Designed peptide analogues of the potassium channel blocker ShK toxin.

ShK toxin, a potassium channel blocker from the sea anemone Stichodactyla helianthus, is a 35-residue polypeptide cross-linked by 3 disulfide bridges. In an effort to generate truncated peptidic analogues of this potent channel blocker, we have evaluated three analogues, one in which the native sequence was truncated and then stabilized by the introduction of additional covalent links (a non-native disulfide and two lactam bridges), and two in which non-native structural scaffolds stabilized by disulfide and/or lactam bridges were modified to include key amino acid residues from the native toxin. The effect of introducing a lactam bridge in the first helix of ShK toxin (to create cyclo14/18[Lys14,Asp18]ShK) was also examined to confirm that this modification was compatible with activity. All four analogues were tested in vitro for their ability to block Kv1.3 potassium channels in Xenopus oocytes, and their solution structures were determined using 1H NMR spectroscopy. The lactam bridge in full-length ShK is well tolerated, with only a 5-fold reduction in binding to Kv1.3. The truncated and stabilized analogue was inactive, apparently due to a combination of slight deviations from the native structure and alterations to side chains required for binding. One of the peptide scaffolds was also inactive because it failed to adopt the required structure, but the other had a K(d) of 92 microM. This active peptide incorporated mimics of Lys22 and Tyr23, which are essential for activity in ShK, and an Arg residue that could mimic Arg11 or Arg24 in the native toxin. Modification of this peptide should produce a more potent, low molecular weight peptidic analogue which will be useful not only for further in vitro and in vivo studies of the effect of blocking Kv1.3, but also for mapping the interactions with the pore and vestibule of this K(+) channel that are required for potent blockade.

A helical capping motif in ShK toxin and its role in helix stabilization.

ShK toxin, a 35-residue polypeptide cross-linked by three disulfides, is a potent blocker of voltage-gated potassium channels and is of interest as a lead in the development of new immunosuppressant agents. ShK toxin contains two short stretches of alpha-helix, the first of which is preceded by a putative N-capping box encompassing residues Thr13 and Gln16. (1)H and (13)C NMR data support the presence of this structural motif, but the hydrogen bonds involving residues 13 and 16 in the solution structure of ShK toxin do not match the pattern expected for a conventional N-cap motif. They do, however, fit the pattern for the recently described ST-motif, class 4a (Wan and Milner-White (1999) Journal of Molecular Biology, 1999, Vol. 286, pp. 1651-1662). The (1)H NMR chemical shifts, nuclear Overhauser effects, and amide exchange rates of native ShK toxin are compared with those of three synthetic analogues with the substitutions Thr13 to Ala and Gln16 to Glu and Ala in order to determine the contribution of this motif to the structure and stability of ShK toxin. Disruption of the capping interactions destabilizes the helices, with the Thr13 to Ala substitution being much more disruptive than Gln16 to Ala, consistent with the lack of hydrogen bonding to the side chain of residue i + 4 in a class 4a ST-motif. Mutation of residues 13 and 16 has only a minor effect on potassium channel binding, probably because the disulfide bonding network minimizes the effect of loss of the capping motif on the overall structure. The implications of these findings for the design of ShK analogues are discussed.

Structure-guided transformation of charybdotoxin yields an analog that selectively targets Ca(2+)-activated over voltage-gated K(+) channels.

We have used a structure-based design strategy to transform the polypeptide toxin charybdotoxin, which blocks several voltage-gated and Ca(2+)-activated K(+) channels, into a selective inhibitor. As a model system, we chose two channels in T-lymphocytes, the voltage-gated channel Kv1.3 and the Ca(2+)-activated channel IKCa1. Homology models of both channels were generated based on the crystal structure of the bacterial channel KcsA. Initial docking of charybdotoxin was undertaken with both models, and the accuracy of these docking configurations was tested by mutant cycle analyses, establishing that charybdotoxin has a similar docking configuration in the external vestibules of IKCa1 and Kv1.3. Comparison of the refined models revealed a unique cluster of negatively charged residues in the turret of Kv1.3, not present in IKCa1. To exploit this difference, three novel charybdotoxin analogs were designed by introducing negatively charged residues in place of charybdotoxin Lys(32), which lies in close proximity to this cluster. These analogs block IKCa1 with approximately 20-fold higher affinity than Kv1.3. The other charybdotoxin-sensitive Kv channels, Kv1.2 and Kv1. 6, contain the negative cluster and are predictably insensitive to the charybdotoxin position 32 analogs, whereas the maxi-K(Ca) channel, hSlo, lacking the cluster, is sensitive to the analogs. This provides strong evidence for topological similarity of the external vestibules of diverse K(+) channels and demonstrates the feasibility of using structure-based strategies to design selective inhibitors for mammalian K(+) channels. The availability of potent and selective inhibitors of IKCa1 will help to elucidate the role of this channel in T-lymphocytes during the immune response as well as in erythrocytes and colonic epithelia.

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.

ShK-Dap22, a potent Kv1.3-specific immunosuppressive polypeptide.

The voltage-gated potassium channel in T lymphocytes, Kv1.3, is an important molecular target for immunosuppressive agents. A structurally defined polypeptide, ShK, from the sea anemone Stichodactyla helianthus inhibited Kv1.3 potently and also blocked Kv1.1, Kv1.4, and Kv1.6 at subnanomolar concentrations. Using mutant cycle analysis in conjunction with complementary mutagenesis of ShK and Kv1.3, and utilizing the structure of ShK, we determined a likely docking configuration for this peptide in the channel. Based upon this topological information, we replaced the critical Lys22 in ShK with the positively charged, non-natural amino acid diaminopropionic acid (ShK-Dap22) and generated a highly selective and potent blocker of the T-lymphocyte channel. ShK-Dap22, at subnanomolar concentrations, suppressed anti-CD3 induced human T-lymphocyte [3H]thymidine incorporation in vitro. Toxicity with this mutant peptide was low in a rodent model, with a median paralytic dose of approximately 200 mg/kg body weight following intravenous administration. The overall structure of ShK-Dap22 in solution, as determined from NMR data, is similar to that of native ShK toxin, but there are some differences in the residues involved in potassium channel binding. Based on these results, we propose that ShK-Dap22 or a structural analogue may have use as an immunosuppressant for the prevention of graft rejection and for the treatment of autoimmune diseases.