Nuclear magnetic resonance investigation of the conformation of delta-haemolysin bound to dodecylphosphocholine micelles

Models of delta-hemolysin membrane channels and crystal structures

Molecular modeling and energy calculations have been used to study how delta-hemolysin and melittin helices may aggregate on membrane surfaces and insert through membranes to form channels. In these models adjacent antiparallel amphipathic helices form planar "raft" structures, in which one surface is hydrophobic and the other hydrophilic. Models of delta-hemolysin crystal structure were developed using these "rafts." These models are based on the unit cell constants and the crystal symmetry obtained from the preliminary crystal data. Energy calculations favor channel models of delta-hemolysin with six or eight monomers per channel.

Determination of the structure of a membrane-incorporated ion channel. Solid-state nuclear magnetic resonance studies of gramicidin A

Solid-state nuclear magnetic resonance (NMR) measurements on 13C-labeled analogues of the ion channel-forming peptide, gramicidin A, have been used to directly determine the structure of this peptide in lipid membranes. Seven gramicidin analogues, each labeled in a single carbonyl group of gly2, L-ala3, D-leu4, L-val7, D-leu10, D-leu12, or D-leu14 were synthesized by the solid-phase method. These gramicidin analogues were incorporated into aligned multilayers of dimyristoylphosphatidylcholine, or diether lipid bearing 14- or 16-carbon chains, at a 1:15 peptide:lipid mole ratio. Proton-enhanced, 13C, solid-state spectra were obtained at several temperatures and over a range of sample orientations with respect to the spectrometer magnetic field to permit accurate measurement of the chemical shift anisotropies. The observed anisotropies indicate that all of the labeled carbonyl bonds are oriented almost parallel to the molecular long axis and perpendicular to the lipid bilayer plane. These orientations are consistent with gramicidin forming a beta 6.3 single-strand helix that is oriented parallel to the methylene chains of the lipid molecules. Comparison of the linewidths from labeled residues that are in the innermost turn of the helix (gly2, ala3, and D-leu4), in the center of the molecule (val7), and in the turn nearest the lipid bilayer surface (D-leu10, D-leu12, and D-leu14) suggests that although the peptide behaves largely as a rigid barrel, segments of the peptide close to the membrane surface possess greater motional freedom. At temperatures above the gel-to-liquid crystalline transition temperature (Tc) the gramicidin molecules rotate, with a less than millisecond correlation time, about the bilayer normal: several degrees below Tc they become immobile on the NMR timescale, without change in the channel conformation. In the L beta' phase the linewidths of the D-leu10, D-leu'2, and D-leu" resonances become equal to those of the other labeled sites, indicating reduced but equivalent motion for all of the peptide carbonyl groups.

Interaction of staphylococcal delta-toxin and synthetic analogues with erythrocytes and phospholipid vesicles. Biological and physical properties of the amphipathic peptides

Staphylococcal delta-toxin, a 26-residue amphiphilic peptide is lytic for cells and phospholipid vesicles and is assumed to insert as an amphipathic helix and oligomerize in membranes. For the first time, the relationship between these properties and toxin structure is investigated by means of eight synthetic peptides, one identical in sequence to the natural toxin, five 26-residue analogues and two shorter peptides corresponding to residues 1-11 and 11-26. These peptides were designed by the Edmundson wheel axial projection in order to maintain: (a) the hydrophilic/hydrophobic balance while rationalizing the sequence, (b) the alpha-helical configuration and (c) the common epitopic structure. The fluorescence of the single Trp residue was used to monitor the behaviour of the natural toxin and analogues. All 26-residue analogues were hemolytically active although to a lesser extent than natural toxin. The peptide of residues 11-26 bound lipids weakly and was hemolytic at high concentration. The peptide of residues 1-11 did not bind lipids and was hemolytically inactive. All peptides except the latter cross-reacted in immunoprecipitation tests with the natural toxin. The study of a 26-residue analogue by circular dichroism revealed an alpha-helical configuration in both the free and lipid-bound state. Changes in the fluorescence of the peptides in the presence of lipid micelles and bilayers varied according to the position of the reporter group. When bound to lipids, Trp5, Trp16 and the Fmoc-1 positions of the analogues became buried while Trp15 of the natural toxin and its synthetic replicate remained more exposed. All changes are rationalized by the proposal of an amphipathic helix whose hydrophobic face is embedded within the apolar core of bilayers while the hydrophilic and charged face remains more exposed to solvent.

Proton nuclear magnetic resonance assignments

The procedures outlined here have been used successfully for more than 30 proteins to date, and are nearly routine for molecules up to a molecular weight of 10,000. Some of the proteins assigned have a molecular weight greater than 10,000. For these larger proteins, relayed-COSY and TOCSY experiments have been essential for the identification of spin systems, although for thioredoxin these experiments could not be used. In this case, assignments were accomplished using nonspecific deuteration to the level of 75% and specific, nearly complete, deuteration of certain kinds of residues (see LeMaster [2], this volume). Nonspecific deuteration reduces the cross-relaxation rates of each proton to the rest of the molecule, thus reducing the linewidths. The cross-peak patterns were also narrowed due to simplification of the coupling patterns. Such a laborious procedure of nonspecific deuteration may not be necessary for complete proton assignments of proteins in this size range, as evidenced by the fact that this method was not used for the other two molecules mentioned above. It may prove, however, to be quite valuable in the study of larger molecules, where linewidths are expected to increase due to longer rotational correlation times. Overlap problems in the NH chemical shifts can be dealt with by making use of the differential temperature dependence of these shifts. Another technique is to take advantage of the wide range of exchange rates between these protons and the solvent. Spectra containing only the slowly exchanging NH protons can be obtained by acquiring spectra of the protein soon after dilution in D2O, and spectra of only the rapidly exchanging protons can be obtained by obtaining spectra in a freshly prepared H2O solution of the protein after having completely exchanged all the NH protons with deuterium. Variation of the pH will resolve problems of overlap in all regions of the spectrum, although many chemical shifts may be unaffected by pH. In some cases, pH variation may change the conformation of the molecule. This may, in fact, assist in the sequential assignment if the chemical shifts can be followed with pH. Finally, the relayed-NOESY experiments can resolve overlap problems with the alpha-proton chemical shifts. Thus, it is very likely that the assignment methods outlined here will be successful for the assignment of the proton spectra of even larger molecules if there is significant secondary structure and significant variety of residues to provide enough dispersion of the chemical shifts.(ABSTRACT TRUNCATED AT 400 WORDS)

Properties of ion channels formed by Staphylococcus aureus delta-toxin

The delta-toxin of Staphylococcus aureus has been investigated in terms of its potential to form ion channels in planar lipid bilayers formed at the tip of patch electrodes. Channel formation has been shown to occur for delta-toxin concentrations in the range 0.1 to 2.0 microM. In 0.5 M KCl, two major classes of channels were seen--'small' with conductances of 70-100 pS, and 'large' with a conductance of approx. 450 pS. Current-voltage relationships for lipid bilayers containing several delta-toxin channels revealed both voltage-dependent and independent components to channel gating. Reversal potential measurements showed the channels to be cation selective. In the presence of 3.0 M KCl, the channel gating kinetics were complex, with multiple open and closed states. The results are interpreted in terms of a model for the channel consisting of a hexameric cluster of alpha-helical delta-toxin molecules.

Conformation and proteolysis of glucagon and insulin in surfactant and lipid solutions

The effects of micelles of nonionic, zwitterionic, anionic and cationic surfactants and lipids on the conformation of glucagon and insulin have been investigated by circular dichroism and intrinsic protein fluorescence. The influence of these amphipathic compounds on the hydrolysis, monitored by HPLC, of glucagon and insulin by trypsin and chymotrypsin has also been studied. The alpha-helix content of glucagon was increased to a similar extent by all the micelles, irrespective of their charge and of whether they were synthetic surfactants or phospholipids. The amphipathic compounds always induced a blue-shift in the wavelength of maximum emission of fluorescence of glucagon of about 9 nm, whereas the fluorescence intensity was increased in some cases and decreased in others. The circular dichroism of insulin was also modified in some cases. Some amphipathic compounds protected glucagon against proteolysis by trypsin and chymotrypsin very markedly, whereas others did not protect at all or only slightly protected the hormone. Two hypotheses have been formulated to explain the different results. Hydrolysis of insulin was generally not influenced by surfactants and lipids.