Electronic (one-photon) photodepletion spectra were recorded for gold cluster anions complexed with one xenon atom over the photon energy range 2.1-3.4 eV. Clusters were generated by pulsed laser vaporization and probed under collisionless molecular beam conditions. The spectra obtained are highly structured with the narrowest features--assigned to individual electronic transitions--having bandwidths of less than 40 meV. Time-dependent density functional theory predictions of optically allowed transitions for the most stable--planar--isomers of the corresponding bare metal cluster anions are generally consistent with the experimental observation.
Site-directed spin labeling is used to investigate the structure of adsorbed T4 lysozyme (T4L). A monolayer of T4L is prepared by tethering the protein selectively via a His-tag to the chelating headgroups (NTA Ni) of a planar quartz-supported lipid bilayer. This results in a vectorially oriented ensemble of proteins on the surface, which gives rise to angular-dependent electron paramagnetic resonance spectra. Similar measurements of spin-labeled lipid bilayers were used to characterize the structure and dynamics of the supports. Electron paramagnetic resonance line shape was analyzed using the stochastic Liouville equation approach developed by Freed and co-workers. The simulations reveal a conservation of the secondary and tertiary structure of T4L upon adsorption although slight conformational changes in the presence of the surface can be detected by probing tertiary contact sites. The orientation of the entire protein was deduced on the basis of an anisotropic motional model for the spin-labeled side chain. In addition, a polar order but azimuthal disorder of the molecules was assumed to fit the data. These results demonstrate the utility of site-directed spin labeling in combination with spectral simulation to study not only the secondary and tertiary structure of adsorbed proteins in monolayer coverage but also their orientation with respect to the surface.
Spin doctoring: Site‐directed spin labeling was used to determine the structure of T4 lysozyme adsorbed on quartz. At high ionic strength significant changes of the backbone fold are limited to the region around the enzymatic cleft. In contrast, at low ionic strength the previously unperturbed parts of the protein interact with the surface. Hydrophobic interactions are thought to play an important role in the partial unfolding at high ionic strength.
Site directed spin labeling is used to investigate the origin of the macroscopic alignment of T4 lysozyme vectorially tethered to planar biomimetic surfaces. T4 lysozyme was adsorbed to a quartz-supported dioleoylphosphatidylcholine (DOPC) bilayer by selective binding of the histidine-tagged protein to functionalized headgroups (1,2-dioleoyl-sn-glycero-3-[[N(5-amino-1-carboxypentyl)iminodiacetic acid]succinyl], DOGS NTA) of the bilayer. This results in a polar oriented ensemble of proteins on the surface, which gives rise to angular-dependent electron paramagnetic resonance (EPR) spectra. In order to reveal the mechanism of the protein alignment, the influence of protein coverage on the order of the molecules was addressed. Along the lines described previously for a full monolayer (Jacobsen, et al. Biophys. J. 2005, 88, 4351), the polar orientation of the molecules was inferred from an analysis of the EPR line shape using the stochastic Liouville equation (SLE) approach developed by Freed and co-workers. The simulations reveal that the orientation of the protein is strongly determined by lateral protein-protein interactions. In comparison to the lipid bilayer, a fusion protein of T4 lysozyme (T4L) with Annexin XII was investigated, where the two-dimensional crystallization of Annexin XII on a dioleoylphosphatidylserine (DOPS) bilayer provides a surface layer of regularly anchored T4L molecules. For this system, it is found that the interaction between T4L and Annexin plays a more important role for understanding the structure in the adsorbed state.
Ortsgerichtete Spinmarkierung führte zur Strukturbestimmung von auf Quarz adsorbiertem T4‐Lysozym. Bei hoher Ionenstärke sind Strukturänderungen auf die Enzymtasche beschränkt, während bei niedriger Ionenstärke auch andere Bereiche betroffen sind. Unter Berücksichtigung der Ladungsverteilung des T4‐Lysozyms wurde hydrophoben Wechselwirkungen bei der partiellen Entfaltung des Proteins eine wichtige Rolle zugeschrieben.
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