Sauvagine analogs selective for corticotropin releasing factor 2 receptor: effect of substitutions at positions 35 and 39 on CRF2R selectivity

Corticotropin releasing factor 2 receptor selective analogs of the amphibian peptide sauvagine, a member of the corticotropin releasing factor (CRF) peptide family, have therapeutic potential for the treatment of skeletal muscle atrophy. Previously, we demonstrated that [P11X12X13]Svg peptides have improved CRF2R selectivity, although not to the level of CRF2R selective hormones such as urocortin 2 and urocortin 3. Since we also demonstrated a potential for improvement in selectivity of sauvagine by modifications of residues 35 and 39, we investigated substitutions of these amino acids in selected [P11X12X13]Svg peptides. We have observed that substitution of Arg35 in sauvagine to Ala35 (the amino acid found in all CRF2R selective agonists), increased the selectivity of [P11, X12, X13]Svg analogs. In contrast, substitution of Asp39 in sauvagine to Ala39 (also the amino acid found in all CRF2R selective agonists) did not further increase the selectivity of [P11, X12, X13, A35]Svg analogs. Thus, the residues 35 along with 11, 12, and 13 in sauvagine represent important sites for improving CRF2R selectivity.     

Differential responsiveness of CRF receptor subtypes to N-terminal truncation of peptidic ligands

The role of the N-terminal domains of corticotropin-releasing factor (CRF) and CRF-like peptides in receptor subtype selectivity, ligand affinity and biological potency was investigated. Therefore, human CRF(12-41), human URP(12-38) and antisauvagine-30 (aSvg) were N-terminally prolonged by consecutive addition of one or two amino acids. The peptides obtained were tested for their binding affinities to rat CRF1 and murine CRF(2beta) receptor, and their capability to stimulate cAMP-release by HEK cells producing either receptor.It was observed that human CRF N-terminally truncated by eight residues was bound with high affinity to CRF2 receptor (Ki=5.4nM), whereas affinity for CRF1 receptor was decreased (Ki=250 nM). A similar shift of affinity was found with sauvagine (Svg) analogs. Truncation of human URP analogs did not affect their preference for CRF(2beta) receptor, but reduced their affinity. Changes in affinity were positively correlated with changes in potency. These results indicated that CRF1 receptor was more stringent in its structural requirements for ligands to exhibit high affinity binding than CRF(2beta) receptor.     

Impact of N-terminal domains for corticotropin-releasing factor (CRF) receptor-ligand interactions

The large extracellular N-terminal domains (NTs) of class B G protein-coupled receptors serve as major ligand binding sites. However, little is known about the ligand requirements for interactions with these receptor domains. Recently, we have shown that the most potent CRF receptor agonist urocortin 1 (Ucn1) has two segregated receptor binding sites Ucn1(1-21) and Ucn1(32-40). For locating the receptor domains interacting with these two sites, we have investigated the binding of appropriate Ucn1 analogues to the receptor N-termini compared to the corresponding full-length receptors. For this purpose receptor NTs of CRF(rat) subtypes 1 and 2(alpha) without their signal sequences were overexpressed in Escherichia coli and folded in vitro. For CRF2(a)-rNT, which bears five cysteine residues (C2-C6), the disulfide arrangement C2-C5 and C4-C6 was found, leaving C3 free. This is consistent with the disulfide pattern of CRF1-rNT, which has six cysteines and in which C1 is paired with C3. Binding studies of N-terminally truncated or C-terminally modified Ucn1 analogues demonstrate that it is the C-terminal part, Ucn1(11-40), that binds to receptor NT, indicating a two-domain binding mechanism for Ucn binding to receptor NT. Since the binding of Ucn1 to the juxtamembrane domain has been shown to be segregated from binding to the receptor N-terminus [Hoare et al. (2004) Biochemistry 43, 3996-4011], a third binding domain should exist, probably comprising residues 8-10 of Ucn, which particularly contribute to a high-affinity binding to full-length receptors but not to receptor NT.     

Development of a selective photoactivatable antagonist for corticotropin-releasing factor receptor, type 2 (CRF2).

A novel photoactivatable analog of antisauvagine-30 (aSvg-30), a specific antagonist for corticotropin-releasing factor (CRF) receptor, type 2 (CRF2), has been synthesized and characterized. The N-terminal amino-acid d-Phe in aSvg-30 [d-Phe11,His12]Svg(11-40) was replaced by a phenyldiazirine, the 4-(1-azi-2,2,2-trifluoroethyl)benzoyl (ATB) residue. The photoactivatable aSvg-30 analog ATB-[His12]Svg was tested for its ability to displace [125I-Tyr0]oCRF or [125I-Tyr0]Svg from membrane homogenates of human embryonic kidney (HEK) 293 cells stably transfected with cDNA coding for rat CRF receptor, type 1 (rCRF1) or mouse CRF receptor, type 2beta (mCRF2beta). Furthermore, the ability of ATB-[His12]Svg(12-40) to inhibit oCRF- or Svg-stimulated cAMP production of transfected HEK 293 cells expressing either rCRF1 (HEK-rCRF1 cells) or mCRF2beta (HEK-mCRF2beta cells) was determined. Unlike astressin and photo astressin, ATB-[His12]Svg(12-40) showed high selective binding to mCRF2beta (Ki = 3.1 +/- 0.2 nm) but not the rCRF1 receptor (Ki = 142.5 +/- 22.3 nm) and decreased Svg-stimulated cAMP activity in mCRF2beta-expressing cells in a similar fashion as aSvg-30. A 66-kDa protein was identified by SDS/PAGE, when the radioactively iodinated analog of ATB-[His12]Svg(12-40) was covalently linked to mCRF2beta receptor. The specificity of the photoactivatable 125I-labeled CRF2beta antagonist was demonstrated with SDS/PAGE by the finding that this analog could be displaced from the receptor by antisauvagine-30, but not other unrelated peptides such as vasoactive intestinal peptide (VIP).     

Opioid receptor selectivity of peptide models of beta-endorphin

Two peptides, designed to contain structural models of the proposed hydrophilic linker domain (residues 6-12) and amphiphilic alpha-helical domain (residues 13-29) in beta-endorphin, have been tested for their abilities to mimic the opioid receptor selectivity profile of the natural hormone. In competitive binding assays employing guinea-pig brain membranes, both peptides displayed a much higher affinity for mu- and delta-opioid receptors than for kappa opioid receptors. Relative to beta-endorphin, the peptide models were 2-3 times more potent in the mu and kappa receptor binding assays, and about equipotent in the delta receptor binding assay. In guinea-pig ileum assays, one peptide was equipotent to beta-endorphin and the other was twice as potent. Like beta-endorphin, their actions on this tissue were highly sensitive to naloxone antagonism, indicating that they were mediated by mu receptors and not kappa receptors. In view of the design of the two peptide models, and their minimal homology to the natural hormone, these results provide additional evidence in support to our proposal for the functional conformation of beta-endorphin.     

Histidine 186 of the nicotinic acetylcholine receptor alpha subunit requires the presence of the 192-193 disulfide bridge to interact with alpha-bungarotoxin

We have previously shown that two histidine residues of the nicotinic acetylcholine receptor are relevant for alpha-bungarotoxin binding. This paper studies: (1) the interaction between alpha-bungarotoxin and the peptide alpha173-202--synthesized according to the sequence of the Torpedo californica receptor alpha subunit--and between the toxin and the same peptide containing His186 modified with ethoxyformic anhydride or substituted by Ala; (2) the influence of the presence of Cys192-Cys193 disulfide bridge on such interactions. Solid-phase and in-solution competition assays were performed: ethoxyformylation of His186 or its substitution by Ala led to a significant drop in the toxin binding capacity only for peptides containing the bridge. Circular dichroism and fourth derivate spectra of all peptides were also analyzed. Results strongly indicate the involvement of His186 in the toxin binding to those peptides with the bridge--also present in the native receptor molecules--but not to their reduced forms; on the other hand, they give further support to the already established premise that, though the bridge does not participate directly in receptor-toxin binding, its presence is relevant to define the appropriate conformation of the interaction area.     

Peptide ligand binding properties of the corticotropin-releasing factor (CRF) type 2 receptor: pharmacology of endogenously expressed receptors, G-protein-coupling sensitivity and determinants of CRF2 receptor selectivity

The CRF2 receptor is involved in stress responses, cardiovascular function and gastric motility. Endogenous agonists (urocortin (UCN) 2, UCN 3) and synthetic antagonists (astressin2-B, antisauvagine-30) are selective for CRF2 over the CRF1 receptor. Peptide ligand binding properties of the CRF2 receptor require further investigation, including ligand affinity for endogenously expressed receptors, the effect of receptor-G-protein coupling on ligand affinity, and the molecular basis of ligand selectivity. Ligand affinity for rat CRF(2a) in olfactory bulb and CRF(2b) in A7r5 cells was similar to that for the cloned human CRF(2a) receptor (within three-fold), except for oCRF (9.4- and 5.4-fold higher affinity in olfactory bulb and A7r5 cells, respectively). Receptor-G-protein uncoupling reduced agonist affinity only 1.2- to 6.5-fold (compared with 92-1300-fold for the CRF1 receptor). Ligand selectivity mechanisms were investigated using chimeric CRF2/CRF1 receptors. The juxtamembrane receptor domain determined selectivity of antisauvagine-30, the N-terminal-extracellular domain contributed to selectivity of UCN 3, and both domains contributed to selectivity of UCN 2 and astressin2-B. Therefore ligands differ in the contribution of receptor domains to their selectivity, and CRF2-selective antagonists bind the juxtamembrane domain. These findings will be important for identifying the CRF2 receptor in tissues and for developing ligands targeting the receptor, both of which will be useful in identifying the emerging physiological functions of the CRF2 receptor.     

Structural basis for hormone recognition by the Human CRFR2{alpha} G protein-coupled receptor

The mammalian corticotropin releasing factor (CRF)/urocortin (Ucn) peptide hormones include four structurally similar peptides, CRF, Ucn1, Ucn2, and Ucn3, that regulate stress responses, metabolism, and cardiovascular function by activating either of two related class B G protein-coupled receptors, CRFR1 and CRFR2. CRF and Ucn1 activate both receptors, whereas Ucn2 and Ucn3 are CRFR2-selective. The molecular basis for selectivity is unclear. Here, we show that the purified N-terminal extracellular domains (ECDs) of human CRFR1 and the CRFR2α isoform are sufficient to discriminate the peptides, and we present three crystal structures of the CRFR2α ECD bound to each of the Ucn peptides. The CRFR2α ECD forms the same fold observed for the CRFR1 and mouse CRFR2β ECDs but contains a unique N-terminal α-helix formed by its pseudo signal peptide. The CRFR2α ECD peptide-binding site architecture is similar to that of CRFR1, and binding of the α-helical Ucn peptides closely resembles CRF binding to CRFR1. Comparing the electrostatic surface potentials of the ECDs suggests a charge compatibility mechanism for ligand discrimination involving a single amino acid difference in the receptors (CRFR1 Glu104/CRFR2α Pro-100) at a site proximate to peptide residue 35 (Arg in CRF/Ucn1, Ala in Ucn2/3). CRFR1 Glu-104 acts as a selectivity filter preventing Ucn2/3 binding because the nonpolar Ala-35 is incompatible with the negatively charged Glu-104. The structures explain the mechanisms of ligand recognition and discrimination and provide a molecular template for the rational design of therapeutic agents selectively targeting these receptors.     

Structure-function relationships of curaremimetic neurotoxin loop 2 and of a structurally similar segment of rabies virus glycoprotein in their interaction with the nicotinic acetylcholine receptor

Peptides corresponding to portions of curaremimetic neurotoxin loop 2 and to a structurally similar segment of rabies virus glycoprotein were synthetically modified in order to gain information on structure-function relationships of neurotoxin loop 2 interactions with the acetylcholine receptor. Binding of synthetic peptides to the acetylcholine receptor of Torpedo electric organ membranes was assessed by measuring their ability to inhibit the binding of 125I-alpha-bungarotoxin to the receptor. The peptides showing the highest affinity for the receptor were a peptide corresponding to the sequence of loop 2 (residues 25-44) of Ophiophagus hannah (king cobra) toxin b (IC50 = 5.7 x 10(-6) M) and the structurally similar segment (residues 173-203) of CVS rabies virus glycoprotein (IC50 = 2.6 x 10(-6) M). These affinities were comparable to those of d-tubocurarine (IC50 = 3.4 x 10(-6) M) and suberyldicholine (IC50 = 2.5 x 10(-6) M). These results demonstrate the importance of loop 2 in the neurotoxin interaction with the receptor. N- and C-terminal deletions of the loop 2 peptides and substitution of residues invariant or highly conserved among neurotoxins were performed in order to determine the role of individual residues in binding. Residues 25-40 are the most crucial in the interaction with the acetylcholine receptor. Modifications involving Lys-27, Trp-29, Phe-33, Arg-37, and Gly-38 reduced affinity of binding. R37D and F33T modifications reduced the affinity of alpha-bungarotoxin residues 28-40 by an order of magnitude. Arg-37 may correspond to the positively charged quaternary ammonium group and Phe-33 to the hydrophobic acetyl methyl group of acetylcholine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Novel high-affinity photoactivatable antagonists of corticotropin-releasing factor (CRF) photoaffinity labeling studies on CRF receptor, type 1 (CRFR1).

Novel photoactivatable antagonists of human/rat corticotropin-releasing factor (h/rCRF) have been synthesized and characterized. The N-terminal amino acid D-phenylalanine in astressin ?cyclo(30-33) [D-Phe12, Nle21,38, Glu30, Lys33]h/rCRF-(12-41)?, a potent CRF peptide antagonist, was replaced by a phenyldiazirine, the 4-(1-azi-2,2,2-trifluoroethyl)benzoyl (ATB) residue. Additionally, His32 of astressin was substituted by either alanine or tyrosine for specific radioactive labeling with 125I at either His13 or Tyr32, respectively. The photoactivatable CRF antagonists were tested for their ability to displace 125I-labeled Tyr0 ovine CRF ([125I-labeled Tyr0]oCRF) in binding experiments and to inhibit oCRF-stimulated adenylate cyclase activity in human embryonic kidney (HEK) 293 cells, permanently transfected with cDNA coding for rat CRF receptor, type 1 (rCRFR1) or human Y-79 retinoblastoma cells known to carry endogenous functional human CRFR1 (hCRFR1). ATB-cyclo(30-33)[Nle21,38, Glu30, Ala32, Lys33]h/rCRF-(13-41) (compound 1) was found to bind with higher affinity to rat or human CRFR1 when compared with ATB-cyclo(30-33)[Nle21,38, Glu30, Tyr32, Lys33]h/rCRF-(13-41) (compound 2) and exhibited higher inhibition of oCRF-stimulated cAMP accumulation in HEK 293 cells stably transfected with cDNA coding for rCRFR1 (HEK-rCRFR1 cells) or Y-79 cells. A highly glycosylated, 66-kDa protein was identified with SDS/PAGE, when the radioactively iodinated compounds 1 or 2 were covalently linked to rCRFR1. The specificity of the photoactivatable 125I-labeled CRF antagonists was demonstrated with SDS/PAGE by the finding that these analogs could be displaced from the receptor by their corresponding nonlabeled form, but not other unrelated peptides such as vasoactive intestinal peptide. The observed molecular size of the receptor was in agreement with the size of CRFR1 found in rat pituitary (66 kDa), but was significantly larger than the size of CRFR1 found in rat cerebellum and olfactory bulb (53 kDa).     

The brain corticotropin-releasing factor (CRF) receptor is of lower apparent molecular weight than the CRF receptor in anterior pituitary. Evidence from chemical cross-linking studies

The ligand binding subunits of the corticotropin-releasing factor (CRF) receptors in brain and anterior pituitary of a number of species have been identified by chemical affinity cross-linking using the homobifunctional cross-linking agent disuccinimidyl suberate and 125I-Tyr0-oCRF (ovine CRF). In homogenates of rat, monkey, and human cerebral cortex, 125I-Tyr0-oCRF was covalently incorporated into a protein of Mr = 58,000. Under identical conditions in the anterior pituitary of rat, monkey, cow, and pig, 125I-Tyr0-oCRF was incorporated into a protein of apparent Mr = 75,000. The specificity of the labeling was typical of the CRF binding site since both the cerebral cortex- and pituitary-labeled proteins exhibited the appropriate pharmacological rank order profile characteristic of the CRF receptor (Nle21,Tyr32-oCRF approximately equal to rat/human CRF approximately equal to ovine CRF approximately equal to alpha-helical CRF(6-41) greater than alpha-helical oCRF(9-41) greater than or equal to oCRF(7-41) greater than rat/human CRF(1-20) approximately equal to vasoactive intestinal peptide). In addition to the major labeled proteins, 125I-Tyr0-oCRF was incorporated into higher molecular weight peptides which may represent precursors and into lower molecular weight components which may represent fragments of the major labeled proteins or altered forms of the CRF binding subunit. In summary, these data indicate a heterogeneity between brain and pituitary CRF receptors with the ligand binding subunit of the brain CRF receptor residing on a Mr = 58,000 protein, while in the anterior pituitary, the identical binding subunit resides on a protein of apparent Mr = 75,000.     

The first selective agonist for the neuropeptide YY5 receptor increases food intake in rats

The first Y(5) receptor-selective analog of neuropeptide Y (NPY), [Ala(31),Aib(32)]NPY, has been developed and biologically characterized. Using competition binding assays on cell lines that express different Y receptors, we determined the affinity of this analog to be 6 nm at the human Y(5) receptor, >500 nm at the Y(1) and Y(2) receptors, and >1000 nm at the Y(4) receptor. Activity studies performed in vitro using a cAMP enzyme immunoassay, and in vivo using food intake studies in rats, showed that the peptide acted as an agonist. Further peptides obtained by the combination of the Ala(31)-Aib(32) motif with chimeric peptides containing segments of NPY and pancreatic polypeptide displayed the same selectivity and even higher affinity (up to 0.2 nm) for the Y(5) receptor. In vivo administration of the new Y(5) receptor-selective agonists significantly stimulated feeding in rats. The NMR solution structures of NPY and [Ala(31),Aib(32)]NPY showed a different conformation in the C-terminal region, where the alpha-helix of NPY was substituted by a more flexible, 3(10)-helical turn structure.     

Molecular modelling and site-directed mutagenesis of human GALR1 galanin receptor defines determinants of receptor subtype specificity

Human galanin is a 30 amino acid neuropeptide that elicits a range of biological activities by interaction with G protein-coupled receptors. We have generated a model of the human GALR1 galanin receptor subtype (hGALR1) based on the alpha carbon maps of frog rhodopsin and investigated the significance of potential contact residues suggested by the model using site-directed mutagenesis. Mutation of Phe186 within the second extracellular loop to Ala resulted in a 6-fold decrease in affinity for galanin, representing a change in free energy consistent with hydrophobic interaction. Our model suggests interaction between Phe186 of hGALR1 and Ala7 or Leu11 of galanin. Receptor subtype specificity was investigated by replacement of residues in hGALR1 with the corresponding residues in hGALR2 and use of the hGALR2-specific ligands hGalanin(2-30) and [D-Trp2]hGalanin(1-30). The His267Ile mutant receptor exhibited a pharmacological profile corresponding to that of hGALR1, suggesting that His267 is not involved in a receptor-ligand interaction. The mutation Phe115Ala resulted in a decreased binding affinity for hGalanin and for hGALR2-specific analogues, indicating Phe115 to be of structural importance to the ligand binding pocket of hGALR1 but not involved in direct ligand interaction. Analysis of Glu271Trp suggested that Glu271 of hGALR1 interacts with the N-terminus of galanin and that the Trp residue in the corresponding position in hGALR2 is involved in receptor subtype specificity of binding. Our model supports previous reports of Phe282 of hGALR1 interacting with Trp2 of galanin and His264 of hGALR1 interacting with Tyr9 of galanin.     

The receptor-binding sequence of urokinase. A biological function for the growth-factor module of proteases

Previous studies have shown that the region of human urokinase-type plasminogen activator (uPA) responsible for receptor binding resides in the amino-terminal fragment (ATF, residues 1-135) (Stoppelli, M.P., Corti, A., Soffientini, A., Cassani, G., Blasi, F., and Assoian, R.K. (1985) Proc. Natl. Acad. Sci. U.S. A. 82, 4939-4943). The area within ATF responsible for specific receptor binding has now been identified by the ability of different synthetic peptides corresponding to different regions of the amino terminus of uPA to inhibit receptor binding of 125I-labeled ATF. A peptide corresponding to human [Ala19]uPA-(12-32) resulted in 50% inhibition of ATF binding at 100 nM. Peptides uPA-(18-32) and [Ala13]uPA-(9-20) inhibit at 100 and 2000 microM, respectively. The human peptide uPA-(1-14) and the mouse peptide [Ala20]uPA-(13-33) have no effect on ATF receptor binding. This region of uPA is referred to as the growth factor module since it shares partial amino acid sequence homology (residues 14-33) to epidermal growth factor (EGF). Furthermore, this region of EGF is responsible for binding of EGF to its receptor (Komoriya, A. Hortsch, M., Meyers, C., Smith, M., Kanety, H., and Schlessinger, J. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 1351-1355). However, EGF does not inhibit ATF receptor binding. Comparison of the sequences responsible for receptor binding of uPA and EGF indicate that the region of highest homology is between residues 13-19 and 14-20 of human uPA and EGF, respectively. In addition, there is a conservation of the spacings of four cysteines in this module whereas there is no homology between residues 20-30 and 21-33 of uPA and EGF. Thus, residues 20-30 of uPA apparently confer receptor binding specificity, and residues 13-19 provide the proper conformation to the adjacent binding region.     

Modifications of the human urocortin 2 peptide that improve pharmacological properties

Recently, we demonstrated that the corticotropin releasing factor 2 receptor agonist, urocortin 2, demonstrated anti-atrophy effects in rodent skeletal muscle atrophy models. Compared to other CRF2R agonists however, the in vivo pharmacological potency of urocortin 2 is poor when it is administered by continuous subcutaneous infusion. Therefore, we attempted to modify the structure of urocortin 2 to improve in vivo efficacy when administered by subcutaneous infusion. By substituting amino acid residues in the linker region of urocortin 2 (residues 22-32), we have demonstrated improved in vivo potency without altering selectivity, probably through reduced CRFBP binding. In addition, attempts to shorten urocortin 2 generally resulted in inactive peptides, demonstrating that the 38 amino acid urocortin 2 peptide is the minimal pharmacophore.     

Synthesis, receptor binding activity and fluorescence property of fluorescent enkephalin analogs containing L-1-pyrenylalanine

The novel fluorescent amino acid, L-1-pyrenylalanine (L-Pya), was prepared by the asymmetric hydrogenation of cyclic dehydrodipeptide. Fluorescent enkephalins containing one or two Pya residues at position 1,4 or 5 of [D-Ala2, Leu5]enkephalin were synthesized by the solution method. Mono-Pya-enkephalins showed strong fluorescence intensities and potent binding affinities with specificity and selectivity for opiate receptors. However, di-Pya-enkephalins showed markedly decreased receptor binding affinities. These results indicate that the incorporation of two Pya residues into enkephalin makes the peptide unable to interact with the opiate receptors, although introduction of one Pya residue is effective to elicit a specific receptor interaction. Di-Pya-enkephalins showed intramolecular excimer spectra, indicating that the peptides are able to take possible folded conformations.     

Synthetic peptides corresponding to sequences of snake venom neurotoxins and rabies virus glycoprotein bind to the nicotinic acetylcholine receptor

Peptides corresponding to portions of loop 2 of snake venom curare-mimetic neurotoxins and to a structurally similar region of rabies virus glycoprotein were synthesized. Interaction of these peptides with purified Torpedo electric organ acetylcholine receptor was tested by measuring their ability to block the binding of 125I-labeled alpha-bungarotoxin to the receptor. In addition, inhibition of alpha-bungarotoxin binding to a 32-residue synthetic peptide corresponding to positions 173-204 of the alpha-subunit was determined. Neurotoxin and glycoprotein peptides corresponding to toxin loop 2 inhibited labeled toxin binding to the receptor with IC50 values comparable to those of nicotine and the competitive antagonist d-tubocurarine and to the alpha-subunit peptides with apparent affinities between those of d-tubocurarine and alpha-cobratoxin. Substitution of neurotoxin residue Arg37, the proposed counterpart of the quaternary ammonium of acetylcholine, with a negatively charged Glu residue reduced the apparent affinity about 10-fold. Peptides containing the neurotoxin invariant residue Trp29 and 10- to 100-fold higher affinities than peptides lacking this residue. These results demonstrate that relatively short synthetic peptides retain some of the binding ability of the native protein from which they are derived, indicating that such peptides are useful in the study of protein-protein interactions. The ability of the peptides to compete alpha-bungarotoxin binding to the receptor with apparent affinities comparable to those of other cholinergic ligands indicates that loop 2 of the neurotoxins and the structurally similar segment of the rabies virus glycoprotein act as recognition sites for the acetylcholine receptor. Invariant toxin residues Arg37 and Trp29 and their viral homologs play important, although not essential, roles in binding, possibly by interaction with complementary anionic and hydrophobic subsites on the acetylcholine receptor. The alpha-subunit peptide most likely contains all of the determinants for binding of the toxin and glycoprotein peptides present on the alpha-subunit, because these peptides bind to the 32-residue alpha-subunit peptide with the same or greater affinity as to the intact subunit.     

Functional evidence for an intramolecular side chain interaction between residues 6 and 10 of receptor-bound parathyroid hormone analogues

The N-terminal domain of PTH(1-34) is critical for PTH-1 receptor (P1R) activation and has been postulated to be alpha-helical when bound to the receptor. We investigated the possibility that the side chains of residues 6 (Gln) and 10 (Gln or Asn) of PTH analogues, which would align on the same face of the predicted alpha-helix, could interact and thereby contribute to the PTH/P1R interaction process. We utilized PTH(1-11), PTH(1-14), and PTH(1-34) analogues substituted with alanine at one or both of these positions and functionally evaluated the peptides in cell lines (HKRK-B7 and HKRK-B28) stably expressing the P1R, as well as in COS-7 cells transiently expressing either the P1R or a P1R construct that lacks the amino-terminal extracellular domain (P1R-DelNt). In HKRK-B7 cells, the single substitutions of Gln(6) --> Ala and Gln(10) --> Ala reduced the cAMP-stimulating potency of [Ala(3),Gln(10),Arg(11)]rPTH(1-11)NH(2) approximately 60- and approximately 2-fold, respectively, whereas the combined Ala(6,10) substitution resulted in a approximately 2-fold gain in potency, relative to the single Ala(6) substitution. Similar effects on P1R-mediated cAMP-signaling potency and P1R-binding affinity were observed for these substitutions in [Aib(1,3),Gln(10),Har(11),Ala(12),Trp(14)]rPTH(1-14)NH(2). Installation of a lactam bridge between the Lys(6) and the Glu(10) side chains of [Ala(3,12),Lys(6),Glu(10),Har(11),Trp(14)]rPTH(1-14)NH(2) increased signaling potency 6-fold, relative to the nonbridged linear analogue. Alanine substitutions at positions 6 and/or 10 of [Tyr(34)]hPTH(1-34)NH(2) did not affect signaling potency nor binding affinity on the intact P1R; however, Ala(6) abolished PTH(1-34) signaling on P1R-DelNt, and this effect was reversed by Ala(10). The overall data support the hypothesis that the N-terminal portion of PTH is alpha-helical when bound to the activation domain of the PTH-1 receptor and they further suggest that intrahelical side chain interactions between residues 6 and 10 of the ligand can contribute to the receptor interaction process.     

Structural determinants for activation or inhibition of ryanodine receptors by basic residues in the dihydropyridine receptor II-III loop

The structures of peptide A, and six other 7-20 amino acid peptides corresponding to sequences in the A region (Thr671- Leu690) of the skeletal muscle dihydropyridine receptor II-III loop have been examined, and are correlated with the ability of the peptides to activate or inhibit skeletal ryanodine receptor calcium release channels. The peptides adopted either random coil or nascent helix-like structures, which depended upon the polarity of the terminal residues as well as the presence and ionisation state of two glutamate residues. Enhanced activation of Ca2+ release from sarcoplasmic reticulum, and activation of current flow through single ryanodine receptor channels (at -40 mV), was seen with peptides containing the basic residues 681Arg Lys Arg Arg Lys685, and was strongest when the residues were a part of an alpha-helix. Inhibition of channels (at +40 mV) was also seen with peptides containing the five positively charged residues, but was not enhanced in helical peptides. These results confirm the hypothesis that activation of ryanodine receptor channels by the II-III loop peptides requires both the basic residues and their participation in helical structure, and show for the first time that inhibition requires the basic residues, but is not structure-dependent. These findings imply that activation and inhibition result from peptide binding to separate sites on the ryanodine receptor.     

Identification of Amino Acids in the N-Terminal Domain of Corticotropin-Releasing Factor Receptor 1 that Are Important Determinants of High-Affinity Ligand Binding

Abstract : The aim of the present study was to identify the N-terminal regions of human corticotropin-releasing factor (CRF) receptor type 1 (hCRF-R1) that are crucial for ligand binding. Mutant receptors were constructed by replacing specific residues in hCRF-R1 with amino acids from the corresponding position in the N-terminal region of the human vasoactive intestinal peptide receptor type 2 (hVIP-R2). In cyclic AMP stimulation and CRF binding assays, it was established that two regions within the N-terminal domain were crucial for the binding of CRF receptor agonists and antagonists : one region mapping to amino acids 43-50 and a second amino acid sequence extending from position 76 to 84 of hCRF-R1. Recently, it was found that the latter sequence plays a very important role in determining the high ligand selectivity of the Xenopus CRF-R1 (xCRF-R1). Replacement of amino acids 76-84 of hCRF-R1 with residues from the same segment of the hVIP-R2 N terminus markedly reduced the binding affinity of CRF ligands. Mutation of Arg⁷⁶ or Asn⁸¹ but not Gly⁸³ of hCRF-R1 to the corresponding amino acids of xCRF-R1 or hVIP-R2 resulted in 100-1,000-fold lower affinities for human/rat CRF, rat urocortin, and astressin. These data underline the importance of the N-terminal domain of CRF-R1 in high-affinity ligand binding.