Selective Penicillamine Substitution Enables Development of a Potent Analgesic Peptide that Acts through a Non-Opioid-Based Mechanism

Venom-derived compounds are of broad interest in neuropharmacology and drug development. α-Conotoxins are small disulfide-containing peptides from Conus snails that target nicotinic acetylcholine receptors (nAChRs) and are in clinical development for non-opioid-based treatment of intractable pain. Although refined by evolution for interaction with target prey receptors, enhancements of pharmacological properties are needed for use in mammalian systems. Therefore, we synthesized analogues of α-conotoxin RgIA using a combination of selective penicillamine substitutions together with natural and non-natural amino acid replacements. This approach resulted in a peptide with 9000-fold increased potency on the human α9α10 nAChR and improved resistance to disulfide shuffling compared to the native peptide. The lead analogue, RgIA-5474, potently blocked α9α10 nAChRs, but not opioid- or other pain-related targets. In addition, RgIA-5474 effectively reversed chemotherapy-induced neuropathic pain.

Cysteine [2,4] Disulfide Bond as a New Modifiable Site of α-Conotoxin TxIB

α-Conotoxin TxIB, a selective antagonist of α6/α3β2β3 nicotinic acetylcholine receptor, could be a potential therapeutic agent for addiction and Parkinson's disease. As a peptide with a complex pharmacophoric conformation, it is important and difficult to find a modifiable site which can be modified effectively and efficiently without activity loss. In this study, three xylene scaffolds were individually reacted with one pair of the cysteine residues ([1,3] or [2,4]), and iodine oxidation was used to form a disulfide bond between the other pair. Overall, six analogs were synthesized with moderate isolated yields from 55% to 65%, which is four times higher than the traditional two-step oxidation with orthogonal protection on cysteines. The cysteine [2,4] modified analogs, with higher stability in human serum than native TxIB, showed obvious inhibitory effect and selectivity on α6/α3β2β3 nicotinic acetylcholine receptors (nAChRs), which was 100 times more than the cysteine [1,3] modified ones. This result demonstrated that the cysteine [2,4] disulfide bond is a new modifiable site of TxIB, and further modification can be a simple and feasible strategy for the exploitation and utilization of α-Conotoxin TxIB in drug discovery.

Chemical Synthesis and NMR Solution Structure of Conotoxin GXIA from Conus geographus

Conotoxins are disulfide-rich peptides found in the venom of cone snails. Due to their exquisite potency and high selectivity for a wide range of voltage and ligand gated ion channels they are attractive drug leads in neuropharmacology. Recently, cone snails were found to have the capability to rapidly switch between venom types with different proteome profiles in response to predatory or defensive stimuli. A novel conotoxin, GXIA (original name G117), belonging to the I₃-subfamily was identified as the major component of the predatory venom of piscivorous Conus geographus. Using 2D solution NMR spectroscopy techniques, we resolved the 3D structure for GXIA, the first structure reported for the I₃-subfamily and framework XI family. The 32 amino acid peptide is comprised of eight cysteine residues with the resultant disulfide connectivity forming an ICK+1 motif. With a triple stranded β-sheet, the GXIA backbone shows striking similarity to several tarantula toxins targeting the voltage sensor of voltage gated potassium and sodium channels. Supported by an amphipathic surface, the structural evidence suggests that GXIA is able to embed in the membrane and bind to the voltage sensor domain of a putative ion channel target.

Synthesis, Pharmacological and Structural Characterization of Novel Conopressins from Conus miliaris

Cone snails produce a fast-acting and often paralyzing venom, largely dominated by disulfide-rich conotoxins targeting ion channels. Although disulfide-poor conopeptides are usually minor components of cone snail venoms, their ability to target key membrane receptors such as GPCRs make them highly valuable as drug lead compounds. From the venom gland transcriptome of Conus miliaris, we report here on the discovery and characterization of two conopressins, which are nonapeptide ligands of the vasopressin/oxytocin receptor family. These novel sequence variants show unusual features, including a charge inversion at the critical position 8, with an aspartate instead of a highly conserved lysine or arginine residue. Both the amidated and acid C-terminal analogues were synthesized, followed by pharmacological characterization on human and zebrafish receptors and structural investigation by NMR. Whereas conopressin-M1 showed weak and only partial agonist activity at hV1bR (amidated form only) and ZFV1a1R (both amidated and acid form), both conopressin-M2 analogues acted as full agonists at the ZFV2 receptor with low micromolar affinity. Together with the NMR structures of amidated conopressins-M1, -M2 and -G, this study provides novel structure-activity relationship information that may help in the design of more selective ligands.

Im10A, a short conopeptide isolated from Conus imperialis and possesses two highly concentrated disulfide bridges and analgesic activity

In the present study, we isolated, synthesized and NMR structurally characterized a novel conopeptide Im10A consisting of 11 amino acids (NTICCEGCMCY-NH2) from Conus imperialis. Unlike other conopeptides with four cysteine residues, Im10A had only two residues in loop 1 and one residue in loop 2 (CC-loop1-C-loop2-C), which formed a stable disulfide connectivity "I-IV, II- III" (framework X) with a type I β-turn. Interestingly, Im10A exhibited 50.7% analgesic activity on rat partial sciatic nerve ligation (PNL) at 2h after Im10A administration. However, 10μM Im10A exhibited no apparent effect on neuronal nicotinic acetylcholine receptor, and it did not target DRG voltage-dependent sodium, potassium and calcium ion channels and opioid receptor. To our knowledge, Im10A had the most concentrated disulfide bridges among conopeptides with four cysteine residues. This finding provided a new motif for the future development of biomimetic compounds.

Antagonist properties of Conus parius peptides on N-methyl-D-aspartate receptors and their effects on CREB signaling

Three members of a family of small neurotoxic peptides from the venom of Conus parius, conantokins (Con) Pr1, Pr2, and Pr3, function as antagonists of N-methyl-D-aspartate receptors (NMDAR). We report structural characterizations of these synthetic peptides, and also demonstrate their antagonistic properties toward ion flow through NMDAR ion channels in primary neurons. ConPr1 and ConPr2 displayed moderate increases in α-helicity after addition of Mg²⁺. Native apo-ConPr3 possessed an α-helical conformation, and the helicity increased only slightly on addition of Mg²⁺. Additionally, these peptides diminished NMDA/Gly-mediated currents and intracellular Ca²⁺ (iCa²⁺) influx in mature rat primary hippocampal neurons. Electrophysiological data showed that these peptides displayed slower antagonistic properties toward the NMDAR than conantokins from other species of cone snails, e.g., ConT and ConG. Furthermore, to demonstrate selectivity of the C. parius-derived conantokins towards specific NMDAR subunits, cortical neurons from GluN2A^-/- and GluN2B^-/- mice were utilized. Robust inhibition of NMDAR-mediated stimulation in GluN2A^-/--derived mouse neurons, as compared to those isolated from GluN2B^-/--mouse brains, was observed, suggesting a greater selectivity of these antagonists towards the GluN2B subunit. These C. parius conantokins mildly inhibited NMDAR-induced phosphorylation of CREB at Ser¹³³, suggesting that the peptides modulated iCa²⁺ entry and, thereby, activation of CREB, a transcription factor that is required for maintaining long-term synaptic activity. Our data mechanistically show that while these peptides effectively antagonize NMDAR-directed current and iCa²⁺ influx, receptor-coupled CREB signaling is maintained. The consequence of sustained CREB signaling is improved neuronal plasticity and survival during neuropathologies.

The three-dimensional solution structure of mini-M conotoxin BtIIIA reveals a disconnection between disulfide connectivity and peptide fold

Conotoxins are bioactive peptides from the venoms of marine snails and have been divided into several superfamilies based on homologies in their precursor sequences. The M-superfamily conotoxins can be further divided into five branches based on the number of residues in the third loop of the peptide sequence. Recently two M-1 branch conotoxins (tx3a and mr3e) with a C1-C5, C2-C4, C3-C6 disulfide connectivity and one M-2 branch conotoxin (mr3a) with a C1-C6, C2-C4, C3-C5 disulfide connectivity were described. Here we report the disulfide connectivity, chemical synthesis and the three-dimensional NMR structure of the novel 14-residue conotoxin BtIIIA, extracted from the venom of Conus betulinus. It has the same disulfide connectivity as mr3a, which puts it in the M-2 branch conotoxins but has a distinctly different structure from other M-2 branch conotoxins. 105 NOE distance restraints and seven dihedral angle restraints were used for the structure calculations. The three-dimensional structure was determined with CYANA based on torsion angle dynamics and refinement in a water solvent box was carried out with CNS. Fifty structures were calculated and the 20 lowest energy structures superimposed with a RMSD of 0.49±0.16 Å. Even though it has the M-2 branch disulfide connectivity, BtIIIA was found to have a 'flying bird' backbone motif depiction that is found in the M-1 branch conotoxin mr3e. This study shows that conotoxins with the same cysteine framework can have different disulfide connectivities and different peptide folds.

The chemical synthesis of α-conotoxins and structurally modified analogs with enhanced biological stability

α-Conotoxins are peptide neurotoxins isolated from the venom ducts of carnivorous marine cone snails that exhibit exquisite pharmacological potency and selectivity for various nicotinic acetylcholine receptor subtypes. As such, they are important research tools and drug leads for treating various diseases of the central nervous system, including pain and tobacco addiction. Despite their therapeutic potential, the chemical synthesis of α-conotoxins for use in structure-activity relationship studies is complicated by the possibility of three disulfide bond isomers, where inefficient folding methods can lead to a poor recovery of the pharmacologically active isomer. In order to achieve higher yields of the native isomer, especially in high-throughput syntheses it is necessary to select appropriate oxidative folding conditions. Moreover, the poor biochemical stability exhibited by α-conotoxins limits their general therapeutic applicability in vivo. Numerous strategies to enhance their stability including the substitution of disulfide bond with diselenide bond and N-to-C cyclization via an oligopeptide spacer have successfully overcome these limitations. This chapter describes methods for performing both selective and nonselective disulfide bond oxidation strategies for controlling the yields and formation of α-conotoxin disulfide bond isomers, as well as methods for the production of highly stable diselenide-containing and N-to-C cyclized conotoxin analogs.

Design of new α-conotoxins: from computer modeling to synthesis of potent cholinergic compounds

A series of 14 new analogs of α-conotoxin PnIA Conus pennaceus was synthesized and tested for binding to the human α7 nicotinic acetylcholine receptor (nAChR) and acetylcholine-binding proteins (AChBP) Lymnaea stagnalis and Aplysia californica. Based on computer modeling and the X-ray structure of the A. californica AChBP complex with the PnIA[A10L, D14K] analog, single and multiple amino acid substitutions were introduced in α-conotoxin PnIA aimed at compounds of higher affinity and selectivity. Three analogs, PnIA[L5H], PnIA[A10L, D14K] and PnIA[L5R, A10L, D14R], have high affinities for AChBPs or α7 nAChR, as found in competition with radioiodinated α-bungarotoxin. That is why we prepared radioiodinated derivatives of these α-conotoxins, demonstrated their specific binding and found that among the tested synthetic analogs, most had almost 10-fold higher affinity in competition with radioactive α-conotoxins as compared to competition with radioactive α-bungarotoxin. Thus, radioiodinated α-conotoxins are a more sensitive tool for checking the activity of novel α-conotoxins and other compounds quickly dissociating from the receptor complexes.

Structure-function relationship of conotoxin lt14a, a potential analgesic with low cytotoxicity

A novel conotoxin lt14a containing 13 amino acid residues with an amidated C-terminus derived from Conus litteratus, belongs to C-C-C-C cysteine pattern. As the smallest peptide of conotoxin framework 14, lt14a could inhibit nicotinic acetylcholine receptor and suppress pain. To elucidate structure-function relationship, we determine the solution structure by NMR and find that lt14a comprises a short duple β-strand region and β-turn motif. An analog [K7A]-lt14a of Ala substitution for Lys in position 7 is designed. Interestingly, [K7A]-lt14a exhibits higher activity than lt14a as long-lasting analgesic in the hotplate pain model in mice. Additionally, MTT assay reveals that the two peptides have low toxicity to human cells. The studies suggest that positively charged residue may not be involved in the blocking mechanism. However, due to the Ala substitution, hydrophobic residues' patch expansion strengthens the binding ability. A hypothesis is given that in conotoxin lt14a, hydrophobic residues rather than charged residues play a key role during target binding.

Chemical synthesis and characterization of two α4/7-conotoxins

α-Conotoxins are small disulfide-constrained peptides that act as potent and selective antagonists on specific subtypes of nicotinic acetylcholine receptors (nAChRs). We previously cloned two α-conotoxins, Mr1.1 from the molluscivorous Conus marmoreus and Lp1.4 from the vermivorous Conus leopardus. Both of them have the typical 4/7-type framework of the subfamily of α-conotoxins that act on neuronal nAChRs. In this work, we chemically synthesized these two toxins and characterized their functional properties. The synthetic Mr1.1 could primarily inhibit acetylcholine (ACh)-evoked currents reversibly in the oocyte-expressed rat α7 nAChR, whereas Lp1.4 was an unexpected specific blocker of the mouse fetal muscle α1β1γδ receptor. Although their inhibition affinities were relatively low, their unique receptor recognition profiles make them valuable tools for toxin-receptor interaction studies. Mr1.1 could also suppress the inflammatory response to pain in vivo, suggesting that it should be further investigated with respect to its molecular role in analgesia and its mechanism or therapeutic target for the treatment of pain.

Novel conopeptides in a form of disulfide-crosslinked dimer

In our present work, seven conotoxins and conopeptides were cloned from four cone snail species based on the M-superfamily signal peptides. Among them, two conopeptides, Vt3.1 and Vt3.2, showed unusual sequence characteristics. Both of them contained two cysteines that are separated by just one non-cysteine residue. In vitro, the chemically synthesized Vt3.1 formed dimers with different intermolecular disulfide linkages. Only the dimer with crossed disulfides showed bioactivity when injected into the intraventricular region of mice brains. Therefore, Vt3.1 and Vt3.2 represent a new group of conopeptides that form disulfide-crosslinked dimers in vitro and probably in vivo.

Characterization of a novel alpha4/4-conotoxin, Qc1.2, from vermivorous Conus quercinus

As part of continuing studies of the identification of gene organization and cloning of novel alpha-conotoxins, the first alpha4/4-conotoxin identified in a vermivorous Conus species, designated Qc1.2, was originally obtained by cDNA and genomic DNA cloning from Conus quercinus collected in the South China Sea. The predicted mature toxin of Qc1.2 contains 14 amino acid residues with two disulfide bonds (I-III, II-IV connectivity) in a native globular configuration. The mature peptide of Qc1.2 is supposed to contain an N-terminal post-translationally processed pyroglutamate residue and a free carboxyl C-terminus. This peptide was chemically synthesized and refolded for further characterization of its functional properties. The synthetic Qc1.2 has two interconvertible conformations in aqueous solution, which may be due to the cis-trans isomerization of the two successive Pro residues in its first Cys loop. Using the Xenopus oocyte heterologous expression system, Qc1.2 was shown to selectively inhibit both rat neuronal alpha3beta2 and alpha3beta4 subtypes of nicotinic acetylcholine receptors with low potency. A block of about 63% and 37% of the ACh-evoked currents was observed, respectively, and the toxin dissociated rapidly from the receptors. Compared with other characterized alpha-conotoxin members, the unusual structural features in Qc1.2 that confer to its receptor recognition profile are addressed.

Conotoxins containing nonnatural backbone spacers: cladistic-based design, chemical synthesis, and improved analgesic activity

Disulfide-rich neurotoxins from venomous animals continue to provide compounds with therapeutic potential. Minimizing neurotoxins often results in removal of disulfide bridges or critical amino acids. To address this drug-design challenge, we explored the concept of disulfide-rich scaffolds consisting of isostere polymers and peptidic pharmacophores. Flexible spacers, such as amino-3-oxapentanoic or 6-aminohexanoic acids, were used to replace conformationally constrained parts of a three-disulfide-bridged conotoxin, SIIIA. The peptide-polymer hybrids, polytides, were designed based on cladistic identification of nonconserved loci in related peptides. After oxidative folding, the polytides appeared to be better inhibitors of sodium currents in dorsal root ganglia and sciatic nerves in mice. Moreover, the polytides appeared to be significantly more potent and longer-lasting analgesics in the inflammatory pain model in mice, when compared to SIIIA. The resulting polytides provide a promising strategy for transforming disulfide-rich peptides into therapeutics.

Two potent alpha3/5 conotoxins from piscivorous Conus achatinus

Every cone snail produces a mixture of different conotoxins and secretes them to immobilize their prey and predators. alpha3/5 Conotoxins, isolated from fish-hunting cone snails, target muscle nicotinic acetylcholine receptors. The structure and function of alpha3/5 conotoxin from the piscivorous Conus achatinus have not been studied. We synthesized two pentadecamer peptides, Ac1.1a and Ac1.1b, with appropriate disulfide bonding, based on cDNA sequences of alpha3/5 conotoxins from C. achatinus. Ac1.1a and Ac1.1b differ by only one amino acid residue. They have similar potency on blocking recombinant mouse muscle acetylcholine receptor expressed in Xenopus laevis oocytes, with IC50 values of 36 nM and 26 nM, respectively. For Ac1.1b, deletion of the first three N-terminal amino acids did not change its activity, indicating that the N-terminus is not involved in the interaction with its receptor. Furthermore, our experiments indicate that both toxins strongly prefer the alpha1-delta subunit interface instead of the alpha1-gamma binding site on the mouse muscle nicotinic acetylcholine receptor. These peptides provide additional tools for the study of the structure and function of nicotinic receptor.

Discovery, Synthesis, and Structure Activity of a Highly Selective α7 Nicotinic Acetylcholine Receptor Antagonist

Nicotinic acetylcholine receptors (nAChRs) that contain an alpha7 subunit are widely distributed in neuronal and nonneuronal tissue. These receptors are implicated in the release of neurotransmitters such as glutamate and in functions ranging from thought processing to inflammation. Currently available ligands for alpha7 nAChRs have substantial affinity for one or more other nAChR subtypes, including those with an alpha1, alpha3, alpha6, and/or alpha9 subunit. An alpha-conotoxin gene was cloned from Conus arenatus. Predicted peptides were synthesized and found to potently block alpha3-, alpha6-, and alpha7-containing nAChRs. Structure-activity information regarding conotoxins from distantly related Conus species was employed to modify the C. arenatus derived toxin into a novel, highly selective alpha7 nAChR antagonist. This ligand, alpha-CtxArIB[V11L,V16D], has low nanomolar affinity for rat alpha7 homomers expressed in Xenopus laevis oocytes, and antagonism is slowly reversible. Kinetic analysis provided insight into the mechanism of antagonism. alpha-CtxArIB interacts with five ligand binding sites per alpha7 receptor, and occupation of a single site is sufficient to block function. The peptide was also shown to be highly selective in competition binding assays in rat brain membranes. alpha-CtxArIB[V11L,V16D] is the most selective ligand yet reported for alpha7 nAChRs.

Helix-Helix Interactions between Homo- and Heterodimeric γ-Carboxyglutamate-containing Conantokin Peptides and Their Derivatives

The conantokins are a family of small, naturally occurring gamma-carboxyglutamate (Gla)-rich peptides that specifically antagonize the N-methyl-D-aspartate (NMDA) subtype of ionotropic glutamate receptor. One member of this family, conantokin-G (con-G), undergoes Ca(2+)-mediated self-assembly to form an antiparallel helical dimer. Subunit interactions in this complex are incumbent upon intermolecular Ca(2+) bridging of Gla residues spaced at i, i + 4, i + 7, i + 11 intervals within the monomer. Herein, we further probe the molecular determinants governing such helix-helix interactions. Select variants were synthesized to evaluate the contributions of non-Gla residues to conantokin self-association. Con-G dimerization was shown to be exothermic and accompanied by positive heat capacity changes. Using positional Gla variants of conantokin-R (con-R), a non-dimerizing conantokin, i, i + 4, i + 7, i + 11 Gla spacing alone was shown to be insufficient for self-assembly. The Ca(2+)-dependent antiparallel heterodimerization of con-G and con-T(K7 gamma), two peptides that harbor optimal Gla spacing, was established. Last, the effects of covalently constrained con-G dipeptides on NMDA-evoked current in HEK293 cells expressing combinations of NR1a, NR1b, NR2A, and NR2B subunits of the NMDA receptor were investigated. The antiparallel dipeptide was unique in its ability to potentiate current at NR1a/2A receptors and, like monomeric con-G, was inhibitory at NR1a/2B and NR1b/2B combinations. In contrast, the parallel species was completely inactive at all subunit combinations tested. These results suggest that, under physiological Ca(2+) concentrations, equilibrium levels of con-G dimer most likely exist in an antiparallel orientation and exert effects on NMDA receptor activity that differ from the monomer.

Disulfide bond rearrangement during regioselective oxidation in PhS(O)Ph/CH3SiCl3 mixture for the synthesis of alpha-conotoxin GI

Rearrangement of disulfide bonds during the synthesis of alpha-conotoxin GI using PhS(O)Ph/CH(3)SiCl(3) oxidation procedure was observed. We have demonstrated that the protecting scheme (order of acetamidomethyl (Acm) and (t)Bu protecting groups) of the Cys residues as well as the reaction time influenced the ratio of the native and the mispaired compounds, while the temperature of the reaction mixture had no significant effect. However, in all cases the nonnative derivative was produced in high amount. The structure of the isomers was identified by the combination of enzymatic digestion and mass spectrometry measurements. We conclude that the air oxidation followed by the application of Tl(tfa)(3) for the regioselective formation of disulfide bonds leads up to the appropriate compound in the case of the synthesis of alpha-conotoxin GI, while the oxidation procedure using PhS(O)Ph/CH(3)SiCl(3) system resulted in the nonnative disulfide isomer.

Protein folding determinants: structural features determining alternative disulfide pairing in alpha- and chi/lambda-conotoxins

Alpha-conotoxins isolated from Conus venoms contain 11-19 residues and preferentially fold into the globular conformation that possesses a specific disulfide pairing pattern (C1-3, C2-4). We and others isolated a new family of chi-conotoxins (also called lambda conotoxins) with the conserved cysteine framework of alpha-conotoxins but with alternative disulfide pairing (C1-4, C2-3) resulting in the ribbon conformation. In both families, disulfide pairing and hence folding are important for their biological potency. By comparing the structural differences, we identified potential structural determinants responsible for the folding tendencies of these conotoxins. We examined the role of conserved proline in the first intercysteine loop and the conserved C-terminal amide on folding patterns of synthetic analogues of ImI conotoxin by comparing the isoforms with the regiospecifically synthesized conformers. Deamidation at the C-terminus and substitution of proline in the first intercysteine loop switch the folding pattern from the globular form of alpha-conotoxins to the ribbon form of chi/lambda-conotoxins. The findings are corroborated by reciprocal folding of CMrVIA chi/lambda-conotoxins. Substitution of Lys-6 from the first intercysteine loop of CMrVIA conotoxin with proline, as well as the inclusion of an amidated C-terminal shifted the folding preference of CMrVIA conotoxin from its native ribbon conformation toward the globular conformation. Binding assays of ImI conotoxin analogues with Aplysia and Bulinus acetylcholine binding protein indicate that both these substitutions and their consequent conformational change substantially impact the binding affinity of ImI conotoxin. These results strongly indicate that the first intercysteine loop proline and C-terminal amidation act as conformational switches in alpha- and chi/lambda-conotoxins.

Synthesis of fluorescent analogs of alpha-conotoxin MII

Alpha-conotoxins (alpha-CTxs) are small peptides that are competitive inhibitors of nicotinic acetylcholine receptors (nAChRs) and have been used to study the kinetics of nAChRs. Alpha-CTx MII, from the venom of Conus magus, has been shown to potently block both rat alpha3beta2 and rat chimeric alpha6/alpha3beta2beta3 cloned nAChRs expressed in Xenopus oocytes. Tetramethylrhodamine (TMR), Bodipy FL, Alexa Fluor 488, and terbium chelates (TbCh) are fluorescent molecules that can be reacted with the N-terminus of the conopeptide to produce fluorescent conjugates. TMR and Bodipy FL were individually conjugated to alpha-CTx MII using different succinimidyl ester amine labeling reactions resulting in the formation of carboxamide conjugates. Alexa Fluor 488 succinimidyl ester conjugation reaction yielded low amounts of conjugate. TbCh was also individually reacted with the N-terminus of MII using the isothiocyanate conjugation reaction resulting in the formation of a thiourea conjugate. The conjugates were purified using reverse-phase high-pressure liquid chromatography (RP-HPLC) and their masses verified by matrix-assisted laser desorption-ionization with time-of-flight mass spectroscopy (MALDI-TOF MS). When tested on target nAChRs expressed in Xenopus oocytes, TMR-MII, Bodipy FL-MII, and TbCh-MII potently blocked the response to acetylcholine with slow off-rate kinetics. These fluorescent conjugates can be used to localize specific subtypes of neuronal nAChRs or ligand-binding sites within receptors in various tissue preparations; additionally, they may also be used to study conformational changes in receptors using fluorescence or lanthanide-based resonance energy transfer.

High-throughput synthesis of conopeptides: a safety-catch linker approach enabling disulfide formation in 96-well format

Conotoxins exhibit a high degree of selectivity and potency for a range of pharmacologically relevant targets. The rapid access to libraries of conotoxin analogues, containing multiple intramolecular disulfide bridges for use in drug development, can be a very labor intensive, multi-step task. This work describes a high-throughput method for the synthesis of cystine-bridged conopeptides. Peptides were assembled on a peptide synthesizer employing the Fmoc solid-phase strategy using a safety-catch amide linker (SCAL). Side-chain protecting groups were removed on solid phase before SCAL activation with ammonium iodide in TFA, finally releasing the peptide into the TFA solution. Disulfide bond formation was performed in the cleavage mixture employing DMSO. This improved method allows mixtures of oxidized peptides to be obtained in parallel directly from a peptide synthesizer. A single HPLC purification of the resulting crude oxidized material produced peptides of > 95% purity.

?-Conotoxin analogs with additional positive charge show increased selectivity towards Torpedo�californica and some neuronal subtypes of nicotinic acetylcholine receptors

Alpha-conotoxins from Conus snails are indispensable tools for distinguishing various subtypes of nicotinic acetylcholine receptors (nAChRs), and synthesis of alpha-conotoxin analogs may yield novel antagonists of higher potency and selectivity. We incorporated additional positive charges into alpha-conotoxins and analyzed their binding to nAChRs. Introduction of Arg or Lys residues instead of Ser12 in alpha-conotoxins GI and SI, or D12K substitution in alpha-conotoxin SIA increased the affinity for both the high- and low-affinity sites in membrane-bound Torpedo californica nAChR. The effect was most pronounced for [D12K]SIA with 30- and 200-fold enhancement for the respective sites, resulting in the most potent alpha-conotoxin blocker of the Torpedo nAChR among those tested. Similarly, D14K substitution in alpha-conotoxin [A10L]PnIA, a blocker of neuronal alpha7 nAChR, was previously shown to increase the affinity for this receptor and endowed [A10L,D14K]PnIA with the capacity to distinguish between acetylcholine-binding proteins from the mollusks Lymnaea stagnalis and Aplysia californica. We found that [A10L,D14K]PnIA also distinguishes two alpha7-like anion-selective nAChR subtypes present on identified neurons of L. stagnalis: [D14K] mutation affected only slightly the potency of [A10L]PnIA to block nAChRs on neurons with low sensitivity to alpha-conotoxin ImI, but gave a 50-fold enhancement of blocking activity in cells with high sensitivity to ImI. Therefore, the introduction of an additional positive charge in the C-terminus of alpha-conotoxins targeting some muscle or neuronal nAChRs made them more discriminative towards the respective nAChR subtypes. In the case of muscle-type alpha-conotoxin [D12K]SIA, the contribution of the Lys12 positive charge to enhanced affinity towards Torpedo nAChR was rationalized with the aid of computer modeling.

Role of the subunit composition of central nicotinic acetylcholine receptors for the stimulatory and dopamine-enhancing effects of ethanol

AIMS

The stimulatory, rewarding, and dopamine (DA)-enhancing effects of ethanol may involve central nicotinic acetylcholine receptors (nAChR), especially those located in the ventral tegmental area (VTA). Identifying the subunit composition that mediates these effects of ethanol would increase the understanding of the neurochemical basis underlying the addictive properties of ethanol. In the present series of experiments, the role of the alpha(3)beta(2)(*) and/or beta(3)(*) and/or alpha(6)(*) subunits of the nAChR for the stimulatory and DA-enhancing effects of ethanol was investigated by using alpha-conotoxin MII (alphaCtxMII), selective to the alpha(3)beta(2)(*) and/or beta(3)(*) and/or the alpha(6)(*) subunits of the nAChR, and the alpha-conotoxin PIA-analogue (alphaCtxPIA-analogue), suggested to be selective to the alpha(6)(*) subunits.

METHODS

alphaCtxMII and the alphaCtxPIA-analogue were synthesized using a modified literature procedure. The purity and identity of the peptides were confirmed with HPLC and FAB-MS analyses, respectively. Locomotor activity and in vivo microdialysis in freely moving mice were used.

RESULTS

alphaCtxMII and the alphaCtxPIA-analogue were synthesized in good yields (>95%; >90%). In addition, we found that synthesized alphaCtxMII antagonized ethanol-induced locomotor stimulation, which confirms our previous results with the commercially available alphaCtxMII. Furthermore, the synthesized alphaCtxPIA-analogue, assumably also selective for alpha(6)(*) subunits of the nAChR, did neither antagonize the stimulatory nor the accumbal DA-enhancing effects of ethanol.

CONCLUSION

These results indicate that alphaCtxMII- but not alphaCtxPIA-analogue-sensitive receptors, i.e. the alpha(3)beta(2)(*) and/or beta(3)(*) rather than the alpha(6)(*) subunits of the nAChR, appear to be of greater importance for these effects of ethanol and that these subunits could constitute neurochemical targets for developing new drugs for the treatment of alcohol dependence.

Two novel O-superfamily conotoxins from Conus vexillum

O-superfamily conotoxins include several families that have diverse pharmacological activity on Na+, K+ or Ca2+ channels. These superfamily toxins have been mainly found in fish-hunting and mollusk-hunting Conus species. Here, we reported two novel O-superfamily conotoxins, vx6a and vx6b, purified from a worm-hunting cone snail, Conus vexillum. Though their cysteine framework and signal peptides share high similarity with those of other members of O-superfamily, the mature vx6a and vx6b both have a low sequence homology with others. To test the biological function of vx6a, the toxin was chemically synthesized and then tested on the locust dorsal unpaired median (DUM) neuron system which containing various ion channels. Although no any activity on ion channels was found on the DUM neuron system, vx6a could clearly elicit a series of symptoms in mouse via intracranial injection, such as quivering, climbing, scratching, barrel rolling and paralysis of limbs at different dose.

Synthesis of linear, branched, and cyclic peptide chimera

Chimeric peptides are unnatural constructs consisting of bioactive compounds from at least two different peptide(s) and/or protein(s) or two sequences from different parts of the same protein. Such multifunctional peptide combinations are prepared to enhance the biological activity or selectivity of their components. New biological effects can also be achieved with the chimera. In this chapter the synthesis of three different types of chimeric peptides will be described. In a linear chimera, two peptide epitopes from different parts of glycoprotein D (gD) of herpes simplex virus (HSV) are combined. A branched chimera, built from linear peptides, consists of tuftsin oligomers with immunostimulatory activity and an epitope peptide of HSV gD. The third compound is a cyclic chimeric molecule, where alpha-conotoxin GI as a host peptide is modified by the incorporation of a core epitope from HSV gD as a guest sequence.

Engineering stable peptide toxins by means of backbone cyclization: stabilization of the alpha-conotoxin MII

Conotoxins (CTXs), with their exquisite specificity and potency, have recently created much excitement as drug leads. However, like most peptides, their beneficial activities may potentially be undermined by susceptibility to proteolysis in vivo. By cyclizing the alpha-CTX MII by using a range of linkers, we have engineered peptides that preserve their full activity but have greatly improved resistance to proteolytic degradation. The cyclic MII analogue containing a seven-residue linker joining the N and C termini was as active and selective as the native peptide for native and recombinant neuronal nicotinic acetylcholine receptor subtypes present in bovine chromaffin cells and expressed in Xenopus oocytes, respectively. Furthermore, its resistance to proteolysis against a specific protease and in human plasma was significantly improved. More generally, to our knowledge, this report is the first on the cyclization of disulfide-rich toxins. Cyclization strategies represent an approach for stabilizing bioactive peptides while keeping their full potencies and should boost applications of peptide-based drugs in human medicine.

A uniquely selective inhibitor of the mammalian fetal neuromuscular nicotinic acetylcholine receptor

We have purified and characterized a novel conotoxin from the venom of Conus obscurus, which has the unique property of selectively and potently inhibiting the fetal form of the mammalian neuromuscular nicotinic acetylcholine receptor (nAChR) (alpha1beta1gammadelta-subunits). Although this conotoxin, alphaA-conotoxin OIVB (alphaA-OIVB), is a high-affinity antagonist (IC50 of 56 nm) of the fetal muscle nAChR, it has >1800-fold lower affinity for the adult muscle nAChR (alpha1beta1epsilondelta-subunits) and virtually no inhibitory activity at a high concentration on various neuronal nAChRs (IC50 > 100 microm in all cases). The peptide (amino acid sequence, CCGVONAACPOCVCNKTCG), with three disulfide bonds, has been chemically synthesized in a biologically active form. Although the neuromuscular nAChRs are perhaps the most extensively characterized of the receptors/ion channels of the nervous system, the precise physiological roles of the fetal form of the muscle nAChR are essentially unknown.alphaA-OIVB is a potentially important tool for delineating the functional roles ofalpha1beta1gammadelta receptors in normal development, as well as in various adult tissues and in pathological states. In addition to its potential as a research tool, alphaA-OIVB may have some direct biomedical applications.

Total chemical synthesis and oxidative folding of delta-conotoxin PVIA containing an N-terminal propeptide

Small disulfide-rich peptides are translated as larger precursors typically containing an N-terminal prepro sequence. In this study, we investigated the role of a propeptide in the oxidative folding of an extremely hydrophobic delta-conotoxin, PVIA. delta-Conotoxin PVIA (delta-PVIA) is a 29-amino acid neurotoxin stabilized by three disulfide bridges. Previous folding studies on delta-conotoxins revealed that their poor folding properties resulted from their hydrophobicity. However, low folding yields of delta-PVIA could be improved by the presence of a nonionic detergent, which acted as a chemical chaperone. delta-PVIA provided an attractive model to investigate whether the hydrophilic propeptide region could function as an intramolecular chaperone. A 58-amino acid precursor for delta-PVIA (pro-PVIA), containing the N-terminal propeptide covalently attached to the mature conotoxin, was synthesized using native chemical ligation. Oxidative folding of pro-PVIA resulted in a very low accumulation of the correctly folded form, comparable to that for the mature conotoxin delta-PVIA. Our results are in accord with the relevant data previously observed for alpha- and omega-conotoxins, indicating that conotoxin prepro sequences are so-called class II propeptides, which are not directly involved in the oxidative folding. We hypothesize that these propeptide regions may be important for interactions with protein folding catalysts and sorting receptors during the secretory process.

Optimizing the connectivity in disulfide-rich peptides: α-conotoxin SII as a case study

We describe a strategy for the efficient, unambiguous assignment of disulfide connectivities in alpha-conotoxin SII, of which approximately 30% of its mass is cysteine, as an example of a generalizable technique for investigation of cysteine-rich peptides. alpha-Conotoxin SII was shown to possess 3-8, 2-18, and 4-14 disulfide bond connectivity. Sequential disulfide bond connectivity analysis was performed by partial reduction with Tris(2-carboxyethyl)phosphine and real-time mass monitoring by direct-infusion electrospray mass spectrometry (ESMS). This method achieved high yields of the differentially reduced disulfide bonded intermediates and economic use of reduced peptide. Intermediates were alkylated with either N-phenylmaleimide or 4-vinylpyridine. The resulting alkyl products were assigned by ESMS and their alkyl positions sequentially identified via conventional Edman degradation. The methodology described allows a more efficient, rapid, and reliable assignment of disulfide bond connectivity in synthetic and native cysteine-rich peptides.

Total chemical synthesis and NMR characterization of the glycopeptide tx5a, a heavily post-translationally modified conotoxin, reveals that the glycan structure is alpha-d-Gal-(13)-alpha-d-GalNAc

The 13-amino acid glycopeptide tx5a (Gla-Cys-Cys-Gla-Asp-Gly-Trp*-Cys-Cys-Thr*-Ala-Ala-Hyp-OH, where Trp* = 6-bromotryptophan and Thr* = Gal-GalNAc-threonine), isolated from Conus textile, causes hyperactivity and spasticity when injected intracerebral ventricularly into mice. It contains nine post-translationally modified residues: four cysteine residues, two gamma-carboxyglutamic acid residues, and one residue each of 6-bromotryptophan, 4-trans-hydroxyproline and glycosylated threonine. The chemical nature of each of these has been determined with the exception of the glycan linkage pattern on threonine and the stereochemistry of the 6-bromotryptophan residue. Previous investigations have demonstrated that tx5a contains a disaccharide composed of N-acetylgalactosamine (GalNAc) and galactose (Gal), but the interresidue linkage was not characterized. We hypothesized that tx5a contained the T-antigen, beta-D-Gal-(1-->3)-alpha-D-GalNAc, one of the most common O-linked glycan structures, identified previously in another Conus glycopeptide, contalukin-G. We therefore utilized the peracetylated form of this glycan attached to Fmoc-threonine in an attempted synthesis. While the result-ing synthetic peptide (Gla-Cys-Cys-Gla-Asp-Gly-Trp*-Cys-Cys-Thr*-Ala-Ala-Hyp-OH, where Trp* =6-bromotryptophan and Thr* = beta-D-Gal-(1-->3)-alpha-D-GalNAc-threonine) and the native peptide had almost identical mass spectra, a comparison of their RP-HPLC chromatograms suggested that the two forms were not identical. Two-dimensional 1H homonuclear and 13C-1H heteronuclear NMR spectroscopy of native tx5a isolated from Conus textile was then used to determine that the glycan present on tx5a indeed is not the aforementioned T-antigen, but rather alpha-D-Gal-(1-->3)-alpha-D-GalNAc.

Effects of modification at the fifth residue of mu-conotoxin GIIIA with bulky tags on the electrically stimulated contraction of the rat diaphragm

Mu-conotoxin GIIIA, a peptide toxin from the cone snail, blocks muscle-type sodium channels. Thr-5 of mu-conotoxin GIIIA, located on the opposite side of the active site in the globular molecule, was replaced by Cys to which the bulky tags were attached. The tagged mu-conotoxin GIIIA derivatives, except for the phospholipid-tagged one, exerted the biological activity with a potency slightly weaker than natural mu-conotoxin GIIIA. When the biotinylated tags of various lengths were added, the presence of avidin suppressed the action of the biotinylated toxins of <4 nm, but not with 5 nm. The bulky biotinylated tags are useful as a caliper to measure the depth of receptor sites in the channels.

Iodo-α-Conotoxin MI Selectively Binds the α/δ Subunit Interface of Muscle Nicotinic Acetylcholine Receptors

The embryonic mouse muscle nicotinic acetylcholine receptor (nAChR) is a ligand-gated ion channel formed by alpha1, beta1, delta, and gamma subunits. The receptor contains two ligand binding sites at alpha/delta and alpha/gamma subunit interfaces. [(3)H]Curare preferentially binds the alpha/gamma interface. We describe the synthesis and properties of a high-affinity iodinated ligand that selectively binds the alpha/delta interface. An analogue of alpha-conotoxin MI was synthesized with an iodine attached to Tyr-12 (iodo-alpha-MI). The analogue potently blocks the fetal mouse muscle subtype of nAChR expressed in Xenopus oocytes. It failed, however, to block alpha3beta4, alpha4beta2, or alpha7 nAChRs. Iodo-alpha-MI potently blocks the alpha1beta1delta but not the alpha1beta1gamma subunit combination expressed in Xenopus oocytes indicating selectivity for the alpha/delta subunit interface. Alpha-conotoxin MI was subsequently radioiodinated, and its properties were further evaluated. Saturation experiments indicate that radioiodinated alpha-conotoxin MI binds to TE671 cell homogenates with a Hill slope of 0.95 +/- 0.0094. Kinetic studies indicate that the binding of [(125)I]alpha-conotoxin MI is reversible (k(off) = 0.084 +/- 0.0045 min(-1)); k(on) is 8.5 x 10(7) min(-1) M(-1). The calculated k(d) is 0.98 nM. This potency is approximately 20-fold higher than the unmodified alpha-MI peptide. Unlike [(125)I]alpha-bungarotoxin, [(125)I]alpha-conotoxin MI binding to TE671 cell homogenates is fully displaceable by the small molecule antagonist d-tubocurarine.

Propeptide Does Not Act as an Intramolecular Chaperone but Facilitates Protein Disulfide Isomerase-Assisted Folding of a Conotoxin Precursor

Conotoxins comprise a large and diverse group of peptide neurotoxins derived from Conus snail venoms; most contain multiple disulfide bonds. The conotoxin precursors consist of three distinct domains: the N-terminal signal sequence, an intervening propeptide region, and the C-terminal mature conotoxin. Formation of the native disulfide bonds during the oxidative folding of conotoxins is a prerequisite for their proper biological function, but in numerous in vitro folding experiments with mature conotoxins, a lack of specificity in formation of the native Cys-Cys connectivities is observed. The mechanisms that ensure that the native disulfide bonds are formed in venom ducts during biosynthesis remain unknown. To evaluate whether the propeptide could potentially function as an intramolecular chaperone, we studied the oxidative folding of a conotoxin precursor, pro-GI, belonging to the alpha-conotoxin family. Our results indicate that the propeptide sequence did not directly contribute to folding kinetics and thermodynamics. However, we found that the propeptide region of pro-GI played an important role when oxidative folding was catalyzed by protein disulfide isomerase (PDI). The PDI-assisted reaction was more efficient during the early folding in the context of the propeptide sequence (pro-GI), as compared to that of the mature conotoxin (alpha-GI). Taken together, our results suggest for the first time that the propeptide region may play a role in the PDI-catalyzed oxidative folding of conotoxin precursors.

A case study of 2,2-dimethylthiazolidine as locked cis proline amide bond: synthesis, NMR and molecular modeling studies of a δ-conotoxin EVIA peptide analog

The delta-conotoxin EVIA from the Conus ermineus venom, a recently characterized toxin, exhibits cis-trans isomerism of the Leu12-Pro13 bond associated with the triggering of its biological activity. In this paper we use the pseudoproline concept to target the presumed bioactive cis conformation. We report the design and the synthesis of loop 2 analogs from residue 8 to 18 containing either the cis-inducing Cys(PsiMe,MePro)13 unit or the natural proline residue. NMR studies in water and molecular modeling allowed us to identify the amide bond "locked" in a cis conformation for as in the suggested bioactive form of the natural toxin.

Synthesis, structure elucidation, in vitro biological activity, toxicity, and Caco-2 cell permeability of lipophilic analogues of alpha-conotoxin MII

The alpha-conotoxin MII is a two disulfide bridge containing, 16 amino acid long peptide toxin isolated from the marine snail Conus magus. This toxin has been found to be a highly selective and potent inhibitor of neuronal nicotinic acetylcholine receptors (nAChRs) of the subtype alpha3beta2. To improve the bioavailability of this peptide, two lipidic analogues of MII have been synthesized, the first by coupling 2-amino-d,l-dodecanoic acid (Laa) to the N terminus (LaaMII) and the second by replacing Asn5 in the MII sequence with this lipoamino acid (5LaaMII). Both lipidic linear peptides were then oxidized under standard conditions. (1)H NMR shift analysis of these peptides and comparison with the native MII peptide showed that the tertiary structure of the N-conjugated analogue, LaaMII, was consistent with that of the native conotoxin, whereas the 5LaaMII analogue formed the correct disulfide bridges but failed to adopt the native helical tertiary structure. The N terminus conjugate was also found to inhibit nAChRs of the subtype alpha3beta2 with equal potency to the parent peptide, whereas the 5LaaMII analogue showed no inhibitory activity. The active LaaMII analogue was found to exhibit significantly improved permeability across Caco-2 cell monolayers compared to the native MII, and both peptides showed negligible toxicity.

Solid-phase synthesis and biological activity of a thioether analogue of conotoxin G1

A bicyclic thioether analogue of alpha-conotoxin G1, a neurotoxin found in the venom of cone snails, was synthesized on solid phase. Two successive intramolecular on-bead cyclizations between a cysteine residue and a chloroacetylated reduced peptide bond are the key steps in the synthesis. The first reduced peptide bond was introduced by a reductive alkylation with a 9-fluorenylmethoxycarbonyl protected amino aldehyde, and the second by coupling of a dipeptide building block containing an allyloxycarbonyl protected reduced peptide bond. The desired bicyclic product was obtained as a mixture of two isomers, which were evaluated for their ability to inhibit the muscular nicotinic acetylcholine receptor expressed in Xenopus oocytes. The two isomers were found to have IC(50) values (inhibitory activities) of 144 microM and 48 microM, compared to 0.18 microM for native conotoxin G1.

Mu-conotoxin SmIIIA, a potent inhibitor of tetrodotoxin-resistant sodium channels in amphibian sympathetic and sensory neurons

Mu-conotoxins are a family of peptides from the venoms of predatory cone snails. Previously characterized mu-conotoxins preferentially block skeletal muscle voltage-gated sodium channels. We report here the discovery (via cloning), synthesis, and electrophysiological characterization of a new peptide in this family, mu-conotoxin SmIIIA from Conus stercusmuscarum. Although mu-conotoxin SmIIIA shares several biochemical characteristics with other mu-conotoxins (the arrangement of cysteine residues and a conserved arginine believed to interact with residues near the channel pore), it has distinctive features such as the absence of hydroxyproline. In voltage-clamped dissociated neurons from frog sympathetic and dorsal root ganglia, the peptide inhibited the majority of tetrodotoxin-resistant sodium currents irreversibly; in contrast, tetrodotoxin-sensitive sodium currents were largely unaffected by the peptide. We believe that mu-conotoxin SmIIIA is the first specific antagonist of tetrodotoxin-resistant voltage-gated sodium channels to be discovered. Thus, the peptide provides a new and potentially useful tool to investigate the functional roles of tetrodotoxin-resistant voltage-gated sodium channels, including those that are found in sensory nerves that convey nociceptive information.

Alpha-conotoxin GIC from Conus geographus, a novel peptide antagonist of nicotinic acetylcholine receptors

Many venomous organisms produce toxins that disrupt neuromuscular communication to paralyze their prey. One common class of such toxins comprises nicotinic acetylcholine receptor antagonists (nAChRs). Thus, most toxins that act on nAChRs are targeted to the neuromuscular subtype. The toxin characterized in this report, alpha-conotoxin GIC, is a most striking exception. The 16-amino acid peptide was identified from a genomic DNA clone from Conus geographus. The predicted mature toxin was synthesized, and synthetic toxin was used in all studies described. alpha-Conotoxin GIC shows no paralytic activity in fish or mice. Furthermore, even at concentrations up to 100 microm, the peptide has no detectable effect on the human muscle nicotinic receptor subtype heterologously expressed in Xenopus oocytes. In contrast, the toxin has high affinity (IC(50) approximately 1.1 nm) for the human alpha3beta2 subunit combination, making it the most neuronally selective nicotinic antagonist characterized thus far. Although alpha-conotoxin GIC shares some sequence similarity with alpha-conotoxin MII, which is also a potent alpha3beta2 nicotinic antagonist, it is much less hydrophobic, and the kinetics of channel block are substantially different. It is noteworthy that the nicotinic ligands in C. geographus venom fit an emerging pattern in venomous predators, with one nicotinic antagonist targeted to the muscle subtype (thereby causing paralysis) and a second nicotinic antagonist targeted to the alpha3beta2 nAChR subtype (possibly inhibiting the fight-or-flight response).

[Efficient synthesis of natural alpha-conotoxins and their analogs]

An efficient scheme for the synthesis of alpha-conotoxins, containing 12-18 amino acid residues and two disulfide bridges, was proposed. Its advantages are: (1) the avoidance of orthogonal protections of Cys residues; (2) a lower number of stages in a cycle of the peptide chain elongation by the method of solid phase synthesis; (3) the linear product is sufficiently pure for being used at the next stage of the disulfide bond formation without additional purification; and (4) a substantially reduced time of oxidation to disulfides at pH 10, which led to the target product in a high yield. A number of natural alpha-conotoxins (GI, ImI, EI, MII, and SIA), affecting the muscle and neuronal nicotinic acetylcholine receptors of various types, and several new analogues of these conotoxins (in particular, [Tyr10]ImI, [Gln12]GI, and [Ser1]GI) were synthesized by this scheme. They were used for elucidating the spatial structure of alpha-conotoxins by 1H NMR spectroscopy and for studying the ligand-binding sites of their receptors.

Synthesis of [Cys(5)]mu-conotoxin GIIIA and its derivatives as a probe of Na(+) channel analysis

The residue of Thr-5 in mu-conotoxin GIIIA (GIIIA), a receptor site I sodium channel blocker, was replaced with Cys. The synthesized [Cys(5)]GIIIA had a similar 3D structure to the native GIIIA, revealed by CD and NMR. [Cys(5)]GIIIA and its tagged peptides inhibited the electrically stimulated contraction of the rat diaphragm with relatively comparable potency to that of GIIIA. Since the contractile response to electrical stimuli is caused by the activation of sodium channels, [Cys(5)]GIIIA could be a prototype for synthesizing useful tools for the analysis of sodium channels. Thus, [Cys(5)]GIIIA could be a prototype for synthesizing useful tools for the analysis of sodium channels.

Chemical syntheses and biological activities of lactam analogues of alpha-conotoxin SI

Bicyclization represents an effective method for the introduction of conformational constraints into small, biologically important peptides. Several strategies have been developed for the preparation of bicyclic lactam analogues of alpha-conotoxin SI, a 13-residue peptide neurotoxin found in cone snail venom. Four analogues of the natural regioisomer of alpha-conotoxin SI were designed and synthesized, each with one of the two paired cysteines of the parent peptide being replaced by a side-chain lactam bridged glutamic acid/lysine pair. Solid-phase lactamization was studied to determine rates of formation of the two possible loops and to document the extent of dimerization and higher oligomerization. Radioligand binding assays were carried out on all synthesized peptides, including the naturally occurring two-disulfide form, in order to determine their affinities for nicotinic acetylcholine receptors (nAChRs). Replacement of the Cys(2)-Cys(7) loop of alpha-conotoxin SI with a lactam bridge resulted in complete loss of activity, whereas replacement of the Cys(3)-Cys(13) disulfide loop resulted in a approximately 60-fold reduction in affinity for one orientation and a approximately 70-fold increase in affinity for the other. The two active lactam analogues retain the selectivity exhibited by the naturally occurring peptide for the alpha/delta subunit of nAChRs, as judged by competition experiments with the curariform antagonist metocurine.

Synthesis and antibody recognition of mucin 1 (MUC1)-alpha-conotoxin chimera

We synthesized and characterized new chimera peptides by inserting an epitope of the mucin 1 glycoprotein (MUC1) as a 'guest' sequence in the 'host' structure of alpha-conotoxin GI, a 13-residue peptide (ECCNPACGRHYSC) isolated from the venom of Conus geographus. The Pro-Asp-Thr-Arg (PDTR) sequence of MUC1 selected for these studies is highly hydrophilic and adopts a beta-turn conformation. The alpha-conotoxin GI also contains a beta-turn in the 8-12 region, which is stabilized by two disulphide bridges in positions 2-7 and 3-13. Thus, the tetramer sequence of alpha-conotoxin, Arg9-His-Tyr-Ser12, has been replaced by PDTR, comprising the minimal epitope for MUC1 specific monoclonal antibodies (MAbs) HMFG1 (PDTR) and HMFG2 (DTR). Synthesis of the chimera peptide was carried out by Fmoc strategy on (4-(2',4'-dimethoxyphenyl-aminomethyl)phenoxy) (Rink) resin and either 5,5'-dithio-bis-(2-nitrobenzoic acid) (DTNB) or air oxidation was applied for the formation of the first Cys3-Cys13 or Cys2-Cys7 disulphide bridge, respectively. For the second disulphide bridge, three different oxidation procedures (iodine in acetic acid, 10% DMSO/1 M HCl or tallium trifluoroacetate (Tl(tfa)3) in TFA) were utilized. The HPLC purified peptides were characterized by electrospray mass spectrometry (ES-MS) and amino acid analysis. The CD spectra of the bicyclic MUC1-alpha-[Tyr1]-conotoxin chimera peptide showed partially ordered conformation with turn character. In antibody binding studies, the RIA data showed that both the linear and the bicyclic forms of MUC1-alpha-[Tyr1]-conotoxin chimera were recognized by MAb HMFG1 specific for PDTR sequence, while no binding was observed between MAb HMFG2 and various forms of the chimera. MAb HMFG1, using synthetic epitope conjugates or native MUC1 as target antigens, recognizes the PDTR motif more efficiently in the linear than in the bicyclic compound, but no reactivity was found with the monocyclic forms of MUC1-alpha-[Tyr1]-conotoxin chimera, underlining the importance of certain conformers stabilized by double cyclization.

Structure-function relationships of the NMDA receptor antagonist peptide, conantokin-R

Conantokin-R (con-R) is a gamma-carboxyglutamate-containing 27-residue neuroactive peptide present in the venom of Conus radiatus, and acts as a non-competitive antagonist of the N-methyl-D-aspartate (NMDA) receptor. This peptide features a single disulfide bond, a type of structural element found in most classes of conotoxins, but not in other conantokins. The NMDA receptor antagonist activity of chemically synthesized con-R was determined through an assay involving inhibition of the spermine-enhanced binding of the NMDA receptor channel blocker, [(3)H]MK-801, to rat brain membranes, and yielded an IC(50) of 93 nM. This value represents a 2-5 times better potency than con-G or con-T, the other two characterized conantokins. Circular dichroism (CD) analysis of the metal-free form of con-R is indicative of a low alpha-helical content. There is an increase in alpha-helicity upon the addition of divalent cations, such as Ca(2+), Mg(2+), or Zn(2+). Isothermal titration calorimetry experiments showed one detectable Mg(2+) binding site with a K(d) of 6.5 microM, and two binding sites for Zn(2+), with K(d) values of 150 nM and 170 microM. Residue-specific information of the conformational state of con-R was obtained by two-dimensional (1)H-NMR. Analyses of the alpha-proton chemical shifts, NOE patterns, and hydrogen exchange rates of the peptide indicated an alpha-helical conformation for residues 1-19. Synthetic con-R-derived peptide variants, containing deletions of 7 and 10 amino acid residues from the carboxy-terminus of the wild-type peptide, displayed unaltered cation binding and NMDA receptor antagonist properties. The alpha-helical secondary structures of the two truncation peptides were more stable than full-length con-R, as evidenced by CD measurements and reduced backbone hydrogen exchange rates. These results provide experimental evidence that the structural elements common to the three conantokins thus far identified are the primary determinants for receptor function and cation binding/secondary structure stability.

In vitro and in vivo characterization of conantokin-R, a selective NMDA receptor antagonist isolated from the venom of the fish-hunting snail Conus radiatus

The purification, characterization, and synthesis of conantokin-R (Con-R), an N-methyl-D-aspartate (NMDA) receptor peptide antagonist from the venom of Conus radiatus, are described. With the use of well defined animal seizure models, Con-R was found to possess an anticonvulsant profile superior to that of ifenprodil and dizocilpine (MK-801). With voltage-clamp recording of Xenopus oocytes expressing heteromeric NMDA receptors from cloned NR1 and NR2 subunit RNAs, Con-R exhibited the following order of preference for NR2 subunits: NR2B approximately NR2A > NR2C >> NR2D. Con-R was without effect on oocytes expressing the alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) receptor subunit GluR1 or the kainate receptor subunit GluR6. In mouse cortical neurons voltage-clamped at -60 mV, Con-R application produced a slowly developing block of inward currents evoked by 10 microM NMDA and 1 microM glycine (IC(50) = 350 nM). At 3 microM, Con-R did not affect gamma-aminobutyric acid- or kainate-evoked currents. Con-R prevented sound-induced tonic extension seizures in the Frings audiogenic seizure-susceptible mice at i.c.v. doses below toxic levels. It was also effective at nontoxic doses in CF#1 mice against tonic extension seizures induced by threshold (15 mA) and maximal (50 mA) stimulation, and it partially blocked clonic seizures induced by s.c. pentylenetetrazol. In contrast, MK-801 and ifenprodil were effective only at doses approaching (audiogenic seizures) or exceeding (electrical and pentylenetetrazol seizures) those required to produce significant behavioral impairment. These results indicate that the subtype selectivity and other properties of Con-R afford a distinct advantage over the noncompetitive NMDA antagonists MK-801 and ifenprodil. Con-R is a useful new pharmacological agent for differentiation between the anticonvulsant and toxic effects of NMDA antagonists.

Synthesis and immunological studies of alpha-conotoxin chimera containing an immunodominant epitope from the 268-284 region of HSV gD protein

We have synthesized and characterized new chimeric peptides by inserting an epitope of the glycoprotein D (gD) of herpes simplex virus (HSV) serotype 1 as 'guest' sequence in the 'host' structure of alpha-conotoxin GI, a 13-residue peptide (ECCNPACGRHYSC) isolated from the venom of Conus geographus. The 276-284 region of HSV gD-1 selected for these studies is highly hydrophilic and adopts a beta-turn. The alpha-conotoxin GI also contains a beta-turn in the 8-12 region, stabilized by two disulfide bridges at positions 2-7 and 3-13. Thus, the tetramer sequence of alpha-conotoxin, 8Arg-His-Tyr-Ser12 has been replaced by Asp-Pro-Val-Gly (DPVG), identified previously as the epitope core. The syntheses were performed by Fmoc strategy on Rink resin and DTNB or air oxidation were applied for the formation of the first 3-13 disulfide bond in the presence of guanidinium hydrochloride. For the formation of the second disulfide Cys2-Cys7 three different oxidation procedures [iodine in 95% acetic acid, air oxidation in dimethyl sulfoxide/1 M HCl or Tl(tfa)3 in trifluoroacetic acid (TFE)] were compared. The high-performance liquid chromatography purified peptides were characterized by electrospray mass spectrometry and amino acid analysis. The bicyclic HSV-alpha-[Tyr1]-conotoxin chimeric peptide and native alpha-conotoxin GI showed similar circular dichroism spectra in phosphate-buffered saline (PBS) and in a PBS-TFE 1:1 (v/v) mixture, which might suggest that these compounds also share similar secondary structures. In immunologic studies the characteristics of the primary and of the memory immunoglobulin (Ig) M- and IgG-type antibody responses showed that the bicyclic HSV-alpha-[Tyr1]-conotoxin chimera is capable to induce strong antibody responses in C57/Bl/6 mice but was poorly immunogenic in CBA and BALB/c mice. Data obtained with the C57/Bl/6 serum indicate that the polyclonal antibodies recognize the DPVG motif presented in the bicyclic HSV-alpha-[Tyr1]-conotoxin and some reactivity was also found with the monocyclic but not with the linear form of the chimera. Results with two IgM type monoclonal antibodies from a bicyclic HSV-alpha-[Tyr1]-conotoxin immunized C57/Bl/6 mouse also point to the specific interaction with the DPVG sequence. Taken together these studies suggest, that the relative intensity of DPVG-specific responses was found to be dependent on the mouse strain and on the conformation of the chimeric molecules. We found that the IgM monoclonal antibodies are able to recognize the linear DPVG sequence, while the majority of IgG antibodies is directed to the same motif in a conformation stabilized by double cyclization.

Controlled syntheses of natural and disulfide-mispaired regioisomers of alpha-conotoxin SI

Methods are reported for the unambiguous syntheses of all three possible disulfide regioisomers with the sequence of alpha-conotoxin SI, a tridecapeptide amide from marine cone snail venom that binds selectively to the muscle subtype of nicotinic acetylcholine receptors. The naturally occurring peptide has two 'interlocking' disulfide bridges connecting Cys2-Cys7 and Cys3-Cys13 (2/7&3/13), while in the two mispaired isomers the disulfide bridges connect Cys2-Cys13 and Cys3-Cys7 (2/13 & 3/7, 'nested') and Cys2-Cys3 and Cys7-Cys13 (2/3 & 7/13, 'discrete'), respectively. Alignment of disulfide bridges was controlled at the level of orthogonal protection schemes for the linear precursors, assembled by Fmoc solid-phase peptide synthesis on acidolyzable tris(alkoxy)benzylamide (PAL) supports. Side-chain protection of cysteine was provided by suitable pairwise combination of the S-9H-xanthen-9-yl (Xan) and S-acetamidomethyl (Acm) protecting groups. The first disulfide bridge was formed from the corresponding bis(thiol) precursor obtained by selective deprotection of S-Xan, and the second disulfide bridge was formed by orthogonal co-oxidation of S-Acm groups on the remaining two Cys residues. It was possible to achieve the desired alignments with either order of loop formation (smaller loop before larger, or vice versa). The highest overall yields were obtained when both disulfides were formed in solution, while experiments where either the first or both bridges were formed while the peptide was on the solid support revealed lower overall yields and poorer selectivities towards the desired isomers.