Single-molecule analysis of fluorescently labeled G-protein-coupled receptors reveals complexes with distinct dynamics and organization.

G-protein-coupled receptors (GPCRs) constitute the largest family of receptors and major pharmacological targets. Whereas many GPCRs have been shown to form di-/oligomers, the size and stability of such complexes under physiological conditions are largely unknown. Here, we used direct receptor labeling with SNAP-tags and total internal reflection fluorescence microscopy to dynamically monitor single receptors on intact cells and thus compare the spatial arrangement, mobility, and supramolecular organization of three prototypical GPCRs: the ß(1)-adrenergic receptor (ß(1)AR), the ß(2)-adrenergic receptor (ß(2)AR), and the γ-aminobutyric acid (GABA(B)) receptor. These GPCRs showed very different degrees of di-/oligomerization, lowest for ß(1)ARs (monomers/dimers) and highest for GABA(B) receptors (prevalently dimers/tetramers of heterodimers). The size of receptor complexes increased with receptor density as a result of transient receptor-receptor interactions. Whereas ß(1)-/ß(2)ARs were apparently freely diffusing on the cell surface, GABA(B) receptors were prevalently organized into ordered arrays, via interaction with the actin cytoskeleton. Agonist stimulation did not alter receptor di-/oligomerization, but increased the mobility of GABA(B) receptor complexes. These data provide a spatiotemporal characterization of ß(1)-/ß(2)ARs and GABA(B) receptors at single-molecule resolution. The results suggest that GPCRs are present on the cell surface in a dynamic equilibrium, with constant formation and dissociation of new receptor complexes that can be targeted, in a ligand-regulated manner, to different cell-surface microdomains.

Rotational diffusion of the α(2a) adrenergic receptor revealed by FlAsH labeling in living cells.

The fluorescein arsenical hairpin binder (FlAsH) shows much promise to determine the relative orientations of protein regions and structures even in living cells and in the plasma membrane. In this study, we characterized FlAsH's photophysical properties by steady-state anisotropy and time-resolved single photon counting for further applications with G-protein coupled receptors. We find that FlAsH has a relatively high initial anisotropy of 0.31 ± 0.01 and a three-component fluorescence lifetime with an average of 4.1 ± 0.1 ns. We characterized the FlAsH fluorophore orientation in the α(2A) adrenergic receptor revealing rigid orientations of FlAsH in the membrane plane for rotational correlation times of ∼50 ns in living cells. To elucidate the fluorophore-membrane orientation and rotational correlation time, an anisotropy treatment similar to that of another researcher (Axelrod, D. 1979. Biophys. J. 26:557-573) was developed. The rotational correlation times were observed to increase by up to 16 ns after agonist addition. The rotational correlation time also allowed for a comparison to the theoretical relationship between translational and rotational diffusion (originally proposed by Saffman, P. G., and M. Delbrück. 1975. Proc. Natl. Acad. Sci. USA. 72:3111-3113) and revealed a discrepancy of a factor between 10 and 100.

Sensing G protein-coupled receptor activation.

G protein-coupled receptors (GPCRs) are the key elements of a highly regulated transduction machinery that generates different signaling outcomes to hormones and neurotransmitters. Until recently, it was assumed that diverse ligands of a given GPCR differ only in their ability to alter the balance between the OFF and the ON state of the receptor. However, it has now become evident that their activation mechanisms are more complex and that receptors presumably display distinguishable active conformational states, which are induced by different agonists and correlate to specific signaling outputs. The use of different labeling strategies to insert fluorescent labels into purified, reconstituted receptors, or into receptors in intact cells, has made it possible to sense receptor activation via changes in their fluorescence. Here, we summarize recent progress in the analysis of agonist-dependent activation mechanisms of GPCRs acquired using modern spectroscopic and crystallographic techniques.

Fluorescent labeling of tetracysteine-tagged proteins in intact cells.

In this paper, we provide a general protocol for labeling proteins with the membrane-permeant fluorogenic biarsenical dye fluorescein arsenical hairpin binder-ethanedithiol (FlAsH-EDT2). Generation of the tetracysteine-tagged protein construct by itself is not described, as this is a protein-specific process. This method allows site-selective labeling of proteins in living cells and has been applied to a wide variety of proteins and biological problems. We provide here a generally applicable labeling procedure and discuss the problems that can occur as well as general considerations that must be taken into account when designing and implementing the procedure. The method can even be applied to proteins with expression below 1 pmol mg⁻¹ of protein, such as G protein-coupled receptors, and it can be used to study the intracellular localization of proteins as well as functional interactions in fluorescence resonance energy transfer experiments. The labeling procedure using FlAsH-EDT2 as described takes 2-3 h, depending on the number of samples to be processed.

Formation of a ternary complex among NHERF1, beta-arrestin, and parathyroid hormone receptor.

ß-Arrestins are crucial regulators of G-protein coupled receptor (GPCR) signaling, desensitization, and internalization. Despite the long-standing paradigm that agonist-promoted receptor phosphorylation is required for ß-arrestin2 recruitment, emerging evidence suggests that phosphorylation-independent mechanisms play a role in ß-arrestin2 recruitment by GPCRs. Several PDZ proteins are known to interact with GPCRs and serve as cytosolic adaptors to modulate receptor signaling and trafficking. Na(+)/H(+) exchange regulatory factors (NHERFs) exert a major role in GPCR signaling. By combining imaging and biochemical and biophysical methods we investigated the interplay among NHERF1, ß-arrestin2, and the parathyroid hormone receptor type 1 (PTHR). We show that NHERF1 and ß-arrestin2 can independently bind to the PTHR and form a ternary complex in cultured human embryonic kidney cells and Chinese hamster ovary cells. Although NHERF1 interacts constitutively with the PTHR, ß-arrestin2 binding is promoted by receptor activation. NHERF1 interacts directly with ß-arrestin2 without using the PTHR as an interface. Fluorescence resonance energy transfer studies revealed that the kinetics of PTHR and ß-arrestin2 interactions were modulated by NHERF1. These findings suggest a model in which NHERF1 may serve as an adaptor, bringing ß-arrestin2 into close proximity to the PTHR, thereby facilitating ß-arrestin2 recruitment after receptor activation.

Site-specific, orthogonal labeling of proteins in intact cells with two small biarsenical fluorophores.

The fusion of fluorescent proteins to proteins of interest has greatly advanced fluorescence microscopy, but is often limited by their large size. Here, we report site-specific, orthogonal labeling of two cellular proteins in intact cells with two small fluorescent dyes: fluorescein arsenical hairpin binder, FlAsH, and its red analogue, ReAsH, which bind to tetracysteine motifs. Development of a sequential labeling method to two different motifs, CCPGCC and FLNCCPGCCMEP, allowed site-specific labeling with FlAsH and ReAsH, respectively. Using the cell surface receptor for parathyroid hormone and its cytosolic binding protein, beta-arrestin2, we show their selective visualization in intact cells and analyze their interaction by colocalization and fluorescence resonance energy transfer (FRET). We propose that this method may be widely applied to label intracellular proteins and to study their interactions in intact cells with minimal disturbance of their function.