A Trial of Mass Spectrometric Characterization of Femto‐Molar Amount from Subtropical Islands

Many kinds of venomous principles modulate physiological responses of mammalian signal transduction systems, on which they act selectively as enhancers, inhibitors or some other kind of effectors. These toxins have become useful tools for physiological research. We have characterized paralyzing toxins from the venom of spiders, scorpions, insects, jellyfishes and sea anemones in the subtropical region including the Ryukyu Islands. Venom profiles are screened by MALDI‐TOF fingerprinting analysis prior to purification of the venomous components, then marked target toxins of small molecular mass (1000–5000) are characterized directly by means of mass spectrometric techniques such as Frit‐FAB MS/MS, PSD/CID‐TOF MS, Capil. ‐HPLC/Q‐TOF MS/MS etc. The proteinous toxins of jellyfish or sea anemone are characterized by RT‐PCR technique by the information of the cleaved peptides after the protein was hydrolyzed by appropriate peptidase and the sequence of the cleaved peptide was determined by conventional methods. The venom of Araneid spider is mainly composed of a mixture of closely related acylpolyamines. More than 90 polyamine toxins were identified from one venom sac of the Madagascan spider, Nephilengys borbonica, by Frit‐Fab MS/MS employing charge remote fragmentation technique. A novel polyamine toxin was also found from the rare wondering spider, Macrothele gigas from Iriomote Island. The structure of the toxin is an analog of polyamine toxin found in trapdoor spiders. Many kinds of cystine‐rich peptides showing various types of ion channel antagonism have been isolated from spiders. A series of toxins possessing the same mode of cystine knots was recently isolated from the saliva of assassin bugs, Peirates turpis, Isyndus obscurus, Agriophodrus dohrni. These toxins act as calcium channel blocker. Most of the scorpion toxins reported are from scorpions hazardous to humans, and they belong to the major super family Buthoidea. Among them are the well‐known genera, such as Buthus, Androctonus, Centruroides, Leiurus, or Tytius. We have investigated the minor group of scorpions from the super family Chactoidea (Scorpionidae, Ishnuridae). The venoms of these scorpions, involving the genera Heterometrus, Pandinus, Opisthacanthus, and Isometrus, contain different kinds of peptide toxins. Fingerprinting peptide analysis of the toxin profiles for these scorpions showed some difference from the profiles of Buthoidea scorpions. These venoms contain linear pore‐forming peptides and 2‐cystine‐bridged toxins in addition to 4‐cystine‐bridged toxins. The most hazardous jellyfish in Okinawa, Chiropsalmus quadrigatus, and the related box jellyfishes, Carybdea rastoni, C. alata, contain quite labile proteinaceous toxins, CqTX, CrTX and CaTX, respectively. The toxins were inactivated by adding an organic solvent such as methanol or acetonitrile, by changing the pH of the toxin solution, dialyzing the toxin solution, storing the toxin in a refrigerator, or by lyophilizing the toxin solution. However, the toxic activity was retained in the presence of sodium chloride. We purified the jellyfish toxins by adding sodium chloride through all steps of the purification procedure and finally obtained the whole primary amino acid sequence of the toxin by RT‐PCR method. The toxic protein CqTX is homologous to the other box jelly fish toxin, CrTX and CaTX. These toxins belong to a new class of proteins since they show no homology to known proteins. Another notorious and dangerous specimen in the Ryukyu Islands is Phyllodiscus semori. The venom is composed of three kinds of proteins (PsTX‐20A, PsTX‐60A, PsTX‐60B). PsTX‐20A shows homology to the proteinaceous toxin actinoporin, a cytolytic protein isolated from the genus Actinia, but PsTX‐60s has no homology to any ever cloned proteins. Further elucidation of the mechanism of toxic action of these Coelenterates is in progress.     

Molecular cloning and genomic analysis of TsNTxp: an immunogenic protein from Tityus serrulatus scorpion venom.

A non-toxic protein (TsNTxP) from Tityus serrulatus scorpion venom has been shown to be an efficient immunogen and anti-TsNTxP antibodies recognize and neutralize the effect of Tityus serrulatus venom [Chávez-Olórtegui et al., 1997. Toxicon 35, 213-221]. With the purpose of studying the organization of the gene that code for this protein, we have isolated a full length cDNA clone for TsNTxP from a cDNA expression library using anti-TsNTxP antibodies. The nucleotide sequence of the gene that encodes TsNTxP was also obtained and it reveals the presence of an intron within the signal peptide sequence. The TsNTxP gene showed high degree of similarity with genes encoding toxins from scorpions of the genus Tityrus.     

Cloning and characterization of the cDNA sequences of two venom peptides from Chinese scorpion Buthus martensii Karsch (BmK).

From a cDNA library made from venom glands of Chinese scorpions of Buthus martensii Karsch, full-length cDNAs encoding precursors of two venom peptides have been isolated using a cDNA probe synthesized by polymerase chain reaction. Sequence analysis of the cDNAs revealed that one encoded precursor was 85 amino acid residues long including a signal peptide of 19 residues and a mature peptide (named BmK T) of 66 residues, and another encoded precursor was 84 residues long containing the same length signal peptide and a mature peptide (BmK M4 isoform, named BmK M4') of 64 residues. The analysis of amino acid sequence similarity indicated that the BmK T was homologous with both mammalian and insect toxins from BmK scorpion or other scorpions, and the BmK M4' was highly homologous with the members of the mammalian neurotoxin family of BmK, having two point mutations in amino acid residue sequence compared to BmK M4, a natural toxin from BmK.     

Isolation of a toxin from Centruroides infamatus infamatus Koch scorpion venom that modifies Na permeability on chick dorsal root ganglion cells

A novel toxin was isolated and characterized from the venom of the Mexican scorpion Centruroides infamatus infamatus. It has an apparent mol. wt of 7600, compatible with the presence of 66 amino acid residues per molecule. The N-terminal amino acid sequence was determined (up to residue 48) and showed approximately 95% similarity with toxins from other Mexican scorpions of the genus Centruroides. Experiments conducted with chick dorsal root ganglion cells showed that toxin 1 is a Na⁺ channel effector, causing a decrease in the peak Na⁺ permeability, similar to decreases observed for typical β-scorpion toxins.     

Cloning,Characterization, and Expression of Animal Toxin Genes for Vaccine Development

Abstract

Gene libraries have been constructed from the messenger ribonucleic acid (mRNA) isolated from venom glands of different poisonous animals such as snakes, scorpions, and snails. The gene banks thus created contain recombinant clones harboring DNA sequences encoding toxins with various pharmacological activities, ranging from myonecrosis-inducing to those affecting neuronal transmission. A number of these clones have been isolated and characterized, and gene expression has been attempted with limited success in Escherichia coli, baculovirus, and in two mammalian cell expression systems by using either cDNAs or synthetically-constructed genes.     

Turkish scorpion Buthacus macrocentrus: General characterization of the venom and description of Bu1, a potent mammalian Na+-channel α-toxin

The venom of the scorpion Buthacus macrocentrus of Turkey was fractionated by high performance liquid chromatography (HPLC) and its mass finger print analysis was obtained by spectrometry. More than 70 different fractions were obtained, allowing the determination of the molecular masses of at least 60 peptides ranging between 648 and 44,336 Da. The venom is enriched with peptides containing molecular masses between 3200–4500 Da, and 6000–7500 Da. They very likely correspond to K⁺-channel and Na⁺-channel specific peptides, respectively, as expected from venoms of scorpions of the family Buthidae, already determined for other species. The major component obtained from HPLC was shown to be lethal to mice and was further purified and characterized. It contains 65 amino acid residues maintained closely packed by 4 disulfide bridges, and shows a molecular weight of 7263 Da. Additionally, a cDNA from the venomous glands of this scorpion was used in conjunction with sequence data from Edman degradation and mass spectrometry for cloning the gene that codes for Bu1 as we named this toxin. This gene codes for a 67 amino acid residues peptide, where the two last are eliminated post-translationally for production of an amidated C-terminal arginine. Its sequence is closely related to toxins from the species Leiurus quinquestriatus, as revealed by a phylogenetic tree analysis. Electrophysiological results conducted with Bu1 using patch-clamp techniques indicate that it modifies the Na⁺ currents, in a similar way as other well known α-scorpion toxins. These results support the conclusion that this species of scorpions is dangerous to humans, having an epidemiological interest for the country.     

The Toxins Purified from Tityus Serrulatus (Lutz & Mello)Venom

Abstract

The toxicity of Tityus serrulatus venom is mainly due to a complex mixture of basic proteins of low molecular weight (MW< 8000 Da) which are active on the voltage-sensitive Na⁺ channel of excitable cells. One group of toxins, the α-toxins, delays inactivation of the Na⁺ channel. A second group, the β- toxins, produces a transient shift in the voltage-dependence of Na⁺ channel activation and increases the tendency of the cells to fire repetitively. The two groups bind specifically to two different binding sites, sites 3 and 4, of Na⁺ channels present in rat brain synaptosomes. The primary structure of the main toxins has been determined and consists of a single amino acid chain of 61 to 66 residues cross-linked by four disulfide bridges. Some secondary structural elements have also been determined. More recently, using molecular biological techniques, cDNAs encoding the precursors of α and β-toxins have been cloned from a cDNA library of Tityus serrulatus venom gland. The precursors contain a signal peptide of about 20 – 22 residues, the mature toxin and three additional Gly-Lys-Lys residues at the C-terminal that are not present in the mature toxins. The Lys residues are removed by a carboxypeptidase and the remaining Gly-extended peptides are converted into α-amidated C-terminal toxins. Toxins active at K⁺ channels have also been purified from Tityus serrulatus venom. At present, only two toxins have been characterized, namely a short polypeptide of 37 amino acid residues cross-linked by three disulfide bridges that competes for 125I-alpha DTX (dendrotoxin) binding sites in synaptic membranes, and a longer nonhomologous toxin of 8 016 Da, whose primary structure has only been determined at the level of its NH2 terminal.     

Identification of BmKAPi, a novel type of scorpion venom peptide with peculiar disulfide bridge pattern from Buthus martensii Karsch

A novel cDNA sequence encoding a new type of scorpion venom peptide (BmKAPi) was first isolated from the venom gland of Buthus martensiiKarsch by cDNA library screening combined with 5′-race. The encoded precursor of BmKAPi consisted of 89 amino acid residues including a signal peptide of 24 residues, a putative mature peptide of 64 residues (BmKAPi) and an extra basic residue at the C-terminus which might be removed in the post-translational processing. BmKAPi is stabilized by five disulfide bridges, whereas all other disulfide-bridged scorpion toxins described are cross-linked by three or four disulfide bridges. It suggested the three-dimensinal scaffold of BmKAPi might be different from other scorpion toxins. The amino acid sequence of BmKAPi showed no homology with other scorpion venom peptides, but shared a little similarity with some anticoagulant peptides and proteinase inhibitors isolated from hookworm, honeybee or European frog, respectively. RT-PCR analysis showed that BmKAPi mRNA could be induced by venom extraction suggesting BmKAPi might be a component of scorpion venom. These results suggest that BmKAPi is a new type of scorpion venom peptide different from other described scorpion toxins in structural and functional aspects.     

Purification, characterization and cDNA cloning of two natterin-like toxins from the skin secretion of oriental catfish Plotosus lineatus

The oriental catfish Plotosus lineatus is known to contain proteinaceous toxins in the skin secretion as well as in the venom gland. However, detailed properties and primary structures of the skin toxins have not been clarified. In this study, two proteinaceous toxins (toxins I and II) were purified from the skin secretion of oriental catfish by a combination of gel filtration, anion-exchange HPLC and hydroxyapatite HPLC. Toxins I and II are monomeric simple proteins with almost the same molecular mass (35 kDa for toxin I and 37 kDa for toxin II) and are distinguishable from each other in isoelectric point (6.5 for toxin I and 5.1 for toxin II). Both toxins display lethal, edema-forming and nociceptive activities, although toxin I is significantly more potent than toxin II. The primary structures of toxins I and II were elucidated by cloning experiments based on the determined partial amino acid sequences. Toxins I (317 amino acid residues) and II (315 amino acid residues) share as high as 86% sequence identity with each other and are also highly homologous (56–75% identities) with the known fish natterin-like proteins.     

Properties and cDNA cloning of a hyaluronidase from the stonefish Synanceia verrucosa venom

The venoms of two classes of fish, freshwater stingray (members of the genus Potamotrygon) and stonefish (members of the genus Synanceia), contain not only proteinaceous toxins but also hyaluronidases, which are considered as spreading factors that facilitate the tissue diffusion of toxins by degrading hyaluronan. So far, the freshwater stingray Potamotrygon motoro hyaluronidase and the stonefish Synanceia horrida hyaluronidase (SFHYA1) have been purified and characterized, although their spreading activity is still unclear. In this study, a 59 kDa hyaluronidase was partially purified from the stonefish Synanceia verrucosa and shown to be optimally active at pH 6.6, 37 °C and 0.15 M NaCl. Importantly, the S. verrucosa hyaluronidase enhanced the capillary permeability-increasing activity of the S. verrucosa toxin (neoverrucotoxin), providing evidence for its spreading activity. Furthermore, the primary structure of the S. verrucosa hyaluronidase was elucidated by cDNA cloning. The S. verrucosa hyaluronidase (463 amino acid residues) shares as high as 92% sequence identity with SFHYA1 but less than 50% with other hyaluronidases. Nevertheless, one catalytic residue and four substrate positioning residues, which constitute the active site of human hyaluronidases, are conserved in the S. verrucosa hyaluronidase.     

Scorpion toxins from Tityus cambridgei that affect Na(+)-channels.

By means of high performance liquid chromatography (HPLC) the soluble venom of the Amazonian scorpion Tityus cambridgei was fractionated into over 50 different components. Four toxic and/or lethal peptides to mice were obtained in pure form and sequenced. Mass spectrometry analysis showed molecular weights of 7310, 7151, 7259 and 7405, respectively, for toxins Tc48a, Tc49a, Tc54 and Tc49b. The N-terminal amino acid sequence was obtained for the three first toxins mentioned, whereas the full primary structure was determined for Tc49b. It contains 64 amino acid residues, closely packed by four disulfide bridges. Sequence comparison analysis showed similarities around 50% with other toxins from scorpions of the genus Tityus of Brazil. It is lethal to mice at doses of 20 microg per 20 g mouse. The toxin was shown to affect the Na(+)-currents permeability of rat cerebellum granular cells in culture. Almost a complete elimination of current was observed with 100 nM toxin concentration. This effect was partially reversible. Furthermore, this toxin does not modify the function of the Shaker B K(+)-channels expressed on Sf9 cells, nor does it modify the Na(+)-channel function in a similar manner as those reported for the alpha-scorpion toxins purified from other scorpions.     

BmK86-P1, a New Degradation Peptide with Desirable Thermostability and Kv1.2 Channel-Specific Activity from Traditional Chinese Scorpion Medicinal Material

Thermally processed Buthus martensii Karsch scorpions are a traditional Chinese medical material for treating various diseases. However, their pharmacological foundation remains unclear. Here, a new degraded peptide of scorpion toxin was identified in Chinese scorpion medicinal material by proteomics. It was named BmK86-P1 and has six conserved cysteine residues. Homology modeling and circular dichroism spectra experiments revealed that BmK86-P1 not only contained representative disulfide bond-stabilized α-helical and β-sheet motifs but also showed remarkable stability at test temperatures from 20–95 °C. Electrophysiology experiments indicated that BmK86-P1 was a highly potent and selective inhibitor of the hKv1.2 channel with IC₅₀ values of 28.5 ± 6.3 nM. Structural and functional dissection revealed that two residues of BmK86-P1 (i.e., Lys¹⁹ and Ile²¹) were the key residues that interacted with the hKv1.2 channel. In addition, channel chimeras and mutagenesis experiments revealed that three amino acids (i.e., Gln³⁵⁷, Val³⁸¹ and Thr³⁸³) of the hKv1.2 channel were responsible for BmK86-P1 selectivity. This research uncovered a new bioactive peptide from traditional Chinese scorpion medicinal material that has desirable thermostability and Kv1.2 channel-specific activity, which strongly suggests that thermally processed scorpions are novel peptide resources for new drug discovery for the Kv1.2 channel-related ataxia and epilepsy diseases.     

INTRASPECIFIC VARIATION IN SCORPION LEIURUS QUINQUESTRIATUS VENOM COLLECTED FROM EGYPT (SINAI AND ASWAN DESERTS)

Leiurus quinquestriatus is a single species genus scorpion of Saharan origin, which has penetrated the Mediterranean region. The Sinai Isthmus is believed to be the region in which the subspecies L.q. quinquestriatus gives way to L.q. hebraeus. To test whether there are qualitative differences in the venom from Leiurus quinquestriatus inhabiting two different geographic regions, venom was obtained from scorpions collected from Aswan in Southern Egypt and from the Southern region of Sinai Peninsula, Egypt. Electrophoresis and a densitometric gel scan showed that in the molecular weight range above that known to include toxins, venom of Aswan origin contained several protein bands that were absent from Sinai-sourced venom. In contrast Sinai venom appeared to have a larger proportion of protein in the molecular weight range known to include toxins. Such differences may reflect a response to local ecological conditions. Application of equal concentrations by weight of the two venoms to rat ileum showed no difference in the contraction produced by the lowest effective dose (0.2 μg ml^-1) but at higher doses (0.5, 1.0 & 2.0 μg ml^-1) venom from Aswan induced stronger and more sustained contractions with a different time course than did Sinai scorpion venom. Geographically related intra-specific variation in venom composition might be important in treating the pathophysiological effects of scorpion venom. This is the first time that differences in the venom components and their physiological effectiveness has been demonstrated for the scorpion L. quinquestriatus venom collected from two distinct areas in Egypt.     

Precursor nucleotide sequence and genomic organization of BmTXKS1, a new scorpion toxin-like peptide from Buthus martensii Karsch.

Scorpion venom contains a variety of small peptides, which can modulate Na+, K+, Ca2+ and Cl- channel conductance in excitable and non-excitable tissues. A novel full-length cDNA encoding a new toxin-like peptide (named BmTXKS1) was isolated from the venom gland cDNA library of Buthus martensii Karsch. The precursor consists of 60 amino acid residues, with a putative signal peptide of 28 residues and an extra residue, and a mature peptide of 31 residues with an amidated C-terminal. BmTXKS1 shared close homology with BmP01 in 5'UTR and the region encoding the putative signal peptide; especially, the positions of six cysteines are highly conserved among BmTXKS1, PbTX1 and P01-type subfamily of scorpion K+ channel toxins, suggesting that they all should present a common three-dimensional fold, namely the Cysteine-Stabilized alphabeta(CSalphabeta) motif. By PCR amplification of the genomic region encoding BmTXKS1, we have confirmed the identity of our cloned cDNA, and found that BmTXKS1 gene contains an intron, which is completely identical with that of the characterized scorpion K+-channel-ligands in the size, consensus junctions, putative branch point and A+T abundance.     

Conus Venoms: A Rich Source of Neuroactive Peptides

Abstract

Purification of toxins from the venoms of two fish-hunting gastropod cone snails, Conus geographus and Conus magus has revealed the presence of three classes of paralytic peptide toxins. These are: 1) the w-conotoxins, which block voltage activated calcium channels at the presynaptic terminus; 2) the α-conotoxins, which block the acetylcholine receptor and 3) the ω-conotoxins, which inhibit muscle sodium channels, and therefore prevent propagation of the muscle action potential. These toxins are basic peptides from 13–27 amino acids long, rich in cystine residues which are present as disulfides. A number of α-conotoxins and one a-conotoxin have been chemically synthesized.

In addition to the paralytic conotoxins, the venoms of Conus have other toxins which have not yet been completely characterized. A large number of neuroactive peptides and proteins have also been found. Since there are approximately 300 species of Conus, all of which produce venoms, the cone snails promise to be a rich source of neuroactive peptides in the years ahead.     

Full Neutralization of Centruroides sculpturatus Scorpion Venom by Combining Two Human Antibody Fragments

A fundamental issue of the characterization of single-chain variable fragments (scFvs), capable of neutralizing scorpion toxins, is their cross-neutralizing ability. This aspect is very important in Mexico because all scorpions dangerous to humans belong to the Centruroides genus, where toxin sequences show high identity. Among toxin-neutralizing antibodies that were generated in a previous study, scFv 10FG2 showed a broad cross-reactivity against several Centruroides toxins, while the one of scFv LR is more limited. Both neutralizing scFvs recognize independent epitopes of the toxins. In the present work, the neutralization capacity of these two scFvs against two medically important toxins of the venom of Centruroides sculpturatus Ewing was evaluated. The results showed that these toxins are recognized by both scFvs with affinities between 1.8 × 10⁻⁹ and 6.1 × 10⁻¹¹ M. For this reason, their ability to neutralize the venom was evaluated in mice, where scFv 10FG2 showed a better protective capacity. A combination of both scFvs at a molar ratio of 1:5:5 (toxins: scFv 10FG2: scFv LR) neutralized the venom without the appearance of any signs of intoxication. These results indicate a complementary activity of these two scFvs during venom neutralization.     

Purification of two depressant insect neurotoxins and their gene cloning from the scorpion Buthus martensi Karsch

Abstract: Insect‐specific neurotoxins are important components of scorpion venoms. In this study, two toxins from the scorpion Buthus martensi Karsch (BmK) were purified. They shared high sequence homology with other depressant insect toxins and were designated BmK ITa and BmK ITb, respectively. They were able to suppress the action potential of cockroach isolated axon, which is due to a decrease in the peak sodium current. Furthermore, the effect of BmK ITb was lower than that of BmK ITa, and some of the electrophysiological characteristics of BmK ITb even resemble that of excitatory insect toxins. Their primary structures were determined by N‐terminal partial sequence determination and cDNA cloning. The differences in their structures, especially the 31st residues, may result in the unique activity of BmK ITb.     

Covalent structure of the insect toxin of the North African scorpion Androctonus australis Hector

The complete covalent structure of the insect toxin purified from the venom of the North-African scorpion Androctonus australis Hector was described. Its amino acid sequence was established by phenylisothiocyanate degradation of several protein derivatives and proteolytic fragments in a liquid protein sequencer using either a “protein” or a “peptide” program. The position of the four disulfide bridges were deduced by analysis of proteolytic peptides before and after performic oxidation, and by partial labeling of the half cystine residues with [¹⁴C]-iodoacetic acid and determining the specific radioactivities of the S-[¹⁴C]-carboxymethylated phenylthiohydantoin cysteines. The sequences of the insect and mammal toxins from scorpions can be aligned with homology with the positions of seven half-cystine residues as registers. The mammal and insect toxins have three disulfide bridges at homologous positions. The fourth bridge is different in that Cys¹² in mammal toxin II is replaced by Cys³⁸ in the insect toxin. It is likely that the position of the disulfide bridges is the same for all scorpion neurotoxins active on mammals. We believe that the shift of one half-cystine residue in the insect toxin may induce a conformational change in the structure of the protein, which, in turn, may partially account for the total specificity of this toxin for insect nervous system.