Role of disulfide bonds in the structure and potassium channel blocking activity of ShK toxin.

ShK toxin, a potassium channel blocker from the sea anemone Stichodactyla helianthus, is a 35 residue polypeptide cross-linked by three disulfide bridges: Cys3-Cys35, Cys12-Cys28, and Cys17-Cys32. To investigate the role of these disulfides in the structure and channel-blocking activity of ShK toxin, a series of analogues was synthesized by selective replacement of each pair of half-cystines with two alpha-amino-butyrate (Abu) residues. The remaining two disulfide pairs were formed unambiguously using an orthogonal protecting group strategy of Cys(Trt) or Cys(Acm) at the appropriate position. The peptides were tested in vitro for their ability to block Kv1.1 and Kv1.3 potassium channels and their ability to displace [(125)I]dendrotoxin binding to rat brain synaptosomal membranes. The monocyclic peptides showed no activity in these assays. Of the dicyclic peptides, [Abu12,28]ShK(3-35,17)(-)(32) (where the subscript indicates disulfide connectivities) had weak activity on Kv1.3 and Kv1.1. [Abu17,32]ShK(3-35,12)(-)(28) blocked Kv1.3 with low nanomolar potency, but was less effective (being comparable to [Abu12,28]ShK(3-35,17)(-)(32)) against Kv1.1. [Abu3, 35]ShK(12-28,17)(-)(32), retained high picomolar affinity against both channels. Corroborating these results, [Abu3,35]ShK(12-28, 17)(-)(32) had an IC(50) ratio relative to native toxin of 18 in the displacement assay, whereas [Abu17,32]ShK(3-35,12)(-)(28) and [Abu12, 28]ShK(3-35,17)(-)(32) had ratios of 69 and 390, respectively. Thus, the disulfide bond linking the N- and C-terminal regions is less important for activity than the internal disulfides. NMR analysis of the [Abu12,28] and [Abu17,32] analogues indicated that they had little residual structure, consistent with their significantly reduced activities. By contrast, [Abu3,35]ShK(12-28,17)(-)(32) had a moderately well-defined solution structure, with a mean pairwise root-mean-square deviation of 1.33 A over the backbone heavy atoms. This structure nevertheless showed significant differences from that of native ShK toxin. The possible interactions of this analogue with the channel and the distinction between native secondary and tertiary structure on one hand and global topology imposed by the disulfide bridges on the other are discussed.

Selective alpha7-nicotinic agonists normalize inhibition of auditory response in DBA mice.

Abnormal sensory inhibition is a measurable indicator of a sensory processing deficit which is observed in schizophrenia, and other disorders, and which may be heritable. This deficit has also been observed in certain inbred mouse strains where the intensity of the deficit has been correlated with reduction in the number of hippocampal alpha-bungarotoxin-sensitive nicotinic receptors. Nicotine and certain nicotinic agonists produce brief periods of normal sensory inhibition in these mice. Similarly, nicotine also transiently normalizes sensory inhibition in schizophrenics. The present study assessed the effects of a novel nicotinic partial agonist (GTS-21), selective for the alpha-bungarotoxin site, on sensory inhibition in DBA mice, a strain with no sensory inhibition under routine experimental conditions. GTS-21 produced a dose-dependent normalization of sensory inhibition which was blocked by alpha-bungarotoxin but not mecamylamine. In contrast to other nicotinic agonists, normalization of sensory inhibition by GTS-21 and two related anabaseine compounds, DMAB-anabaseine and DMAC-anabaseine, was observed when administered a second time to the animal, after a 40-min delay. Our results indicated that the anabaseine compounds increase sensory inhibition through alpha7 nicotinic receptors, and that their ability to act repeatedly on these receptors may be less affected by desensitization.

Anabaseine is a potent agonist on muscle and neuronal alpha-bungarotoxin-sensitive nicotinic receptors.

We assessed the pharmacological activity of anabaseine, a toxin found in certain animal venoms, relative to nicotine and anabasine on a variety of vertebrate nicotinic receptors, using cultured cells, the Xenopus oocyte expression system, contractility assays with skeletal and smooth muscle strips containing nicotinic receptors and in vivo rat prostration assay involving direct injection into the lateral ventricle of the brain. Anabaseine stimulated every subtype of nicotinic receptor that was tested. It was the most potent frog skeletal muscle nicotinic receptor agonist. At higher concentrations it also blocked the BC3H1 (adult mouse) muscle type receptor ion channel. The affinities of the three nicotinoid compounds for rat brain membrane alpha-bungarotoxin binding sites and their potencies for stimulating Xenopus oocyte homomeric alpha7 receptors, expressed in terms of their active monocation concentrations, displayed the same rank order, anabaseine>anabasine> nicotine. Although the maximum currents generated by anabaseine and anabasine at alpha7 receptors were equivalent to that of acetylcholine, the maximum response to nicotine was only about 65% of the acetylcholine response. At alpha4-beta2 receptors the affinities and apparent efficacies of anabaseine and anabasine were much less than that of nicotine. Anabaseine, nicotine and anabasine were nearly equipotent on sympathetic (PC12) receptors, although parasympathetic (myenteric plexus) receptors were much more sensitive to anabaseine and nicotine but less sensitive to anabasine. These differences suggest that there may be different subunit combinations in these two autonomic nicotinic receptors. The preferential interactions of anabaseine, anabasine and nicotine with different receptor subtypes provides molecular clues that should be helpful in the design of selective nicotinic agonists.

An essential binding surface for ShK toxin interaction with rat brain potassium channels.

An "Ala scan" analysis of ShK toxin, a 35-residue basic peptide possessing three disulfide bonds, identifies seven side chains which influence binding to brain delayed rectifier potassium channels. Additional analogs were synthesized and tested to further decipher the roles of these residues, particularly Tyr23. The inhibitory effects of these analogs on 125I-labeled dendrotoxin binding to rat brain membranes showed that replacement of Tyr23 with Ala drastically lowered the affinity of the toxin for the Kv1.2 channels. Ala substitution of Phe27 reduced potency more than 15-fold. Monosubstituted Ala analogs for Ile7, Ser20, or Lys30 each displayed 5-fold reductions in potency. Thus, aromaticity at position 23 is important for effective delayed rectifier brain K channel binding. In contrast, the aromatic residue at position 27 was not critical, since cyclohexylalanine substitution increased affinity. The solution structure of ShK toxin clusters Ile7, Arg11, Ser20, Lys22, Tyr23, and Phe27 in close proximity, forming the potassium channel binding surface of the toxin. We propose an essential binding surface on the toxin in which Lys22 and Tyr23 are major contributors, through ionic and aromatic (hydrophobic) interactions, with the potassium channel.

Identification of three separate binding sites on SHK toxin, a potent inhibitor of voltage-dependent potassium channels in human T-lymphocytes and rat brain.

Eighteen synthetic analogs of ShK toxin, a thirty-five residue K channel blocker derived from the sea anemone Stichodactyla helianthus, were prepared in order to identify functionally important residues. CD spectra of sixteen of the analogs were virtually identical with the spectrum of wild-type toxin, indicating that the conformations were not affected by the substitutions. A conserved residue, Lys22, is essential for ShK binding to rat brain K channels which are primarily of the Kv1.2 type. However, a cationic side chain at position 22 is not essential for binding to the human Jurkat T-lymphocyte Kv1.3 channel. While decreasing bulkiness at this position affected toxin affinity for the brain K channels, increasing bulkiness decreased toxin affinity for both brain and lymphocyte K channels. In contrast to the rat brain channels, ShK binding to Kv1.3 was sensitive to substitution at Lys9 and Arg11.

Chemical synthesis and characterization of ShK toxin: a potent potassium channel inhibitor from a sea anemone.

ShK-toxin, a 35 residue peptide isolated from the sea anemone Stichodactyla helianthus, was synthesized using an Fmoc strategy and successfully folded to the biologically active form containing three intramolecular disulfide bonds. The ability of synthetic ShK toxin to inhibit specific [125I]-dendrotoxin I binding to rat brain membranes slightly exceeded (was more potent than) that of the natural ShK toxin sample, but was comparable with previously reported data for ShK toxin. The peptide toxin inhibited [125I]-charybdotoxin binding to Jurkat T lymphocytes with an IC50 value of 32 pM. In addition, Jurkat T lymphocytes Kv1.3 potassium channels were inhibited with an IC50 value of 133 pM. Owing to their unique structure and high affinity for at least some potassium channels, ShK toxin and related sea anemone potassium channel toxins may become useful molecular probes for investigating potassium channels.

Evidence for several types of biologically active substances in north Pacific sea anemones.

1. Twenty-two sea anemone samples from seven species were collected in Aleutian and Comandorskiye Islands from sub-littoral region (> 50m depth). 2. Water-ethanol extracts of sea anemones were tested using various test-systems after ethanol evaporation. 3. All sea anemones extracts inhibited DNA and most of them inhibited RNA synthesis in Ehrlich carcinoma tumor cells. 4. Extracts of most sea anemones species showed high hemolytic activity. 5. The extracts proved to be nontoxic or display low toxicity being i.p. injected into mice. 6. Some extracts precipitated virus of aleutian disease of mink. 7. None of the extracts showed activity toward Gram +ve, Gram -ve bacteria or yeast.

Sea anemone Radianthus macrodactylus--a new source of palytoxin.

A very potent non-protein toxin was isolated from the sea anemone Radianthus macrodactylus with the use of chromatography on polytetrafluoroethylene, CM-Sephadex C-25 and by cation and anion exchange HPLC. The toxin was identified as palytoxin by u.v.-, i.r.- and 500 MHz 1H NMR spectroscopy. Its LD50 was 0.74 +/- 0.29 micrograms/kg by i.v. injection into mice. So far, palytoxin has been associated with zoanthids only. The toxin caused the loss of haemoglobin from erythrocytes but only in about 2 hr after the beginning of incubation, which is characteristic for palytoxin from zoanthids. Sea anemone palytoxin was divided into major and minor components by HPLC. The latter proved to be a product of degradation of palytoxin.

Structure-toxicity relationships of neurotoxin RTX-III from the sea anemone Radianthus macrodactylus: modification of amino groups.

The effect of modification of amino groups on RTX-III induced lethality in mice has been studied. The toxicity was not affected by guanidination of one or two lysine residues with O-methylisourea, but guanidination of three or four lysine residues decreased lethality two-fold. Acetylation of the N-terminal amino group with [3H]acetic anhydride caused a 12-fold decrease of lethality. The toxin containing acetylated Lys-4 or one of three C-terminal lysine residues had half the lethal potency of the native RTX-III. Diacetylated derivatives were 30- to 35-fold less toxic than the native toxin. By circular dichroism, it was shown that modification of one or two amino groups did not affect the secondary structure of the toxin. We conclude that protonated amino groups are essential for neurotoxicity.

Modification of carboxyl groups in sea anemone toxin RTX-III from Radianthus macrodactylus.

The toxin was treated with [14C]trimethyloxonium tetrafluoroborate or [3H]glycine methyl ester in the presence of 1-ethyl-3(3-dimethylaminopropyl) carbodiimide. Esterification of separate carboxyl groups with [14C]trimethyloxonium tetrafluoroborate decreased the toxicity no more than two-fold. Blocking of any single carboxyl group with [3H]glycine methyl ester did not cause more than a two-fold decrease of toxicity, and modification of two carboxyl groups caused no more than a six-fold decrease. Partial localization of modified residues in the amino acid sequence was performed. By circular dichroism, it was shown that the decrease of toxicity was not associated with alteration of secondary or tertiary structure. It is concluded that free carboxyl groups are not absolutely essential for toxicity, however they are necessary for expression of the maximum RTX-III toxicity.

Modification of arginine in sea anemone toxin RTX-III from Radianthus macrodactylus.

Chemical modifications of the polypeptide neurotoxin RTX-III have allowed us to study the functional role of Arg residues. The effect of chemical modification has been estimated by measuring toxicity in mice. 2,4-Pentanedione did not react with Arg residues of RTX-III even after 100 hr incubation. Malonic aldehyde reacted readily with RTX-III, yielding an unusual derivative; a Schiff's base obtained by condensation of one of two aldehyde groups of malonic aldehyde with the guanidine group. The derivative was one-fourth as toxic as the native toxin. Modification of the guanidine side chain of Arg-13 with both 1,2-cyclohexanedione and phenylglyoxal decreased the toxicity of RTX-III by a factor of five. We conclude that Arg-13 is not fully responsible for toxicity. The toxin-receptor attachment might be multipoint, involving several structural elements of the protein molecule, with Arg-13, probably being one of them. The guanidine side chain of Arg-45 is buried in the sequence and apparently functionally nonessential.