Claire Normand scite author profile

The recognition that individual GPCRs can activate multiple signaling pathways has raised the possibility of developing drugs selectively targeting therapeutically relevant ones. This requires tools to determine which G proteins and barrestins are activated by a given receptor. Here, we present a set of BRET sensors monitoring the activation of the 12 G protein subtypes based on the translocation of their effectors to the plasma membrane (EMTA). Unlike most of the existing detection systems, EMTA does not require modification of receptors or G proteins (except for Gs). EMTA was found to be suitable for the detection of constitutive activity, inverse agonism, biased signaling and polypharmacology. Profiling of 100 therapeutically relevant human GPCRs resulted in 1,500 pathway-specific concentration-response curves and revealed a great diversity of coupling profiles ranging from exquisite selectivity to broad promiscuity. Overall, this work describes unique resources for studying the complexities underlying GPCR signaling and pharmacology.

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Effector membrane translocation biosensors reveal G protein and βarrestin coupling profiles of 100 therapeutically relevant GPCRs

Avet

Mancini

Breton

et al. 2020

Preprint

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The ability of individual G protein-coupled receptors (GPCR) to engage multiple signaling pathways opens opportunities for the development of better drugs. This requires new knowledge and tools to determine the G protein subtypes and arrestins engaged by a given receptor. Here, we used a new BRET-based effector membrane translocation assay (EMTA) that monitors activation of each Gα protein through the recruitment of selective G protein effectors and βarrestins to the plasma membrane. Profiling of 100 therapeutically relevant GPCR revealed a great diversity of coupling profiles with some receptors displaying exquisite selectivity, whereas others promiscuitely engage all four G protein families. Comparison with existing datasets points to commonalities but also to critical differences between studies.Combining a biosensor subset allowed detecting activity of nearly all GPCR thus providing a new tool for safety screens and systems pharmacology. Overall, this work describes unique resources for studying GPCR function and drug discovery. KEYWORDSG protein-coupled receptor (GPCR), enhanced bystander bioluminescence resonance energy transfer (ebBRET), Biosensor, Effector membrane translocation assay (EMTA), Highthroughput assay, G protein activation, Functional selectivity, Systems pharmacology.

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Common coupling map advances GPCR-G protein selectivity

Hauser

Avet

Normand

et al. 2022

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Two-thirds of human hormones and one-third of clinical drugs act on membrane receptors that couple to G proteins to achieve appropriate functional responses. While G protein transducers from literature are annotated in the Guide to Pharmacology database, two recent large-scale datasets now expand the receptor-G protein 'couplome'. However, these three datasets differ in scope and reported G protein couplings giving different coverage and conclusions on GPCR-G protein signaling. Here, we report a common coupling map uncovering novel couplings supported by both large-scale studies, the selectivity/promiscuity of GPCRs and G proteins, and how the co-coupling and co-expression of G proteins compare to the families from phylogenetic relationships. The coupling map and insights on GPCR-G protein selectivity will catalyze advances in receptor research and cellular signaling towards the exploitation of G protein signaling bias in design of safer drugs.

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Cellular interactions promote tissue-specific function, biomatrix deposition and junctional communication of primary cultured hepatocytes

1988

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Hepatocytes, prepared from normal adult rat liver, were seeded onto a collagen substratum and cultured alone or in the presence of rat liver endothelial cells. When hepatocytes were cultured alone in a hormonally defined serum-free medium, decreased albumin production and rapid morphological deterioration of bile canaliculi structures and gap junctions occurred within 4 to 5 days. In contrast, hepatocytes cocultured with liver mesenchymal cells remained morphologically intact and biochemically functional for at least 4 weeks. They reorganized into small islands, continued to secrete high levels of albumin, did not express alpha-fetoprotein (a fetal marker), and remained strongly dye coupled. All of the hepatocytes synthesized albumin and retained their gap junctional channels. No junctional communication was observed between hepatocytes and endothelial cells. Long fibers containing fibronectin, Type I collagen and laminin distributed over the hepatocytes were induced in coculture but never appeared in hepatocytes cultured alone. Moreover, supplementation of the hormonally defined medium with phenobarbital and dimethyl sulfoxide, both of which improve the life span and functional activities of cultured hepatocytes, failed to induce reticulin fiber formation in pure culture of hepatocytes. The modulation of albumin secretion, biomatrix deposition and junctional communication observed in hepatocytes cultured with sinusoidal liver cells was also obtained when hepatocytes were in association with various epithelial or mesenchymal cells [rat liver epithelial cells (T51B), mouse embryonic fibroblasts (NIH 3T3), human or rat dermal fibroblasts and bovine aorta endothelial cells (AG 4762)].

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Claire Normand

Effector membrane translocation biosensors reveal G protein and βarrestin coupling profiles of 100 therapeutically relevant GPCRs

Effector membrane translocation biosensors reveal G protein and βarrestin coupling profiles of 100 therapeutically relevant GPCRs

Common coupling map advances GPCR-G protein selectivity

Cellular interactions promote tissue-specific function, biomatrix deposition and junctional communication of primary cultured hepatocytes

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