Structural changes in native membrane proteins monitored at subnanometer resolution with the atomic force microscope: a review.

Three membrane proteins, OmpF porin from Escherichia coli, bacteriorhodopsin from Halobacterium salinarium, and the hexagonally packed intermediate (HPI) layer from Deinoccocus radiodurans, were investigated with the atomic force microscope in buffer solution. A resolution of up to 0.8 nm allowed structural differences of individual proteins to be detected. OmpF porin exhibits different static conformations on the outer surface, which possibly represent the two conductive states of the ion channels. Reversible structural changes in the cytoplasmic surface of purple membrane have been induced by changing the force applied to the scanning stylus: doughnut-shaped bacteriorhodopsin trimers transformed into a structure with three pronounced protrusions when the force was reduced from 300 to 100 pN. Furthermore, individual pores of the inner surface of the HPI layer were observed to switch from an "open" to a "closed" state. Together, the structural changes in proteins monitored under physiological conditions suggest that direct observation of function-related conformational changes of biomolecules with the atomic force microscope is feasible.

Vertical dimension of hydrated biological samples in tapping mode scanning force microscopy.

The vertical dimensions of the well-characterized test samples tobacco mosaic virus, T4 bacteriophage polyhead, purple membrane, and hexagonally packed intermediate (HPI) layer were investigated by tapping mode scanning force microscopy (SFM) in solution. Purple membrane and HPI layer were imaged in both contact mode and tapping mode SFM for direct comparison. All vertical dimensions match the known heights. The practical implications of the absence of frictional forces in tapping mode are discussed.

Imaging purple membranes in aqueous solutions at sub-nanometer resolution by atomic force microscopy.

Purple membranes adsorbed to mica were imaged in buffer solution using the atomic force microscope. The hexagonal diffraction patterns of topographs from the cytoplasmic and the extracellular surface showed a resolution of 0.7 and 1.2 nm, respectively. On the cytoplasmic surface, individual bacteriorhodopsin molecules consistently exhibited a distinct substructure. Depending on the pH value of the buffer solution, the height of the purple membranes decreased from 5.6 nm (pH 10.5) to 5.1 nm (pH 4). The results are discussed with respect to the structure determined by cryo-electron microscopy.

Native Escherichia coli OmpF porin surfaces probed by atomic force microscopy.

Topographs of two-dimensional porin OmpF crystals reconstituted in the presence of lipids were recorded in solution by atomic force microscopy (AFM) to a lateral resolution of 10 angstroms and a vertical resolution of 1 angstrom. Protein-protein interactions were demonstrated on the basis of the AFM results and earlier crystallographic findings. To assess protein-lipid interactions, the bilayer was modeled with kinked lipids by fitting the head groups to contours determined with AFM. Finally, two conformations of the extracellular porin surface were detected at forces of 0.1 nanonewton, demonstrating the potential of AFM to monitor conformational changes with high resolution.

Reproducible acquisition of Escherichia coli porin surface topographs by atomic force microscopy.

Crystalline membranes reconstituted from Escherichia coli OmpF porin and phospholipids were adsorbed to freshly cleaved mica and imaged in solution by the atomic force microscope. The extracellular as well as the periplasmic side of the porin trimers could be identified and the conditions to record topographs at 1-nm lateral and 0.1-nm vertical resolution were established.

Covalent binding of biological samples to solid supports for scanning probe microscopy in buffer solution.

Scanning force microscopy allows imaging of biological molecules in their native state in buffer solution. To this end samples have to be fixed to a flat solid support so that they cannot be displaced by the scanning tip. Here we describe a method to achieve the covalent binding of biological samples to glass surfaces. Coverslips were chemically modified with the photoactivatable cross-linker N-5-azido-2-nitrobenzoyloxysuccinimide. Samples are squeezed between derivatized coverslips and then cross-linked to the glass surface by irradiation with ultraviolet light. Such samples can be imaged repeatedly by the scanning force microscope without loss of image quality, whereas identical but not immobilized samples are pushed away by the stylus.

Degenerated confocal resonato.

The properties of confocal resonators with g(1) = g(2) = 0 and with one mirror confined by an aperture were investigated both theoretically and experimentally. The fundamental mode operation with complete filling of the medium, which ds located near the unconfined mirror, can always be obtained by an appropriate choice of the aperture radius. Numerical calculations based on Fresnel integrals, including the amplification of the gain medium, provide a detailed understanding of the resonator properties, with guidelines for an optimum resonator performance. Diffraction loss, mode structure, beam quality, extraction efficiency, and misalignment sensitivity of these resonators are measured with a pulsed Nd:YAG laser in a single-shot operation.