The MALDI mass spectrometry in the identification of new proteins in snake venoms

By MALDI MS, we searched cobra venoms for new low-content polypeptides. A number of new proteins with molecular masses 7–25 kDa, characteristic of the known snake protein toxins, were identified, with the content of one of them less than 0.02%.     

Conformational studies of neurotoxin II from Naja naja oxiana. Selective N-acylation, circular dichroism and nuclear-magnetic-resonance study of acylation products.

After treatment of neurotoxin II, a component part of the venom of the Middle Asian cobra Naja naja oxiana, with acetoxysuccinimide all five possible epsilon-acetylated-lysyl derivatives were obtained and the position of the label was established. Trifluoroacetylation of both the derivatives and the parent toxin yielded, respectively, the five acetyl-penta(trifluoroacetyl)-neurotoxins II and the hexa(trifluoroacetyl)-neurotoxin II, which were studied by circular dichroism (CD), 1H and 19F nuclear magnetic resonance (NMR) spectroscopy. The availability of this series of compounds made possible assignment of all six fluorine signals (from the N-terminal and the five epsilon-amino groups) in the hexa(trifluoroacetyl)-neurotoxin II NMR spectra and disclosure of the proximity of the Lys-26 and Lys-46 trifluoroacetyl groups. The pH dependence of the 19F NMR signals was determined and the pK values of the groups affecting the signal chemical shifts were calculated by a computer iterative program. In order to ascertain the relative accessibility of the lysyl side chains, the change in halfwidths of the hexatrifluoroacetylated neurotoxin II 19F signals, with addition of varying amounts of an iminoxyl spin probe, was determined. The data obtained are compared with the X-ray data on sea snake neurotoxins and the significance of the side chain interactions observed in solution is discussed.     

Natural α-conotoxins and their synthetic analogues in study of nicotinic acetylcholine receptors

α-Conotoxins, peptide neurotoxins from poisonous marine snails of the genus Conus that highly specifically block nicotinic acetylcholine receptors (AChRs) of various types, are reviewed. Preliminarily, the structural organization of AChRs of the muscular and neuronal types, their involvement in physiological processes, and their role in various diseases are briefly discussed. In this connection, the necessity of quantitative determination of AChR subtypes using neurotoxins and other approaches is substantiated. The chemical structure, spatial organization, and specificity of α-conotoxins are mainly discussed, taking into consideration the recent results on the ability of α-conotoxins to interact with muscular or neuronal hetero-and homooligomeric AChRs exhibiting a high species specificity. Particular emphasis is placed upon a thorough characterization of the surfaces of interaction of α-conotoxins with AChRs using synthetic analogues of α-conotoxins, mutations in AChRs, and pairwise mutations in both α-conotoxins and AChRs. The discovery in 2001 of the acetylcholine-binding protein from the pond snail Lymnaea stagnalis and the determination of its crystalline structure led to rapid progress in understanding the structural organization of ligand-binding domains of AChRs with which α-conotoxins also interact. We discuss the interaction of various α-conotoxins with acetylcholine-binding proteins, the recently reported X-ray structure of the complex of the acetylcholine-binding protein from Aplysia californica with the α-conotoxin analogue PnIA, and the application of this structure to the modeling of complexes of α-conotoxins with various AChRs.     

Natural alpha-conotoxins and their synthetic analogues in studies of nicotinic acetylcholine receptors

alpha-Conotoxins, peptide neurotoxins from poisonous marine snails of the genus Conus that highly specifically block nicotinic acetylcholine receptors (AChRs) of various types, are reviewed. Preliminarily, the structural organization of AChRs of the muscular and neuronal types, their involvement in physiological processes, and their role in various diseases are briefly discussed. In this connection, the necessity of quantitative determination of AChR subtypes using neurotoxins and other approaches is substantiated. The chemical structure, spatial organization, and specificity of alpha-conotoxins are mainly discussed, taking into consideration the recent results on the ability of alpha-conotoxins to interact with muscular or neuronal hetero- and homooligomeric AChRs exhibiting a high species specificity. Particular emphasis is placed upon a thorough characterization of the surfaces of interaction of alpha-conotoxins with AChRs using synthetic analogues of alpha-conotoxins, mutations in AChRs, and pairwise mutations in both alpha-conotoxins and AChRs. The discovery in 2001 of the acetylcholine-binding protein from the pond snail Lymnaea stagnalis and the determination of its crystalline structure led to rapid progress in understanding the structural organization of ligand-binding domains of AChRs with which alpha-conotoxins also interact. We discuss the interaction of various alpha-conotoxins with acetylcholine-binding proteins, the recently reported X-ray structure of the complex of the acetylcholine-binding protein from Aplysia californica with the alpha-conotoxin analogue PnIA, and the application of this structure to the modeling of complexes of alpha-conotoxins with various AChRs.     

Relation between radiation safety criteria of human and the environment

System approach is used for developing of procedures of complex radiation safety of human and the environment. Relation between radiation safety criteria of human and the environment is considered by the example of different strategies of water bodies using. It is demonstrated that as to water bodies (though the methodology and conclusions are correct to terrestrial ecosystems too) observance of human radiation safety standards on condition that environment resources are used unrestrictedly (considering radiation factor) is necessary and sufficient to protection of objects of the environment. It allows reaching compromise between anthropocentric and ecological approaches to radiation protection of the environment from general biospheric principles.     

Phospholipases A2 isolated from snake venoms block acetylcholine-elicited currents in identified Lymnaea stagnalis neurons

Phospholipases A₂ (PLA₂s) are the most abundant family of snake venom proteins and play a significant role in prey envenomation. Their content in venoms is rather high. PLA₂s not only have enzyme activity but exhibit other types of biological activities including neurotoxicity. We have earlier shown that a protein bitanarin from the venom of the puff adder Bitis arietans is capable to block the responses of Lymnaea stagnalis neurons to acetylcholine and represents an active PLA₂ at the same time. Further investigation of PLA₂s isolated from the venoms of snakes of two families revealed their capability to interact with nicotinic acetylcholine receptors (nAChRs): PLA₂ from Vipera ursinii (Viperidae family), Naja kaouthia, and Bungarus fasciatus (Elapidae family) suppressed acetylcholine-induced current in identified neurons of L. staganlis. The effect was evident at PLA₂ concentration in the range of tens micromoles. The data obtained suggest the presence in a PLA₂ molecule of a site interacting with nAChR and a possible involvement of nAChR block in toxic action of PLA₂s.     

Neurotoxins from Snake Venoms and α-Conotoxin ImI Inhibit Functionally Active Ionotropic γ-Aminobutyric Acid (GABA) Receptors

Ionotropic receptors of γ-aminobutyric acid (GABA_AR) regulate neuronal inhibition and are targeted by benzodiazepines and general anesthetics. We show that a fluorescent derivative of α-cobratoxin (α-Ctx), belonging to the family of three-finger toxins from snake venoms, specifically stained the α1β3γ2 receptor; and at 10 μm α-Ctx completely blocked GABA-induced currents in this receptor expressed in Xenopus oocytes (IC₅₀ = 236 nm) and less potently inhibited α1β2γ2 ≈ α2β2γ2 > α5β2γ2 > α2β3γ2 and α1β3δ GABA_ARs. The α1β3γ2 receptor was also inhibited by some other three-finger toxins, long α-neurotoxin Ls III and nonconventional toxin WTX. α-Conotoxin ImI displayed inhibitory activity as well. Electrophysiology experiments showed mixed competitive and noncompetitive α-Ctx action. Fluorescent α-Ctx, however, could be displaced by muscimol indicating that most of the α-Ctx-binding sites overlap with the orthosteric sites at the β/α subunit interface. Modeling and molecular dynamic studies indicated that α-Ctx or α-bungarotoxin seem to interact with GABA_AR in a way similar to their interaction with the acetylcholine-binding protein or the ligand-binding domain of nicotinic receptors. This was supported by mutagenesis studies and experiments with α-conotoxin ImI and a chimeric Naja oxiana α-neurotoxin indicating that the major role in α-Ctx binding to GABA_AR is played by the tip of its central loop II accommodating under loop C of the receptors.     

Bacterial production and refolding from inclusion bodies of a “Weak” toxin, a disulfide rich protein

The gene for the “weak” toxin of Naja kaouthia venom was expressed in Escherichia coli. “Weak” toxin is a specific inhibitor of nicotine acetylcholine receptor, but mechanisms of interaction of similar neurotoxins with receptors are still unknown. Systems previously elaborated for neurotoxin II from venom of the cobra Naja oxiana were tested for bacterial production of “weak” toxin from N. kaouthia venom. Constructs were designed for cytoplasmic production of N. kaouthia “weak” toxin in the form of a fused polypeptide chain with thioredoxin and for secretion with the leader peptide STII. However, it became possible to obtain “weak” toxin in milligram amounts only within cytoplasmic inclusion bodies. Different approaches for refolding of the toxin were tested, and conditions for optimization of the yield of the target protein during refolding were investigated. The resulting protein was characterized by mass spectrometry and CD and NMR spectroscopy. Experiments on competitive inhibition of ¹²⁵I-labeled α-bungarotoxin binding to the Torpedo californica electric organ membranes containing the muscle-type nicotine acetylcholine receptor (α1₂β1_γδ) showed the presence of biological activity of the recombinant “weak” toxin close to the activity of the natural toxin (IC₅₀ = 4.3 ± 0.3 and 3.0 ± 0.5 µM, respectively). The interaction of the recombinant toxin with α7 type human neuronal acetylcholine receptor transfected in the GH₄C₁ cell line also showed the presence of activity close to that of the natural toxin (IC₅₀ 31 ± 5.0 and 14.8 ± 1.3 µM, respectively). The developed bacterial system for production of N. kaouthia venom “weak” toxin was used to obtain ¹⁵N-labeled analog of the neurotoxin.