Large conductance Ca2+ -activated K+ (BK) channel activity and its potentiation by ethanol are both critically modulated by bilayer phosphatidylserine (PS), a phospholipid involved in membrane-bound signaling. Whether PS is uniquely required for ethanol to modify channel activity is unknown. Furthermore, the structural determinants in membrane phospholipid molecules that control alcohol action remain to be elucidated. We addressed these questions by reconstituting BK channels from human brain (hslo) into bilayers that contained phospholipids differing in headgroup size, charge, and acyl chain saturation. Data demonstrate that ethanol potentiation of hslo channels is blunted by conical phospholipids but favored by cylindrical phospholipids, independently of phospholipid charge. As found with ethanol action, basal channel activity is higher in bilayers containing cylindrical phospholipids. Basal activity and its ethanol potentiation in bilayers containing phosphatidylcholine, however, are not as robust as in those containing PS. These results are best interpreted as resulting from the relief of bilayer stress caused by inclusion of cylindrical phospholipids, with this relief being synergistically evoked by molecular shape and negative headgroup charge. Present findings suggest that hslo gating structures targeted by ethanol are accessible to sense changes in bilayer stress. In contrast, hslo unitary conductance is significantly higher in bilayers that contain negatively charged phospholipids independently of molecular shape, a result that is likely to be dependent on an interaction between anionic phospholipids and deep channel residues coupled to the selectivity filter.

The activity of large conductance, Ca2+-sensitive K+ (BKCa) channels, known to control neuronal excitability, is increased by ethanol (EtOH) exposure. Moreover, brain cholesterol (CHS) is elevated after chronic exposure to EtOH, suggesting that membrane CHS may play a role in drug tolerance. Here, we use BKCa channels from human brain (hslo subunits), reconstituted into 1-palmitoyl-2-oleoyl phosphatidylethanolamine/1-palmitoyl-2-oleoyl phosphatidylserine (POPS) bilayers, to examine CHS modulation of EtOH sensitivity. Acute exposure to clinically relevant EtOH levels increases channel activity without modifying conductance. In this minimal system, increases in CHS content within the range found in neuronal membranes lead to progressive antagonism of EtOH action. Furthermore, CHS inhibits basal channel activity with an affinity similar to that of CHS blunting of the alcohol effect. Modification of channel gating by either EtOH or CHS is reduced dramatically by removal of POPS from the bilayer, suggesting a common mechanism(s) of action. Indeed, channel dwell-time analysis indicates that CHS and EtOH exert opposite actions on the stability of channel closed states. However, each agent also acts on distinct dwell states not mirrored by the other, which contribute to the opposite effects of CHS and EtOH on channel gating.

The large conductance Ca++-activated K+ channel (BKCa) regulates neuronal excitability through the efflux of K+, in response to membrane depolarization and increases in intracellular Ca++. The activity of the BKCa channel is increased by acute exposure to ethanol (EtOH), which is thought to underlie, in part, the influence of the drug on peptide hormone release from neurohypophysial nerve terminals (Dopico et al., 1996, 1998). Moreover, chronic EtOH exposure attenuates acute drug action on hormone release, and reduces the sensitivity of BKCa channels to acute EtOH exposure (Knott et al., 2002). The factors regulating EtOH action on BKCa channels are not well understood. Several lines of evidence suggest, however, that the lipid composition of the plasma membrane may influence channel sensitivity to the drug. The plasma membrane is highly complex in its organization (Welti and Glaser, 1994; Brown and London, 1998). There is a growing body of literature indicating that the local lipid composition of the membrane can influence the function of ion channels, including BKCa (Chang et al., 1995a, b; Moczydlowski et al., 1985; Park et al., 2003; Turnheim et al., 1999). Interestingly, chronic exposure to EtOH in animal models results in alterations in the composition of synaptic plasma membranes, including changes in the amount and distribution of membrane cholesterol (CHS) (Chin et al., 1978; Chin et al., 1979; Wood et al., 1989). The significance of these alterations is unclear. Here, we set out to determine the ability of membrane lipids to modulate BKCa channel activity and EtOH sensitivity. To address this, we implement the planar lipid bilayer technique, allowing control of both the protein and lipid components of the membrane. Native BKCa channels retain EtOH sensitivity in this reductionist preparation (Chu et al., 1998), and we extend the study here to examine cloned human brain (hslo) BKCachannels. We show here that hslo channels maintain their characteristic large conductance, voltage and Ca++-dependent gating, and sensitivity to 50 mM EtOH in bilayers cast from a 3:1 mixture of 1-pamiltoyl-2-oleoyl-phosphatidylethanolamine (POPE) and 1-pamiltoyl-2-oleoyl-phosphatidylserine (POPS). The addition of CHS to the bilayer decreases both the basal activity and EtOH sensitivity of the channels, in a concentration-dependent manner. This lends support to the notion that alterations in plasma membrane CHS levels following chronic EtOH exposure may reflect adaptations to the acute actions of the drug on ion channels. Furthermore, the EtOH sensitivity and CHS modulation of these reconstituted hslo channels are greatly reduced in the absence of negatively charged POPS in the bilayer (pure POPE). Based on these findings, we look to gain mechanistic insight into the lipid headgroup and acyl chain properties that may regulate BKCa channel modulation by EtOH and CHS. When POPS is replaced with the uncharged lipid 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC), the hslo response to EtOH and CHS is restored, suggesting that the loss of negative surface charge or PS headgroup structure itself cannot explain the lack of channel modulation by these agents in POPE bilayers. Moreover, increases in the proportion of unsaturated acyl chains in the bilayer cannot significantly influence the hslo response to EtOH. The loss of EtOH sensitivity in pure POPE and CHS-containing bilayers may, therefore, reflect the propensity of POPE and CHS to form nonlamellar (nonbilayer) structures. Regarding the basal activity of the channel, we demonstrate that decreases in negative surface charge, increases in the proportion of unsaturated acyl chains, and increases in the complexity of head group interactions can all influence the steady-state activity of reconstituted hslochannels, relative to control POPE/POPS (3:1) bilayers. Overall, these data further suggest the ability of the local lipid environment to regulate the basal function and EtOH sensitivity of an ion channel protein. Parts of this dissertation have appeared in separate publications: Treistman, S.N., O'Connell, R.J., and Crowley, J.J. (2002). Artificial Bilayer Techniques in Ion Channel Study. In Methods in Alcohol-Related Neuroscience Research, D. Lovinger and Y. Liu, eds. (Boca Raton, Florida: CRC Press) Crowley, J.J., Treistman, S.N., and Dopico, A.M. (2003). Cholesterol antagonizes ethanol potentiation of human BKCA channels in binary phospholipid bilayers. Mol. Pharma. 64(2):364-372.