Structural diversity among subtypes of small-conductance Ca2+-activated potassium channels.

125I-Apamin and photolabile derivatives of the toxin have been used to investigate the binding properties and subunit composition of small conductance Ca2+-activated potassium channels (SK(Ca) channels) expressed on plasma membranes from rat brain, rabbit liver, or rat pheochromocytoma (PC12) cells. On all preparations, 125I-apamin recognized single classes of acceptor binding sites with similar high affinity (Kd approximately 3-6 pM). Gallamine, however, was found to readily discriminate between 125I-apamin acceptors present in these preparations, showing a maximal approx nine-fold difference in affinity for acceptors expressed by rabbit liver or PC12 cells. Affinity-labeling patterns revealed the expression of different hetero-oligomeric combinations of high (86 or 59 kDa) and low (33 or 30 kDa) molecular mass 125I-apamin-binding polypeptides, consistent with pharmacological differences. Alternative expression of either 86- or 59-kDa polypeptides appeared to be the most important factor influencing gallamine's affinity for SK(Ca) channel subtypes. Both high- and low-molecular-mass polypeptides are integral membrane proteins, the latter being glycosylated in a tissue-specific manner.

A novel small conductance Ca2+-activated K+ channel blocker from Oxyuranus scutellatus taipan venom. Re-evaluation of taicatoxin as a selective Ca2+ channel probe.

Taicatoxin, isolated from the venom of the Australian taipan snake Oxyuranus scutellatus, has been previously regarded as a specific blocker of high threshold Ca2+ channels in heart. Here we show that taicatoxin (in contrast to a range of other Ca2+ channel blockers) interacts with apamin-sensitive, small conductance, Ca2+-activated potassium channels on both chromaffin cells and in the brain. Taicatoxin displays high affinity recognition of 125I-apamin acceptor-binding sites, present on rat synaptosomal membranes (Ki = 1.45 +/- 0.22 nM) and also specifically blocks affinity-labeling of a 33-kDa 125I-apamin-binding polypeptide on rat brain membranes. Taicatoxin (50 nM) completely blocks apamin-sensitive after-hyperpolarizing slow tail K+ currents generated in rat chromaffin cells (mean block 97 +/- 3%, n = 12) while only partially reducing total voltage-dependent Ca2+ currents (mean block 12 +/- 4%, n = 6). In view of these findings, the use of taicatoxin as a specific ligand for Ca2+ channels should now be reconsidered.

Photolabile derivatives of 125I-apamin: defining the structural criteria required for labeling high and low molecular mass polypeptides associated with small conductance Ca(2+)-activated K+ channels.

The structure of apamin-sensitive Ca(2+)-activated K+ channels has been investigated using high-affinity, photolabile azidoaryl derivatives of 125I-[alpha-formyl-Cys1]apamin and 125I-[epsilon-formyl-Lys4]-apamin. Labeling patterns suggest that similar structural constraints are required for labeling analogous polypeptides associated with distinct channel subtypes. When photoprobes are coupled at the epsilon-amino-Lys4 position of apamin, comparable low molecular mass (approximately 30 kDa) polypeptides are efficiently labeled on either brain or liver plasma membranes, irrespective of the structure of the photoprobe. However, when photoprobes are coupled at the alpha-amino-Cys1 position of apamin, the pattern of labeling on both brain and liver plasma membranes varies, depending upon the length of the spacer arm incorporated into the photoprobe. Spacer arms of approximately 8-9 A efficiently label only high molecular mass polypeptides (86, 59 kDa), accompanied by weak, variable labeling of a 44-kDa component. A shorter spacer arm (5.7 A) results in feeble labeling of 86- and 59-kDa polypeptides and barely detectable labeling of 44- and approximately 30-kDa polypeptides. In contrast, a long spacer arm (12.8 A) efficiently labels only approximately 30-kDa polypeptides. These findings point to close similarities in the topography of the 125I-apamin binding site present on pharmacologically distinct subtypes of apamin-sensitive Ca2+-activated K+ channels and indicates that heterooligomeric association of high and low molecular mass polypeptide subunits may be a general structural feature of members belonging to this family of K+ channels.

Alteration in the glial cell metabolism of glutamate by kainate and N-methyl-D-aspartate.

Incubation of coronal slices of rat brain with neurotoxic concentrations of kainate (300 microM) and N-methyl-D-aspartate (NMDA; 500 microM) for 40 min reduced the activity of the glial enzyme, glutamine synthetase, by 33% and 21%, respectively. The immunoreactivity of the neuronal enzyme, gamma gamma-enolase (neuron-specific enolase), was also decreased, but to a lesser extent than glutamine synthetase. Pre-incubation of the slices with L-methionine-S-sulphoximine (500 microM), an irreversible inhibitor of both glutamine synthetase and gamma-glutamylcysteine synthetase, before addition of either kainate or NMDA produced a supra-additive reduction in the activity of the enzyme in both cases. Neither kainate nor NMDA directly inhibited the activity of glutamine synthetase, but kainate did inhibit gamma-glutamylcysteine synthetase, a rate-limiting enzyme of the gamma-glutamyl cycle, which is responsible for maintaining glutathione levels within cells. Pre-incubation of the slices with L-NG-nitroarginine, a competitive inhibitor of nitric oxide synthase, effectively prevented the NMDA-induced reduction in glutamine synthetase and neuron specific enolase, but did not diminish the kainate-induced decrease in the activity of either enzyme. These results provide evidence that NMDA, as well as kainate, indirectly affects the activity of glutamine synthetase in brain slices, yet does so by a different mechanism from kainate. The results are discussed in terms of the possible mode of action of each toxin in inhibiting the glial cell metabolism of glutamate.

Comparable 30-kDa apamin binding polypeptides may fulfill equivalent roles within putative subtypes of small conductance Ca(2+)-activated K+ channels.

Apamin, a peptide neurotoxin from bee venom, blocks small conductance Ca(2+)-activated K+ channels in central synapses and peripheral tissues. Using 125I-apamin, single classes of high affinity binding sites (Kd 1-3 pM) were identified on plasma membranes from rat, rabbit, guinea pig, and bovine brain and from rabbit, guinea pig, and bovine liver. Binding was sensitive to scyllatoxin, dequalinium, gallamine, and d-tubocurarine but not to charybdotoxin, toxin I, or mast cell degranulating peptide. In contrast, saturable binding of 125I-apamin to rat liver plasma membranes was virtually undetectable, thereby providing a correlation with the ability to measure apamin-sensitive Ca(2+)-activated potassium currents in rabbit and guinea pig hepatocytes but not in rat hepatocytes. In agreement with membrane binding studies, homobifunctional cross-linkers identified apparently identical 33-kDa 125I-apamin binding polypeptides on brain plasma membranes from all species and analogous but distinct polypeptides on plasma membranes from rabbit, guinea pig, and bovine liver. None of these affinity-labeled polypeptides were detectable on plasma membranes from rat liver. Affinity labeling was abolished on both liver and brain membranes by apamin, scyllatoxin, dequalinium, gallamine, and d-tubocurarine. These results indicate that comparable approximately 30-kDa polypeptides may fulfill equivalent functional roles within putative subtypes of apamin-sensitive small conductance Ca(2+)-activated K+ channels.