Erwen Mei

Seeing the light: Preassembly and ligand-induced changes of the interferon Gamma receptor complex in cells

Our experiments were designed to test the hypothesis that the cell surface interferon γ receptor chains are preassembled rather than associated by ligand and to assess the molecular changes on ligand binding. To accomplish this, we used fluorescence resonance energy transfer, a powerful spectroscopic technique that has been used to determine molecular interactions and distances between the donor and acceptor. However, current commercial instruments do not provide sufficient sensitivity or the full spectra to provide decisive results of interactions between proteins labeled with blue and green fluorescent proteins in living cells. In our experiments, we used the blue fluorescent protein and green fluorescent protein pair, attached a monochrometer and charge-coupled device camera to a modified confocal microscope, reduced background fluorescence with the use of two-photon excitation, and focused on regions of single cells to provide clear spectra of fluorescence resonance energy transfer. In contrast to the prevailing view, the results demonstrate that the receptor chains are preassociated and that the intracellular domains move apart on binding the ligand interferon γ. Application of this technology should lead to new rapid methods for high throughput screening and delineation of the interactome of cells.

Preassembly and ligand-induced restructuring of the chains of the IFN-gamma receptor complex: the roles of Jak kinases, Stat1 and the receptor chains.

We previously demonstrated using noninvasive technologies that the interferon-gamma (IFN-γ) receptor complex is preassembled 1. In this report we determined how the receptor complex is preassembled and how the ligand-mediated conformational changes occur. The interaction of Stat1 with IFN-γR1 results in a conformational change localized to IFN-γR1. Jak1 but not Jak2 is required for the two chains of the IFN-γ receptor complex (IFN-γR1 and IFN-γR2) to interact; however, the presence of both Jak1 and Jak2 is required to see any ligand-dependant conformational change. Two IFN-γR2 chains interact through species-specific determinants in their extracellular domains. Finally, these determinants also participate in the interaction of IFN-γR2 with IFN-γR1. These results agree with a detailed model of the IFN-γ receptor that requires the receptor chains to be pre-associated constitutively for the receptor to be active.

Controlled bimolecular collisions allow sub-diffraction limited microscopy of lipid vesicles

The concentration and vesicle size-controlled collisions of single molecules with target biological assemblies allow sub-diffraction limited optical images to be obtained that are not subject to the usual photobleaching problems with single molecule experiments. For example, single molecules of the probe Nile Red in aqueous solution emit a burst of fluorescence when they collide with a 50 nm hydrophobic vesicle situated on the surface in the laser focus. The bimolecular kinetics of the bursts is defined by their on- and off-time distribution functions which depend on the concentration and diffusion of the probe and the vesicle size. The mean burst frequency changes much more sharply than does the fluorescence intensity when a vesicle is raster scanned through the laser focus. This sharpness allows the spatial resolution of two objects to be improved and separations less than the diffraction limited resolution of the conventional optical microscope to be measured. The principle of this method of trajectory time distribution optical microscopy (TTDOM) could be used in a far field optical microscopic system with a resolution of several nanometers.

Direct visualization of nanopatterns by single-molecule imaging

The structures of patterned surface regions were clearly visualized by superimposing a series of single-molecule images from a total internal reflection fluorescence microscope, clearly demonstrating that a single-molecule imaging method can be used to directly visualize nanostructures. The pattern was fabricated on a microscope cover glass that formed a sandwich with a regular cover glass. The incorporated solution of fluorescent probe dyes was examined by single-molecule techniques. The effect of the surface pattern on the diffusion of the probe has also been examined.