–26 obstructs gating motions of the cyclic nucleotide binding domain to allosterically stabilize the open conformation of the pore.

Resonance assignments of the nucleotide-free wildtype MloK1 cyclic nucleotide-binding domain

Cyclic nucleotide-sensitive ion channels, known as HCN and CNG channels play crucial roles in neuronal excitability and signal transduction of sensory cells. These channels are activated by binding of cyclic nucleotides to their intracellular cyclic nucleotide-binding domain (CNBD). A comparison of the structures of wildtype ligand-free and ligand-bound CNBD is essential to elucidate the mechanism underlying nucleotide-dependent activation of CNBDs. We recently reported the solution structure of the Mesorhizobium loti K1 (MloK1) channel CNBD in complex with cAMP. We have now extended these studies and achieved nearly complete assignments of (1)H, (13)C and (15)N resonances of the nucleotide-free CNBD. A completely new assignment of the nucleotide-free wildtype CNBD was necessary due to the sizable chemical shift differences as compared to the cAMP bound CNBD and the slow exchange behaviour between both forms. Scattering of these chemical shift differences over the complete CNBD suggests that nucleotide binding induces significant overall conformational changes.

Dissecting the cAMP-inducible allosteric switch in protein kinase A RIalpha

The regulatory subunits of cAMP-dependent protein kinase (PKA) are the major receptors of cAMP in most eukaryotic cells. As the cyclic nucleotide binding (CNB) domains release cAMP and bind to the catalytic subunit of PKA, they undergo a major conformational change. The change is mediated by the B/C helix in CNB-A, which extends into one long helix that now separates the two CNB domains and docks onto the surface of the catalytic subunit. We explore here the role of three key residues on the B/C helix that dock onto the catalytic subunit, Arg226, Leu233, and Met 234. By replacing each residue with Ala, we show that each contributes significantly to creating the R:C interface. By also deleting the second CNB domain (CNB-B), we show furthermore that CNB-B is a critical part of the cAMP-induced conformational switch that dislodges the B/C helix from the surface of the catalytic subunit. Without CNB-B the K(a) for activation by cAMP increases from 80 to 1000 nM. Replacing any of the key interface residues with Ala reduces the K(a) to 25-40 nM. Leu233 and M234 contribute to a hydrophobic latch that binds the B/C helix onto the large lobe of the C-subunit, while Arg226 is part of an electrostatic switch that couples the B/C helix to the phosphate binding cassette where the cAMP docks.

Cooperative and uncooperative cyclic-nucleotide-gated ion channels

Ion channels gated by cyclic nucleotides serve multiple functions in sensory signaling in diverse cell types ranging from neurons to sperm. Newly discovered members from bacteria and marine invertebrates provide a wealth of structural and functional information on this channel family. A hallmark of classical tetrameric cyclic-nucleotide-gated channels is their cooperative activation by binding of several ligands. By contrast, the new members seem to be uncooperative, and binding of a single ligand molecule suffices to open these channels. These new findings provide a fresh look at the mechanism of allosteric activation of ion channels.

Identification and experimental verification of a novel family of bacterial cyclic nucleotide-gated (bCNG) ion channels

Studies of bacterial ion channels have provided significant insights into the structure-function relationships of mechanosensitive and voltage-gated ion channels. However, to date, very few bacterial channels that respond to small molecules have been identified, cloned, and characterized. Here, we use bioinformatics to identify a novel family of bacterial cyclic nucleotide-gated (bCNG) ion channels containing a channel domain related by sequence homology to the mechanosensitive channel of small conductance (MscS). In this initial report, we clone selected members of this channel family, use electrophysiological measurements to verify their ability to directly gate in response to cyclic nucleotides, and use osmotic downshock to demonstrate their lack of mechanosensitivity. In addition to providing insight into bacterial physiology, these channels will provide researchers with a useful model system to investigate the role of ligand-gated ion channels (LGICs) in the signaling processes of higher organisms. The identification of these channels provides a foundation for structural and functional studies of LGICs that would be difficult to perform on mammalian channels. Moreover, the discovery of bCNG channels implies that bacteria have cyclic nucleotide-gated and cyclic nucleotide-modulated ion channels, which are analogous to the ion channels involved in eukaryotic secondary messenger signaling pathways.

Sequence or structure: using bioinformatics and homology modeling to understand functional relationships in cAMP/cGMP binding domains

The relationship between sequence, structure, and function is examined by comparing nineteen cyclic nucleotide monophosphate binding domains of known structure from six different functional families. Comparisons are made by structure and sequence alignment and through the generation of 3610 homology models. This analysis suggests there are only weak relationships between functional families, sequence, and/or structure. However, we have identified that for cyclic nucleotide monophosphate binding domains privileged template structures occur for homology modeling. The existence of privileged template structures, capable of creating accurate modeling for a broad family of proteins, may lead to improved homology modeling protocols.

An atypical CNG channel activated by a single cGMP molecule controls sperm chemotaxis

Sperm of the sea urchin Arbacia punctulata can respond to a single molecule of chemoattractant released by an egg. The mechanism underlying this extreme sensitivity is unknown. Crucial signaling events in the response of A. punctulata sperm to chemoattractant include the rapid synthesis of the intracellular messenger guanosine 3',5'-monophosphate (cGMP) and the ensuing membrane hyperpolarization that results from the opening of potassium-selective cyclic nucleotide-gated (CNGK) channels. Here, we use calibrated photolysis of caged cGMP to show that approximately 45 cGMP molecules are generated during the response to a single molecule of chemoattractant. The CNGK channel can respond to such small cGMP changes because it is exquisitely sensitive to cGMP and activated in a noncooperative fashion. Like voltage-activated Ca(v) and Na(v) channels, the CNGK polypeptide consists of four homologous repeat sequences. Disabling each of the four cyclic nucleotide-binding sites through mutagenesis revealed that binding of a single cGMP molecule to repeat 3 is necessary and sufficient to activate the CNGK channel. Thus, CNGK has developed a mechanism of activation that is different from the activation of other CNG channels, which requires the cooperative binding of several ligands and operates in the micromolar rather than the nanomolar range.

Molecular mechanisms for drug interactions with hERG that cause long QT syndrome

The human ether-a-go-go-related gene (hERG) encodes the pore-forming alpha-subunit of a voltage-gated potassium (K(+)) channel. A variety of unrelated compounds reduce K(+ )current in the heart by blocking the pore or disrupting trafficking of the hERG channel to the membrane surface. This induces a syndrome known as long QT, which arises from abnormalities in action potential repolarisation and can degenerate into lethal cardiac arrhythmias. As a result, this undesirable side effect has severely hindered safe drug development. This review describes progress in understanding the molecular basis for drug binding to hERG, outlines the characteristics of hERG ligands and discusses experimental and in silico approaches for identifying compounds with QT liabilities. Recent developments should enable recognition of hERG-positive compounds at the early stages of their development.

Structural basis of GDP release and gating in G protein coupled Fe2+ transport

G proteins are key molecular switches in the regulation of membrane protein function and signal transduction. The prokaryotic membrane protein FeoB is involved in G protein coupled Fe(2+) transport, and is unique in that the G protein is directly tethered to the membrane domain. Here, we report the structure of the soluble domain of FeoB, including the G protein domain, and its assembly into an unexpected trimer. Comparisons between nucleotide free and liganded structures reveal the closed and open state of a central cytoplasmic pore, respectively. In addition, these data provide the first observation of a conformational switch in the nucleotide-binding G5 motif, defining the structural basis for GDP release. From these results, structural parallels are drawn to eukaryotic G protein coupled membrane processes.

Conformational dynamics of the inner pore helix of voltage-gated potassium channels

Voltage-gated potassium (Kv) channels control the electrical excitability of neurons and muscles. Despite this key role, how these channels open and close or gate is not fully understood. Gating is usually attributed to the bending and straightening of pore-lining helices at glycine and proline residues. In this work we focused on the role of proline in the Pro-Val-Pro (PVP) motif of the inner S6 helix in the Kv1.2 channel. We started by developing a simple hinged-rod model to fully explore the configurational space of bent helices and we related these configurations to the degree of pore opening. We then carried out fully atomistic simulations of the S6 helices and compared these simulations to the hinged-rod model. Both methods suggest that Kv1 channels are not tightly closed when the inner helices are straight, unlike what is seen in the non-PVP containing channels KcsA and KirBac. These results invite the possibility that the S6 helices may be kinked when Kv1 channels are closed. Our simulations indicate that the wild-type helix adopts multiple spatially distinct configurations, which is consistent with its role in adopting a closed state and an open state. The two most dominant configurational basins correspond to a 6 A movement of the helix tail accompanied by the PVP region undergoing a local alpha-helix to 3(10)-helix transition. We explored how single point mutations affect the propensity of the S6 helix to adopt particular configurations. Interestingly, mutating the first proline, P405 (P473 in Shaker), to alanine completely removed the bistable nature of the S6 helix possibly explaining why this mutation compromises the channel. Next, we considered four other mutations in the area known to affect channel gating and we saw similarly dramatic changes to the helix's dynamics and range of motion. Our results suggest a possible mechanism of helix pore closure and they suggest differences in the closed state of glycine-only channels, like KcsA, and PVP containing channels.

Absence of direct cyclic nucleotide modulation of mEAG1 and hERG1 channels revealed with fluorescence and electrophysiological methods

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) > or = 51 microm) 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.

Combining electron crystallography and X-ray crystallography to study the MlotiK1 cyclic nucleotide-regulated potassium channel

We have recently reported the X-ray structure of the cyclic nucleotide-regulated potassium channel, MlotiK1. Here we describe the application of both electron and X-ray crystallography to obtain high quality crystals. We suggest that the combined application of these techniques provides a useful strategy for membrane protein structure determination. We also present negative stain projection and cryo-data projection maps. These maps provide new insights about the properties of the MlotiK1 channel. In particular, a comparison of a 9A cryo-data projection with calculated model maps strongly suggests that there is a very weak interaction between the pore and the S1-S4 domains of this 6 TM tetrameric cation channel and that the S1-S4 domains can adopt multiple orientations relative to the pore.

Solution structure of the Mesorhizobium loti K1 channel cyclic nucleotide-binding domain in complex with cAMP

Cyclic nucleotide-sensitive ion channels, known as HCN and CNG channels, are crucial in neuronal excitability and signal transduction of sensory cells. HCN and CNG channels are activated by binding of cyclic nucleotides to their intracellular cyclic nucleotide-binding domain (CNBD). However, the mechanism by which the binding of cyclic nucleotides opens these channels is not well understood. Here, we report the solution structure of the isolated CNBD of a cyclic nucleotide-sensitive K(+) channel from Mesorhizobium loti. The protein consists of a wide anti-parallel beta-roll topped by a helical bundle comprising five alpha-helices and a short 3(10)-helix. In contrast to the dimeric arrangement ('dimer-of-dimers') in the crystal structure, the solution structure clearly shows a monomeric fold. The monomeric structure of the CNBD supports the hypothesis that the CNBDs transmit the binding signal to the channel pore independently of each other.

Dynamically driven ligand selectivity in cyclic nucleotide binding domains

One of the mechanisms that minimize the aberrant cross-talk between cAMP- and cGMP-dependent signaling pathways relies on the selectivity of cAMP binding domains (CBDs). For instance, the CBDs of two critical eukaryotic cAMP receptors, i.e. protein kinase A (PKA) and the exchange protein activated by cAMP (EPAC), are both selectively activated by cAMP. However, the mechanisms underlying their cAMP versus cGMP selectivity are quite distinct. In PKA this selectivity is controlled mainly at the level of ligand affinity, whereas in EPAC it is mostly determined at the level of allostery. Currently, the molecular basis for these different selectivity mechanisms is not fully understood. We have therefore comparatively analyzed by NMR the cGMP-bound states of the essential CBDs of PKA and EPAC, revealing key differences between them. Specifically, cGMP binds PKA preserving the same syn base orientation as cAMP at the price of local steric clashes, which lead to a reduced affinity for cGMP. Unlike PKA, cGMP is recognized by EPAC in an anti conformation and generates several short and long range perturbations. Although these effects do not alter significantly the structure of the EPAC CBD investigated, remarkable differences in dynamics between the cAMP- and cGMP-bound states are detected for the ionic latch region. These observations suggest that one of the determinants of cGMP antagonism in EPAC is the modulation of the entropic control of inhibitory interactions and illustrate the pivotal role of allostery in determining signaling selectivity as a function of dynamic changes, even in the absence of significant affinity variations.

First-principles determination of molecular conformations of cyclic adenosine 3',5'-monophosphate in gas phase and aqueous solution

Extensive first-principles electronic structure calculations were performed in this study to explore the possible molecular structures and their concentration distribution of an intracellular second messenger, that is, cyclic adenosine 3',5'-monophosphate (cAMP), and its protonated form (cAMPH) in the gas phase and aqueous solution. The calculations resulted in prediction of four different stable conformers of cAMP and eight different stable conformers of cAMPH and their relative Gibbs free energies in the gas phase and aqueous solution. All of the computational results consistently demonstrate that the predominant conformers of cAMP and cAMPH are always the cAMP-chair-anti and cAMPH-chair2-syn conformers, respectively, in both the gas phase and aqueous solution. It has been demonstrated that the free energy barriers calculated for the intertransformation reactions between different conformers are very low (below approximately 6 kcal/mol) such that the intertransformation reactions between different conformers are very fast so that the concentration distribution of the system can quickly reach the thermodynamic equilibration during the process of binding with a protein. The calculated phenomenological pKa of 3.66 is in good agreement with the experimental pKa of 3.9 reported in literature, suggesting that the computational predictions resulted from this study are reasonable.

Role of intracellular domains in the function of the herg potassium channel

The functional role of the large intracellular regions (which include the cyclic nucleotide binding domain, cNBD, and the Per-Arnt-Sim domain, PAS) in the herg channel is not well understood. We have studied possible interactions of the cNBD with other parts of the channel protein using lysine mutations to disrupt such interactions. Some lysine mutations caused significant right shifts in the voltage dependence of inactivation; almost all the mutants caused speeding up of deactivation time course. In a homology model of the cNBD, lysine mutations that affected both inactivation and deactivation lie in a hydrophobic band on the surface of the structure of this domain. Some known mutations in the Long QT Syndrome type 2, with effects on deactivation, are located at residues close to hydrophobic bands on the cNBD and the PAS domains. Such bands of residues in these intracellular domains may play an important part in channel function.

Movements of native C505 during channel gating in CNGA1 channels

We investigated conformational changes occurring in the C-linker and cyclic nucleotide-binding (CNB) domain of CNGA1 channels by analyzing the inhibition induced by thiol-specific reagents in mutant channels Q409C and A414C in the open and closed state. Cd(2+) (200 microM) inhibited irreversibly mutant channels Q409C and A414C in the closed but not in the open state. Cd(2+) inhibition was abolished in the mutant A414C(cys-free), in the double mutant A414C + C505T and in the tandem construct A414C + C505T/CNGA1, but it was present in the construct A414C + C505(cys-free). The cross-linker reagent M-2-M inhibited mutant channel Q409C in the open state. M-2-M inhibition in the open state was abolished in the double mutant Q409C + C505T and in the tandem construct Q409C + C505T/CNGA1. These results show that C(alpha) of C505 in the closed state is located at a distance between 4 and 10.5 A from the C(alpha) of A414 of the same subunit, but in the open state C505 moves towards Q409 of the same subunit at a distance that ranges from 10.5 to 12.3 A from C(alpha) of this residue. These results are not consistent with a 3-D structure of the CNGA1 channel homologous to the structure of HCN2 channels either in the open or in the closed state.

Cyclic nucleotide-gated channels

Cyclic nucleotide-gated (CNG) channels are ion channels which are activated by the binding of cGMP or cAMP. The channels are important cellular switches which transduce changes in intracellular concentrations of cyclic nucleotides into changes of the membrane potential and the Ca2+ concentration. CNG channels play a central role in the signal transduction pathways of vision and olfaction. Structurally, the channels belong to the superfamily of pore-loop cation channels. They share a common domain structure with hyperpolarization-activated cyclic nucleotide-gated (HCN) channels and Eag-like K+ channels. In this chapter, we give an overview on the molecular properties of CNG channels and describe the signal transduction pathways these channels are involved in. We will also summarize recent insights into the physiological and pathophysiological role of CNG channel proteins that have emerged from the analysis of CNG channel-deficient mouse models and human channelopathies.

Cyclic nucleotide-regulated cation channels

Cyclic nucleotide-regulated cation channels are ion channels whose activation is regulated by the direct binding of cAMP or cGMP to the channel protein. Two structurally related families of channels regulated by cyclic nucleotides have been identified, the cyclic nucleotide-gated channels and the hyperpolarization-activated cyclic nucleotide-gated channels. Cyclic nucleotide-gated channels play a key role in visual and olfactory transduction. Hyperpolarization-activated cyclic nucleotide-gated channels are present in the conduction system of the heart and are involved in the control of cardiac automaticity. Moreover, these channels are widely expressed in central and peripheral neurons, where they control a variety of fundamental processes.

Ion channels in microbes

Studies of ion channels have for long been dominated by the animalcentric, if not anthropocentric, view of physiology. The structures and activities of ion channels had, however, evolved long before the appearance of complex multicellular organisms on earth. The diversity of ion channels existing in cellular membranes of prokaryotes is a good example. Although at first it may appear as a paradox that most of what we know about the structure of eukaryotic ion channels is based on the structure of bacterial channels, this should not be surprising given the evolutionary relatedness of all living organisms and suitability of microbial cells for structural studies of biological macromolecules in a laboratory environment. Genome sequences of the human as well as various microbial, plant, and animal organisms unambiguously established the evolutionary links, whereas crystallographic studies of the structures of major types of ion channels published over the last decade clearly demonstrated the advantage of using microbes as experimental organisms. The purpose of this review is not only to provide an account of acquired knowledge on microbial ion channels but also to show that the study of microbes and their ion channels may also hold a key to solving unresolved molecular mysteries in the future.

In silico description of fluorescent probes in vivo

Fluorescent imaging in vivo has became one of the most powerful tools to follow the temporal and spatial localization of a variety of intracellular molecular events. Genetically encoded fluorescent indicators using the FRET effect are routinely used although the molecular basis regulating their functioning is not completely known. Here, the structural and dynamics properties of a commonly used FRET sensor for the second messenger cAMP based on the cAMP-binding domains of the regulatory subunit of Protein Kinase A are presented. Molecular dynamics simulations allowed pinpointing the main features of cAMP driven conformational transition and dissecting the contributions of geometric factors governing the functioning of the biosensor. Simulations suggest that, although orientational factors are not fully isotropic, they are highly dynamic making the inter-chromophore distance the dominant feature, determining the functioning of the probes. It is expected that this computer-aided methodology may state general basis for rational design strategies of fluorescent markers for in vivo imaging.

Structure of Epac2 in complex with a cyclic AMP analogue and RAP1B

Epac proteins are activated by binding of the second messenger cAMP and then act as guanine nucleotide exchange factors for Rap proteins. The Epac proteins are involved in the regulation of cell adhesion and insulin secretion. Here we have determined the structure of Epac2 in complex with a cAMP analogue (Sp-cAMPS) and RAP1B by X-ray crystallography and single particle electron microscopy. The structure represents the cAMP activated state of the Epac2 protein with the RAP1B protein trapped in the course of the exchange reaction. Comparison with the inactive conformation reveals that cAMP binding causes conformational changes that allow the cyclic nucleotide binding domain to swing from a position blocking the Rap binding site towards a docking site at the Ras exchange motif domain.

Epac and PKA: a tale of two intracellular cAMP receptors

cAMP-mediated signaling pathways regulate a multitude of important biological processes under both physiological and pathological conditions, including diabetes, heart failure and cancer. In eukaryotic cells, the effects of cAMP are mediated by two ubiquitously expressed intracellular cAMP receptors, the classic protein kinase A (PKA)/cAMP-dependent protein kinase and the recently discovered exchange protein directly activated by camp (Epac)/cAMP-regulated guanine nucleotide exchange factors. Like PKA, Epac contains an evolutionally conserved cAMP binding domain that acts as a molecular switch for sensing intracellular second messenger cAMP levels to control diverse biological functions. The existence of two families of cAMP effectors provides a mechanism for a more precise and integrated control of the cAMP signaling pathways in a spatial and temporal manner. Depending upon the specific cellular environments as well as their relative abundance, distribution and localization, Epac and PKA may act independently, converge synergistically or oppose each other in regulating a specific cellular function.

Structural and energetic analysis of activation by a cyclic nucleotide binding domain

MlotiK1 is a prokaryotic homolog of cyclic-nucleotide-dependent ion channels that contains an intracellular C-terminal cyclic nucleotide binding (CNB) domain. X-ray structures of the CNB domain have been solved in the absence of ligand and bound to cAMP. Both the full-length channel and CNB domain fragment are easily expressed and purified, making MlotiK1 a useful model system for dissecting activation by ligand binding. We have used X-ray crystallography to determine three new MlotiK1 CNB domain structures: a second apo configuration, a cGMP-bound structure, and a second cAMP-bound structure. In combination, the five MlotiK1 CNB domain structures provide a unique opportunity for analyzing, within a single protein, the structural differences between the apo state and the bound state, and the structural variability within each state. With this analysis as a guide, we have probed the nucleotide selectivity and importance of specific residue side chains in ligand binding and channel activation. These data help to identify ligand-protein interactions that are important for ligand dependence in MlotiK1 and, more globally, in the class of nucleotide-dependent proteins.

Entropy-driven cAMP-dependent allosteric control of inhibitory interactions in exchange proteins directly activated by cAMP

Exchange proteins directly activated by cAMP (EPACs) are guanine nucleotide-exchange factors for the small GTPases Rap1 and Rap2 and represent a key receptor for the ubiquitous cAMP second messenger in eukaryotes. The cAMP-dependent activation of apoEPAC is typically rationalized in terms of a preexisting equilibrium between inactive and active states. Structural and mutagenesis analyses have shown that one of the critical determinants of the EPAC activation equilibrium is a cluster of salt bridges formed between the catalytic core and helices alpha1 and alpha2 at the N terminus of the cAMP binding domain and commonly referred to as ionic latch (IL). The IL stabilizes the inactive states in a closed topology in which access to the catalytic domain is sterically occluded by the regulatory moiety. However, it is currently not fully understood how the IL is allosterically controlled by cAMP. Chemical shift mapping studies consistently indicate that cAMP does not significantly perturb the structure of the IL spanning sites within the regulatory region, pointing to cAMP-dependent dynamic modulations as a key allosteric carrier of the cAMP-signal to the IL sites. Here, we have therefore investigated the dynamic profiles of the EPAC1 cAMP binding domain in its apo, cAMP-bound, and Rp-cAMPS phosphorothioate antagonist-bound forms using several 15N relaxation experiments. Based on the comparative analysis of dynamics in these three states, we have proposed a model of EPAC activation that incorporates the dynamic features allosterically modulated by cAMP and shows that cAMP binding weakens the IL by increasing its entropic penalty due to dynamic enhancements.

A generalized allosteric mechanism for cis-regulated cyclic nucleotide binding domains

Cyclic nucleotides (cAMP and cGMP) regulate multiple intracellular processes and are thus of a great general interest for molecular and structural biologists. To study the allosteric mechanism of different cyclic nucleotide binding (CNB) domains, we compared cAMP-bound and cAMP-free structures (PKA, Epac, and two ionic channels) using a new bioinformatics method: local spatial pattern alignment. Our analysis highlights four major conserved structural motifs: 1) the phosphate binding cassette (PBC), which binds the cAMP ribose-phosphate, 2) the "hinge," a flexible helix, which contacts the PBC, 3) the beta(2,3) loop, which provides precise positioning of an invariant arginine from the PBC, and 4) a conserved structural element consisting of an N-terminal helix, an eight residue loop and the A-helix (N3A-motif). The PBC and the hinge were included in the previously reported allosteric model, whereas the definition of the beta(2,3) loop and the N3A-motif as conserved elements is novel. The N3A-motif is found in all cis-regulated CNB domains, and we present a model for an allosteric mechanism in these domains. Catabolite gene activator protein (CAP) represents a trans-regulated CNB domain family: it does not contain the N3A-motif, and its long range allosteric interactions are substantially different from the cis-regulated CNB domains.

Structure of the transmembrane regions of a bacterial cyclic nucleotide-regulated channel

The six-transmembrane helix (6 TM) tetrameric cation channels form the largest ion channel family, some members of which are voltage-gated and others are not. There are no reported channel structures to match the wealth of functional data on the non-voltage-gated members. We determined the structure of the transmembrane regions of the bacterial cyclic nucleotide-regulated channel MlotiK1, a non-voltage-gated 6 TM channel. The structure showed how the S1-S4 domain and its associated linker can serve as a clamp to constrain the gate of the pore and possibly function in concert with ligand-binding domains to regulate the opening of the pore. The structure also led us to hypothesize a new mechanism by which motions of the S6 inner helices can gate the ion conduction pathway at a position along the pore closer to the selectivity filter than the canonical helix bundle crossing.

Structural dynamics in the activation of Epac

Epac1 is a cAMP-responsive exchange factor for the small G-protein Rap. It consists of a regulatory region containing a cyclic nucleotide binding (CNB) domain and a catalytic region that activates Rap. In the absence of cAMP, access of Rap to the catalytic site is blocked by the regulatory region. We analyzed the conformational states of the CNB domain in the absence and in the presence of cAMP and cAMP analogues by NMR spectroscopy, resulting in the first direct insights into the activation mechanism of Epac. We prove that the CNB domain exists in equilibrium between the inactive and the active conformation, which is shifted by binding of cAMP. cAMP binding results in conformational changes in both the ligand binding pocket and the outer helical segments. We used two different cAMP antagonists that block these successive changes to elucidate the steps of this process. Highlighting the role of dynamics, the superactivator 8-pCPT-2'-O-Me-cAMP induces similar conformational changes as cAMP but causes different internal mobility. The results reveal the critical elements of the CNB domain of Epac required for activation and highlight the role of dynamics in this process.

The structure of the prokaryotic cyclic nucleotide-modulated potassium channel MloK1 at 16 A resolution

The gating ring of cyclic nucleotide-modulated channels is proposed to be either a two-fold symmetric dimer of dimers or a four-fold symmetric tetramer based on high-resolution structure data of soluble cyclic nucleotide-binding domains and functional data on intact channels. We addressed this controversy by obtaining structural data on an intact, full-length, cyclic nucleotide-modulated potassium channel, MloK1, from Mesorhizobium loti, which also features a putative voltage-sensor. We present here the 3D single-particle structure by transmission electron microscopy and the projection map of membrane-reconstituted 2D crystals of MloK1 in the presence of cAMP. Our data show a four-fold symmetric arrangement of the CNBDs, separated by discrete gaps. A homology model for full-length MloK1 suggests a vertical orientation for the CNBDs. The 2D crystal packing in the membrane-embedded state is compatible with the S1-S4 domains in the vertical "up" state.

Cyclic nucleotide-regulated ion channels: spotlight on symmetry

In this issue of Structure, Chiu et al. (2007) report the 16 A EM structure of the prokaryotic cyclic nucleotide-regulated K(+) channel MloK1. This structure reveals that the channel is arranged as a four-fold symmetric tetramer.

Understanding cAMP-dependent allostery by NMR spectroscopy: comparative analysis of the EPAC1 cAMP-binding domain in its apo and cAMP-bound states

cAMP (adenosine 3',5'-cyclic monophosphate) is a ubiquitous second messenger that activates a multitude of essential cellular responses. Two key receptors for cAMP in eukaryotes are protein kinase A (PKA) and the exchange protein directly activated by cAMP (EPAC), which is a recently discovered guanine nucleotide exchange factor (GEF) for the small GTPases Rap1 and Rap2. Previous attempts to investigate the mechanism of allosteric activation of eukaryotic cAMP-binding domains (CBDs) at atomic or residue resolution have been hampered by the instability of the apo form, which requires the use of mixed apo/holo systems, that have provided only a partial picture of the CBD apo state and of the allosteric networks controlled by cAMP. Here, we show that, unlike other eukaryotic CBDs, both apo and cAMP-bound states of the EPAC1 CBD are stable under our experimental conditions, providing a unique opportunity to define at an unprecedented level of detail the allosteric interactions linking two critical functional sites of this CBD. These are the phosphate binding cassette (PBC), where cAMP binds, and the N-terminal helical bundle (NTHB), which is the site of the inhibitory interactions between the regulatory and catalytic regions of EPAC. Specifically, the combined analysis of the cAMP-dependent changes in chemical shifts, 2 degrees structure probabilities, hydrogen/hydrogen exchange (H/H) and hydrogen/deuterium exchange (H/D) protection factors reveals that the long-range communication between the PBC and the NTHB is implemented by two distinct intramolecular cAMP-signaling pathways, respectively, mediated by the beta2-beta3 loop and the alpha6 helix. Docking of cAMP into the PBC perturbs the NTHB inner core packing and the helical probabilities of selected NTHB residues. The proposed model is consistent with the allosteric role previously hypothesized for L273 and F300 based on site-directed mutagenesis; however, our data show that such a contact is part of a significantly more extended allosteric network that, unlike PKA, involves a tight coupling between the alpha- and beta-subdomains of the EPAC CBD. The proposed mechanism of allosteric activation will serve as a basis to understand agonism and antagonism in the EPAC system and provides also a general paradigm for how small ligands control protein-protein interfaces.

Conformational analysis of Epac activation using amide hydrogen/deuterium exchange mass spectrometry

Exchange proteins directly activated by cAMP (Epac) play important roles in mediating the effects of cAMP through the activation of downstream small GTPases, Rap. To delineate the mechanism of Epac activation, we probed the conformation and structural dynamics of Epac using amide hydrogen/deuterium exchange and structural modeling. Our studies show that cAMP induces significant conformational changes that lead to a spatial rearrangement of the regulatory components of Epac and allows the exposure of the catalytic core for effector binding without imposing significant conformational change on the catalytic core. Homology modeling and comparative structural analyses of the cAMP binding domains of Epac and cAMP-dependent protein kinase (PKA) lead to a model of Epac activation, in which Epac and PKA activation by cAMP employs the same underlying principle, although the detailed structural and conformational changes associated with Epac and PKA activation are significantly different.

Structure and rearrangements in the carboxy-terminal region of SpIH channels

Hyperpolarization-activated cyclic nucleotide-modulated (HCN) ion channels regulate the spontaneous firing activity and electrical excitability of many cardiac and neuronal cells. The modulation of HCN channel opening by the direct binding of cAMP underlies many physiological processes such as the autonomic regulation of the heart rate. Here we use a combination of X-ray crystallography and electrophysiology to study the allosteric mechanism for cAMP modulation of HCN channels. SpIH is an invertebrate HCN channel that is activated fully by cAMP, but only partially by cGMP. We exploited the partial agonist action of cGMP on SpIH to reveal the molecular mechanism for cGMP specificity of many cyclic nucleotide-regulated enzymes. Our results also elaborate a mechanism for the allosteric conformational change in the cyclic nucleotide-binding domain and a mechanism for partial agonist action. These mechanisms will likely extend to other cyclic nucleotide-regulated channels and enzymes as well.

Gating of HCN channels by cyclic nucleotides: residue contacts that underlie ligand binding, selectivity, and efficacy

Cyclic nucleotides (cNMPs) regulate the activity of various proteins by interacting with a conserved cyclic nucleotide-binding domain (CNBD). Although X-ray crystallographic studies have revealed the structures of several CNBDs, the residues responsible for generating the high efficacy with which ligand binding leads to protein activation remain unknown. Here, we combine molecular dynamics simulations with mutagenesis to identify ligand contacts important for the regulation of the hyperpolarization-activated HCN2 channel by cNMPs. Surprisingly, out of 7 residues that make strong contacts with ligand, only R632 in the C helix of the CNBD is essential for high ligand efficacy, due to its selective stabilization of cNMP binding to the open state of the channel. Principal component analysis suggests that a local movement of the C helix upon ligand binding propagates through the CNBD of one subunit to the C linker of a neighboring subunit to apply force to the gate of the channel.

Subunits act independently in a cyclic nucleotide-activated K(+) channel

Ion channels gated by cyclic nucleotides have crucial roles in neuronal excitability and signal transduction of sensory neurons. Here, we studied ligand binding of a cyclic nucleotide-activated K(+) channel from Mesorhizobium loti and its isolated cyclic nucleotide-binding domain. The channel and the binding domain alone bind cyclic AMP with similar affinity in a non-cooperative manner. The cAMP sensitivities of binding and activation coincide. Thus, each subunit in the tetrameric channel acts independently of the others. The binding and gating properties of the bacterial channel are distinctively different from those of eukaryotic cyclic nucleotide-gated channels.

Patch clamp and phenotypic analyses of a prokaryotic cyclic nucleotide-gated K+ channel using Escherichia coli as a host

Prokaryotic ion channels have been valuable in providing structural models for understanding ion filtration and channel-gating mechanisms. However, their functional examinations have remained rare and usually been carried out by incorporating purified channel protein into artificial lipid membranes. Here we demonstrate the utilization of Escherichia coli to host the functional analyses by examining a putative cyclic nucleotide-gated K+ channel cloned from Magnetospirillum magnetotacticum, MmaK. When expressed in wild-type E. coli cells, MmaK renders the host sensitive to millimolar concentrations of externally applied K+, indicating MmaK forms a functional K+ conduit in the E. coli membrane in vivo. After enlarging these cells into giant spheroplasts, macro- and microscopic MmaK currents are readily detected in excised E. coli membrane patches by a patch clamp. We show that MmaK is indeed gated by submicromolar cAMP and approximately 10-fold higher concentration of cGMP and manifests as an inwardly rectified, K+-specific current with a 10.8 pS unitary conductance at -100 mV. Additionally, MmaK is inactivated by slightly acidic pH only from the cytoplasmic side. Our in vitro biophysical characterizations of MmaK correlate with its in vivo phenotype in E. coli, implicating its critical role as an intracellular cAMP and pH sensor for modulating bacterial membrane potential. Exemplified by MmaK functional studies, we establish that E. coli and its giant spheroplast provide a convenient and versatile system to express foreign channels for biophysical analyses that can be further dovetailed with microbial genetics.

Ligand binding and activation in a prokaryotic cyclic nucleotide-modulated channel

We designed a technique that directly determines binding of cyclic nucleotides to the prokaryotic cyclic nucleotide modulated ion channel MloK1. The ability to purify large quantities of MloK1 facilitated equilibrium binding assays, which avoided the inherent problem of relatively low affinity binding which hindered the use of eukaryotic channels. We found that MloK1 specifically binds cAMP and cGMP with affinity values in the range of those observed for activity assays for eukaryotic channels. Notably, the concentration of ligand that elicited 50% of maximum response in (86)Rb flux assays (K1/2), also referred to as ligand sensitivity, was smaller than the corresponding value obtained from binding assays (Kd) potentially indicating significant channel activity in partially liganded states. To gain further insight into the mechanism of binding and activation of these channels, we mutated several amino acids in the ligand-binding pocket of MloK1, known from electrophysiological studies of homologous eukaryotic channels to affect ligand selectivity and binding efficacy. The S308V MloK1 mutant (a mutation which decreases cGMP selectivity in eukaryotic channels) decreased both the observed cGMP binding affinity and the sensitivity to cGMP relative to the wild-type (WT) channel, leaving those for cAMP unchanged. Conversely, the A352D MloK1 mutant (a mutation which increases cGMP selectivity in eukaryotic channels) increased both the affinity and the sensitivity for cGMP relative to the WT channel, again leaving those for cAMP unchanged. Mutations at R307 in MloK1, the most conserved residue in the binding pocket of cyclic nucleotide-binding proteins, were not tolerated as these mutants do not form functional channels. Furthermore, for each mutation, changes in binding affinities were mirrored by equivalent changes in ligand sensitivity. These data, together with the evidence that partially liganded channels open significantly, suggested strong coupling between cyclic nucleotide binding and MloK1 channel opening.

Origin of functional diversity among tetrameric voltage-gated channels

The aim of the present work is to relate functional differences of voltage-gated K(+) (K(v)), hyperpolarization-activated cyclic nucleotide-gated (HCN), and cyclic nucleotide gated (CNG) channels to differences in their amino acid sequences. By means of combined bioinformatic sequence analyses and homology modelling, we suggest that: (1) CNG channels are less voltage-dependent than K(v) channels since the charge of their voltage sensor, the S4 helix, is lower than that of K(v) channels and because of the presence of a conserved proline in the S4-S5 linker, which is quite likely to uncouple S4 from S5 and S6. (2) In HCN channels, S4 features a higher net positive charge with respect to K(v) channels and an extensive network of hydrophobic residues, which is quite likely to provide a tight coupling among S4 and the neighboring helices. We suggest insights on the gating of HCN channels and the reasons why they open with membrane hyperpolarization and with a significantly longer time constant with respect to other channels.

Capturing cyclic nucleotides in action: snapshots from crystallographic studies

Fifty years ago, cyclic AMP was discovered as a second messenger of hormone action, heralding the age of signal transduction. Many cellular processes were found to be regulated by cAMP and the related cyclic GMP. Cyclic nucleotides function by binding to and activating their effectors - protein kinase A, protein kinase G, cyclic-nucleotide-regulated ion channels and the guanine nucleotide-exchange factor Epac. Recent structural insights have now made it possible to propose a general structural mechanism for how cyclic nucleotides regulate these proteins.

cAMP activation of PKA defines an ancient signaling mechanism

cAMP and the cAMP binding domain (CBD) constitute a ubiquitous regulatory switch that translates an extracellular signal into a biological response. The CBD contains alpha- and beta-subdomains with cAMP binding to a phosphate binding cassette (PBC) in the beta-sandwich. The major receptors for cAMP in mammalian cells are the regulatory subunits (R-subunits) of PKA where cAMP and the catalytic subunit compete for the same CBD. The R-subunits inhibit kinase activity, whereas cAMP releases that inhibition. Here, we use NMR to map at residue resolution the cAMP-dependent interaction network of the CBD-A domain of isoform Ialpha of the R-subunit of PKA. Based on H/D, H/H, and N(z) exchange data, we propose a molecular model for the allosteric regulation of PKA by cAMP. According to our model, cAMP binding causes long-range perturbations that propagate well beyond the immediate surroundings of the PBC and involve two key relay sites located at the C terminus of beta(2) (I163) and N terminus of beta(3) (D170). The I163 site functions as one of the key triggers of global unfolding, whereas the D170 locus acts as an electrostatic switch that mediates the communication between the PBC and the B-helix. Removal of cAMP not only disrupts the cap for the B' helix within the PBC, but also breaks the circuitry of cooperative interactions stemming from the PBC, thereby uncoupling the alpha- and beta-subdomains. The proposed model defines a signaling mechanism, conserved in every genome, where allosteric binding of a small ligand disrupts a large protein-protein interface.

Dissecting the mechanism of Epac activation via hydrogen-deuterium exchange FT-IR and structural modeling

Exchange proteins directly activated by cAMP (Epac) make up a family of cAMP binding domain-containing proteins that play important roles in mediating the effects of cAMP through the activation of downstream small GTPases, Ras-proximate proteins. To delineate the mechanism of Epac activation, we probed the conformation and structural dynamics of Epac using amide hydrogen-deuterium (H-D) exchange coupled with Fourier transform infrared spectroscopy (FT-IR) and structural modeling. Our studies show that unlike that of cAMP-dependent protein kinase (PKA), the classic intracellular cAMP receptor, binding of cAMP to Epac does not induce significant changes in overall secondary structure and structural dynamics, as measured by FT-IR and the rate of H-D exchange, respectively. These results suggest that Epac activation does not involve significant changes in the amount of exposed surface areas as in the case of PKA activation, and conformational changes induced by cAMP in Epac are most likely confined to small local regions. Homology modeling and comparative structural analyses of the CBDs of Epac and PKA lead us to propose a model of Epac activation. On the basis of our model, Epac activation by cAMP employs the same underlying structural principal utilized by PKA, although the detailed structural and conformational changes associated with Epac and PKA activation are significantly different. In addition, we predict that during Epac activation the first beta-strand of the switchboard switches its conformation to a alpha-helix, which folds back to the beta-barrel core of the CBD and interacts directly with cAMP to form the base of the cAMP-binding pocket.

The RCK Domain of the KtrAB K+ Transporter: Multiple Conformations of an Octameric Ring

The KtrAB ion transporter is a complex of the KtrB membrane protein and KtrA, an RCK domain. RCK domains regulate eukaryotic and prokaryotic membrane proteins involved in K(+) transport. Conflicting functional models have proposed two different oligomeric arrangements for RCK domains, tetramer versus octamer. Our results for the KtrAB RCK domain clearly show an octamer in solution and in the crystal. We determined the structure of this protein in three different octameric ring conformations that resemble the RCK-domain octamer observed in the MthK potassium channel but show striking differences in size and symmetry. We present experimental evidence for the association between one RCK octameric ring and two KtrB membrane proteins. These results provide insights into the quaternary organization of the KtrAB transporter and its mechanism of activation and show that the RCK-domain octameric ring model is generally applicable to other ion-transport systems.

Sperm chemotaxis: a primer

Sperm become attracted by chemical substances that are released from the outer coating of the egg, a process called chemotaxis. In this paper the cellular pathway and the motor response during chemotaxis of sperm from sea urchin and starfish are briefly outlined.

Mapping Allostery through Equilibrium Perturbation NMR Spectroscopy

The understanding of allostery relies on the comparative analysis of macromolecules in their free and bound states. However, the direct free versus bound comparison is often challenging due to the instability of one of the two forms. This problem is effectively circumvented by using minor free/bound equilibrium perturbations which are tolerated without compromising sample stability. The subtle equilibrium perturbations are still able to reveal significant apo/holo differences if monitored by NMR experiments that are sensitive to minor populations within dynamic equilibria, such as NMR relaxation dispersion (NMRD) and hydrogen exchange (H/D and H/H) rates. These measurements are complementary to each other as they unmask how a ligand affects both the stable and the excited states of the free energy landscape for its protein receptor. The proposed equilibrium perturbation approach therefore significantly expands the scope of applicability of NMRD and hydrogen exchange experiments to the investigation of ligand-protein interactions, in general, unveiling allosteric "hot spot" maps for systems that have been traditionally elusive to direct free/bound comparisons.

cAMP Modulation of the cytoplasmic domain in the HCN2 channel investigated by molecular simulations

The hyperpolarization-activated cyclic nucleotide-modulated (HCN) cation channels are opened by membrane hyperpolarization, while their activation is modulated by the binding of cyclic adenosine monophosphate (cAMP) in the cytoplasm. Here we investigate the molecular basis of cAMP channel modulation by performing molecular dynamics simulations of a segment comprising the C-linker and the cyclic nucleotide binding domain (CNBD) in the presence and absence of cAMP, based on the available crystal structure of HCN2 from mouse. In presence of cAMP, the protein undergoes an oscillation of the quaternary structure on the order of 10 ns, not observed in the apoprotein. In contrast, the absence of ligand causes conformational rearrangements within the CNBDs, driving these domains to a more flexible state, similar to that described in CNBDs of other proteins. This increased flexibility causes a rather disordered movement of the CNBDs, resulting in an inhibitory effect on the channel. We propose that the cAMP-triggered large-scale oscillation plays an important role for the channel's function, being coupled to a motion of the C-linker which, in turn, modulates the gating of the channel.

Structure of the cyclic-AMP-responsive exchange factor Epac2 in its auto-inhibited state

Epac proteins (exchange proteins directly activated by cAMP) are guanine-nucleotide-exchange factors (GEFs) for the small GTP-binding proteins Rap1 and Rap2 that are directly regulated by the second messenger cyclic AMP and function in the control of diverse cellular processes, including cell adhesion and insulin secretion. Here we report the three-dimensional structure of full-length Epac2, a 110-kDa protein that contains an amino-terminal regulatory region with two cyclic-nucleotide-binding domains and a carboxy-terminal catalytic region. The structure was solved in the absence of cAMP and shows the auto-inhibited state of Epac. The regulatory region is positioned with respect to the catalytic region by a rigid, tripartite beta-sheet-like structure we refer to as the 'switchboard' and an ionic interaction we call the 'ionic latch'. As a consequence of this arrangement, the access of Rap to the catalytic site is sterically blocked. Mutational analysis suggests a model for cAMP-induced Epac activation with rigid body movement of the regulatory region, the features of which are universally conserved in cAMP-regulated proteins.