Deteriorating insulin resistance due to WL15 peptide from cysteine and glycine-rich protein 2 in high glucose-induced rat skeletal muscle L6 cells.

This study investigates the antioxidant and antidiabetic activity of the WL15 peptide derived from Channa striatus on regulating the antioxidant property in the rat skeletal muscle cell line (L6) and enhancing glucose uptake via glucose metabolism. Increased oxidative stress plays a major role in the development of diabetes and its complications. Strategies are needed to mitigate the oxidative stress that can reduce these pathogenic processes. Our results showed that with treatment with WL15 peptide, the reactive oxygen species significantly decreased in L6 myotubes in a dose-dependent manner, and increased antioxidant enzymes help to prevent the formation of lipid peroxidation in L6 myotubes. The cytotoxicity of WL15 is evaluated in the L6 cells and found to be non-cytotoxic at the tested concentration. Also, for the analysis of glucose uptake activity in L6 cells, the 2-(N-[7-nitrobenz-2-oxa-1,3-diazol-4-yl]amino)-2-deoxy- d -glucose assay was performed in the presence of wortmannin and genistein inhibitors. WL15 demonstrated antidiabetic activities through a dose-dependent increase in glucose uptake (64%) and glycogen storage (7.8 mM). The optimal concentration for the maximum activity was found to be 50 µM. In addition, studies of gene expression in L6 myotubes demonstrated upregulation of antioxidant genes and genes involved in the pathway of insulin signaling. In cell-based assays, WL15 peptide decreased intracellular reactive oxygen species levels and demonstrated insulin mimic activity by enhancing the primary genes involved in the insulin signaling pathway by increased glucose uptake indicating that glucose transporter type 4 (GLUT4) is regulated from the intracellular pool to the plasma membrane.

Biochemical and histopathological effects of the stonefish (Synanceia verrucosa) venom in rats.

The Reef Stonefish (Synanceia verrucosa) is one of the most dangerous venomous fish known, and has caused occasional human fatalities. The present study was designed to examine some of the pathological effects of the venom from this fish in Sprague Dawley rats. Crude venom was extracted from venom glands of the dorsal spines of stonefish specimens collected from coral reefs in the Gulf of Aqaba (in the northeastern branch of the Red Sea). The rats were given intramuscular injections of the venom and acute toxicity and effect on selected serum marker enzymes as well as normal architecture of vital organs were evaluated. The rat 24 h LD50 was 38 µg/kg body weight. The serum biochemical markers; alanine transaminase (ALT), lactate dehydrogenase (LDH) and creatine kinase (CK) increased after 6 h of administration of a sub lethal dose of the venom and remained significantly raised at 24 h. Amylase levels also significantly increased after venom injection. The venom caused histological damage manifested as an interstitial hemorrhage, inflammatory cell infiltration, and necrosis. The demonstrated rises in the levels of different critical biochemical parameters in the serum may have led to the observed abnormal morphological changes in these organs. These results may account for some of the clinical manifestations observed in victims of stonefish envenomation. Thus, the presented data provide further in vivo evidence of the stonefish toxic effects that may threaten human life and call for the need for special measures to be considered.

Purification, properties and cDNA cloning of neoverrucotoxin (neoVTX), a hemolytic lethal factor from the stonefish Synanceia verrucosa venom.

A proteinaceous toxin with hemolytic and lethal activities, named neoverrucotoxin (neoVTX), was purified from the venom fluid of stonefish Synanceia verrucosa and its primary structure was elucidated by a cDNA cloning technique. NeoVTX is a dimeric 166 kDa protein composed of alpha-subunit (702 amino acid residues) and beta-subunit (699 amino acid residues) and lacks carbohydrate moieties. Its hemolytic activity is inhibited by anionic lipids, especially potently by cardiolipin. These properties are comparable to those of stonustoxin (SNTX) previously purified from S. horrida. Alignment of the amino acid sequences also reveals that the neoVTX alpha- and beta-subunits share as high as 87 and 95% sequence identity with the SNTX alpha- and beta-subunits, respectively. The distinct differences between neoVTX and SNTX are recognized only in the numbers of Cys residues (18 for neoVTX and 15 for SNTX) and free thiol groups (10 for neoVTX and 5 for SNTX). In contrast, neoVTX considerably differs from verrucotoxin (VTX), a tetrameric 322 kDa glycoprotein, previously purified from S. verrucosa. In addition, the sequence identity of the neoVTX beta-subunit with the reported VTX beta-subunit is 90%, being lower than that with the SNTX beta-subunit.

Synergism between hydrogen sulfide (H(2)S) and nitric oxide (NO) in vasorelaxation induced by stonustoxin (SNTX), a lethal and hypotensive protein factor isolated from stonefish Synanceja horrida venom.

Stonustoxin (SNTX) is a 148 kDa, dimeric, hypotensive and lethal protein factor isolated from the venom of the stonefish Synanceja horrida. SNTX (10-320 ng/ml) progressively causes relaxation of endothelium-intact, phenylephrine (PE)-precontracted rat thoracic aortic rings. The SNTX-induced vasorelaxation was inhibited by L-N(G)-nitro arginine methyl ester (L-NAME), suggesting that nitric oxide (NO) contributes to the SNTX-induced response. Interestingly, D, L-proparglyglycine (PAG) and beta-cyano-L-alanine (BCA), irreversible and competitive inhibitors of cystathionine-gamma-lyase (CSE) respectively, also inhibited SNTX-induced vasorelaxation, indicating that H(2)S may also play a part in the effect of SNTX. The combined use of L-NAME with PAG or BCA showed that H(2)S and NO act synergistically in effecting SNTX-induced vasorelaxation.

Natterins, a new class of proteins with kininogenase activity characterized from Thalassophryne nattereri fish venom.

A novel family of proteins with kininogenase activity and unique primary structure was characterized using combined pharmacological, proteomic and transcriptomic approaches of Thalassophryne nattereri fish venom. The major venom components were isolated and submitted to bioassays corresponding to its main effects: nociception and edema. These activities were mostly located in one fraction (MS3), which was further fractionated. The isolated protein, named natterin, was able to induce edema, nociception and cleave human kininogen and kininogen-derived synthetic peptides, releasing kallidin (Lys-bradykinin). The enzymatic digestion was inhibited by kallikrein inhibitors as Trasylol and TKI. Natterin N-terminal peptide showed no similarity with already known proteins present in databanks. Primary structure of natterin was obtained by a transcriptomic approach using a representative cDNA library constructed from T. nattereri venom glands. Several expressed sequence tags (ESTs) were obtained and processed by bioinformatics revealing a major group (18%) of related sequences unknown to gene or protein sequence databases. This group included sequences showing the N-terminus of isolated natterin and was named Natterin family. Analysis of this family allowed us to identify five related sequences, which we called natterin 1-4 and P. Natterin 1 and 2 sequences include the N-terminus of the isolated natterin. Furthermore, internal peptides of natterin 1-3 were found in major spots of whole venom submitted to mass spectrometry/2DGE. Similarly to the ESTs, the complete sequences of natterins did not show any significant similarity with already described tissue kallikreins, kininogenases or any proteinase, all being entirely new. These data present a new task for the knowledge of the action of kininogenases and may help in understanding the mechanisms of T. nattereri fish envenoming, which is an important medical problem in North and Northeast of Brazil.

Biological properties of the venom from the scorpionfish (Scorpaena plumieri) and purification of a gelatinolytic protease.

In this work we describe some biological properties and a partial biochemical characterization of the Scorpanea plumieri crude venom. The fresh venom induced a decrease in blood pressure, cardiac and respiratory frequency, and exhibited hemorrhagic, hemolytic and proteolytic activities. The LD(50) (i.v. mouse) was 0.28 mg/kg. The pharmacological activities were found to be very unstable and this fact could be associated with proteolytic activity. Enzymes which hydrolyze casein and gelatin were found in this venom. A gelatinolytic protease (Sp-GP) was purified to homogeneity from S. plumieri venom through a combination of three chromatographic steps: gel filtration on Sephacryl S-200; ion exchange on DEAE-cellulose and reverse-phase/HPLC on a Vydac C4 column. The purified protease was approximately 2% of the whole protein in the soluble crude venom. The molecular mass of the Sp-GP scorpionfish gelatinase estimated by SDS-PAGE was around 80,000 Da under reducing conditions and 72,000 Da under non-reducing conditions. Attempts to determine the N-terminal sequence by automatic Edman degradation were unsuccessful, probably due to blockage of the N-terminal group. Gelatinolytic activity was optimal at pH 7-8. This is the first report of the isolation and characterization of a scorpionfish venom protease.

The effects of L-arginine, D-arginine, L-name and methylene blue on channa striatus-induced peripheral antinociception in mice.

PURPOSE: To determine the involvement of nitric oxide/cyclic guanosine monophosphate (NO/cGMP) pathway in aqueous supernatant of haruan (Channa striatus) fillet (ASH) antinociception using the acetic acid-induced abdominal constriction test. METHODS: The ASH was prepared by soaking fresh haruan fillet in chloroform:methanol (CM) (2/1 (v/v)) for 72 h followed by evaporation of the upper layer supernatant to remove any solvent residues. The supernatant was then subjected to a freeze-drying process (48 h) followed by doses preparation. RESULTS: Subcutaneous (SC) administration of ASH alone (0.170, 0.426 and 1.704 mg/kg) exhibited a dose-dependent antinociception. On the other hand, 20 mg/kg (SC) of L-arginine and MB exhibited a significant nociception and antinociception, while D-arginine and L-NAME did not produce any effect at all. Pre-treatment with L-arginine was found to significantly reverse the three respective doses of ASH antinociception; pre-treatment with D-arginine did not produce any significant change in the ASH activity; pre-treatment with L-NAME only significantly increased the 0.170 and 0.426 mg/kg ASH antinociception; and pre-treatment with MB significantly enhanced the respective doses of ASH antinociception, respectively. Furthermore, co-treatment with L-NAME significantly enhanced the L-arginine reversal effect on 0.426 mg/kg ASH antinociception. In addition, MB significantly reversed the L-arginine nociception on 0.426 mg/kg ASH. CONCLUSIONS: These finding suggest ASH antinociception involves the nitric oxide (NO)/cyclic guanosine monophosphate (cGMP) pathway. The presence of NO was found to reverse ASH antinociceptive activity while blocking of cGMP system enhanced it.

Identification of C-type isolectins in the venom of the scorpionfish Scorpaena plumieri.

Chemical analyses of the hemagglutinating fraction from Scorpaena plumieri venom revealed that it contains five components (Sp-CL 1-5) with similar chromatographic elution profiles (35-38% of acetonitrile), molecular masses (16,800-17,000 Da) and N-terminal sequences, suggesting that they are isoforms of the same protein. The amino acid sequence of Sp-CL4 was determined and shown to have homology with fish C-type lectins. These data demonstrate for the first time the presence of C-type isolectins in a scorpionfish venom.

Isolation, characterization and synthesis of a novel paradaxin isoform.

We report the isolation of a novel pardaxin isoform from the toxic secretion of the Red Sea Moses sole (Pardachirus marmoratus). Mass spectrometrical analysis of the newly purified peptide revealed a different primary structure compared to the previously known pardaxin isoforms. Sequence analysis disclosed an aspartic acid residue instead of glycine at position 31 of the new isoform. According to the novel sequence, a synthetic Asp-31-peptide was compared with the native compound as well as with synthetic Gly-31-pardaxin. The isolated Asp-31-pardaxin isoform and its synthetic analog exhibited identical elution properties during reverse-phase HPLC, as well as similar dose-dependent lytic effects on human erythrocytes at a concentration of 10(-6) to 10(-5)M. The hemolytic activity of Asp-31-pardaxins was lower than that of Gly-31-pardaxin and no synergistic effect between these peptides was found. The additional negative charge introduced by Asp-31 is likely to affect the selectivity of pardaxin pores towards a variety of ions.

[Toxic complex from parrotfish]. / Le complexe toxinique des poissons perroquets.

Clinical and epidemiological observations suggested that a complex toxic molecule is involved in the parrotfish flesh (Scarus gibbus) poisoning from Gambier Islands. The fat soluble extract obtained from the muscles upon ciguatoxin preparation showed two toxic substances after fractionation by DEAE cellulose column chromatography. The major toxin is different from ciguatoxin judging by its chromatographic behaviour. The other is closely similar to (or identical with) ciguatoxin from the moray eel Gymnothorax javanicus. They were named SG1 for the new toxin and SG2 for the ciguatoxin like compound. Successive filtrations on Sephadex LH-20 of SG1 and SG2 gave respectively a lethality to mice of 0.03 microgram/g and 0.06 microgram/g. SG1, specifically occurs in the muscles of the parrotfish family (scaritoxin) while it is absent from other ciguateric fishes. According to that specificity and the lack of SG1 in S. gibbus liver and gut contents, the origin of scaritoxin is briefly discussed.

Purification of a lethal fraction from the venom of the weever fish, Trachinus vipera C.V.

We report the purification of a lethal fraction of Weever fish venom using preparative electrophoresis. It was found to be composed of four identical subunits with an overall mol. wt of approximately 324,000. A 20 g mouse was killed instantly by an i.v. injection of 2 micrograms.

Isolation and characterization of dracotoxin from the venom of the greater weever fish Trachinus draco.

Dracotoxin, a protein possessing toxic, membrane depolarizing and hemolytic activities, was isolated from the crude venom of the greater weever fish Trachinus draco. The purification involved ammonium sulfate precipitation of crude venom followed by gel filtration on a high performance liquid chromatograph column. About 300 micrograms of dracotoxin was obtained from 18 mg of crude venom proteins extracted from one average size fish. Dracotoxin consists of a single polypeptide of about 105,000 mol. wt. It hemolyzed rabbit erythrocytes with an EC50 of 3 ng/ml. Rabbit erythrocytes possessed binding sites for dracotoxin on their surface. Preincubation of dracotoxin with rabbit ghosts increased its EC50 value for rabbit erthrocytes from 3 to 25 ng/ml. Incubation of dracotoxin with enriched glycophorin fraction from rabbit erythrocytes also led to an increase in the EC50 to 70 ng/ml. The high specificity of dracotoxin for rabbit erythrocytes resembles that of staphylococcal alpha-toxin. Dracotoxin, however, caused hemolysis even at 4 degrees C and did not interact with cholesterol indicating substantial differences between the two hemolysins. Dracotoxin represents a major toxic component of T. draco venom.

Thalassophryne nattereri fish venom: biological and biochemical characterization and serum neutralization of its toxic activities.

Envenomation by Thalassophryne nattereri fishes are an important medical problem in northeast of Brazil, causing in human victims considerable pain and edema followed by necrosis. Venom obtained from fresh captured specimens of this fish was tested in vitro or in animal models for a better characterization of its toxic activities. Intradermal injection of the venom in the foot pad of mice induced local edema and hemorrhage followed a few hours later by necrosis. Subcutaneous injection of the venom induced systemic effects consisting in jerking motions, paralysis of hind limbs, erection of hair, rotational movements and violent convulsions followed by death. Dead animals showed hyperemia of the small intestine and lungs. The venom showed distinct edematous, necrotizing and hemolytic activities, a low level of hemorrhagic, myotoxic and proteolytic activities and no detectable phospholipase A2 activity. SDS-PAGE analysis of the crude venom showed at least 17 components with the major band located around Mw = 19,000. Almost all proteins stained by amido black were also revealed by Western blotting with antibodies to T. nattereri venom. Fractionation of the venom by either gel filtration or cation exchange chromatography resulted in a few distinct peaks but in both situations the biological activities were located in only one of the peaks which corresponded to basic proteins with approximately Mw = 47,000. Heating of the venom at 56 degrees C for 60 min completely destroyed its biological activities. All venom toxic activities except edema were completely neutralized after in vitro incubation with anti-T. nattereri serum.

Enzymatic properties of the stonefish (Synanceia verrucosa Bloch and Schneider, 1801) venom and purification of a lethal, hypotensive and cytolytic factor.

The crude venom of the stonefish (Synanceia verrucosa) possesses numerous enzymatic properties (hyaluronidase, eight esterases and ten aminopeptidases). Verrucotoxin was isolated by DEAE and hydroxyapatite chromatography, followed by FPLC gel filtration on Superdex 200 HR 10/30. It was found to be a glycoprotein with a mol. wt of 322,000 +/- 2000, comprising four subunits, 2 alpha (83,000) and 2 beta (78,000). Verrucotoxin, as the crude venom, is lethal for mice, haemolyses washed rabbit erythrocytes and induces a fall in arterial pressure in anaesthetized rats.

A new saxitoxin analogue from a xanthid crab Atergatis floridus.

A novel paralytic toxin was isolated from toxic specimens of a xanthid crab Atergatis floridus inhabiting the Pacific coast of Shikoku Island. Its structure was deduced to be 11-saxitoxinethanoic acid (SEA) based on high-performance liquid chromatography, electrospray ionization mass spectrometry, and 1H and 13C-NMR spectrometries. This acid was assumed to exist as an equilibrium mixture of three tautomers, the main tautomer being the hydrate form 11 beta-epimer. SEA showed a specific toxicity of 830 mouse units per mumole on i.p. injection into mice.

Isolation and structures of grammistins, peptide toxins from the skin secretion of the soapfish Grammistes sexlineatus.

Two peptide toxins (named grammistins Gs 1 and Gs 2) with hemolytic and ichthyotoxic activities were isolated from the skin secretion of the soapfish Grammistes sexlineatus. Grammistin Gs 2 showed 6-11 x higher hemolytic activity and 10x higher ichthyotoxicity than grammistin Gs 1. The complete amino acid sequences of Gs 1 comprising 25 residues and Gs 2 comprising 24 residues were determined. Although a search by the database failed to find any homologous toxins from other sources, the grammistins were similar in secondary structures as well as biological activities to the two classes of peptide toxins, melittin from the bee venom and pardaxins from the skin secretion of two species of soles. CD experiments and helical wheel projections showed that the grammistins were randomly coiled in distilled water but formed amphiphilic alpha-helices in the presence of SDS micelles. In addition, they were found to be surface seeking peptides by the Eisenberg plot and assumed to exist as aggregates of 3-4 molecules. Interestingly, grammistin Gs 2 is much more abundant in amphiphilic alpha-helices and much higher in biological activities than melittin and pardaxins as well as grammistin Cs 1.

Purification of a toxic factor from Arabian Gulf catfish epidermal secretions.

The Arabian Gulf catfish, Arius bilineatus (Valenciennes) secretes a proteinaceous epidermal secretion when threatened or injured. A toxic factor has been isolated and purified from the crude extract (crude skin toxin) of these secretions by a combination of gel filtration on Sephacryl S-300 and preparative discontinuous polyacrylamide gel electrophoresis. The purified skin toxin has a molecular weight of 39,000 Da and an isoelectric point (pI) of 5.45. Injection of the purified skin toxin into rabbits i.v. and determination of the LD50 indicated that the protein had been purified approximately 30 fold by these procedures. Injection of the purified skin toxin into rabbits caused agitation, convulsions and death within 5 min. Analysis of plasma levels of lactate dehydrogenase, glutamate-oxaloacetate transaminase and glutamate pyruvate transaminase in injected rabbits indicated that the skin toxin caused cardiac and liver damage to the animals.

Occurrence of a water soluble toxin in a parrotfish (Ypsiscarus ovifrons) which is probably responsible for parrotfish liver poisoning.

The liver of the parrotfish Ypsiscarus ovifrons sometimes causes severe muscle pain, paralysis and dyspnea when ingested by humans. Individual livers, ovaries and digestive tracts and their contents were examined for lethal potency in mice. They were all toxic, except for livers obtained from April to June. Lethal potency ranged from 0.25 to 5.0 MU/g tissue. Livers were extracted with acidic aqueous ethanol and the extracts purified by charcoal treatment, gel filtration and partition and reversed phase column chromatography. Both the crude and partially purified toxin showed chemical and/or pharmacological properties different from those of tetrodotoxin or paralytic shellfish poisons.

An extract of lionfish (Pterois volitans) spine tissue contains acetylcholine and a toxin that affects neuromuscular transmission.

A soluble toxic extract derived from spine tissue of the lionfish (Pterois volitans) decreased heart rate and force of contraction in isolated clam and frog hearts. These actions were due to the presence of micromolar concentrations of acetylcholine in the extract. Toxicity was retained after hydrolysis of acetylcholine by exogenous acetylcholinesterase, but heart function was no longer affected. Toxin treated in this way induced muscle fibrillation in an isolated nerve-muscle preparation, followed by blockade of neuromuscular transmission. Bursts of transient depolarizations were recorded at the muscle endplate shortly after toxin addition that correlated in time with the duration of toxin-induced muscle fibrillation. These effects are thought to be due to the increased release and then depletion of acetylcholine from the nerve terminal.

Biological properties of a crude venom extract from the greater weever fish Trachinus draco.

Crude venom of the greater weever fish, Trachinus draco was analyzed to assess its toxicity, stability and biological properties. The best yield of venom was obtained by extraction in physiological saline of the whole venom apparatus of the fish which were shock-frozen and stored at -70 degrees C. This extract had a mouse i.v. minimum lethal dose of 1.8 micrograms protein per gram mouse and a total of 61,000 minimum lethal doses were obtained from venom apparatus of one fish. The lethal activity was unstable at room temperature especially at lower protein concentrations. Stability was achieved either by storing the extract at -70 degrees C or by precipitation with ammonium sulfate at 50% saturation. Toxicity of the crude venom was abolished by trypsin treatment. The crude venom did not possess any proteolytic or histamine-releasing activities. The venom caused an outflow of tetraphenylphosphonium from preloaded rat brain particles in a concentration-dependent manner. Like toxicity, this effect was also abolished by trypsin treatment or by keeping the venom at higher temperatures. The crude venom also possessed hemolytic activity with an EC50 for rabbit erythrocytes of 75 ng/ml venom protein. The hemolytic activity was also sensitive to heat and proteolytic treatment. Rabbit erythrocytes were most sensitive to venom followed by rat erythrocytes. Mouse and cattle erythrocytes were only slightly sensitive, whereas human, chicken and guinea pig erythrocytes were totally resistant.