Interactions of the Neurotoxin Vipoxin in Solution Studied by Dynamic Light Scattering

AbstractThe neurotoxin vipoxin is the lethal component of the venom of Vipera ammodytes meridionalis. It is a heterodimer of a basic toxic His-48 phospholipase A2 (PLA2) and an acidic nontoxic Gln-48 PLA2. The shape of the neurotoxin and its separated components in solution as well as their interactions with calcium, the brain phospholipid phosphatidylcholine, and two inhibitors, elaidoylamide and vitamin E, were investigated by dynamic light scattering. Calcium binding is connected with a conformational change in vipoxin observed as a change of the hydrodynamic shape from oblate ellipsoid to a shape closer to a sphere. The Ca2+-bound form of vipoxin, which is catalytically active, is more compact and symmetric than the calcium-free heterodimer. Similar changes were observed as a result of the Ca2+-binding to the two separated subunits. In the presence of aggregated phosphatidylcholine, the neurotoxic complex dissociates to subunits. It is supposed that only the toxic component binds to the substrate, and the other subunit, which plays a chaperone function, remains in solution. The inhibition of vipoxin with the synthetic inhibitor elaidoylamide and the natural compound vitamin E changes the shape of the toxin from oblate to prolate ellipsoid. The inhibited toxin is more asymmetric in comparison to the native one. Similar, but not so pronounced, effects were observed after the inhibition of the monomeric and homodimeric forms of the toxic His-48 PLA2. Circular dichroism measurements in the presence of urea, methylurea, and ethylurea indicate a strong hydrophobic stabilization of the neurotoxin. Hydrophobic interactions stabilize not only the folded regions but also the regions of intersubunit contacts

Fluorescence properties of subtilisins and related proteinases (subtilases): Relation to X-ray models

The fluorescence properties of six subtilases with known X-ray structure were determined using the same experimental conditions and instrumentation. The steady state and nanosecond lifetime measurements were performed on purified samples of phenylmethanesulphonyl-inhibited proteinases in the presence of 20 mM CaCl2 which stabilizes the molecules. The tryptophan emission quantum yield strongly depends on the local environment and varies from 0.02 to 0.10. The efficiency of tyrosine-to-tryptophan energy transfer also varies (0%–70%) in the different enzymes; the most efficient transfer was observed for thermitase.Experiments with nanosecond excitation indicated that the tryptophan fluorescence of subtilases decays with two exponential components. The X-ray models of the six proteinases were analysed in the region of the tryptophyl residues and were used to explain the observed propertie

Crystallization and Preliminary X-ray Analysis of Vipoxin, a Complex between a Toxic Phospholipase A2 and its Natural Polypeptide Inhibitor

The toxin vipoxin, which is a complex between a basic toxic phospholipase A2 and an acidic non-toxic protein inhibitor, is found in the venom of the Bulgarian viper (Vipera ammodytes ammodytes), the most toxic snake in Europe. The two polypeptide chains each consist of 122 residues and are highly homologous (62%). The vipoxin complex is the first reported example of a high degree of structural homology between an enzyme and its natural inhibitor. The present crystals diffract in the X-ray beam to 1·8 Å resolution. The space group is P 212121. The cell dimensions are a = 45·80 Å, b = 55·36 Å and c = 107·69 Å. Native data to a resolution of 2·8 Å have been recorded

Snake venomics of the Siamese Russell's viper (Daboia russelli siamensis) - Relation to pharmacological activities

The venom proteome of Daboia russelli siamensis, a snake of medical importance in several Asian countries, was analysed by 2-D electrophoresis, subsequent MS/MS and enzymatic assays. The proteome comprises toxins from six protein families: serine proteinases, metalloproteinases, phospholipases A(2), L-amino acid oxidases, vascular endothelial growth factors and C-type lectin-like proteins. The venom toxin composition correlates with the clinical manifestation of the Russell's viper bite and explains pathological effects of the venom such as coagulopathy, oedema, hypotensive, necrotic and tissue damaging effects. The vast majority of toxins are potentially involved in coagulopathy and neurotoxic effects. The predominant venom components are proteinases capable of activating blood coagulation factors and promoting a rapid clotting of the blood, and neurotoxic phospholipase A(2)s. The analysis of the venom protein composition provides a catalogue of secreted toxins. The proteome of D. r. siamensis exhibits a lower level of toxin diversity than the proteomes of other viperid snakes. In comparison to the venoms of Vipera ammodytes ammodytes and Vipera ammodytes meridionalis, the venom from D. r. siamensis showed quantitative differences in the proteolytic, phospholipase A2, L-amino acid oxidase and alkaline phosphatase activities. (c) 2009 Published by Elsevier B.V

Snake Venomic of Crotalus durissus terrificus-Correlation with Pharmacological Activities

The snake venomic of Crotalus durissus terrificus was analyzed by 2-D and 1-D electrophoresis and subsequent MS/MS and enzymatic assays. The venomic of the South American rattlesnake comprises toxins from seven protein families: phospholipases A(2), serine proteinases, ecto-5'-nucleotidases, metalloproteinases, nerve growth factors, phosphodiesterases, and glutaminyl cyclase. The venom toxin composition correlates with the clinical manifestation of the crotalinae snake bites and explains pathological effects of the venom such as neurotoxicity, systemic myonecrosis, hemostatic disorders, myoglobinuria, and acute renal failure. The vast majority of toxins are potentially involved in neurotoxicity, myotoxicity, and coagulopathy. The predominant venom components are neurotoxic phospholipases A2 and serine proteinases. The venom is a rich source of 5'-nucleotidases (7.8% of the identified toxins) inducing hemostatic disorders. Analysis of the venom protein composition provided a catalogue for secreted toxins. The venomic composition of Crotalus d. terrificus and venom gland transcriptome of the synonymous subspecies Crotalus d. collilineatus show differences in the occurrence of protein families and in the abundance of toxins. Some of the venom components identified by the proteomic analysis were not reported in the transcriptome of the Crotalus d. collilineatus venom gland. Enzymatic activities of the Crotalus d. terrificus venom were determined and correlated with the proteomic composition.Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP

The Venomics of Bothrops alternatus is a Pool of Acidic Proteins with Predominant Hemorrhagic and Coagulopathic Activities

The venom proteome of Bothrops alternatus, a venomous snake widespread in South America, was analyzed by 2-D electrophoresis followed by mass spectrometric analysis and determination of enzymatic activities. The venomic composition revealed that metallo- and serine proteinases play primary roles in the pathogenesis of the envenomation by this pitviper. The identified 100 venom components with molecular masses from 10 to 100 kDa belong to six protein families: metalloproteinases, serine/thrombin-like proteinases, phospholipases A(2), L-amino acid oxidases, disintegrins and thrombin inhibitors. Metalloproteinases predominate and belong exclusively to the P-III class including the most potent hemorrhagic toxins. They represent 50% of all identified proteins. Two isoforms were identified: homologous to jararhagin, a hemorrhagic toxin, and to beritractivase, a nonhemorrhagic and pro-coagulant metalloproteinase. The B. alternatus venom is a rich source of proteins influencing the blood coagulation system with a potential for medical application. The isoelectric points of the components are distributed in the acidic pH range (the p/values are between 4 and 7) and no basic proteins were detected.Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq

First experimental evidence for the preferential stabilization of the natural D- over the nonnatural L-configuration in nucleic acids

The homochirality of biomolecules is a prerequisite for the origin and evolution of terrestrial life. The unique selection of D-monosaccharides, in particular, D-ribose in RNA and D-deoxyribose in DNA, leads to the construction of proteins by L-amino acids. This points to the exclusive role of stereoselectivity in the most important physiological processes. So far, there is no experimental confirmation for the theoretical calculations of the energy differences between enantiomers used for the explanation of the stereoselection of biomolecules. Therefore, the question of why nature prefers one configuration over the other still lacks a definitive answer. Here, we present the first experimental evidence that the D-enantiomer of RNA has a different electronic structure compared to the corresponding L-enantiomer. When varying the incident photon energy of the ultraviolet Raman probe across 5 eV, D- and L-isomers of the RNA duplex with the sequence [r(CUGGGCGG).r(CCGCCUGG)] show differences in the intensity of the vibrational modes with energies of 124.0 meV to 210.8 meV. The intensity difference of these vibrational modes can be traced back to energy differences in the electronic levels of D- and L-RNA leading to the preferential stabilization of the naturally occurring D-configuration of RNA over the L-configuration