Direct studies of ligand-receptor interactions and ion channel blocking (Review)

Small molecules can activate membrane bound receptors to elicit cellular responses and ~80% of all such responses are mediated through membranes. Solid state nuclear magnetic resonance (NMR) methods have been developed for the resolution of specifically labelled ligands, designed to report back structural, dynamic and electronic details of the ligand whilst at its site of action. In particular, ion channel blockers, drugs, inhibitors, prosthetic groups and solutes have been studied when at their target site in functionally competent membranes. A blocker of the channel in the anion transporter of erythrocytes (AE1) has been studied to show that considerable motional freedom within the channel site occurs. The activating agonist of the ligand gated ion channel, the nicotinic acetylcholine receptor, is constrained at its site of action and binds through a cation- &#126 interaction as revealed in the NMR spectra. The footprint for the inhibitor binding site of the digitalis receptor, the Na + /K + -ATPase has been resolved as well as the molecular conformation of digitalis showing a bent structure whilst at its site of action. For the gastric proton pump, however, a planar conformation is observed for a reversible substituted imidazopyridine. In all cases not only the structure, but also some indications about the electronic interactions of ligand and target have been resolved using these approaches.     

Direct studies of ligand-receptor interactions and ion channel blocking (Review)

Small molecules can activate membrane bound receptors to elicit cellular responses and approximately 80% of all such responses are mediated through membranes. Solid state nuclear magnetic resonance (NMR) methods have been developed for the resolution of specifically labelled ligands, designed to report back structural, dynamic and electronic details of the ligand whilst at its site of action. In particular, ion channel blockers, drugs, inhibitors, prosthetic groups and solutes have been studied when at their target site in functionally competent membranes. A blocker of the channel in the anion transporter of erythrocytes (AE1) has been studied to show that considerable motional freedom within the channel site occurs. The activating agonist of the ligand gated ion channel, the nicotinic acetylcholine receptor, is constrained at its site of action and binds through a cation-pi interaction as revealed in the NMR spectra. The footprint for the inhibitor binding site of the digitalis receptor, the Na(+)/K(+)-ATPase has been resolved as well as the molecular conformation of digitalis showing a bent structure whilst at its site of action. For the gastric proton pump, however, a planar conformation is observed for a reversible substituted imidazopyridine. In all cases not only the structure, but also some indications about the electronic interactions of ligand and target have been resolved using these approaches.     

Solution Characterization of the Extracellular Region of CD147 and Its Interaction with Its Enzyme Ligand Cyclophilin A

The CD147 receptor plays an integral role in numerous diseases by stimulating the expression of several protein families and serving as the receptor for extracellular cyclophilins; however, neither CD147 nor its interactions with its cyclophilin ligands have been well characterized in solution. CD147 is a unique protein in that it can function both at the cell membrane and after being released from cells where it continues to retain activity. Thus, the CD147 receptor functions through at least two mechanisms that include both cyclophilin-independent and cyclophilin-dependent modes of action. In regard to CD147 cyclophilin-independent activity, CD147 homophilic interactions are thought to underlie its activity. In regard to CD147 cyclophilin-dependent activity, cyclophilin/CD147 interactions may represent a novel means of signaling since cyclophilins are also peptidyl-prolyl isomerases. However, direct evidence of catalysis has not been shown within the cyclophilin/CD147 complex. In this report, we have characterized the solution behavior of the two most prevalent CD147 extracellular isoforms through biochemical methods that include gel-filtration and native gel analysis as well as directly through multiple NMR methods. All methods indicate that the extracellular immunoglobulin-like domains are monomeric in solution and, thus, suggest that CD147 homophilic interactions in vivo are mediated through other partners. Additionally, using multiple NMR techniques, we have identified and characterized the cyclophilin target site on CD147 and have shown for the first time that CD147 is also a substrate of its primary cyclophilin enzyme ligand, cyclophilin A.     

The structure of the zinc sites of Escherichia coli DNA-dependent RNA polymerase.

X-ray absorption spectroscopy is ideally suited for the investigation of the electronic structure and the local environment (approximately 5 A) of specific atoms in biomolecules. While the edge region provides information about the valence state of the absorbing atom, the chemical identity of neighboring atoms, and the coordination geometry, the extended x-ray absorption fine structure region contains information about the number and average distance of neighboring atoms and their relative disorder. The development of sensitive detection methods has allowed studies using near physiological concentrations (as low as approximately 100 microM). RNA polymerase from Escherichia coli contains two zinc atoms: one tightly bound in the beta' subunit, the subunit that participates in template binding, and the other loosely bound in the beta subunit, the subunit that participates in substrate binding. X-ray absorption studies of these zinc sites in the native protein and of the zinc site in the beta' subunit after removal of the zinc in the beta subunit site by p-(hydroxymercuri)benzenesulfonate (Giedroc, D. P., and Coleman, J. E. (1986) Biochemistry 25, 4969-4978) indicate that both zinc sites have octahedral coordination. The zinc in the beta' subunit site has four sulfur ligands at an average distance of 2.36 +/- 0.02 A and two oxygen (or nitrogen) ligands at an average distance of 2.23 +/- 0.02 A. The beta subunit zinc site has five sulfur ligands at an average distance of 2.38 +/- 0.01 A and one histidine nitrogen ligand at 2.14 +/- 0.02 A. These results are in general agreement with earlier biochemical and spectroscopic studies.     

Molecular dissection of cholinergic binding sites: how do snakes escape the effect of their own toxins?

Snakes have evolved a novel binding site demonstrating selective biorecognition. The snake nicotinic acetylcholine receptor is sensitive to acetylcholine while resistant to the effect of the lethal neurotoxins secreted in their own venom. By subjecting recombinant binding sites to point mutagenesis, biochemical analyses and NMR spectroscopy the binding characteristics of three cholinergic ligands have been measured. The amino acid residue at position 189 has been found to be of particular importance to toxin binding.     

Molecular probes for the cannabinoid receptors

Cannabinoids produce most of their biochemical and pharmacological effects by interacting with CB1 and CB2 cannabinoid receptors, both of which are G-protein coupled membrane-bound functional proteins. CB1 is found in the central nervous system and in a variety of other organs including heart, vascular endothelium, uterus, vas deferens, testis and small intestine. Conversely, the CB2 receptor appears to be associated exclusively with the immune system and is found in the periphery of the spleen and other cells associated with immunochemical functions. Although both CB1 and CB2 have been cloned and the primary sequences are known, their three dimensional structures and the amino acid residues at the active site, critical for ligand recognition, binding and activation have not been characterized. In the absence of any X-ray crystallographic and NMR data, information on the structural requirements for ligand-receptor interactions is obtained with the help of suitably designed molecular probes. These ligands either interact with the receptor in a reversible fashion (reversible probes) or, alternatively, attach at or near the receptor active site with the formation of a covalent bond (irreversible probes). Subsequently, information related to ligand binding and receptor activation is further amplified with the help of receptor mutants and computer modeling. This review focuses on molecular probes related to the classical and non-classical cannabinoids that have been reported since the discovery of the first cannabinoid receptor over a decade ago.     

Design, synthesis, and structure-affinity relationship studies in NK1 receptor ligands based on azole-fused quinolinecarboxamide moieties

The substituent in position 2 of the quinoline nucleus of NK(1) receptor ligands 5 has been constrained into different five-membered heterocyclic moieties in order to obtain information on the binding site pocket interacting with this apparently critical portion of ligands 5. This structure-affinity relationship study led to the discovery of novel tricyclic NK(1) receptor ligands 6 showing affinity in the nanomolar range to the sub-micromolar one. The systematic structure variation suggests that electronic features of the tricyclic moiety play a role in modulating the interaction of these amide derivatives with their receptor.     

Modeling the epidermal growth factor -- epidermal growth factor receptor l2 domain interaction: implications for the ligand binding process

Signaling from the epidermal growth factor (EGF) receptor is triggered by the binding of ligands such as EGF or transforming growth factor alpha (TGF-alpha) and subsequent receptor dimerization. An understanding of these processes has been hindered by the lack of structural information about the ligand-bound, dimerized EGF receptor. Using an NMR-derived structure of EGF and a homology model of the major ligand binding domain of the EGF receptor and experimental data, we modeled the binding of EGF to this EGF receptor fragment. In this low resolution model of the complex, EGF sits across the second face of the EGF receptor L2 domain and EGF residues 10-16, 36-37, 40-47 bind to this face. The structural model is largely consistent with previously published NMR data describing the residues of TGF-alpha which interact strongly with the EGF receptor. Other EGF residues implicated in receptor binding are accounted by our proposal that the ligand binding is a two-step process with the EGF binding to at least one other site of the receptor. This three-dimensional model is expected to be useful in the design of ligand-based antagonists of the receptor.     

Active site of mu-conotoxin GIIIA, a peptide blocker of muscle sodium channels.

The amino acid sequence of mu-conotoxin GIIIA (otherwise called geographutoxin I), a peptide having 22 amino acid residues with three disulfide bridges, was modified by replacing each residue with Ala or Lys to elucidate its active center for blocking sodium channels of skeletal muscle. NMR and CD spectra were virtually identical between native and modified toxins, indicating the similarity of their conformation including disulfide bridges. The inhibitory effect of these modified peptides on twitch contractions of the rat diaphragm showed that Arg at the 13th position and the basicity of the molecule are crucial for the biological action. The segment Lys11-Asp12-Arg13 has been reported to be flexible (Lancelin, J.-M., Kohda, D., Tate, S., Yanagawa, Y., Abe, T., Satake, M., and Inagaki, F. (1991) Biochemistry, in press), and this may represent a clue for the subtle fit of Arg13 to the specific site of sodium channels. Since known ligands to sodium channels, such as tetrodotoxin, anthopleulin-A, etc., contain guanidino groups as a putative binding moiety, Arg may be a general residue for peptide toxins to interact with the receptor site on sodium channels.     

Novel 3-iodo-8-ethoxypyrazolo[5,1-c][1,2,4]benzotriazine 5-oxide as promising lead for design of alpha5-inverse agonist useful tools for therapy of mnemonic damage

The synthesis and the binding study of new 3-iodiopyrazolo[5,1-c][1,2,4] benzotriazine 5-oxides 8-alkyloxy substituted are reported. The replacement at position 3 with an iodine atom, with respect to substituents capable to form a three centered hydrogen bond and/or to form pi-pi stacking interaction with receptor protein, gave high affinity ligands, independently of the 8-alkyloxy substituent. High-affinity ligands were studied in mice in vivo for their pharmacological effects, considering five potential benzodiazepine actions: anxiolytic-like effects, motor coordination, anticonvulsant action, mouse learning and memory impairment, and ethanol-potentiating action. Compounds 5c and 5'c have an inverse agonist profile and for the first time is evidenced a pro-mnemonic activity. These compounds were evaluated also for their binding at Benzodiazepine site on GABA(A) receptor complex (GABA(A)/BzR complex) subtype to evaluate their subtype selectivity.     

Computational chemistry approaches to drug discovery in signal transduction

The advent of therapeutic strategies aimed at targeting specific macromolecular components of deregulated signaling pathways associated with particular disease states has given rise to the idea that it should be possible to design ligands as drug candidates to these targets from first principles. This concept has been beckoning for a long time but structure-based ligand design only became feasible once it was possible to determine the 3-D structures of molecular targets at atomic resolution. However, structure-based design turned out to be difficult, chiefly because under physiological conditions both receptors and ligands are not static but they behave dynamically. While it is possible to design ligands with high steric and electronic complementarity to a receptor site, it is always uncertain how biologically relevant the assumed conformations of both ligand and receptor actually are. The fact that it remains beyond our current abilities to predict with sufficient accuracy the affinity between hypothetical ligand and receptor poses is in part connected with this problem and continues to confound the reliable prediction of drug-like ligands for therapeutic targets. Nevertheless, significant progress has been made and so-called virtual screening methods that use computational methods to dock candidate ligands into receptor sites and to score the resulting complexes are now used routinely as one of the components in drug discovery screening campaigns. Here an overview is given of the underlying principles, implementations, and applications of structure-guided computational design technologies. Although the emphasis is on receptor-based strategies, mention will also be made of some of the more established ligand-based approaches, such as similarity analyses and quantitative structure-activity relationship methods.     

NMR screening in drug discovery

NMR methods in drug discovery have traditionally been used to obtain structural information for drug targets or target-ligand complexes. Recently, it has been shown that NMR may be used as an alternative approach for identification of ligands that bind to protein drug targets, shifting the emphasis of many NMR laboratories towards screening and design of potential drug molecules, rather than structural characterization.     

Computational approaches to understand alpha-conotoxin interactions at neuronal nicotinic receptors.

Recent and increasing use of computational tools in the field of nicotinic receptors has led to the publication of several models of ligand-receptor interactions. These models are all based on the crystal structure at 2.7 A resolution of a protein related to the extracellular N-terminus of nicotinic acetylcholine receptors (nAChRs), the acetylcholine binding protein. In the absence of any X-ray or NMR information on nAChRs, this new structure has provided a reliable alternative to study the nAChR structure. We are now able to build homology models of the binding domain of any nAChR subtype and fit in different ligands using docking programs. This strategy has already been performed successfully for the docking of several nAChR agonists and antagonists. This minireview focuses on the interaction of alpha-conotoxins with neuronal nicotinic receptors in light of our new understanding of the receptor structure. Computational tools are expected to reveal the molecular recognition mechanisms that govern the interaction between alpha-conotoxins and neuronal nAChRs at the molecular level. An accurate determination of their binding modes on the neuronal nAChR may allow the rational design of alpha-conotoxin-based ligands with novel nAChR selectivity.     

Search for invisible binding sites of low-molecular-weight compounds on protein molecules and prediction of inhibitory activity

Molecular Biology - Current computational methods have not been able to discover an unknown site for low-molecular-weight ligands on a protein receptor and predict parameters of their interaction...     

Novel potent 5-HT(3) receptor ligands based on the pyrrolidone structure. Effects of the quaternization of the basic nitrogen on the interaction with 5-HT(3) receptor

The results of a comprehensive structure-affinity relationship study on the effect of the quaternization (i.e., N-methylation) of structurally different ligands in the classes of tropane and quinuclidine derivatives are described. This study shows that the effects of the quaternization of the basic nitrogen of these 5-HT(3) receptor ligands appear to be strictly structure-dependent suggesting that different binding modes are operative at 5-HT(3) receptor binding site. The different effect of the quaternization of the basic nitrogen of structurally different ligands were rationalized in terms of the interaction with the receptor by means of the combined use of experimental techniques (X-ray diffraction and NMR studies) and computational simulation studies.     

The two NK-1 binding sites correspond to distinct, independent, and non-interconvertible receptor conformational states as confirmed by plasmon-waveguide resonance spectroscopy

Two nonstoichiometric ligand binding sites have been previously reported for the NK-1 receptor, with the use of classical methods (radioligand binding and second messenger assays). The most populated (major, NK-1M) binding site binds substance P (SP) and is related to the adenylyl cyclase pathway. The less populated (minor, NK-1m) binding site binds substance P, C-terminal hexa- and heptapeptide analogues of SP, and the NK-2 endogenous ligand, neurokinin A, and is coupled to the phospholipase C pathway. Here, we have examined these two binding sites with plasmon-waveguide resonance (PWR) spectroscopy that allows the thermodynamics and kinetics of ligand-receptor binding processes and the accompanying structural changes of the receptor to be monitored, through measurements of the anisotropic optical properties of lipid bilayers into which the receptor is incorporated. The binding of the three peptides, substance P, neurokinin A, and propionyl[Met(O(2))(11)]SP(7-11), to the partially purified NK-1 receptor has been analyzed by this method. Substance P and neurokinin A bind to the reconstituted receptor in a biphasic manner with two affinities (K(d1) = 0.14 +/- 0.02 nM and K(d2) = 1.4 +/- 0.18 nM, and K(d1) = 5.5 +/- 0.7 nM and K(d2) = 620 +/- 117 nM, respectively), whereas only one binding affinity (K(d) = 5.5 +/- 0.4 nM) could be observed for propionyl[Met(O(2))(11)]SP(7-11). Moreover, binding experiments in which one ligand was added after another one has been bound to the receptor have shown that the binding of these ligands to each binding site was unaffected by the fact that the other site was already occupied. These data strongly suggest that these two binding sites are independent and non-interconvertible on the time scale of these experiments (1-2 h).     

The interaction of the trp repressor from Escherichia coli with L-tryptophan and indole propanoic acid

The binding of the corepressor, L-tryptophan, and an inducer, indole propanoic acid, to the trp repressor from Escherichia coli was studied by absorbance, fluorescence, circular dichroic and proton NMR spectroscopy. The two ligands bind to the same site on the repressor in the same orientation; they are molecular competitors. The binding site is of relatively low polarity and contains at least one methyl group that lies 0.3 nm over the indole moiety near the C5 proton of the bound ligand, and an aromatic residue, probably tyrosine. The dissociation constant was determined as a function of temperature and pH. At 25 degrees C in 0.1 M phosphate buffer, pH 7.6, the dissociation constant is 18 +/- 2 microM for both ligands. In the same buffer system, the van't Hoff enthalpy for dissociation is 35.5 +/- 1 kJ/mol for tryptophan, and 30.5 +/- 2 kJ/mol for indole propanoic acid. The affinity of the repressor for indole propanoic acid is independent of pH in the range 7 less than 10, but decreases four fold for tryptophan in the same range. The amino group of tryptophan makes a significant contribution to its binding affinity. Difference NMR spectra showed that there are few changes of protein resonances on binding ligands. The NMR signals of the bound resonances were assigned by difference and nuclear Overhauser effect spectroscopy. The properties of the bound resonances are consistent with the ligands being largely immobilised within the binding site. The difference spectra, and the known functional differences of the two ligands, suggest that tryptophan induces a slightly different conformational state in the repressor from that induced by indole propanoic acid. There is no evidence for a global transition. The rate of dissociation of ligands is relatively large, being in the range 400-600 s-1.     

Site of action of a pentapeptide agonist at the glucagon-like peptide-1 receptor. Insight into a small molecule agonist-binding pocket

The development of small molecule agonists for class B G protein-coupled receptors (GPCRs) has been quite challenging. With proof-of-concept that exenatide, the parenterally administered peptide agonist of the glucagon-like peptide-1 (GLP1) receptor, is an effective treatment for patients with diabetes mellitus, the development of small molecule agonists could have substantial advantages. We previously reported a lead for small molecule GLP1 receptor agonist development representing the pentapeptide NRTFD. In this work, we have prepared an NRTFD derivative incorporating a photolabile benzoylphenylalanine and used it to define its site of action. This peptide probe was a full agonist with potency similar to NRTFD, which bound specifically and saturably to a single, distinct site within the GLP1 receptor. Peptide mapping using cyanogen bromide and endoproteinase Lys-C cleavage of labeled wild type and M397L mutant receptor constructs identified the site of covalent attachment of NRTFD within the third extracellular loop above the sixth transmembrane segment (TM6). This region is the same as that identified using an analogous photolabile probe based on secretin receptor sequences, and has been shown in mutagenesis studies to be important for natural agonist action of several members of this family. While these observations suggest that small molecule ligands can act at a site bordering the third extracellular loop to activate this class B GPCR, the relationship of this site to the site of action of the amino-terminal end of the natural agonist peptide is unclear.     

Dissection of RAP-LRP interactions: binding of RAP and RAP fragments to complement-like repeats 7 and 8 from ligand binding cluster II of LRP

The receptor associated protein (RAP) is a three domain 38kDa ER-resident chaperone that helps folding of LRP and other LDL receptor family members and prevents premature binding of protein ligands. It competes strongly with all known LRP ligands. To further understanding of the specificity of RAP-LRP interactions, the binding of RAP and RAP fragments to two domains (CR7-CR8) from one of the main ligand-binding regions of LRP has been examined by 2D HSQC NMR spectroscopy and isothermal titration calorimetry. We found that RAP contains two binding sites for CR7-CR8, with the higher affinity site (K(d) approximately 1microM) located in the C-terminal two-thirds and the weaker site (K(d) approximately 5microM) in the N-terminal third of RAP. Residues from both CR7 and CR8 are involved in binding at each RAP site. The presence of more than one binding site on RAP for CR domains from LRP, together with the previous demonstration by others that RAP can bind to CR5-CR6 with comparably low affinities suggest an explanation for the dual roles of RAP as a folding chaperone and a tight competitive inhibitor of ligand binding.