Etude de la relation entre les conformations et la signalisation des 7TMRs.

摘要

Ligand binding to 7TMRs is thought to induce conformational changes within the receptor that translate into activation of downstream effectors. The link between receptor conformation and activity is still poorly understood, as current models of receptor activation fail to take an increasing amount of experimental data into account. Classical pharmacological models such as the ternary complex model are based on the concept that receptors can only adopt a limited number of conformations.;To clarify structure-function relationships in 7TMRs, first we studied chemokine receptor CXCR4. This receptor is an important drug target, involved in HIV-1 entry and cancer metastasis. Bioluminescence Resonance Energy Transfer (BRET) allows us to directly probe conformational changes within pre-formed CXCR4 homodimers in live cells. Using BRET, we measured the conformation of CXCR4 mutants and we also monitored their function by measuring their ability to induce Galphai activation. The analyzed mutants had substitutions in locations which are pivotal molecular switches for receptor conformation and activation. We show that agonist induced Galphai activation is altered for most mutants. These mutations also alter CXCR4's conformation at basal conditions (in absence of ligand) and in the presence of the agonist, SDF-1, the partial agonist, AMD3100 and the inverse agonist, TC14012. Moreover, different conformations of active receptors were detected in the presence of SDF-1, suggesting that different receptor conformations are able to trigger Galphai activity. These data provide biophysical evidence for different active receptor conformations, that cannot be explained by classical models of receptor function (Berchiche et al. 2007).;Furthermore, the second part of our work focused on chemokine receptor CCR2. Mainly expressed on immune cells, CCR2 is involved in many inflammatory and vascular diseases. This receptor binds seven natural ligands that have been referred to as redundant. We set out to explore whether the different chemokine ligands of CCR2 receptor induce different conformational changes leading to different functional consequences. Our results show that the different natural ligands of CCR2 are not pharmacologically redundant. Moreover, chemokines CCL8, CCL7 and CCL13 (MCP-2 to MCP-4) are partial agonists of CCR2, at least in the systems we used. Our results support the validity of models for receptor-ligand interactions in which different ligands stabilize different receptor conformations also for endogenous receptor ligands, demonstrating that these natural ligands are not pharmacologically and functionally redundant (Berchiche et al. 2011).;As the third part of this work, we studied chemokine receptor CXCR7, the alternative receptor for SDF-1. Until recently, CXCR4 was the only receptor known to bind SDF-1. Moreover, the expression patterns are similar for receptors CXCR4 and CXCR7. Therefore, we investigated the conformational and functional consequences of the synthetic inhibitor of CXCR4, AMD3100, on CXCR7. We show that AMD3100 also binds the alternative SDF-1 receptor, CXCR7. SDF-1 or AMD3100 alone trigger beta-arrestin recruitment to CXCR7, which we identify as a previously unreported signalling pathway of CXCR7. In addition, AMD3100 has positive allosteric effects on SDF-1 binding to CXCR7, on SDF-1-induced conformational rearrangements in the receptor dimer as measured by BRET, and on SDF-1-induced beta-arrestin recruitment to CXCR7. The finding that AMD3100 not only binds CXCR4, but also to CXCR7, with opposite effects on the two receptors, call for caution in the use of this compound as a tool to dissect SDF-1 effects on the respective receptors in vitro and in vivo .;Finally, these data provide biophysical evidence for different active receptor conformations, and support models of 7TMR structure-activity relationships that take conformational heterogeneity into account.;Keywords: 7TMR, chemokine receptor, CXCR4, CXCR7, CCR2, BRET, SDF-1, AMD3100, TC14012, beta-arrestin, receptor homodimer, G protein