Conformations of a Metastable SH3 Domain Characterized by smFRET and an Excluded-Volume Polymer Model.

Conformational states of the metastable drkN SH3 domain were characterized using single-molecule fluorescence techniques. Under nondenaturing conditions, two Förster resonance energy transfer (FRET) populations were observed that corresponded to a folded and an unfolded state. FRET-estimated radii of gyration and hydrodynamic radii estimated by fluorescence correlation spectroscopy of the two coexisting conformations are in agreement with previous ensemble x-ray scattering and NMR measurements. Surprisingly, when exposed to high concentrations of urea and GdmCl denaturants, the protein still exhibits two distinct FRET populations. The dominant conformation is expanded, showing a low FRET efficiency, consistent with the expected behavior of a random chain with excluded volume. However, approximately one-third of the drkN SH3 conformations showed high, nearly 100%, FRET efficiency, which is shown to correspond to denaturation-induced looped conformations that remain stable on a timescale of at least 100 µs. These loops may contain interconverting conformations that are more globally collapsed, hairpin-like, or circular, giving rise to the observed heterogeneous broadening of this population. Although the underlying mechanism of chain looping remains elusive, FRET experiments in formamide and dimethyl sulfoxide suggest that interactions between hydrophobic groups in the distal regions may play a significant role in the formation of the looped state.

Sub-diffusion decays in fluorescence correlation spectroscopy: dye photophysics or protein dynamics?

Transitions between bright and dark fluorescent states of several rhodamine dyes were investigated by fluorescence correlation spectroscopy. We resolved two sub-diffusion exponential decays for free rhodamines in aqueous solutions, of which the slower component scales linearly with the viscosity of the solution. Correlation data for proteins and DNA labeled with tetramethylrhodamine were fitted with three to four exponential decays describing flickering dynamics on a time scale between 0.5 and 100 µs. We investigated the nature of these processes by performing experiments under different experimental conditions and for different samples. On the basis of how their population and lifetime change with viscosity, the oxygen content of the solution, the laser irradiance, and the detection geometry, we assigned these states, in the order of increasing lifetimes, to a triplet state, a hybrid between twisted-intramolecular-charge-transfer state and a ground state lactonic state, a lactonic state, and a photoionized state, respectively. Our data suggests that none of the observed sub-diffusion correlation decays can be directly assigned to the intramolecular dynamics of the labeled biomolecules. However, we found evidence that the intrinsic conformational dynamics of the biomolecule appears in the correlation curves as a modulation of the photophysics of the dye label. This shows the importance of accurate control measurements and appropriate modeling of the dye photophysics in fluorescence correlation studies, and it cautions against direct assignments of dark-state relaxation times to folding kinetics in proteins and nucleic acids.

Ultrasensitive on-column laser-induced fluorescence in capillary electrophoresis using multiparameter confocal detection.

We report a simple method to efficiently couple on-column, standard Capillary Electrophoresis with Confocal MultiParameter Fluorescence detection (CE-CMPF) using only commercially available components. A molecular collection of 13% and a concentration limit of detection of 1.5 pM fluorescein are achieved in our instrument by gating the arrival time of individual photons in order to reduce the scattering contribution. The proposed scheme allows for amplification-free detection and separation of three different microRNAs from the MCF-7 cell lysate. The limit of detection is approximately 500 times smaller and the separation time is 3 times shorter compared to protocols based on commercial CE instrumentation. Although the optical design can be further improved, it is shown that the current CE-CMPF prototype is already capable of analyzing the microRNA content of single cells. In addition, all CE protocols previously developed for commercial instruments can be performed with our CE-CMPF without modification but with nearly 3 orders of magnitude better limit of detection.

Phosphopeptide selective coordination complexes as promising SRC homology 2 domain mimetics.

Src Homology 2 (SH2) domains are the paradigm of phosphotyrosine (pY) protein recognition modules and mediate numerous cancer-promoting protein-protein complexes. Effective SH2 domain mimicry with pY-binding coordination complexes offers a promising route to new and selective disruptors of pY-mediated protein-protein interactions. We herein report the synthesis and in vitro characterization of a library of coordination complex SH2 domain proteomimetics. Compounds were designed to interact with phosphopeptides via a two-point interaction, principally with pY, and to make secondary interactions with pY+2/3, thereby achieving sequence-selective discrimination. Here, we report that lead mimetics demonstrated high target phosphopeptide affinity (K(a) ∼ 10(7) M(-1)) and selectivity. In addition, biological screening in various tumor cells for anticancer effects showed a high degree of variability in cytotoxicity among receptors, which supported the proposed two-point binding mode. Several receptors potently disrupted cancer cell viability in breast cancer, prostate cancer, and acute myeloid leukemia cell lines.

Detection of a thousand copies of miRNA without enrichment or modification.

We report direct quantitative analysis of multiple miRNAs with a detection limit of 1000 copies without miRNA enrichment or modification. A 300-fold improvement over the previously published detection limit was achieved by combining capillary electrophoresis with confocal time-resolved fluorescence detection through an embedded capillary interface. The method was used to determine levels of three miRNA biomarkers of breast cancer (miRNA 21, 125b, 145) in a human breast cancer cell line (MCF-7). A 30 pL volume of the cell lysate with approximately a material content of a single cell was sampled for the analysis. MiRNA 21, which is up-regulated in breast cancer, was detected at a level of approximately 12 thousand copies per cells. MiRNAs 125b and 145, which are down-regulated in breast cancer, were below the 1000-copy detection limit. This sensitive method may facilitate the analysis of miRNA in fine-needle-biopsy samples and even in single cells without enrichment or modification of miRNA. Advantageously, the instrumental setup developed here can be reproduced by others as it requires no sophisticated custom-made parts.

On the performance of bioanalytical fluorescence correlation spectroscopy measurements in a multiparameter photon-counting microscope.

Fluorescence correlation spectroscopy (FCS) data acquisition and analysis routines were developed and implemented in a home-built, multiparameter photon-counting microscope. Laser excitation conditions were investigated for two representative fluorescent probes, Rhodamine110 and enhanced green fluorescent protein (EGFP). Reliable local concentrations and diffusion constants were obtained by fitting measured FCS curves, provided that the excitation intensity did not exceed 20% of the saturation level for each fluorophore. Accurate results were obtained from FCS measurements for sample concentrations varying from pM to µM range, as well as for conditions of high background signals. These experimental constraints were found to be determined by characteristics of the detection system and by the saturation behavior of the fluorescent probes. These factors actually limit the average number of photons that can be collected from a single fluorophore passing through the detection volume. The versatility of our setup and the data analysis capabilities were tested by measuring the mobility of EGFP in the nucleus of Drosophila cells under conditions of high concentration and molecular crowding. As a bioanalytical application, we studied by FCS the binding affinity of a novel peptide-based drug to the cancer-regulating STAT3 protein and corroborated the results with fluorescence polarization analysis derived from the same photon data.

Trapping single molecules in liposomes: surface interactions and freeze-thaw effects.

We report on an improved method to encapsulate proteins and other macromolecules inside surface-tethered liposomes to reduce or eliminate environmental interference for single-molecule investigations. These lipid vesicles are large enough for the molecule to experience free diffusion but sufficiently small so that the molecule appears effectively immobile under the fluorescence microscope. Single-molecule fluorescence experiments were used to characterize this anchoring method relative to direct immobilization via biotin-streptavidin linkers. Multidimensional histograms of intensity, polarization, and lifetime revealed that molecules trapped in liposomes display a narrow distribution around a single peak, while the molecules directly immobilized on surface show highly dispersed values for all parameters. By hydrating the lipid film at low volumes, high encapsulation efficiencies can be achieved with ~10 times less biological material than previous protocols. We measured vesicle size distributions and found no significant advantage for using freeze-thaw cycles during vesicle preparation. On the contrary, the temperature jump can induce irreversible damage of fluorophores and it reduces significantly the functionality of proteins, as demonstrated on single-molecule binding experiments on STAT3. Our improved and biologically gentle molecule encapsulation protocol has a great potential for widespread applications in single-molecule fluorescence spectroscopy.