Construction of Structural Mimetics of the Thyrotropin Receptor Intracellular Domain.

The signaling of a G protein-coupled receptor (GPCR) is dictated by the complementary responsiveness of interacting intracellular effectors such as G proteins. Many GPCRs are known to couple to more than one G protein subtype and induce a multitude of signaling pathways, although the in vivo relevance of particular pathways is mostly unrecognized. Dissecting GPCR signaling in terms of the pathways that are activated will boost our understanding of the molecular fundamentals of hormone action. The structural determinants governing the selectivity of GPCR/G protein coupling, however, remain obscure. Here, we describe the design of soluble GPCR mimetics to study the details of the interplay between G-proteins and activators. We constructed functional mimetics of the intracellular domain of a model GPCR, the thyrotropin receptor. We based the construction on a unique scaffold, 6-Helix, an artificial protein that was derived from the elements of the trimer-of-hairpins structure of HIV gp41 and represents a bundle of six α-helices. The 6-Helix scaffold, which endowed the substituted thyrotropin receptor intracellular domain elements with spatial constraints analogous to those found in native receptors, enabled the reconstitution of a microdomain that consists of intracellular loops 2 and 3, and is capable of binding and activating Gα-(s). The 6-Helix-based mimetics could be used as a platform to study the molecular basis of GPCR/G protein recognition. Such knowledge could help investigators develop novel therapeutic strategies for GPCR-related disorders by targeting the GPCR/G protein interfaces and counteracting cellular dysfunctions via focused tuning of GPCR signaling.

Tethered ribozyme ligation enables detection of molecular proximity in homogeneous solutions.

In contemporary drug discovery, bulk selection represents an important alternative to time consuming and expensive high-throughput screening. The selection methods, however, generally rely on affinity separation, a step that limits overall selection process efficiency. To overcome common drawbacks of conventional methods, we exploited the unique catalytic properties of an artificial enzyme, ribozyme ligase, to develop a selection methodology in which the entire detection process takes place in a homogeneous solution, thus eliminating the need for affinity separation. A molecular target is associated with the ribozyme, and library compounds are attached to a barcoded oligonucleotide that is a substrate for the ribozyme ligase. Spatial proximity resulting from specific target-compound interactions increases the probability of ribozyme ligation to the oligo-substrate, thus differentiating the interacting species from the bulk mixture. The covalent link formed between the ribozyme and target-interacting compounds diminishes the mass-action effect on the efficiency with which low-affinity and rare active species are detected. In addition, the magnitude of the detection signal associated with the interaction event renders the methodology an efficient platform for identifying inhibitors of intermolecular interactions. The proposed solution-based tethered ribozyme-ligation proximity detection method may facilitate the discovery of target-interacting compounds using both library selection and high-throughput screening approaches.