Many human hereditary neurodegenerative diseases are caused by expanded CAG repeats, and anonymous CAG expansions have also been described in schizophrenia and bipolar disorder. We have isolated and sequenced a novel human cDNA encoding a neuronal, small conductance calcium-activated potassium channel (hSKCa3) that contains two arrays of CAG trinucleotide repeats. The second CAG repeat in hSKCa3 is highly polymorphic in control individuals, with alleles ranging in size from 12 to 28 repeats. The overall allele frequency distribution is significantly different in patients with schizophrenia compared to ethnically matched controls (Wilcoxon Rank Sum test, P = 0.024), with CAG repeats longer than the modal value being over-represented in patients (Fisher Exact test, P = 0.0035). A similar, non-significant, trend is seen for patients with bipolar disorder. These results provide evidence for a possible association between longer alleles in the hSKCa3 gene and both of these neuropsychiatric diseases, and emphasize the need for more extensive studies of this new gene. Small conductance calcium-activated K + channels play a critical role in determining the firing pattern of neurons. These polyglutamine repeats may modulate hSKCa3 channel function and neuronal excitability, and thereby increase disease risk when combined with other genetic and environmental effects.
Aquaporins facilitate the diffusion of water across cell membranes. We previously showed that acid pH or low Ca2+ increase the water permeability of bovine AQP0 expressed in Xenopus oocytes. We now show that external histidines in loops A and C mediate the pH dependence. Furthermore, the position of histidines in different members of the aquaporin family can “tune” the pH sensitivity toward alkaline or acid pH ranges. In bovine AQP0, replacement of His40 in loop A by Cys, while keeping His122 in loop C, shifted the pH sensitivity from acid to alkaline. In the killifish AQP0 homologue, MIPfun, with His at position 39 in loop A, alkaline rather than acid pH increased water permeability. Moving His39 to His40 in MIPfun, to mimic bovine AQP0 loop A, shifted the pH sensitivity back to the acid range. pH regulation was also found in two other members of the aquaporin family. Alkaline pH increased the water permeability of AQP4 that contains His at position 129 in loop C. Acid and alkaline pH sensitivity was induced in AQP1 by adding histidines 48 (in loop A) and 130 (in loop C). We conclude that external histidines in loops A and C that span the outer vestibule contribute to pH sensitivity. In addition, we show that when AQP0 (bovine or killifish) and a crippled calmodulin mutant were coexpressed, Ca2+ sensitivity was lost but pH sensitivity was maintained. These results demonstrate that Ca2+ and pH modulation are separable and arise from processes on opposite sides of the membrane.
The voltage-gated potassium channel in T lymphocytes, Kv1.3, an important target for immunosuppressants, is blocked by picomolar concentrations of the polypeptide ShK toxin and its analogue ShK-Dap22. ShK-Dap22 shows increased selectivity for Kv1.3, and our goal was to determine the molecular basis for this selectivity by probing the interactions of ShK and ShK-Dap22 with the pore and vestibule of Kv1.3. The free energies of interactions between toxin and channel residues were measured using mutant cycle analyses. These data, interpreted as approximate distance restraints, guided molecular dynamics simulations in which the toxins were docked with a model of Kv1.3 based on the crystal structure of the bacterial K(+)-channel KcsA. Despite the similar tertiary structures of the two ligands, the mutant cycle data imply that they make different contacts with Kv1.3, and they can be docked with the channel in configurations that are consistent with the mutant cycle data for each toxin but quite distinct from one another. ShK binds to Kv1.3 with Lys22 occupying the negatively charged pore of the channel, whereas the equivalent residue in ShK-Dap22 interacts with residues further out in the vestibule, producing a significant change in toxin orientation. The increased selectivity of ShK-Dap22 is achieved by strong interactions of Dap22 with His404 and Asp386 on Kv1.3, with only weak interactions between the channel pore and the toxin. Potent and specific blockade of Kv1.3 apparently occurs without insertion of a positively charged residue into the channel pore. Moreover, the finding that a single residue substitution alters the binding configuration emphasizes the need to obtain consistent data from multiple mutant cycle experiments in attempts to define protein interaction surfaces using these data.
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