The mode of interaction of the polycationic aminoglycoside antibiotics with the surface of Pseudomonas aeruginosa cells was studied with the hydrophobic fluorescent probe 1-N-phenylnaphthylamine (NPN). The addition of the aminoglycoside gentamicin to intact cells in the presence of NPN led to a shift in the fluorescence emission maximum from 460 to 420 nm. At the same time the NPN fluorescence intensity increased fourfold. Gentamicin caused no such effects when added to outer membrane vesicles, suggesting that the increased fluorescence resulted from the interaction of gentamicin with intact cells. Gentamicin-promoted NPN uptake was inhibited by the divalent cations Mg2+ and Ca2+, but occurred in the absence of gentamicin transport across the inner membrane. Low concentrations of gentamicin (2 ,ig/ml) caused NPN fluorescence to increase over a period of 4 min in a sigmoidal fashion. At higher concentrations (50 ,ug/ml) the increase occurred within a few seconds. The final fluorescence intensity was almost independent of the gentamicin concentration. A centrifugation technique was used to demonstrate that gentamicin caused actual uptake of NPN from the supernatant. The initial rate of NPN uptake varied according to the gentamicin concentration in a sigmoidal fashion. Similar data were obtained for seven other aminoglycoside antibiotics. The data, when reanalyzed as a Hill plot, gave a series of lines with a mean slope (the Hill number) of 2.26 0.26, suggesting that the interaction of aminoglycosides with the cell surface to permeabilize it to NPN involved at least three sites and demonstrated positive cooperativity. There was a statistically significant relationship between the pseudoassociation constant K, from the Hill plots and the minimal inhibitory concentrations for the eight antibiotics. These results are consistent with the concept that aminoglycosides interact at a divalent cation binding site on the P. aeruginosa outer membrane and permeabilize it to the hydrophobic probe NPN.
Selectively deuterated transmembrane peptides comprising alternating leucine-alanine subunits were examined in fluid bilayer membranes by solid-state nuclear magnetic resonance (NMR) spectroscopy in an effort to gain insight into the behavior of membrane proteins. Two groups of peptides were studied: 21-mers having a 17-amino-acid hydrophobic domain calculated to be close in length to the hydrophobic thickness of 1-palmitoyl-2-oleoyl phosphatidylcholine and 26-mers having a 22-amino-acid hydrophobic domain calculated to exceed the membrane hydrophobic thickness. (2)H NMR spectral features similar to ones observed for transmembrane peptides from single-span receptors of higher animal cells were identified which apparently correspond to effectively monomeric peptide. Spectral observations suggested significant distortion of the transmembrane alpha-helix, and/or potential for restriction of rotation about the tilted helix long axis for even simple peptides. Quadrupole splittings arising from the 26-mer were consistent with greater peptide "tilt" than were those of the analogous 21-mer. Quadrupole splittings associated with monomeric peptide were relatively insensitive to concentration and temperature over the range studied, indicating stable average conformations, and a well-ordered rotation axis. At high peptide concentration (6 mol% relative to phospholipid) it appeared that the peptide predicted to be longer than the membrane thickness had a particular tendency toward reversible peptide-peptide interactions occurring on a timescale comparable with or faster than approximately 10(-5) s. This interaction may be direct or lipid-mediated and was manifest as line broadening. Peptide rotational diffusion rates within the membrane, calculated from quadrupolar relaxation times, T(2e), were consistent with such interactions. In the case of the peptide predicted to be equal to the membrane thickness, at low peptide concentration spectral lineshape indicated the additional presence of a population of peptide having rotational motion that was restricted on a timescale of 10(-5) s.
As part of a study of receptor tyrosine kinase behavior in membranes, we have collected extensive NMR data from three well-defined probe locations within the transmembrane region of the human EGF receptor. Spectra were obtained for selectively deuterated alanine residues in a series of peptides corresponding to the putative transmembrane domain (with short extramembranous extensions). Peptides were incorporated into fluid unsonicated liposomes of 1-palmitoyl-2-oleoylphosphatidylcholine (POPC) and POPC containing 33 mol % cholesterol to mimic common lipid composition of cell plasma membranes. The peptide concentration was in the range of 1-6 mol % relative to that of phospholipid. Data acquired at 35 degreesC have been analyzed quantitatively to determine their implications to receptor spatial orientation and dynamics. If it is presumed that the single transmembrane portion approximates an alpha-helix of 3.6 residues per turn, this helix was found to be tilted away from the membrane perpendicular, about which there was rapid axial diffusion. However, rotation about the peptide long axis was static on the NMR time scale of 10(-)4 s, and the peptide appeared to have a preferred direction(s) of lean. The results for this peptide, whose hydrophobic length is greater than the membrane hydrophobic thickness, were very similar between membranes of POPC and membranes of POPC containing 33 mol % cholesterol, despite considerable host matrix differences in thickness and order. Allowed values of peptide tilt occupied a narrow range: between 10 and 14 degrees in POPC and between 10 and 12 degrees in POPC/cholesterol. Although the existence of some preferred direction(s) of lean was demanded by the results, the direction of lean was not uniquely determined. We have interpreted these results, which were essentially unchanged at 65 degreesC, as reflecting the behavior of peptide monomers undergoing rapidly reversible peptide-peptide interactions. For transmembrane monomers, interference with rotation about the peptide long axis might be understood to arise from an energy benefit (in a tilted peptide) to prevention of particular amino acid side chains near the membrane surfaces from moving in and out of hydrophobic or hydrophilic environments. It will be desirable to test the conclusion of preferential lean of a monomeric receptor since such behavior could provide a mechanism for modulating monomer association with other species (i.e., signal transduction).
The first wide-line 2H NMR investigation of a receptor tyrosine kinase is reported. Selectively deuterated peptides from the membrane-associated portion of the human epidermal growth factor (EGF) receptor were synthesized for examination in lipid bilayers mimicking certain natural membrane features. The peptide sequence included the 23-amino acid hydrophobic stretch thought to span the membrane (Ile622-Met644 of the EGF receptor), plus the first 10 amino acids of the receptor's cytoplasmic domain (Arg645-Thr654). Dispersion of the peptide with lipid in the lipomimetic solvent, trifluoroethanol (TFE), was found to be a very useful initial step for sample preparation. TFE readily dissolved all components and was then easily removed in vacuo to yield thin films which could be subsequently hydrated to produce bilayers incorporating homogeneously dispersed peptide. Samples extensively studied consisted of 6 mol % peptide in multilamellar liposomes of 1-palmitoyl-2-oleoylphosphatidylcholine and similar liposomes containing cholesterol. 2H NMR spectra of the resulting unsonicated model membranes indicated the existence of peptide monomers undergoing rapid axially symmetric diffusion. It was possible to examine structural and behavioral effects of events often suggested as pivotal in signaling mechanisms and to consider by wide-line NMR for the first time the effect of cholesterol on hydrophobic peptides. When it was incorporated into bilayers by an alternative method involving dialysis of aqueous solutions prepared using a cationic detergent, spectra suggested that the peptide existed primarily as irreversibly aggregated oligomers which were relatively immobile on a time scale of 10(-3)-10(-4) s. For liposomes prepared by hydration of thin films, deuterated methyl groups on the peptide at locations corresponding to Ala623, Met644, and Val650 of the human EGF receptor were individually distinguishable. In highly fluid matrices, spectra suggested the presence of peptide monomers, diffusing symmetrically about axes perpendicular to the membrane. Studied as a function of temperature, 2H NMR spectra of such samples permitted independent consideration of membrane/peptide relationships at separate locations in the receptor tyrosine kinase. None of the locations probed demonstrated significant conformational sensitivity to temperature over a wide range. Effects seen at Ala623 and Met644, at opposite ends of the putative membrane-spanning domain, suggested slight increases in motional order with decreasing temperature. Addition of 33% cholesterol to the membrane caused little apparent conformational change at Val650 or Met644. However, in the presence of the sterol, Met644 and Ala623 exhibited nonaxially symmetric motion at low temperatures, perhaps as a result of peptide oligomerization. Moreover, the presence of cholesterol led to considerable change in spatial arrangement or order at Ala623. There was little evidence to support transmission of conformational changes along the peptide segment probed.
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