The Diaphanous-Related Formins: Dynamic Regulators of Smooth Muscle Cell-Specific Gene Transcription

We and others have previously shown that RhoA-dependent actin polymerization stimulates SMC-specific gene transcription by promoting the nuclear accumulation of the myocardin-related transcription factors (MRTF)-A and -B. Very little is known about the downstream RhoA effectors that mediate this response, and the goal of the studies described herein was to define the role of the diaphanous-related formins (DRFs) in regulating smooth muscle cell (SMC) differentiation. The DRFs mDia1 and mDia2 are highly expressed in cultured SMCs and in tissues containing a high smooth muscle component. Activation of mDia1 or mDia2 by RhoA stimulated actin polymerization, MRTF nuclear accumulation, and SMC-specific gene transcription. Interestingly, we found that phosphorylation of the Diaphanous Autoregulatory Domain (DAD) by Rho-kinase also stimulated mDia2 activity and SM-marker gene expression. Knockdown of mDia1/2 using siRNA significantly attenuated expression of numerous SM-marker genes in primary aortic SMCs. While we originally attributed these findings to the regulation of cytoplasmic actin dynamics by the DRFs, recent evidence linking nuclear globular (G)-actin to MRTF nuclear export led us to investigate a possible role for the DRFs in the nucleus. We found that mDia2, but not mDia1 or FHOD1, accumulated in the nucleus following treatment with leptomycin, an inhibitor of Crm-1 dependent nuclear export. Deletion and mutation analyses identified nuclear localization sequences (NLS) in the core formin homology 2 (FH2) domain and extreme N-terminus, and a leucine-rich nuclear export sequence (NES) was identified in the C-terminus of mDia2. Importantly, mDia2 variants that were excluded from the nucleus did not stimulate SMC-specific gene transcription and MRTF-B nuclear accumulation as well as wild-type mDia2. Taken together, these data support a model in which mDia2 activity in the nucleus and cytoplasm depletes cellular G-actin pools resulting in MRTF nuclear accumulation and activation of SMC-specific gene transcription

Allosteric “beta-blocker” isolated from a DNA-encoded small molecule library

The present study reports the discovery of a small-molecule negative allosteric modulator for the β2-adrenergic receptor (β2AR) via in vitro affinity-based iterative selection of highly diverse DNA-encoded small-molecule libraries. Characterization of the compound demonstrates its selectivity for the β2AR and that it negatively modulates a wide range of receptor functions. More importantly, our findings establish a generally applicable, proof-of-concept strategy for screening DNA-encoded small-molecule libraries against purified G-protein–coupled receptors (GPCRs), which holds great potential for discovering therapeutic molecules

Allosteric nanobodies reveal the dynamic range and diverse mechanisms of G-protein-coupled receptor activation

G-protein coupled receptors (GPCRs) modulate many physiological processes by transducing a variety of extracellular cues into intracellular responses. Ligand binding to an extracellular orthosteric pocket propagates conformational change to the receptor cytosolic region to promote binding and activation of downstream signaling effectors such as G proteins and β-arrestins. It is widely appreciated that different agonists can share the same binding pocket but evoke unique receptor conformations leading to a wide range of downstream responses (i.e., ‘efficacy’)1. Furthermore, mounting biophysical evidence, primarily using the β-adrenergic receptor (β2AR) as a model system, supports the existence of multiple active and inactive conformational states2–5. However, how agonists with varying efficacy modulate these receptor states to initiate cellular responses is not well understood. Here we report stabilization of two distinct β2AR conformations using single domain camelid antibodies (nanobodies): a previously described positive allosteric nanobody (Nb80) and a newly identified negative allosteric nanobody (Nb60)6,7. We show that Nb60 stabilizes a previously unappreciated low affinity receptor state which corresponds to one of two inactive receptor conformations as delineated by X-ray crystallography and NMR spectroscopy. We find that the agonist isoproterenol has a 15,000-fold higher affinity for the β2AR in the presence of Nb80 compared to Nb60, highlighting the full allosteric range of a GPCR. Assessing the binding of 17 ligands of varying efficacy to the β2AR in the absence and presence of Nb60 or Nb80 reveals large ligand-specific effects that can only be explained using an allosteric model which assumes equilibrium amongst at least three receptor states. Agonists generally exert efficacy by stabilizing the active Nb80-stabilized receptor state (R80). In contrast, for a number of partial agonists, both stabilization of R80 and destabilization of the inactive, Nb60-bound state (R60) contribute to their ability to modulate receptor activation. These data demonstrate that ligands can initiate a wide range of cellular responses by differentially stabilizing multiple receptor states

Allosteric Nanobodies Reveal the Dynamic Range and Diverse Mechanisms of GPCR Activation

G-protein coupled receptors (GPCRs) modulate many physiological processes by transducing a variety of extracellular cues into intracellular responses. Ligand binding to an extracellular orthosteric pocket propagates conformational change to the receptor cytosolic region to promote binding and activation of downstream signaling effectors such as G proteins and β-arrestins. It is widely appreciated that different agonists can share the same binding pocket but evoke unique receptor conformations leading to a wide range of downstream responses (i.e., ‘efficacy’)1. Furthermore, mounting biophysical evidence, primarily using the β-adrenergic receptor (β2AR) as a model system, supports the existence of multiple active and inactive conformational states2–5. However, how agonists with varying efficacy modulate these receptor states to initiate cellular responses is not well understood. Here we report stabilization of two distinct β2AR conformations using single domain camelid antibodies (nanobodies): a previously described positive allosteric nanobody (Nb80) and a newly identified negative allosteric nanobody (Nb60)6,7. We show that Nb60 stabilizes a previously unappreciated low affinity receptor state which corresponds to one of two inactive receptor conformations as delineated by X-ray crystallography and NMR spectroscopy. We find that the agonist isoproterenol has a 15,000-fold higher affinity for the β2AR in the presence of Nb80 compared to Nb60, highlighting the full allosteric range of a GPCR. Assessing the binding of 17 ligands of varying efficacy to the β2AR in the absence and presence of Nb60 or Nb80 reveals large ligand-specific effects that can only be explained using an allosteric model which assumes equilibrium amongst at least three receptor states. Agonists generally exert efficacy by stabilizing the active Nb80-stabilized receptor state (R80). In contrast, for a number of partial agonists, both stabilization of R80 and destabilization of the inactive, Nb60-bound state (R60) contribute to their ability to modulate receptor activation. These data demonstrate that ligands can initiate a wide range of cellular responses by differentially stabilizing multiple receptor states

Sortase ligation enables homogeneous GPCR phosphorylation to reveal diversity in β-arrestin coupling

The ability of G protein-coupled receptors (GPCRs) to initiate complex cascades of cellular signaling is governed by the sequential coupling of three main transducer proteins, G protein, GPCR kinase (GRK), and β-arrestin. Mounting evidence indicates these transducers all have distinct conformational preferences and binding modes. However, interrogating each transducer's mechanism of interaction with GPCRs has been complicated by the interplay of transducer-mediated signaling events. For example, GRK-mediated receptor phosphorylation recruits and induces conformational changes in β-arrestin, which facilitates coupling to the GPCR transmembrane core. Here we compare the allosteric interactions of G proteins and β-arrestins with GPCRs' transmembrane cores by using the enzyme sortase to ligate a synthetic phosphorylated peptide onto the carboxyl terminus of three different receptors. Phosphopeptide ligation onto the β2-adrenergic receptor (β2AR) allows stabilization of a high-affinity receptor active state by β-arrestin1, permitting us to define elements in the β2AR and β-arrestin1 that contribute to the receptor transmembrane core interaction. Interestingly, ligation of the identical phosphopeptide onto the β2AR, the muscarinic acetylcholine receptor 2 and the μ-opioid receptor reveals that the ability of β-arrestin1 to enhance agonist binding relative to G protein differs substantially among receptors. Furthermore, strong allosteric coupling of β-arrestin1 correlates with its ability to attenuate, or "desensitize," G protein activation in vitro. Sortase ligation thus provides a versatile method to introduce complex, defined phosphorylation patterns into GPCRs, and analogous strategies could be applied to other classes of posttranslationally modified proteins. These homogeneously phosphorylated GPCRs provide an innovative means to systematically study receptor-transducer interactions