Site of resting state inhibition of the nicotinic acetylcholine receptor by a hydrophobic inhibitor.

The lipophilic photoactivatable probe 3-(trifluoromethyl)-3-(m-iodophenyl) diazirine (TID) is a noncompetitive, resting-state inhibitor of the nicotinic acetylcholine receptor (nAChR) that requires tens of milliseconds of preincubation to inhibit agonist-induced cation efflux. At equilibrium, [(125)I]TID photoincorporates into both the ion channel and the lipid-protein interface of the Torpedo nAChR. To determine which of these regions is responsible for resting-state inhibition, we characterized the interactions between [(125)I]TID and nAChR-rich membranes milliseconds after mixing, by use of time-resolved photolabeling. Photolabeling was performed after preincubation times of 2 ms or 600 s (equilibrium), and the efficiencies of incorporation at specific residues were determined by amino-terminal sequence analysis of nAChR-subunit proteolytic fragments isolated by SDS-PAGE and/or reversed-phase HPLC. Equilibration of TID with lipid was complete within a millisecond as determined by both stopped-flow fluorescence quenching of diphenylhexatriene in lipid bilayers and photoincorporation into nAChR-rich membrane phospholipids. Equilibration with the lipid-protein interface (alphaM4) was slightly slower, reaching approximately 50% that at equilibrium after 2 ms preincubation. In contrast, equilibration with the channel region (alpha 2 and deltaM2) was much slower, reaching only 10% that at equilibrium after 2 ms preincubation. Within the ion channel, the ratio of [(125)I]TID incorporation between M2 residues 9', 13', and 16' was independent of preincubation time. We conclude that TID's access to the ion channel is more restricted than to the lipid-protein interface and that TID bound within the ion channel is responsible for flux inhibition upon activation of the nAChR.

Synthesis and properties of 3-(2-hydroxyethyl)-3-n-pentyldiazirine, a photoactivable general anesthetic.

To overcome the difficulties of locating the molecular sites of general anesthetic action, we synthesized a novel photoactivable general anesthetic, 3-(2-hydroxyethyl)-3-n-pentyldiazirine (3-diazirinyloctanol), which anesthetized tadpoles with an ED(50) of 160 microM. Subanesthetic concentrations of 3-diazirinyloctanol enhanced GABA-induced currents in GABA(A) receptors, an effect that has been implicated in general anesthetic action. It also enhanced [(3)H]muscimol binding to this receptor. In muscle nicotinic acetylcholine receptors (nAcChoR), it inhibited the response to acetylcholine with an IC(50) of 33 microM. 3-Diazirinyloctanol's pharmacological actions were comparable to those of octanol. 3-(2-Hydroxyethyl)-3-[4,5-(3)H(2)]-n-pentyldiazirine photoincorporated into Torpedo nAcChoR-rich membranes mainly in the alpha subunit with 70% being in a proteolytic fragment containing the M4 transmembrane segment. Agonist enhanced the photolabeling 10-fold in a fragment containing the M1, M2, and M3 transmembrane segments. Thus, 3-diazirinyloctanol is a novel general anesthetic that acts on, and can be photoincorporated into, postsynaptic receptors.

Time-resolved photolabeling of membrane proteins: application to the nicotinic acetylcholine receptor.

An apparatus has been developed that allows photoaffinity ligands to be crossed-linked to milligram quantities of membrane proteins with maximum attainable yield following contact times of approximately 1 ms. The apparatus consisted of three parts: a conventional rapid mixing unit, a novel freeze-quench unit, and a photolabeling unit. The freeze-quench unit consisted of a rapidly rotating metal disk which was precooled in liquid nitrogen. Correct alignment of the exit jet from the sample mixer allowed up to 2 ml of sample to be frozen in a thin film on the disk. Experiments with colorimetric reactions showed the combined dead time of mixing and freeze-quenching to be submillisecond. Photoincorporation was maximized by prolonged irradiation of the freeze-quenched sample. Using this apparatus we determine the binding kinetics of the resting state channel inhibitor 3-[125I](trifluoromethyl)-3-(m-iodophenyl) diazirine (TID) to nicotinic acetylcholine receptor-rich membranes from Torpedo. The binding kinetics for the 125I-labeled alpha and delta subunits were biphasic; about half the binding was complete by 2.4 ms, and the remainder could be resolved and occurred with a pseudo-first-order rate constant determined at 4 microM [125I]TID of 12.0 +/- 2.3 and 13.6 +/- 4.0 s-1, respectively. This compares well to the same constant determined for the inhibition of agonist-induced cation flux in Torpedo membranes.

Where does cholesterol act during activation of the nicotinic acetylcholine receptor?

Why agonist-induced activation of the nicotinic acetylcholine receptor (nAcChoR) fails completely in the absence of cholesterol is unknown. Affinity-purified nAcChoRs from Torpedo reconstituted into 1,2-dioleoyl-sn-glycero-3-phosphatidylcholine/1, 2-dioleoyl-sn-glycero-3-phosphate/steroid bilayers at mole ratios of 58:12:30 were used to distinguish between three regions of the membrane where cholesterol might act: the lipid bilayer, the lipid-protein interface, or sites within the protein itself. In the bilayer, the role of fluidity has been ruled out and certain neutral lipids can substitute for cholesterol [C. Sunshine, M.G. McNamee, Biochim. Biophys. Acta 1191 (1994) 59-64]; therefore, we first tested the hypothesis that flip-flop of cholesterol across the membrane is important; a plausible mechanism might be the relief of mechanical bending strain induced by a conformation change that expands the two leaflets of the bilayer asymmetrically. Cholesterol analogs prevented from flipping by charged groups attached to the 3-position's hydroxyl supported channel opening, contrary to this hypothesis. The second hypothesis is that interstitial cholesterol binding sites exist deep within the nAcChoR that must be occupied for channel opening to occur. When cholesterol hemisuccinate was covalently 'tethered' to the glycerol backbone of phosphatidylcholine, channel opening was still supported. Thus, if there are functionally important cholesterol sites, they must be very close to the lipid-protein interface and might be termed periannular.

Approaches to proving there are general anesthetic sites on ligand gated ion channels.

(1) There are at least two broad classes of general anesthetic action on the anesthetic-sensitive ligand gated superfamily of ion channels. (2) First, some channels may be inhibited upon opening. Pharmacology, kinetics and site directed mutagenesis all suggest that inhibition is mediated by a site on the acetylcholine receptor probably located in the channel lumen. (3) Second, the agonist's concentration response curve may be shifted to the left without affecting the maximum response. (4) This effect does not saturate with anesthetic concentration and might involve partial occupancy of many low affinity sites, mechanism consistent with the observation that the conformation changes accompanying channel gating involve most structural features of the receptor and its surrounding environment.

The cholesterol dependence of activation and fast desensitization of the nicotinic acetylcholine receptor.

When nicotinic acetylcholine receptors are reconstituted into lipid bilayers lacking cholesterol, agonists no longer stimulate cation flux. The kinetics of this process are difficult to study because variations in vesicle morphology cause errors in flux measurements. We developed a new stopped-flow fluorescence assay to study activation independently of vesicle morphology. When receptors were rapidly mixed with agonist plus ethidium, the earliest fluorescence increase reported the fraction of channels that opened and their apparent rate of fast desensitization. These processes were absent when the receptor was reconstituted into dioleoylphosphatidylcholine or into a mixture of that lipid with dioleoylphosphatidic acid (12 mol%), even though a fluorescent agonist reported that resting-state receptors were still present. The agonist-induced channel opening probability increased with bilayer cholesterol, with a midpoint value of 9 +/- 1.7 mol% and a Hill coefficient of 1.9 +/- 0.69, reaching a plateau above 20-30 mol% cholesterol that was equal to the native value. On the other hand, the observed fast desensitization rate was comparable to that for native membranes from the lowest cholesterol concentration examined (5 mol%). Thus the ability to reach the open state after activation varies with the cholesterol concentration in the bilayer, whereas the rate of the open state to fast desensitized state transition is unaffected. The structural basis for this is unknown, but an interesting corollary is that the channels of newly synthesized receptors are not fully primed by cholesterol until they are inserted into the plasma membrane--a novel form of posttranslational processing.

A novel peptide-IgG conjugate, CAP18(106-138)-IgG, that binds and neutralizes endotoxin and kills gram-negative bacteria.

Although type-specific IgG directed to the O-polysaccharide antigen of bacterial lipopolysaccharide (LPS) is protective in most models of LPS or bacterial challenge, no currently available IgG binds to LPS from all gram-negative bacteria. The ability of a peptide-IgG conjugate, CAP18(106-138)-IgG, to bind and neutralize LPS, to kill gram-negative bacteria, and to protect in a sensitized mouse model of LPS toxicity was studied. CAP18(106-138)-IgG bound LPS from multiple gram-negative bacteria in four different binding assays. In a fluid-phase RIA, half-maximal binding of 5 microg/mL 3H-labeled LPS occurred at 5-10 microg/mL CAP18(106-138)-IgG, similar to binding with monoclonal type-specific IgG. CAP18(106-138)-IgG neutralized LPS, as assessed by LPS-induced coagulation of limulus amebocyte lysate and production of tumor necrosis factor in vitro, was bactericidal for a wide range of gram-negative bacteria, and decreased LPS-induced lethality in sensitized mice. Antibacterial peptide-IgG conjugates merit further study as a novel adjunctive therapy for gram-negative sepsis.

Amyloid beta-protein reduces acetylcholine synthesis in a cell line derived from cholinergic neurons of the basal forebrain.

The characteristic features of a brain with Alzheimer disease (AD) include the presence of neuritic plaques composed of amyloid beta-protein (Abeta) and reductions in the levels of cholinergic markers. Neurotoxic responses to Abeta have been reported in vivo and in vitro, suggesting that the cholinergic deficit in AD brain may be secondary to the degeneration of cholinergic neurons caused by Abeta. However, it remains to be determined if Abeta contributes to the cholinergic deficit in AD brain by nontoxic effects. We examined the effects of synthetic Abeta peptides on the cholinergic properties of a mouse cell line, SN56, derived from basal forebrain cholinergic neurons. Abeta 1-42 and Abeta 1-28 reduced the acetylcholine (AcCho) content of the cells in a concentration-dependent fashion, whereas Abeta 1-16 was inactive. Maximal reductions of 43% and 33% were observed after a 48-h treatment with 100 nM of Abeta 1-42 and 50 pM of Abeta 1-28, respectively. Neither Abeta 1-28 nor Abeta 1-42 at a concentration of 100 nM and a treatment period of 2 weeks was toxic to the cells. Treatment of the cells with Abeta 25-28 (48 h; 100 nM) significantly decreased AcCho levels, suggesting that the sequence GSNK (aa 25-28) is responsible for the AcCho-reducing effect of Abeta. The reductions in AcCho levels caused by Abeta 1-42 and Abeta 1-28 were accompanied by proportional decreases in choline acetyltransferase activity. In contrast, acetylcholinesterase activity was unaltered, indicating that Abeta specifically reduces the synthesis of AcCho in SN56 cells. The reductions in AcCho content caused by Abeta 1-42 could be prevented by a cotreatment with all-trans-retinoic acid (10 nM), a compound previously shown to increase choline acetyltransferase mRNA expression in SN56 cells. These results demonstrate a nontoxic, suppressive effect of Abeta on AcCho synthesis, an action that may contribute to the cholinergic deficit in AD brain.

13C nuclear magnetic resonance relaxation-derived psi, phi bond rotational energy barriers and rotational restrictions for glycine 13C alpha-methylenes in a GXX-repeat hexadecapeptide.

Spin-lattice relaxation of 13C multiplet spectra and [1H]-13C nuclear Overhauser enhancement (NOE) coefficients of selectively 13C-enriched glycines in a collagen GXX-repeat motif hexadecapeptide, G1VKG4DKG7NPG10WPG13APY, has been investigated. Data have been collected at two 13C Larmor frequencies (90 and 150 MHz) over the temperature range from 5 to 70 degrees C. Relaxation data indicate that the most restricted internal rotations are at G7 and G10. Mobility of other glycine residues can be arranged in the order G4, G13, and G1. G1 glycine shows that least change in motional anisotropy with temperature. Several motional models have been used to explain the experimental data. While any one model is not completely satisfactory in describing all experimental parameters, only the model of restricted internal diffusion yields the observed positive sign for the cross-correlated spectral densities. Energetic and angular limits of psi, phi bond rotational motions derived from relaxation data and the restricted diffusion model are in good agreement with those calculated as Ramachandran potentional energy profiles. G1 rotational energy barriers for overall tumbling and internal rotation are approximately equal, suggesting strong interaction between the N-terminus and water. Internal rotational parameters for GV and GG dipeptides confirm this view. Nonterminal glycine internal motions are apparently less dependent on water-peptide interactions.

Effects of free and macromolecular-bound TXA2 receptor antagonist BM 13.505 on U46619-induced platelet aggregation.

The goal of this study was to synthesize a macromolecular probe of the TXA2 receptor antagonist BM13.505 which is unable to penetrate the platelet membrane for localization and characterization of the TXA2 receptor. The active NHS-ester of BM13.505 was synthesized and purified. It was used for covalent coupling of BM13.505 to bovine serum albumin, a macromolecular carrier. Inhibitory effects of free and macromolecular bound BM13.505 on aggregatory properties of U46619-stimulated platelets were measured and compared to TXA2 generation in platelets, as determined by TXB2 radioimmunoassay. No inhibitory effects of free and macromolecular-bound BM13.505 on ADP- or thrombin-induced platelet aggregation were observed. Equimolar concentrations of free or macromolecular bound BM13.505 inhibited U46619-induced platelet aggregation and TXA2 generation with equal potency. IC50-values for platelet aggregation inhibition by free and macromolecular bound BM13.505 were 64 nM and 96 nM respectively. It appears that the TXA2 receptor ligand binding site is located close to the outer membrane surface of platelets. Interaction of macromolecular bound BM13.505 with the platelet thromboxane receptor does not depend on the availability of the free carboxyl residue in BM13.505. The method for coupling a TXA2 receptor antagonist to a macromolecule will aid in constructing probes for the localization and characterization of the TXA2 receptor.