Amino acid sequence of toxin III from Anemonia sulcata.

Toxin III, the smallest toxin component of the poison of the sea anemone Anemonia sulcata, is a polypeptide with 27 amino acids. Its structure is stabilized by three disulfide bridges. The amino acid sequence was determined by solid-phase Edman degradation of the aminoethylated derivative. The peptide was coupled to the carrier, porous glass, by thiourea bridges between the alpha-amino group of arginine-1 and the epsilon-amino group of lysine-26 and the isothiocyanate groups of the carrier. Another fraction of the polypeptide was bound by an acid-amide condensation of the C-terminal valine-27 with the aminopropyl group of the carrier. The sequence of toxin III has no regions homologous to the 47-residue toxin II. Comparison with the known partial sequence of toxin I, which contains 46 amino acids (Wunderer, G. & Eulitz, M., in preparation) also fails to reveal homologies.     

The amino acid sequence of toxin V from Anemonia sulcata

Preparations of the β-galactoside-binding lectin of bovine heart have been shown to stimulate $\text{in vitro}$ the sialylation of the oligosaccharide Ga1β1→4G1cNAc and asialo-α₁-acid glycoprotein by bovine colostrum β-D-galactoside α2→6 sialyltransferase. Kinetic data revealed that in the presence of lectin the K_m values for Ga1β1→4G1cNAc and CMP-NeuAc were reduced from 25.0 to 11.6 mM and from 0.42 to 0.19 mM respectively, but the K_m for asialo-α₁-acid glycoprotein and the V_max values for all three substrates were little affected. Stimulation by the lectin was partially inhibited by Fucα1→2Ga1β1→4G1cNAc. This, together with the effects of certain plant lectins, suggests that the stimulation of sialytransferase may be mediated through the carbohydrate-binding properties of the lectin.     

Radioactive labeling of toxin II from Anemonia sulcata

Anemone toxins are useful tools for the investigation of sodium channels in nerve membranes. For this application radioactive derivatives are necessary and are described in this report. Toxin II from Anemonia sulcata (ATX II) has been tritiated by reductive alkylation via the Schiff base formed by pyridoxal phosphate and amino groups of the peptide toxin. From the mixture of reaction products two monosubstituted toxins have been isolated by ion-exchange chromatography. The site of modification has been identified as the N-terminal amino group in the one toxin and the ?-amino group of lysine 35 in the other. The modified toxins prolonged action potentials similar to those of the native toxins. The threshold concentration to obtain this effect was approximately three times higher for the tritiated derivatives.     

Structure-function relationships of sea anemone toxin II from Anemonia sulcata

Chemical modifications of sea anemone toxin II from Anemonia sulcata have been used to study the residues involved in its toxic action on crabs and mice and in its binding properties to the Na+ channel of rat brain synaptosomes. Guanidination of th epsilon-amino groups of lysines 35, 36, and 46 with O-methylisourea hydrogen sulfate did not change the net charge of the toxin molecule and had no effect upon its toxic and binding properties. Either acetylation or fluorescamine treatment of the toxin that destroyed the positive charges of the three epsilon-amino groups and of the alpha-amino function of Gly produced an almost complete loss of toxicity and a considerable decrease in the binding activity. Iodination of the toxin on His induced practically no loss of toxic or binding properties. Carbethoxylation of both histidines 32 and 37 with diethyl pyrocarbonate provoked an important decrease of both the toxicity and the binding activity. Modifications of the guanidine side chain of Arg with 1,2-cyclohexanedione fully destroyed both toxicity and binding of the toxin to the Na+ channel. Modification of the carboxylate functions of Asp, Asp, and of the COOH-terminal Gln with glycine ethyl ester in the presence of a soluble carbodiimide completely abolished the toxicity but left the affinity for the sea anemone toxin receptor unchanged. The antagonist character of this carboxylate-modified derivative was further confirmed by electrophysiological and Na+ flux experiments. The theoretical and practical significance of these results are discussed.     

Radioactive labelling of toxin I from Anemonia sulcata and binding to crayfish nerve in vitro

1. Radioactive derivatives of neurotoxin I (ATX I) from Anemonia sulcata have been synthesized: Iodination of ATX I with 125I yielded a mixture of reaction products from which monoiodo and diiodo ATX I were isolated. 2. 125I-ATX I was shown to bind to the axonal membrane from Astacus leptodactylus main walking nerve. Specificity of binding was shown by saturability of the binding sites and by competitive binding of native and radioactive toxin. 3. Astacus nerve bound 44 fmol of 125I-ATX I/mg nerve (wet weight). The axonal membrane surface of the nerve was determined to be 7800 cm2/g nerve. This amounts to a binding site density of around 35/mu2 axonal surface. Binding was not inhibited by tetrodotoxin, the blocker of the selectivity filter of voltage-dependent sodium channels. 125I-ATX I therefore may bind to the sodium channel-inactivating gate. 4. The affinity of the nerve membrane receptors for 125I-ATX I appears to be voltage-dependent: KD = 5 nM was found with whole crayfish nerves in the presence of tetrodotoxin, KD = 40nM in the absence of tetrodotoxin and an even lower affinity was obtained with axonal membrane fragments isolated from the nerve. Drugs destabilizing the membrane potential, e.g. veratridine, ouabain and sodium azide lowered the affinity or abolished binding completely.     

Specific assignment of resonances in the 1H-NMR spectrum of the polypeptide toxin I from Anemonia sulcata

The assignment of a large number of resonances in the 300-MHz ¹H-nmr spectrum of the polypeptide neurotoxin Anemonia sulcata toxin I is described. The initial identification of spin systems is made using both one- and two-dimensional nmr spectra. The subsequent assignment of these spin systems to specific residues in the molecule is based largely on the observation in two-dimensional spectra of through-space connectivities between H^α and NH resonances from adjacent residues in the amino acid sequence. Using these techniques, the full spin systems of 22 residues are specifically assigned, together with partial assignments for a further 8. Many of the spin systems from the remaining 16 residues have been defined, although not yet specifically assigned. From the pattern of through-space connectivities between protons from adjacent residues in the sequence, some inferences may be drawn concerning the secondary structure of this polypeptide in aqueous solution.     

Biological significance of peptides from Anemonia sulcata

Three polypeptide toxins have been isolated from the sea anemone Anemonia sulcata and characterized: ATX I (mol wt 4702), ATX II (mol wt 4935), and ATX II (mol wt 2678). In different crustacean and amphibian preparations the toxins act primarily on the fast sodium channels, which leads to delayed inactivation of fast sodium permeability and thus increases the duration of the action potential. When applied to crustacean preparations the three toxins are nearly equally effective. However, in a comparison of the biological activities of ATX I and ATX II in myelinated nerves of the frog, ATX I seems to be inactive. It is suggested that cardiotoxicity is the primary cause of death in mammals, ATX II being more toxic than ATX I. At very low concentrations ATX II induces a pronounced positive inotropic effect in different mammalian heart preparations, which is accompanied by a prolongation of the action potential. It is suggested that the positive inotropic effect of ATX II is caused by a delayed inactivation of the fast sodium current, which leads to an increase of the sodium transient and of the pump activity of Na+,K+-ATPase. In contrast to the presynaptic mode of action on crustacean and frog nerve-muscle preparations, ATX II has a direct effect on mammalian skeletal muscle fiber membranes and induces a sodium-dependent increase of twitch responses and duration of the action potential.     

Modification of sodium channels in myelinated nerve by Anemonia sulcata toxin II

1. Single myelinated nerve fibres of the frog, Rana esculenta, were investigated predominantly in voltage clamp experiments. 2. Sodium current (INa) inactivation was measured in the presence of 10 mM TEA to suppress IK. Inactivation was diphasic but complete in toxin-free solution; it was delayed and became incomplete in Anemonia sulcata toxin II (ATX II) leading to persistent INa flow even during long depolarizations. The effects were reversible. Activation was not affected. 3. The persistent INa component increased with increasing toxin concentration and saturated at ca. 15 microM. The lowest concentration yielding unequivocal effects in the voltage clamp was 0.5 microM. 4. The curve relating the steady-state inactivation parameter, h infinity to the conditioning potential V became non-monotonic in ATX II i.e. dh infinity/dV greater than 0 for V greater than 30 mV. 5. Inactivation could be formally described by a three-state model with two conducting (h2 and h2) and one closed state (x) in the sequence h1 in equilibrium x in equilibrium h2. 6. Ca2+ modifies h2(V) more than h1(V) whose reaction to Ca2+ is similar to h(V) in toxin-free solution. The Ca2+ effect is very rapid and reversible.     

Amino-acid sequence of toxin III of Naja haje.

The complete amino acid sequence of toxin III of Naja haje (72 residues) has been established mainly by use of a protein sequenator (identification of 70 residues). The two C-terminal residues have been determined by digestion with carboxypeptidases A and B. Addition of succinylated protein or peptide greatly improved the performance of the sequenator for the Edman degradation of peptides: on one peptide (39 residues) degradation went to step 34 with a protein program and on two peptides (10 and 13 residues) degradation reached the last amino acid with a peptide program (use of dimethylbenzylamine). Amino acid analysis of tryptic peptides obtained by digestion of the C-terminal cyanogen bromide peptide are in full agreement with the sequence established by automatic degradation. The sequence of toxin III of Naja haje is unique and is very similar to that of Naja nivea alpha (although there are 9 differences), of Naja melanoleuca b (11 differences) and also to that of Naja naja A (18 differences).     

A mechanistic interpretation of the action of toxin II from Anemonia sulcata on the cardiac sodium channel

Cardiac sodium channels, modified by Anemonia sulcata toxin II, have been analyzed by the patch-clamp method. The open state of the modified sodium channels proved to be prolonged highly significantly and reopening from a closed state denoted c*-state frequently occurred, interrupted by silent periods, denoted i*-state. Activation from the c*-state was apparently not affected by toxin action, whereas activation from the i*-state was markedly prolonged. Upon higher depolarizations toxin-induced sodium channels disappeared and this behaviour has been attributed to dissociation of the toxin from the channel by use of a special pulse-protocol. The onset of the toxin effect on the action potential proved to depend on stimulation, and it is concluded that the toxin binds preferentially to the open (o)-state. Taking together the results, a kinetic scheme is suggested for action of the toxin on the cardiac sodium channel.     

Structural and functional study of an Anemonia elastase inhibitor, a "nonclassical" Kazal-type inhibitor from Anemonia sulcata

Anemonia elastase inhibitor (AEI) is a "nonclassical" Kazal-type elastase inhibitor from Anemonia sulcata. Unlike many nonclassical inhibitors, AEI does not have a cystine-stabilized alpha-helical (CSH) motif in the sequence. We chemically synthesized AEI and determined its three-dimensional solution structure by two-dimensional NMR spectroscopy. The resulting structure of AEI was characterized by a central alpha-helix and a three-stranded antiparallel beta-sheet of a typical Kazal-type inhibitor such as silver pheasant ovomucoid third domain (OMSVP3), even though the first and fifth half-cystine residues forming a disulfide bond in AEI are shifted both toward the C-terminus in comparison with those of OMSVP3. Synthesized AEI exhibited unexpected strong inhibition toward Streptomyces griseus protease B (SGPB). Our previous study [Hemmi, H., et al. (2003) Biochemistry 42, 2524-2534] demonstrated that the site-specific introduction of the engineered disulfide bond into the OMSVP3 molecule to form the CSH motif could produce an inhibitor with a narrower specificity. Thus, the CSH motif-containing derivative of AEI (AEI analogue) was chemically synthesized when a Cys(4)-Cys(34) bond was changed to a Cys(6)-Cys(31) bond. The AEI analogue scarcely inhibited porcine pancreatic elastase (PPE), even though it exhibited almost the same potent inhibitory activity toward SGPB. For the molecular scaffold, essentially no structural difference was detected between the two, but the N-terminal loop from Pro(5) to Ile(7) near the putative reactive site (Met(10)-Gln(11)) in the analogue moved by 3.7 A toward the central helix to form the introduced Cys(6)-Cys(31) bond. Such a conformational change in the restricted region correlates with the specificity change of the inhibitor.     

Anemonia sulcata toxin (ATX II) enhances spontaneous electrical activity and tension in chronically denervated rat diaphragm

In isolated strips of rat diaphragm denervated 9-21 days prior to experimentation, spontaneous action potentials were recorded extracellularly and twitch and resting tension were measured. The sea anemone toxin ATX II enhances the occurrence of spontaneous action potentials, increases resting tension and depresses twitch tension. These effects are essentially irreversible. In low sodium solution substituted with sucrose the effects of ATX II are attenuated, however, they fully develop upon return to normal sodium solution with a marked transient increase in the incidence of spontaneous action potentials and in resting tension. ATX II remains uneffective after pretreatment with tetrodotoxin. Reelevation of the extracellular sodium concentration after exposure to low sodium solution per se causes a marked increase in occurrence of fibrillation potentials, however the transient increase in resting tension was much smaller than in the presence of ATX II. Substitution of chloride with the impermeable anion methylsulphate enhances spontaneous activity and resting tension without an effect on twitch tension. Addition of ATX II elevates resting tension although the concomitant further increase in incidence of spontaneous action potentials is small. It is concluded that the increase in resting tension reflects a summation of the fibrillatory activity, but fibrillations become more effective when the preparations are exposed to ATX II. This finding points at the possible r?le of sodium ions in excitation contraction coupling of denervated skeletal muscle.     

Synthesis and properties of the chromophore of the asFP595 chromoprotein from Anemonia sulcata

A model compound for the chromophore within the purple nonfluorescent GFP-like chromoprotein asFP595 was synthesized. The postulated structure of the chromophore, 2-acetyl-4-(p-hydroxybenzylidene)-1-methyl-5-imidazolone, was taken from the high-resolution crystal structure analysis of intact asFP595 [Quillin, M. L., Anstrom, D., Shu, X., O'Leary, S., Kallio, K., Lukyanov, K. A., and Remington, S. J. (2005) Kindling Fluorescent Protein from Anemonia sulcata: Dark-State Structure at 1.38 A Resolution, Biochemistry 44, 5774-5787]. Erlenmeyer lactonization and oxidation of the methylene group attached to the heteroaromatic moiety with selenium dioxide were used at the key stages of the synthesis. The spectral properties of the model chromophore in solution and their dependence on the pH and polarity of the solvent were investigated. In water, the chromophore was found to exist in two forms, neutral and anionic, with a pK(a) of 7.1. In a dimethylformamide solution, the spectral properties of the anionic form closely match those of the native protein, demonstrating that under these conditions, the compound is an excellent model for the chromophore within native asFP595.     

Kindling fluorescent protein from Anemonia sulcata: dark-state structure at 1.38 A resolution

When the nonfluorescent chromoprotein asFP595 from Anemonia sulcata is subjected to sufficiently intense illumination near the absorbance maximum (lambda(abs)(max) = 568 nm), it undergoes a remarkable transition, termed "kindling", to a long-lived fluorescent state (lambda(em)(max) = 595 nm). In the dark recovery phase, the kindled state relaxes thermally on a time scale of seconds or can instantly be reverted upon illumination at 450 nm. The kindling phenomenon is enhanced by the Ala143 --> Gly point mutation, which slows the dark recovery time constant to 100 s at room temperature and increases the fluorescence quantum yield. To investigate the chemical nature of the chromophore and the possible role of chromophore isomerization in the kindling phenomenon, we determined the crystal structure of the "kindling fluorescent protein" asFP595-A143G (KFP) in the dark-adapted state at 1.38 A resolution and 100 K. The chromophore, derived from the Met63-Tyr64-Gly65 tripeptide, closely resembles that of the nonfluorescent chromoprotein Rtms5 in that the configuration is trans about the methylene bridge and there is substantial distortion from planarity. Unlike in Rtms5, in the native protein the polypeptide backbone is cleaved between Cys62 and Met63. The size and shape of the chromophore pocket suggest that the cis isomer of the chromophore could also be accommodated. Within the pocket, partially disordered His197 displays two conformations, which may constitute a binary switch that stabilizes different chromophore configurations. The energy barrier for thermal relaxation was found by Arrhenius plot analysis to be approximately 71 kJ/mol, somewhat higher than the value of approximately 55 kJ/mol observed for cis-trans isomerization of a model chromophore in solution.     

A new inhibitor of elastase from the sea anemone (Anemonia sulcata)

A proteinase inhibitor for elastases was isolated from extracts of the sea anemone Anemonia sulcata and purified to apparent homogeneity. The procedure comprises ethanolic extraction of the deep-frozen animals followed by gel filtration on Sephadex G-50 and by ion exchange chromatography on DEAE-Sephadex A-25 and SP-Sephadex C-25 and by hydroxylapatite chromatography. The slightly acidic inhibitor (isoelectric point 5.9) is a small protein consisting of 48 amino-acid residues without tryptophan and phenylalanine. The single chain molecule contains two methionines and no free sulfhydryl group but six cysteines presumably forming disulfide bonds. Reaction with cyanogen bromide abolishes the inhibitory properties. The inhibitor exhibits a rather narrow specificity for elastases. It strongly inhibits porcine pancreatic elastase in a permanent fashion with an equilibrium dissociation constant Ki of about 10(-10)M and somewhat weaker the elastase from human leucocytes with a Ki of about 10(-7)M. No obvious inhibition is observed of other serine proteinase such as bovine trypsin, bovine chymotrypsin, subtilisin from Bacillus subtilis and cathepsin G from human leucocytes when tested with synthetic substrates.