DSPE-PEG Modification of α-Conotoxin TxID.

In order to improve stability of a peptide marine drug lead, α-conotoxin TxID, we synthesized and modified TxID at the N-terminal with DSPE-PEG-NHS by a nucleophilic substitution reaction to prepare the DSPE-PEG-TxID for the first time. The reaction conditions, including solvent, ratio, pH, and reaction time, were optimized systematically and the optimal one was reacted in dimethyl formamide at pH 8.2 with triethylamine at room temperature for 120 h. The in vitro stabilities in serum, simulated gastric juice, and intestinal fluid were tested, and improved dramatically compared with TxID. The PEG-modified peptide was functionally tested on α3ß4 nicotinic acetylcholine receptor (nAChR) heterologously expressed in Xenopus laevis oocytes. The DSPE-PEG-TxID showed an obvious inhibition effect on α3ß4 nAChR. All in all, the PEG modification of TxID was improved in stability, resistance to enzymatic degradation, and may prolong the half-life in vivo, which may pave the way for the future application in smoking cessation and drug rehabilitation, as well as small cell lung cancer.

Proteomic analysis provides insights on venom processing in Conus textile.

Conus species of marine snails deliver a potent collection of toxins from the venom duct via a long proboscis attached to a harpoon tooth. Conotoxins are known to possess powerful neurological effects and some have been developed for therapeutic uses. Using mass-spectrometry based proteomics, qualitative and quantitative differences in conotoxin components were found in the proximal, central and distal sections of the Conus textile venom duct suggesting specialization of duct sections for biosynthesis of particular conotoxins. Reversed phase HPLC followed by Orbitrap mass spectrometry and data analysis using SEQUEST and ProLuCID identified 31 conotoxin sequences and 25 post-translational modification (PTM) variants with King-Kong 2 peptide being the most abundant. Several previously unreported variants of known conopeptides were found and this is the first time that HyVal is reported for a disulfide rich Conus peptide. Differential expression along the venom duct, production of PTM variants, alternative proteolytic cleavage sites, and venom processing enroute to the proboscis all appear to contribute to enriching the combinatorial pool of conopeptides and producing the appropriate formulation for a particular hunting situation. The complementary tools of mass spectrometry-based proteomics and molecular biology can greatly accelerate the discovery of Conus peptides and provide insights on envenomation and other biological strategies of cone snails.

Two for the Price of One: Heterobivalent Ligand Design Targeting Two Binding Sites on Voltage-Gated Sodium Channels Slows Ligand Dissociation and Enhances Potency.

Voltage-gated sodium (NaV) channels are pore-forming transmembrane proteins that play essential roles in excitable cells, and they are key targets for antiepileptic, antiarrhythmic, and analgesic drugs. We implemented a heterobivalent design strategy to modulate the potency, selectivity, and binding kinetics of NaV channel ligands. We conjugated µ-conotoxin KIIIA, which occludes the pore of the NaV channels, to an analogue of huwentoxin-IV, a spider-venom peptide that allosterically modulates channel gating. Bioorthogonal hydrazide and copper-assisted azide-alkyne cycloaddition conjugation chemistries were employed to generate heterobivalent ligands using polyethylene glycol linkers spanning 40-120 Å. The ligand with an 80 Å linker had the most pronounced bivalent effects, with a significantly slower dissociation rate and 4-24-fold higher potency compared to those of the monovalent peptides for the human NaV1.4 channel. This study highlights the power of heterobivalent ligand design and expands the repertoire of pharmacological probes for exploring the function of NaV channels.

An attempt to modulate the microporous diffusion of a model polypeptide by altering its secondary structure.

The purpose of the present study was to determine whether intentional alteration of the secondary structure of a model polypeptide, conantokin-G, influenced the rate and extent of aqueous pore diffusion across a synthetic microporous membrane. Use of a microporous synthetic membrane allowed for analysis of polypeptide transport without the confounding variables of protein binding, acid- and/or enzyme-mediated degradation, endocytotic uptake, and enzymatic inactivation associated with a biological membrane. Conantokin-G was intentionally changed from its native random coil structure to the alpha-helix structure using calcium, and both structures were verified using circular dichroism. The alpha-helix structure of conantokin-G was retained even after additional free calcium was removed by equilibrium dialysis. Over the concentration range of 1.25 to 20 mM, there was a linear relationship between the solution calcium concentration and the percent of the alpha-helix conformer present. The apparent permeability, the apparent aqueous diffusion coefficient with and without inclusion of the Renkin function, and the hydrodynamic radii estimated by diffusion and a computer-software program were calculated for the random coil and alpha-helix structures of conantokin-G. Calcium-mediated conversion of conantokin-G to its alpha-helix structure did not significantly (p >.05) change its apparent permeability across a microporous membrane. It is suggested that perhaps complete conversion to the alpha-helix structure of only a fraction of the conantokin-G molecules (only 0.45 or 45% of the molecules can be converted to the alpha-helix structure at Ca(2+) concentrations >or= 20 mM) may have limited the extent of transport of the alpha-helix conformer.

Conjugation of peptides to the passivation shell of gold nanoparticles for targeting of cell-surface receptors.

We report the preparation of gold nanoparticles (AuNPs) functionalized with the peptide-toxin conantokin-G and their selective binding to N-methyl-d-aspartate (NMDA) receptors recombinantly expressed by transfected HEK 293 cells. The AuNPs are passivated with a mixed self-assembled monolayer of ω-carboxy- and ω-amino-polyethylene glycol (PEG) thiols. We compare two different passivation systems: the alkyl-PEG600 system is characterized by a C(11)-alkyl chain between the thiol group and the PEG segment, whereas the PEG3000 system lacks this alkyl-chain. We show that only the alkyl-PEG600 passivation system allows selective conjugation of cysteine-terminated peptides to the periphery of the passivation layer via a heterobifunctional linker strategy. In contrast, using the PEG3000 passivation system, peptides are immobilized both on the passivation layer and directly on the gold surface via concurrent place-exchange reaction. We therefore recommend the use of the alkyl-PEG600 system to precisely control the number of immobilized peptides on AuNPs. In fact, we show that the number of conjugated peptides per particle can be varied with good control simply by varying the composition of the self-assembled monolayer. Finally, we demonstrate that conjugation of the conantokin-G peptide to the solvent-exposed interface of the passivation layer results in maximal binding interaction between the peptide-functionalized AuNPs and the targeted NMDA receptors on the cell surface. Conantokin G-coupled AuNP may be used to spatially restrict NMDA-receptor-blockade on neuronal surfaces.

Docking of mu-conotoxin GIIIA in the sodium channel outer vestibule.

mu-Conotoxin GIIIA (mu-CTX) is a high-affinity ligand for the outer vestibule of selected isoforms of the voltage-gated Na(+) channel. The detailed bases for the toxin's high affinity binding and isoform selectivity are unclear. The outer vestibule is lined by four pore-forming (P) loops, each with an acidic residue near the mouth of the vestibule. mu-CTX has seven positively charged residues that may interact with these acidic P-loop residues. Using pair-wise alanine replacement of charged toxin and channel residues, in conjunction with double mutant cycle analysis, we determined coupling energies for specific interactions between each P-loop acidic residue and selected toxin residues to systematically establish quantitative restraints on the toxin orientation in the outer vestibule. Xenopus oocytes were injected with the mutant or native Na(+) channel mRNA, and currents measured by two-electrode voltage clamp. Mutant cycle analysis revealed novel, strong, toxin-channel interactions between K9/E403, K11/D1241, K11/D1532, and R19/D1532. Experimentally determined coupling energies for interacting residue pairs provided restraints for molecular dynamics simulations of mu-CTX docking. Our simulations suggest a refined orientation of the toxin in the pore, with toxin basic side-chains playing key roles in high-affinity binding. This modeling also provides a set of testable predictions for toxin-channel interactions, hitherto not described, that may contribute to high-affinity binding and channel isoform selectivity.

In silico detection of binding mode of J-superfamily conotoxin pl14a with Kv1.6 channel.

A novel conotoxin pl14a containing 25 amino acid residues with an amidated C-terminus from vermivorous cone snail, Conus planorbis belongs to J-conotoxin superfamily and this is the first conotoxin, which inhibits both nicotinic acetylcholine receptor subtypes and Kv1.6 channel. We have attempted through bioinformatics approaches to elucidate the extent of specificity of pl14a towards Kv1 channel subtypes (Kv1.1-Kv1.6). Our work provides rationale for the relatively high specificity and binding mode of pl14a to Kv1.6 channel. The pl14a peptide contains two types of structural elements, namely the putative dyad (Lys18 and Tyr19) and basic residue ring constituted of arginine residues. We have carried out in silico docking studies so as to assess the contribution of one or combination of both structural elements of pl14a in blocking of Kv1.6 channel. For this purpose, we have built by homology modelling, the theoretical 3D structure of Kv1.6 channel based on the available crystal structure of mammalian shaker Kv1.2 channel. Docking studies suggest that positively charged residues ring may be involved in the blocking mechanism of Kv1.6 channel. The models suggest that the peptide interacts with negatively charged extracellular loops and pore-mouth of the potassium channel and blocks the channel by covering the pore as a lid, akin to previously proposed blocking mechanism of kappaM-conotoxin RIIIK from Conus radiatus to Tsha1 potassium channel. The newly detected pharmacophore for pl14a interacting with Kv1.6 channel provides a pointer to experimental work to validate the observations made here. Based on differences in the number and distribution of the positively-charged residues in other conopeptides from the J-superfamily, we hypothesize different selectivity profiles against subtypes of the potassium channels for these conopeptides.

chi-Conotoxin and tricyclic antidepressant interactions at the norepinephrine transporter define a new transporter model.

Monoamine neurotransmitter transporters for norepinephrine (NE), dopamine and serotonin are important targets for antidepressants and analgesics. The conopeptide chi-MrIA is a noncompetitive and highly selective inhibitor of the NE transporter (NET) and is being developed as a novel intrathecal analgesic. We used site-directed mutagenesis to generate a suite of mutated transporters to identify two amino acids (Leu(469) and Glu(382)) that affected the affinity of chi-MrIA to inhibit [(3)H]NE uptake through human NET. Residues that increased the K(d) of a tricyclic antidepressant (nisoxetine) were also identified (Phe(207), Ser(225), His(296), Thr(381), and Asp(473)). Phe(207), Ser(225), His(296), and Thr(381) also affected the rate of NE transport without affecting NE K(m). In a new model of NET constructed from the bLeuT crystal structure, chi-MrIA-interacting residues were located at the mouth of the transporter near residues affecting the binding of small molecule inhibitors.