Abstract: Aspects of the present disclosure include conformationally restricted analogs of catecholamine type compounds (e.g., isoprenaline, adrenaline, noradrenaline) which activate ?2AR with high selectivity over ?1AR. The subject beta-2 selective adrenergic receptor agonist compounds may serve as bronchiodilators and find use in the treatment of a variety of bronchoconstrictive diseases and conditions. Also provided are compositions and methods for treating preterm labor. A method of treating acute asthma including administration of a subject compound to a subject in need thereof is provided. The subject method can provide for reduced undesirable side effects associated with non-selective ?-adrenergic receptor agonism, such as inotropic and chronotropic effects that leads to elevated blood pressure. The compounds can also be used to prevent or treat heart failure. Kits and compositions for practicing the subject methods are also provided.

Abstract: Provided are methods for treating neuropathic pain by administering to a subject in need thereof a compound comprising phenyl-indole scaffold, wherein the compound has a modulatory effect on cannabinoid type 1 receptor (CB1R). Pharmaceutical compositions containing compounds comprising phenyl-indole scaffolds and pharmaceutically acceptable carriers are also provided, along with methods of using the same.

Abstract: Provided herein are modulators of beta-adrenergic receptors.

Abstract: Provided herein are several methods for selecting agents that bind to transmembrane receptors in a conformationally-selective way. In some embodiments, the method may comprise producing: a transmembrane receptor in an active conformation; and said transmembrane receptor in an inactive conformation and using cell sorting to select, from a population of cells comprising a library of cell surface-tethered extracellular capture agents, cells that are specifically bound to either the transmembrane receptor in its active conformation or the transmembrane receptor in its inactive conformation, but not both. In other embodiments, the method may comprise: contacting a GPCR with a population of cells that comprise a library of surface-tethered extracellular proteins; labeling the cell population with a conformationally-specific binding agent, e.g., a G-protein or mimetic thereof; and using cell sorting to select from the cell population cells that bind to the agent.

Abstract: Aspects of the present disclosure include conformationally restricted analogs of catecholamine type compounds (e.g., isoprenaline, adrenaline, noradrenaline) which activate ?2AR with high selectivity over ?1AR. The subject beta-2 selective adrenergic receptor agonist compounds may serve as bronchiodilators and find use in the treatment of a variety of bronchoconstrictive diseases and conditions. Also provided are compositions and methods for treating preterm labor. A method of treating acute asthma including administration of a subject compound to a subject in need thereof is provided. The subject method can provide for reduced undesirable side effects associated with non-selective ?-adrenergic receptor agonism, such as inotropic and chronotropic effects that leads to elevated blood pressure. The compounds can also be used to prevent or treat heart failure. Kits and compositions for practicing the subject methods are also provided.

Abstract: Provided herein are several methods for selecting agents that bind to transmembrane receptors in a conformationally-selective way. In some embodiments, the method may comprise producing: a transmembrane receptor in an active conformation; and said transmembrane receptor in an inactive conformation and using cell sorting to select, from a population of cells comprising a library of cell surface-tethered extracellular capture agents, cells that are specifically bound to either the transmembrane receptor in its active conformation or the transmembrane receptor in its inactive conformation, but not both. In other embodiments, the method may comprise: contacting a GPCR with a population of cells that comprise a library of surface-tethered extracellular proteins; labeling the cell population with a conformationally-specific binding agent, e.g., a G-protein or mimetic thereof; and using cell sorting to select from the cell population cells that bind to the agent.

Abstract: Provided herein are several methods for selecting agents that bind to transmembrane receptors in a conformationally-selective way. In some embodiments, the method may comprise producing: a transmembrane receptor in an active conformation; and said transmembrane receptor in an inactive conformation and using cell sorting to select, from a population of cells comprising a library of cell surface-tethered extracellular capture agents, cells that are specifically bound to either the transmembrane receptor in its active conformation or the transmembrane receptor in its inactive conformation, but not both. In other embodiments, the method may comprise: contacting a GPCR with a population of cells that comprise a library of surface-tethered extracellular proteins; labeling the cell population with a conformationally-specific binding agent, e.g., a G-protein or mimetic thereof; and using cell sorting to select from the cell population cells that bind to the agent.

Abstract: Provided herein are several methods for selecting agents that bind to transmembrane receptors in a conformationally-selective way. In some embodiments, the method may comprise producing: a transmembrane receptor in an active conformation; and said transmembrane receptor in an inactive conformation and using cell sorting to select, from a population of cells comprising a library of cell surface-tethered extracellular capture agents, cells that are specifically bound to either the transmembrane receptor in its active conformation or the transmembrane receptor in its inactive conformation, but not both. In other embodiments, the method may comprise: contacting a GPCR with a population of cells that comprise a library of surface-tethered extracellular proteins; labeling the cell population with a conformationally-specific binding agent, e.g., a G-protein or mimetic thereof; and using cell sorting to select from the cell population cells that bind to the agent.

Abstract: Certain embodiments provide a GPCR fusion protein. In particular embodiments, the GPCR fusion protein comprises: a) a G-protein coupled receptor (GPCR); and b) an autonomously folding stable domain, where the autonomously folding stable domain is N-terminal to the GPCR and is heterologous to the GPCR. The GPCR fusion protein is characterized in that is crystallizable under lipidic cubic phase crystallization conditions. In certain embodiments, the GPCR fusion protein may be crystallizable in a complex with a G-protein or in a complex with an antibody that binds to the IC3 loop of the GPCR.

Abstract: Certain embodiments provide a GPCR fusion protein. In particular embodiments, the GPCR fusion protein comprises: a) a G-protein coupled receptor (GPCR); and b) an autonomously folding stable domain, where the autonomously folding stable domain is N-terminal to the GPCR and is heterologous to the GPCR. The GPCR fusion protein is characterized in that is crystallizable under lipidic cubic phase crystallization conditions. In certain embodiments, the GPCR fusion protein may be crystallizable in a complex with a G-protein or in a complex with an antibody that binds to the IC3 loop of the GPCR.

Abstract: Certain embodiments provide a GPCR fusion protein. In particular embodiments, the GPCR fusion protein comprises: a) a G-protein coupled receptor (GPCR); and b) an autonomously folding stable domain, where the autonomously folding stable domain is N-terminal to the GPCR and is heterologous to the GPCR. The GPCR fusion protein is characterized in that is crystallizable under lipidic cubic phase crystallization conditions. In certain embodiments, the GPCR fusion protein may be crystallizable in a complex with a G-protein or in a complex with an antibody that binds to the IC3 loop of the GPCR.

Abstract: Certain embodiments provide a GPCR fusion protein. In particular embodiments, the GPCR fusion protein comprises: a) a G-protein coupled receptor (GPCR); and b) an autonomously folding stable domain, where the autonomously folding stable domain is N-terminal to the GPCR and is heterologous to the GPCR. The GPCR fusion protein is characterized in that is crystallizable under lipidic cubic phase crystallization conditions. In certain embodiments, the GPCR fusion protein may be crystallizable in a complex with a G-protein or in a complex with an antibody that binds to the IC3 loop of the GPCR.

Abstract: A computer readable medium comprising atomic coordinates for the human ?2 adrenoreceptor is provided. The computer readable medium programming for displaying a molecular model of the human ?2 adrenoreceptor, programming for identifying a compound that binds to said human ?2 adrenoreceptor and/or a database of structures of known test compounds. Also provided is a method comprising computationally identifying a compound that binds to the human ?2 adrenoreceptor using the atomic coordinates.

Abstract: A computer readable medium comprising atomic coordinates for the human ?2 adrenoreceptor is provided. The computer readable medium programming for displaying a molecular model of the human ?2 adrenoreceptor, programming for identifying a compound that binds to said human ?2 adrenoreceptor and/or a database of structures of known test compounds. Also provided is a method comprising computationally identifying a compound that binds to the human ?2 adrenoreceptor using the atomic coordinates.

Abstract: The present invention provides methods and compositions for detection of compounds that have activity in modulating activity of membrane-spanning, signal-transducing (MSST) proteins, e.g., agonists, and antagonists. The detection method is based upon detection of a conformational change in a MSST protein upon interaction with a ligand. Conformational change of the MSST protein upon ligand interaction is accomplished by modifying the MSST protein to comprise a conformationally sensitive detectable probe, so that ligand interaction that results in a conformational change in the MSST protein is detected by a change in detectable signal from the detectable probe. The conformationally sensitive detectable probe can be a chemical label (e.g., a fluorophore) or moiety integral to the protein (e.g., a protease cleavage site, or immunodetectable moiety). The conformational assays of the invention provide for high-throughput screening.

Abstract: The present invention provides methods and compositions for detection of compounds that have activity in modulating G protein-coupled receptor (GPCR) activity, e.g., agonists, and antagonists. The detection method is based upon detection of a conformational change in a GPCR upon interaction with a ligand. Conformational change of the GPCR upon ligand interaction can be accomplished by modifying the GPCR to have a bound detectable label so that ligand interaction results in a conformational change in the GPCR that is detected by a change in detectable signal from the detectable label. Conformational change of the GPCR upon ligand interaction can also be detected by detecting a change in the accessibility of a protease cleavage site to protease cleavage, where the protease cleavage site is naturally-occurring in the GPCR or introduced into the GPCR.

Abstract: Chimeric polypeptides containing the N-terminal amino acid sequence of a glycoprotein hormone receptor polypeptide and a membrane anchor polypeptide, with a protease recognition site between the two, are disclosed. Also disclosed are nucleic acids encoding such polypeptides, expression vectors containing such nucleic acids and methods of producing such recombinant chimeric polypeptides, as well as uses thereof. The chimeric polypeptides are particularly useful for the production of soluble glycoprotein hormone receptor polypeptides.