key: cord-0705335-unmqhvw8 authors: Speck, David; Kleinau, Gunnar; Szczepek, Michal; Kwiatkowski, Dennis; Catar, Rusan; Philippe, Aurélie; Scheerer, Patrick title: Angiotensin and Endothelin Receptor Structures With Implications for Signaling Regulation and Pharmacological Targeting date: 2022-04-19 journal: Front Endocrinol (Lausanne) DOI: 10.3389/fendo.2022.880002 sha: 0b3314b7d86723dc2e383c1e9eb306f86f0f1f64 doc_id: 705335 cord_uid: unmqhvw8 In conjunction with the endothelin (ET) type A (ET(A)R) and type B (ET(B)R) receptors, angiotensin (AT) type 1 (AT(1)R) and type 2 (AT(2)R) receptors, are peptide-binding class A G-protein-coupled receptors (GPCRs) acting in a physiologically overlapping context. Angiotensin receptors (ATRs) are involved in regulating cell proliferation, as well as cardiovascular, renal, neurological, and endothelial functions. They are important therapeutic targets for several diseases or pathological conditions, such as hypertrophy, vascular inflammation, atherosclerosis, angiogenesis, and cancer. Endothelin receptors (ETRs) are expressed primarily in blood vessels, but also in the central nervous system or epithelial cells. They regulate blood pressure and cardiovascular homeostasis. Pathogenic conditions associated with ETR dysfunctions include cancer and pulmonary hypertension. While both receptor groups are activated by their respective peptide agonists, pathogenic autoantibodies (auto-Abs) can also activate the AT(1)R and ET(A)R accompanied by respective clinical conditions. To date, the exact mechanisms and differences in binding and receptor-activation mediated by auto-Abs as opposed to endogenous ligands are not well understood. Further, several questions regarding signaling regulation in these receptors remain open. In the last decade, several receptor structures in the apo- and ligand-bound states were determined with protein X-ray crystallography using conventional synchrotrons or X-ray Free-Electron Lasers (XFEL). These inactive and active complexes provide detailed information on ligand binding, signal induction or inhibition, as well as signal transduction, which is fundamental for understanding properties of different activity states. They are also supportive in the development of pharmacological strategies against dysfunctions at the receptors or in the associated signaling axis. Here, we summarize current structural information for the AT(1)R, AT(2)R, and ET(B)R to provide an improved molecular understanding. The high biological, medical, and pharmacological relevance of GPCRs (~830 in humans) is due to their key role in signal transduction across the cell membrane from the extracellular side toward the cell interior (1) . They interact with a large number of stimulants (agonists), such as odors, peptides, metabolites, light, nucleotides, amines, or a variety of hormones and proteins (2) . Generally, receptor interaction with agonists results in an increased capacity of intracellular coupling and subsequent activation of G-protein(s) or arrestin(s) (3) . This causes induction of downstream pathways regulating e.g., ion channel activity or gene expression (4) (5) (6) (7) . GPCR signaling is linked with almost all physiological processes, such as growth, learning, memory, reproduction, or senses like taste and vision (7) . More than 100 diseases or pathogenic conditions are linked to dysfunctional GPCRs (8) , including viral infections, cancer, infertility, inflammation, and metabolic and neurological disorders (9) (10) (11) , which, altogether, makes these receptors essential for pharmacological and structural studies [e.g (12) ]. The angiotensin (ATRs) and endothelin receptors (ETRs) belong to class A GPCRs (13, 14) . For the groups of ETRs and ATRs, respectively, much detailed physiological information, but also pathophysiological relations are known. In brief, the AT 1 receptor (AT 1 R) binds different angiotensin (Ang) subtypes Ang I, Ang II, Ang III, and Ang IV, which are the main effector peptide hormones of the renin-angiotensin system (15) . AT 1 R can activate the G-protein subtypes Gi/o and Gq/11, and also b-arrestin, upon agonist action (16) . Pharmacologic interventions that either decrease Ang production or modulate Ang actions through AT 1 R blockade are the current mainstay of renoprotection, as documented by extensive experimental work and clinical trials of diabetic and non-diabetic renal diseases (17) . AT 1 R dysfunction leads to several pathophysiological conditions, including hypertrophy, vascular inflammation, atherosclerosis, endothelial dysfunction, insulin resistance, angiogenesis, and cancer (18) . Antibodies (Abs) are involved in the development of preeclampsia, acute graft rejection, and systemic sclerosis (19) (20) (21) (22) . Of note, the Ang II/AT 1 R signaling axis was identified recently to be involved in inflammatory processes, collateral tissue damage, and systemic failure related to COVID-19 infection (23) . AT 1 R blockers or biased AT 1 R agonists are discussed to contribute potentially to treatment strategies against COVID-19 effects (24) (25) (26) . Endogenous ligands of the AT 2 receptor (AT 2 R) are Ang II and Ang III with affinities in the nanomolar range (14) . Of note, during the elucidation of AT 2 R related signaling pathways several hypotheses arised and were studied/confirmed, including G-protein independent signal transduction (27) (28) (29) (30) , G-protein subtype Gi/o activation (31) , and also ligandindependent signaling crucial in apoptosis (32) . AT 2 R is expressed in vessels (endothelial cells), heart, kidney (tubules, glomeruli, collecting ducts, arterioles, and interstitial cells), brain, and immune cells (33) . In the kidney, physiological stimulation of the receptor causes diuresis and natriuresis by decreasing salt and water transport from the tubules to the capillaries, triggering sodium and water excretion (34) . Chronic AT 2 R overexpression has deleterious effects on cardiomyocytes (35) and AT 2 R activation, as AT 1 R, is involved in neuropathic pain (36, 37) . The ET A receptor (ET A R) (38, 39) is localized mainly in vascular smooth muscle cells and, therefore, in all tissues supplied with blood, including the heart, lung, and brain, but are also present on other cell types, including myocytes within the heart (38, 40) or endothelial cells. ET A R has a stronger affinity for ET-1 and ET-2 than for ET-3, all three constituting the family of endothelin peptides (41) . ET A R has been associated with the vasoconstrictive effects of ET-1 and is involved in different pathologies (6) . Hence, it was shown that ET A R activation has detrimental effects on preeclampsia (42) , heart failure (43) , and pulmonary hypertension (44) . In the kidney, ET A R induces natriuresis (45) and its inhibition can improve short-term lesions triggered by ischemia-reperfusion injury (46) . Finally, point mutations in the gene coding for ET A R are responsible for mandibulofacial dysostosis with alopecia (47) and Oro-Oto-Cardiac syndrome (48) , as the receptor is involved in craniofacial development. ET A R signaling activity is associated primarily with the G-protein subtypes Gq/11, but there are also indications for Gi/o signaling (16) . With the same affinity the ET B receptor (ET B R) interacts with all three endothelin (ET-1, ET-2, and ET-3) peptides. It resembles many actions of ATRs on renal cell types (49) . This receptor couples to the G-protein subtypes Gs, Gi/o, and Gq/11 (16) . ET B R is expressed in the lungs and brain (50) , and conveys reversal effects as ET A R, mainly vasodilatation by stimulating nitric oxide (NO) production and clearing ET-1 (51) . In the kidney, ET B R is involved in sodium excretion (52) . The ET B R contains a metal-proteinase cleavage site at the long N-terminus around an A-G-x-P-P-R motif ( Figure 1 ) (55) . Interestingly, there are reports on endothelin receptors homo-or heterodimerization with other receptors (see chapter below for details). Depending on the particular receptor-receptor configuration, the resulting signaling effects can differ (56) . In summary, AT and ET receptors are of high physiological and medical importance, including e.g., renal effects, blood pressure (57), cell proliferation (6, 58, 59) , or cancer development (60) . Of note, an increasing amount of structural information has been published in recent years, complementing functional insights. Several structures in different activity states were determined by protein X-ray crystallography using conventional synchrotrons or XFELs ( Table 1) for AT 1 R, AT 2 R, and ET B R. They reveal details of the signal transduction process at the molecular level. In this brief review, we summarise the current state of knowledge about these receptors and receptor complex structures. We aimed to provide a first systematic overview of structural insights into these receptors including ligand binding, dimerization, receptor activation, and inactivation. Thus, we will also identify open knowledge gaps that will aid in the identification of topics relevant for future studies. Two AT 1 R and three ET B R inactive state structures solved by Xray crystallography have been published (as of January 2022; summarized in Table 1 ). They provide deeper insights into structural features associated with the inactive receptor states and how antagonists block the signaling process. Highly conserved amino acids ( Figure 2A ) significant for each GPCR class (74, 75) are generally important for expression and the folding of diverse receptor components, e.g., prolines defining weak points in helices because of steric conflicts with the preceding residue and the loss of a backbone H-bond, which can cause kinks (76, 77) as observed in the CWxP 6.50 motif in transmembrane helix 6 (TM6) [superscripted numbers are provided additionally according to the unifying Ballesteros & Weinstein numbering for class A GPCRs (74) ]. Conserved amino acids also play a fundamental role in maintaining an inactive state conformation(s), as, for example, in the AT 1 R the D74 2.50 in the transmembrane helix (TM) 2, or N298 7.49 in TM7 ( Figure 2A ). They interact through hydrogen bonds with each other or with other hydrophilic amino acid side chains, or with water molecules constraining the inactive state between TM's 1, 2, 3, and 7 ( Figure 2B ). In most of the inactive state structures of AT 1 R and ET B R, no water or sodium ions (region between D 2.50 -N 7.49 , as known from other GPCRs (78)) can be observed due to the low resolutions between 2.7 to 3.6 Å ( Table 1) . However, in the ET B R structure with a resolution of 2.2 Å [Protein Data Bank (79) (PDB) ID: 5x93 (68)], water molecules in tight interaction to hydrophilic amino acid side chains are visible ( Figure 2B ). This network of hydrogen bonds between hydrophilic residues in TM1, TM3, and TM7, as well as water molecules, is not observable in all active state structures of ATRs or ET B R receptors, nor in other active state GPCR structures (80), because they disappear in the course of receptor activation and related structural rearrangements. Of note, in an active state, such as the ET B R structure complexed with the partial agonist IRL1620, a few water molecules are still observed, and they are supposed to partly preserve the interaction network typical for inactive states (70) . This might be related to the fact that in this FIGURE 1 | Sequence comparison between the ATRs, ETRs, and bovine rhodopsin (bOPSD) or human b-2 adrenergic receptor (hADRB2). The length of each transmembrane helix (TM1-7) or loops (IL, intracellular loop; EL, extracellular loop) are indicated above the sequence according to an AT 1 R structure [PDB ID: 4zud (53) ] but can differ slightly in other structures. The overall sequence similarity between ET A R and ET B R is approximately 63%, whereas between AT 1 R and AT 2 R 47%. Sequence similarities between ATRs and ETRs, respectively, are around 30%. The sequences of prototypical class A GPCRs bOPSD and hADRB2 are provided additionally for comparison. The alignment was visualized using the software BioEdit (54) . Specific background colors reflect chemical properties of the amino acid side chains or the type of amino acid: black-proline; blue-positively charged; cyan/green-aromatic and hydrophobic; green-hydrophobic; red-negatively charged; gray-hydrophilic; dark red-cysteines; and magenta-histidine. structure, as for all ET B R structures with bound agonists so far, no intracellular transducer protein as a G-protein molecule stabilizes the active state conformation and, therefore, the TM6 orientation is different to known fully active state structures (restricted movement toward the membrane). In conclusion, such structures do not display a fully active receptor conformation. For diverse GPCRs a significant interaction (previously named "ionic lock") between the highly conserved R 3.50 in TM3 (Figure 2A ) of the DR 3.50 Y motif and a negatively charged residue located at the intracellularly site of TM6 is known to be essential for maintaining the inactive state (72, 73) . According to the available structures, such interaction has not yet been observed in AT 1 R or ET B R. Only in the case of an AT 1 R structure [PDB ID: 4yay (61)] a potential hydrogen bond interaction between R126 3.50 and N235 6.30 (backbone) is observable ( Figure 2C ), which may constrain the typical Additional information is provided as the bound ligand or fusion proteins. Color code: green: active state-like; blue: inactive or antagonized; white: ligand-free. inactive state conformation of TM6 directed inward to the transmembrane core ( Figure 2A ) (1). All previously known structures of inactivated or antagonized receptor states were obtained by binding antagonists ("antagonized") or inverse agonists ("inactive"), in addition to specifically-directed mutations, which were usually necessary to stabilize an individual receptor state or improve receptor expression. (Table 1 , Figures 2D, E) . In the two inactive/antagonized AT 1 R structures, the ligands are bound mainly between residues located in the EL2, TM1, and TM2 ( Figure 2D ). This binding crevice ( Figure 2D1 ) overlaps greatly with the binding sites of antagonists for the ET B R ( Figure 2E ). However, significant differences exist in binding details by an extended binding region of ET B R antagonists and the inverse agonist IRL2500 ( Figure 2E ). Here, specific residues in TM3 and TM5 are essentially involved in antagonist binding. Of note, the inverse agonist IRL2500 in the inactive ET B R structure [PDB ID: 6k1q (67)] interacts, in addition to other residues, with an aromatic moiety directly at W336 6.48 in TM6, which is known generally for class A GPCRs to be a crucial trigger for receptor activation. This W 6.48 is located in the CWxP 6.50 motif involved in activation-related TM6 outward movement as part of the "global toggle-switch" activation model (81, 82) , also described as the "rotamer toggle switch" hypothesis (1, 83) . The inverse agonistic activity of this ligand is assumed to be potentially associated with this interaction, which constraints tryptophan in a basally non-active state (67) . However, independent of the antagonist or an inverse agonist status, these ligands ( Figures 2D, E) occupy a receptor region that is also involved in agonist binding (next section, Figure 4 ) and therefore compete with agonist binding. Notably, aside from diverse directed structural alterations for protein stabilization such as fusion with T4 lysozyme or Conserved residues in class A GPCRs (magenta sticks) important for receptor-fold, expression, and signaling are highlighted at the inactive state structure of AT 1 R (backbone cartoon) in complex with the antagonist ZD7155 (green sticks). Highly significant for non-active state conformations is the inward direction of the transmembrane helix (TM) 6 into the helical bundle, which closes the intracellular binding cavity for G-proteins or arrestin (see also Figure 4E ). The antagonist ZD7155 (green) is bound in a pocket between the transmembrane helices and their transition to the extracellular loops. Notably, a disulfide bridge (yellow sticks) between the N-terminus and the EL3-TM7 transition forms and stabilizes the spatial region between the N-terminus and EL3, which is also present in the AT 2 R and the ET B R (not shown). (B) In the antagonized ET B R structure bound with the antagonist K-8794, water molecules solved at a high resolution of 2.2 Å. These water molecules are located centrally in the helical bundle, participating by H-bonds with hydrophilic residues in maintaining an inactive state conformation. (C) Of the currently known five inactive state structures for ETRs and ATRs, only one inactive state shows a H-bond between the intracellular parts of TM3 and TM6 involving the highly conserved R 3.50 . In several class A GPCRs, an "ionic lock" between this arginine and a negatively charged amino acid in TM6 has been postulated or shown to be essential for constraining the inactive state (72, 73) . This cannot be perceived equally for most of the available inactive ET B R and AT 1 R structures. (D) AT 1 R antagonists olmesartan (inverse agonist, cyan sticks) and ZD7155 (green sticks, Table 1 ) are bound mainly between three residues in EL2, TM1, and TM2 in the upper part of the helical bundle (PDB IDs: 4zud and 4yay). Red circles indicate the main contact points. (D1) Visualized is the binding pocket of olmesartan by a clipped inner surface representation. (E) Superimposition of ET B R structures (PDB IDs: 6k1q, 5x93, 5xpr -only one backbone structure is visualized as cartoon because of high overlap between these structures) with antagonists K-8794 (green), bosentan (orange), and IRL2500 (inverse agonist, magenta) shows partially largely binding regions in the receptors, but also significant differences to antagonist binding sites of AT 1 R (red circles). While a residue of the N-terminal EL2 is involved in ligand binding in both receptors, several H-bonds to amino acids in TM3 and TM5 can be observed in the ET B R. The inverse agonist IRL2500 additionally contacts (blocks) the highly conserved tryptophan in TM6 (W336 in ET B R), which is part of the CWxP 6.50 motif that participates in the activation mechanism of class A GPCRs. Red circles indicate the main contact points. All graphic representations in this article were created using the PyMol Molecular Graphics System Version 1.5 (Schrödinger, LLC, New York, NY). EL, extracellular loop; Nt, N terminus; IL, intracellular loop; H8, helix 8; TM1-7, transmembrane helices 1-7. deletions, the inactive, apo-, and agonist bound structural complexes of the ET B R are modified in their amino acid sequence ( Table 1) . Five combined particular substitutions were used to stabilize complexes with both antagonists, the apo state, and also with agonists, which is not unusual in GPCR preparation for crystallization studies (Supplementary Table S1 ). These mainly alanine substitutions are located in diverse receptor regions as TM's 1, 2, 5, 6, and 7 ( Figure 3A ). Generally, individual or combined thermostabilizing mutations used in class A GPCRs (Supplementary Table S1 , Figures 3B-D) can be localized at very diverse structural parts, either with side chains directed into the transmembrane core or with side chains directed toward the membrane. A statistical analysis of the distribution of thermostabilizing mutations used for class A GPCR crystallization (analysis of 17 different GPCRs; Supplementary Table S1 and Figure 3D ) shows thermostabilization via mutations is principally feasible in each helix, including helix 8. The molecular effect of such mutations and their combinations is associated with, e.g., the stabilization of a certain conformational state (directed into the transmembrane core) as inactive or active, substitutions of residues facing lipids (directed toward the membrane or detergent), or mutations stabilizing local structural areas (e.g., helix-helix interface directed) (84, 85) . In the case of the ET B R, a mixture of these "types" of substitutions can be postulated, whereby R124Y and I381A are directed to the membrane, D154A points into the helical core, K270A is in the interface between TM5 and EL2, and S342A is part of the TM6-TM7 interface ( Figure 3A ). GPCR activation commonly involves binding of an agonistic ligand or sensing of a physical trigger (e.g., light or mechanical forces), which induces alterations in the binding region and, subsequently, in specific helical adjustments relative to each other. This process finally enables intracellular binding of a transducer protein by enlargement of the crevice between the helices and ILs. The active state conformation is, therefore, stabilized by the ligand, the intracellular effector, and particular Table S1 ) demonstrates that they act in a contrasting manner, either by modulating the protein-membrane interaction or by changes of intramolecular interactions participating in the regulation of activity state-related conformations. The substitutions used for stabilizing class A GPCR structures either in the apo-, inactive-, or active-state (in the diagram termed as Agonist, Antagonist or Neutral according to the state of ligand occupancy) are located at each helix, however, more identified mutants to stabilize active than inactive state conformations are located in TM1, TM2, TM6, and TM7, whereby in TM3 and also in TM5/TM6 a high number of inactive state stabilizing mutations were identified. intramolecular side-chain interactions. In turn, this process, with the receptor as a central signaling hub of information, is primarily related to structural rearrangements, dependent on spatial-fit-in's and biochemical recognition patterns [or "recognition barcodes" (86) ] between the receptor-ligand complex and effector, such as the G-protein. How is this "activation process", "signal transduction", or "stabilization of the active state conformation" reflected by available ATR and ET B R structures? More than ten ET B R and AT 1 R/AT 2 R structures ( Table 1 ) with a bound agonist are known so far (Figure 4) . These structures show specific features as intracellularly bound nanobodies ( Figure 3A) , extracellular bound antibody-fragments ( Figure 4B) , a noncanonical helix 8 orientation ( Figure 4B1 ), or specificities in transmembrane helix conformations ( Figure 4C) . However, none of them is part of a complex with a G-protein or arrestin. However, when compared to inactive/antagonized conformations ( Figures 4E, F) , these active state-like conformations reveal how these GPCRs interact with agonists and how this binding process induces changes in receptor structure ( Figure 5) . Generally, ATR and ETR agonists bind deep into an extracellular cleft formed between the EL1-3 and the adjacent TMs close to W 6.48 (Figures 4, 5) . The EL2, EL3, and the Nterminus cover the ligand-binding pocket extracellularly for both Table 1 ). The agonist [endogenous peptide agonist sequences are provided in (A1), including annotated disulfide bridges and conserved regions (colored background)] is bound extracellularly between the ELs and their transitions to the helices ( Figure 5) . Several AT 1 R structures are stabilized intracellularly by a bound nanobody ( Table 1 ). The agonist-bound structures are not complexed yet with G-protein or arrestin. (B) The AT 2 R structures not only contain various agonists but have been further stabilized in some cases with Fabs (fragment antigen binding), which bind on the extracellular side. (B1) For AT 2 R, intracellular helix 8 has been observed to be directed inward to the transmembrane helix core and stabilizes the active state structure instead of a transducer protein like the G-protein. Generally, helix 8 is oriented parallel to the membrane and outside the helical bundle in GPCRs. (C) The active state ET B R structure bound with ET-1 represents endogenous ligand binding, whereby the ligand is buried deep within the ligand-binding pocket (see Figure 5 ). The helical transition from EL2 to TM5 is kinked (red line) in contrast to the ATR structures. (D) Comparison with the ligand-free apo-state conformation highlights structural differences in the extracellular region where the ligand is bound, mainly in TM6 and TM7, but also for EL2 (red arrows). A further difference is the helical transition between the Nterminus and helix 1 in the apo-state structure compared to an unfolded transition in the ligand-bound structure. (E) Agonist-bound AT 1 R and AT 2 R receptor conformations deviate from the inactive state structures in the intracellular orientation of TM6, but also relative spatial shifts are observed at the intracellular parts of TM5 and TM7 (red arrows). For the AT 1 R, strong deviations in the H8 orientation are observable in dependency of the activity state. (E1) The structural transitions between inactive and active state conformations are accompanied by re-organization of intramolecular interactions in the transmembrane helical core (62), as visualized here exemplarily at amino acid residues in TM6 and TM7. This re-organization and subsequent new interactions are involved in maintaining active state-like conformations. Figures 4A, 5A-A1) . Receptor amino acids participating in ligand binding are located mainly at the Cterminal part of the receptor EL2, in TM2, TM6, and TM7 ( Figures 5A, B) . Further, direct interactions between the ligand and the N-terminus can be observed (AT 1 R-b-arrestin biased agonist TRV026 (PDB ID: 6os2) and ET B R/ET-3 (PDB ID: 6igk) complexes, Figure 5B ). Although no structure is available for the ET A R yet, it can be assumed that the binding mode of peptide-agonists at this receptor should be in principle similar to the binding mode observed at the agonist-bound ET B R structures. This hypothesis is based on comparison between receptor amino acids that are in direct contact to agonists (e.g. structure ET B R/ET-1, PDB ID: 5glh). Key contact (hydrogen bonds) amino acid residues from the receptor to the ligand are for instance K161 (TM2), K182 (TM3), E236 (TM5), R343 (TM6), K346 (TM6), Y350 (TM6), and they can be found also in the ET A R sequence at corresponding positions (K140, K166, E220, R326, K329, Y333). Based on this circumstance and the high overall sequence similarity of 62% between both receptor subtypes, it can be expected that the identified ET B R structures can serve as ideal templates to build ET A R homology-models. This is supported by experimental studies providing overlapping amino acids relevant for peptide-ligand binding (87) . However, elucidation of potential differences in ligand binding properties (88) , such as ligand affinity, definitely requires the determination of ET A R structures and structural complexes. Together with W 6.48 , hydrophobic amino acids in TM3 (e.g., at positions 3.32 and 3.36) form a hydrophobic pocket that triggers receptor activation caused by endogenous ligand contact with an aromatic moiety (66) . As mentioned above, this tryptophan is part of the CWxP 6.50 motif that participates in the activation mechanism of class A GPCRs. Superimposition of ET-1 (bound to ET B R, PDB ID: 5glh) and Ang II (bound to shows partially overlapping binding pockets close to W 6.48 . (C) Superimposition of ET-1 (bound to ET B R, 5glh) and Ang II (bound to AT 1 R, 6os0) reveal structural differences between the ligands due to deviations in sequence composition and length (see also Figure 4A1 ); however, the C-terminally located aromatic residue in both ligands is close to the highly conserved W 6.48 , which is part of the activation-related toggle switch motif in helix 6. (D) Non-peptide AT 2 R agonists as compound 1 ( Table 1 ) are bound deep within the ligand-binding region. This section is also occupied by the endogenous peptide agonist Ang II, indicating a region highly relevant for receptor activation. (D1) The non-peptide inverse agonist olmesartan for AT 1 R (4zud) is principally bound in the same region as the AT 2 R non-peptide agonist compound 1 (5ung) with identical interactions to EL2. The different effects of these ligands are attributed to their detailed interactions in corresponding receptors (not visualized in detail). Frontiers in Endocrinology | www.frontiersin.org April 2022 | Volume 13 | Article 880002 AT 1 R, PDB ID: 6os0, Figure 5C ) reveals structural differences between the ligands due to strong diversity in their sequence composition and length ( Figure 4A1) ; however, the C-terminally located aromatic residues in both ligands are close to the highly conserved W 6.48 . Of note, the arrestin-biased Ang II analog ligand TRV023 with a shorter C-terminus does not interact with W 6.48 ( Figures 5B-B1) , indicating selective receptor activation-dependent on specific ligand features. What else can be observed via a comparison of structures with agonists vs. antagonists? Superimposing the structure of the agonistic peptide ET-1 in ET B R with that of the non-peptidic antagonist bosentan reveals a partially overlapping binding mode in the vicinity of W 6.48 , indicating that this region is important for receptor activation or inhibition of activation ( Figure 5A2 ). In addition, several positively charged lysines are essential for ET-1 binding to the receptor in the ET B R/ET-1 complex ( Figure 5A) . These lysines are also key interaction partners for antagonist binding ( Figure 2E) , suggesting the importance of the inhibitory effect of antagonists on the binding of agonists. In the case of AT 1 R, the non-peptide inverse agonist olmesartan (PDB ID: 4zud) is bound in the same region as the AT 2 R non-peptide agonist compound 1 (PDB ID: 5ung, Figure 5D1 ), including identical interactions to the EL2. The different effects of these ligands can be attributed to their detailed interactions in corresponding receptors, namely an additional hydrogen-bond of the antagonist with a tyrosine in TM1 and a contact of the agonist with W 6.48 , which is blocked by a tyrosine in TM7 (Y292 7.43 ) of the AT 1 R with an inverse agonist. Interestingly, a comparison of the ET B R/ET-1 complex with the ligand-free apo-state conformation ( Figure 4D ) highlights structural differences specifically in the ligand-binding region at the extracellular ends of TM6, TM7, and in the EL2. Agonist binding causes structural modifications in the extracellular part, which, is, in strong contrast to observations from the comparison between agonist-bound and inactive/antagonized structures by antagonists ( Figures 4E, E1) . The agonist-bound structures of AT 1 R and AT 2 R deviate from the inactive state structures in the intracellular orientation of TM6 (shift of~9Å), combined with relative spatial shifts at the intracellular parts of TM5 and TM7 ( Figure 4E ). These structural transitions between inactive and active state conformations are accompanied by re-organization of intramolecular interactions in the transmembrane helical core (62) ( Figure 4E1) . As already noted, intracellular processes, such as G-protein binding or arrestin interactions concomitant to receptor-agonist complex formation, cannot yet be studied at available structures ( Table 1) . Usually, these molecules contribute toward stabilizing active state conformations. In the agonist-bound AT 1 R, a nanobody instead stabilizes the active state conformation [ Figure 4A (63) ] and, surprisingly, helix H8 is intracellularly directed inward to the transmembrane helix core of AT 2 R and stabilizes the active state receptor structure [ Figure 4B1 (65) ]. This non-canonical helix 8 orientation would impede binding of G-protein or arrestin and is assumed to be related to the finding of G-protein independent AT 2 R signaling (27) (28) (29) (30) . However, in a recent AT 2 R structure complexed with Ang II a regular helix 8 orientation as known to be canonical in GPCRs is observed (PDB ID: 6jod (66), shown in Figure 6 ), which evidences that this receptor can also adapt into a conformation able to bind G-protein or arrestin. In the agonist-bound ET B R structures ( Table 1 ) without a nanobody, G-protein, or an inside orientated helix 8, the TM6 orientation is similar as in the inactive state conformations, whereby comparing the inactive state structure (PDB ID: 4zud) with the active state conformation (PDB ID: 6do1) of AT 1 R, a distance of intracellular TM6 of 9.4Å can be measured ( Figure 4E) . Moreover, in AT 2 R structures bound with a developed antibody Fab fragment without an intracellular stabilizer (PDB ID's: 5xjm, 6jod), the extent of TM6 movement outside is smaller, only by approximately 7.8 Å compared to inactive AT 1 R structures, which indicates that these structures likely do not represent fully "active state conformations". The available AT 2 R-Fab complexes with Ang II or its derivative [Sar1, Ile8]-AngII (64, 66) show a specific binding epitope of the Fab fragment at the receptor, which is close to the ligand 'core' binding region, although not overlapping. The Fab fragment (Fab4A03) acts as a positive allosteric modulator without direct interaction with the ligands but increases the affinity of both agonists (64) . Such a receptor/antibody interplay is known for many GPCRs (89) . Recently, a human antibody (Ab) against human ET A R that exhibits antitumor potency has been published (90) . Autoantibodies (auto-Abs) directed against AT 1 R acting as agonists or probably positive agonistic modulators inducing pathogenic conditions have been demonstrated several times (22, (91) (92) (93) as in women with preeclampsia (21) , or in patients with acute vascular graft rejection (19, 94, 95) . AT 1 R auto-Abs association with clinical features has also been studied extensively in the context of transplantation (96-100), or their effects on angiogenesis in preeclampsia (101) (102) (103) . Binding of activating AT 1 R-Abs promotes specific downstream signaling via activation of AT 1 R (19, 20) ; however, while Ang II binding to the receptor has been already explored intensively (104) (105) (106) (107) (108) , the binding mode(s) between auto-Abs and receptors have not yet been determined. Based on current literature, only AT 1 R auto-Abs from patients with transplant rejection recognize epitopes that are located primarily in EL2 (19, 21) . Accordingly, the known crystallized AT 2 R-Fab complexes (64, 66) (Table 1 and Figure 6 ) reveal that EL2 is involved in binding, namely with residues E188, Y189, and G191 located in the central EL2 ( Figure 6 ). Furthermore, Y106 (backbone) and D109 in the receptor EL1 contribute to Fab binding as well as Q37 and P39 (backbone) in the N-terminus. This leads to the conclusion for ATRs that distinct receptor parts can interact simultaneously with Fabs and agonistic ligands , whereby the concrete binding sites are distinct as at the Nterminus or EL2. This observation helps to explain how Fab fragments or antibodies mediate positive allosteric effects on signaling or directly trigger activation. The Abs may increase the predisposition of the receptor to bind Ang by a direct structural impact on the extended ligand-binding site (e.g., EL2), or/and increased signaling activity by bound Abs should lower the energetic barrier for the endogenous ligand to further stimulate the receptor. Of note, sequence comparison reveals that potential binding sites for antibodies in the EL1, EL2, and N-terminus are not conserved among ATRs and ETRs subtypes (Figure 1) , with only a few amino acids at corresponding positions identical. This may support that so far known activating antibodies for both receptor subtypes could recognize specific structural conformations rather than binding-specific epitope residues at the receptor, which is in principle known from antibody studies at other proteins (109) (110) (111) . However, different antibodies will bind naturally in a variety of ways and may differ in their receptor binding sites. The term oligomerization indicates dimeric, trimeric, tetrameric, or higher-order complexes between GPCR protomers (monomers) and has been reported for numerous GPCRs not only in vitro (112) but also in native tissues (in vivo) (113) (114) (115) . Homo-or hetero-oligomerization between single receptor protomers are mostly not a prerequisite for class A GPCR signaling capacity (116) , but defines the spectrum of finetuning options in signaling, as they can act as a functional unit (117, 118) . GPCR oligomerization has been reported for several GPCR classes, such as for class A, class B, taste receptors (119) (120) (121) , or class D (122) . Dimerization describes interacting xGPCR/xGPCR (homodimer) or xGPCR-yGPCR (heterodimer) constellations. For defining relevant GPCR-GPCR dimers or oligomers, several aspects are of significance, such as direct intermolecular side-chain interactions or an impact on functionalities (e.g., expression, internalization, signaling, ligand binding) compared to monomeric receptors. In heterodimerization, GPCR expression in the same cell type and cell compartment, as well as simultaneous occurrence (time-dependent expression), are prerequisites (123, 124) . A large amount of GPCR-GPCR protomer interfaces with intermolecular interactions between single amino acids or between several side chains have been reported under the involvement of TM4 (125) (126) (127) , TM1, and TM5-6 (128, 129) . Studying the available class A GPCR dimers in determined structures, specifically the TM1-TM1/helix8-helix8 and the TM4-TM4/TM5- (131) and GPCRs are expressed as a mixture of monomers and homomers, whereby the two forms may interconvert dynamically (132) . Several examples demonstrate that GPCR oligomerization can have a major impact on the signaling properties of interacting protomers, e.g., in ligand binding (133, 134) , G-protein coupling specificity, and signal transduction mechanisms (114) , or cell surface expression (135) . In the event of a direct mutual effect of GPCRs organized in dimeric arrangements, a horizontal allosteric impact on each other, either positively or negatively, may occur (136) . For the ATRs and ETRs, a tremendous set of information is available, supporting a wide spectrum of oligomer formations. As exemplarily summarized from literature databases and a direct collection of GPCR oligomers (GPCR Interaction Network, http://www.gpcr-hetnet.com (137)), the following oligomers have been reported for ATRs or ETRs: • AT 1 R with PAR1 (138), mOR (139), prostaglandin F2aR (140) Oligomerization of wild-type and a non-functional AT 1 R mutant inhibits Gaq-mediated signaling but not ERK activation, supporting a functional influence of a homooligomerization (156) . Aldosterone-related effects activate AT 1 R and AT 2 R hetero-dimerizations (149) , altering trafficking and arrestin recruitment profiles (145) . Further functional effects reported to be associated with homo-or heterodimerization are, for example, transactivation and synergism [AT 1 R with PAR1 (138)], altered expression levels for AT 1 R -ET B R heteromers (141) , or ATRs with RXFP1 show functional crosstalk in myofibroblasts (142, 143) . AT 2 R heterodimerization with bradykinin B 2 R (150) has a strong impact on the signaling outcome and amplitude (NO production). ET B R-ET A R heterodimers are modified in internalization rates compared to the homo-dimerization of the wild-type receptors (152) . To date, only one report on the AT 1 R homodimer structure exists [PDB ID: 6do1 (62) ]. The interface between the single protomers is constituted by hydrophobic and aromatic amino acid side chain contacts at EL1, TM1, TM2, TM3, and helix 8 ( Figure 7A) . Interestingly, this dimer is in an active state conformation, bound with an Ang II analog and with intracellularly stabilizing nanobodies at each protomer. The observable interface in the AT 1 R dimer is in agreement with interfaces in many other GPCR dimers (157) , which might imply relevance also in vivo to cause a mutually allosteric (158) functional impact on ligand binding capacities or internalization rates. However, other interfaces were studied and recently proposed by A B FIGURE 7 | Dimer arrangement of the active state AT 1 R bound with an Ang II analog and nanobodies. (A) The complex between the Ang II analog, AT 1 R, and active state stabilizing nanobodies has been crystallized as a homodimer [PDB ID: 6do1 (62)]. The interface between the protomers is constituted by hydrophobic and aromatic amino acid side chain contacts at EL1 (M90, F96), TM1 (F55, intracellularly), TM2 (Y99), and helix 3 (L100). (B) In a putative scenario of a dimeric receptor arrangement with antibody binding at one protomer, the Fab fragment should also simultaneously contact the second receptor protomer. For this model, the AT 2 R structure (6jod), with and without a Fab, were arranged together as suggested by the AT 1 R homodimer. atom molecular dynamics simulations (159) , which is in line with the assumed multitude of feasible GPCR oligomer arrangements. As exemplified in Figure 6B in a dimeric receptor formation, a bound antibody at one protomer should simultaneously contact the second protomer ( Figure 7B ). This should be the case for homodimers of AT 1 R (156), AT 2 R (149), or heterodimers of ATRs (145) and ETRs (56, 141) , which are known to be occupied endogenously by antibodies under pathogenic conditions (160, 161) . As already mentioned above, an AT 2 R/Ang II analog complex was co-crystallized with a Fab. This Fab acts as a positive allosteric modulator (64) , which might also be related to observed dimeric receptor constellations or might have consequences on the functional reactivity of receptor dimers. Finally, if homo-or heterodimeric ATR and ETR arrangements are of functional and physiological relevance, pharmacological interventions may (must) target or consider these oligomers, especially with the aim of circumventing adverse effects mediated by allosteric heterodimer actions. Correspondingly, if the large number of putative heterodimers between ATRs/ETRs and other GPCRs are functionally relevant in vivo, any pharmacological intervention at their interaction partner should also have an impact on both receptor subtypes (ETR, ATR), which might be registered medically as unwanted adverse effects. Pharmacological strategies may profit from homo-or heterobivalent ligands specifically entering GPCR dimers (162, 163) in diverse ligand constellations, e.g., as bitopic and dualsteric ligands (164) . As summarized in this short review, an enormous amount of structural-functional information on ATRs and ETRs is available, with a clear boost on structure determination since 2015. These structures provide details and general insights into mechanisms of activation and features of nonactive or inactive states. An advantage of the high number of solved structures is the resulting capability for comparison, including diversities in ligand binding, and to study the spectrum of possibilities in structural arrangements, e.g., helix conformations or dimer formation. However, several gaps in knowledge are evident, with primary emphasis on not yet determined ET A R structures and missing structural information on G-protein or arrestin binding. Moreover, reflecting the high number of GPCR heteromer reports for ATRs and ETRs with functional impact, it also appears necessary to intensify further means of exploring ways to elucidate heteromer arrangements, both structurally and functionally for these receptors and binding partners. In addition, this is an area of utmost pharmacological importance (165, 166) and, therefore, must be of structural interest, especially given the increasing possibilities in the determination of complex structures (167) . Finally, the relevance of autoantibody binding to both receptor groups require questions on antibody binding and its functional significance to be explored in-depth, intending to use improved understanding to tailor the design of optimal ligands useful for pharmacological intervention strategies or to recruit these receptors (as monomers or dimers) as hubs for precisely sought specific responses. The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fendo.2022. 880002/full#supplementary-material A G-Protein-Coupled Receptor at Work: The Rhodopsin Model Molecular Mechanisms of Ligand Binding, Signaling, and Regulation Within the Superfamily of G-Protein-Coupled Receptors: Molecular Modeling and Mutagenesis Approaches to Receptor Structure and Function The Molecular Basis of G-Protein-Coupled Receptor Activation Regulation of Transcription Factors by Heterotrimeric G-Proteins The G-Protein-Coupled Receptor-Transient Receptor Potential Channel Axis: Molecular Insights for Targeting Disorders of Sensation and Inflammation Endothelin Receptor Signaling: New Insight Into its Regulatory Mechanisms The Receptor Concept: A Continuing Evolution G-Protein-Coupled Receptors as Targets for Approved Drugs: How Many Targets and How Many Drugs G-Protein-Coupled Receptors and Cancer Mutant G-Protein-Coupled Receptors as a Cause of Human Diseases Structures of Active Melanocortin-4 Receptor-Gs-Protein Complexes With NDP-Alpha-MSH and Setmelanotide Phylogeny, Taxonomy, and Evolution of the Endothelin Receptor Gene Family Angiotensin Receptors: Structure, Function, Signaling and Clinical Applications Synthesis and Effects of Active Fragments of Angiotensin II The IUPHAR/BPS Guide to PHARMACOLOGY in 2020: Extending Immunopharmacology Content and Introducing the IUPHAR/MMV Guide to MALARIA PHARMACOLOGY Treatment of Chronic Kidney Disease International Union of Basic and Clinical Pharmacology. XCIX. Angiotensin Receptors: Interpreters of Pathophysiological Angiotensinergic Stimuli Angiotensin II Type 1-Receptor Activating Antibodies in Renal-Allograft Rejection Involvement of Functional Autoantibodies Against Vascular Receptors in Systemic Sclerosis Patients With Preeclampsia Develop Agonistic Autoantibodies Against the Angiotensin AT1 Receptor Autoantibodies Targeting AT1-and ETA-Receptors Link Endothelial Proliferation and Coagulation via Ets-1 Transcription Factor Insights to SARS-CoV-2 Life Cycle, Pathophysiology, and Rationalized Treatments That Target COVID-19 Clinical Complications The Rationale for Angiotensin Receptor Neprilysin Inhibitors in a Multi-Targeted Therapeutic Approach to COVID-19 Possible Therapeutic Interventions in COVID-19 Induced ARDS by Cotinine as an ACE-2 Promoter and AT-1R Blocker Beta-Arrestin-Biased Angiotensin II Receptor Agonists for COVID-19 Angiotensin II AT2 Receptors Do Not Interact With Guanine Nucleotide Binding Proteins Gbeta Gamma -Independent Constitutive Association of Galpha s With SHP-1 and Angiotensin II Receptor AT2 is Essential in AT2-Mediated ITIM-Independent Activation of SHP-1 Characterization of a Rat Type 2 Angiotensin II Receptor Stably Expressed in 293 Cells Angiotensin II Stimulates Protein Tyrosine Phosphatase Activity Through a G-Protein Independent Mechanism The AT2 Receptor Selectively Associates With Gialpha2 and Gialpha3 in the Rat Fetus Ligand-Independent Signals From Angiotensin II Type 2 Receptor Induce Apoptosis Angiotensin II Type 2 Receptor: A Target for Protection Against Hypertension, Metabolic Dysfunction, and Organ Remodeling The Angiotensin Type 2 Receptor and the Kidney Ventricular-Specific Expression of Angiotensin II Type 2 Receptors Causes Dilated Cardiomyopathy and Heart Failure in Transgenic Mice Angiotensin Receptors and Neuropathic Pain AT2 Receptor Activities and Pathophysiological Implications Cloning and Expression of a cDNA Encoding an Endothelin Receptor Cloning and Expression of Human Endothelin-1 Receptor cDNA Anatomical Profiling of G Protein-Coupled Receptor Expression Endothelin@25 -New Agonists, Antagonists, Inhibitors and Emerging Research Frontiers: IUPHAR Review 12 The Endothelin System: A Critical Player in the Pathophysiology of Preeclampsia Double-Blind, Placebo-Controlled Study of Sitaxsentan to Improve Impaired Exercise Tolerance in Patients With Heart Failure and a Preserved Ejection Fraction Bosentan Therapy for Pulmonary Arterial Hypertension Contribution of Endothelin A Receptors in Endothelin 1-Dependent Natriuresis in Female Rats Gene Activation Initiates Chronic/End-Stage Renal Disease Following Experimental Ischemic/Reperfusion Injury Mutations in the Endothelin Receptor Type A Cause Mandibulofacial Dysostosis With Alopecia Loss-Of-Function of Endothelin Receptor Type A Results in Oro-Oto-Cardiac Syndrome Therapeutic Potential of Endothelin Receptor Antagonism in Kidney Disease Endothelins in Cardiovascular Biology and Therapeutics Endothelin and Endothelin Receptors in the Renal and Cardiovascular Systems Structural Basis for Ligand Recognition and Functional Selectivity at Angiotensin Receptor BioEdit: A User-Friendly Biological Sequence Alignment Editor and Analysis Program for Windows 95/98/Nt Primary Structure of Bovine Endothelin ETB Receptor and Identification of Signal Peptidase and Metal Proteinase Cleavage Sites Endothelin Receptor Dimers Evaluated by FRET, Ligand Binding, and Calcium Mobilization Endothelin Receptors, Renal Effects and Blood Pressure Signal Transduction Mechanisms Mediating the Vascular Actions of Endothelin Molecular Identification of Guanine-Nucleotide-Binding Regulatory Proteins Which Couple to Endothelin Receptors Endothelins and Their Receptors in Cancer: Identification of Therapeutic Targets Distinctive Activation Mechanism for Angiotensin Receptor Revealed by a Synthetic Nanobody Angiotensin and Biased Analogs Induce Structurally Distinct Active Conformations Within a GPCR Crystal Structure of the Human Angiotensin II Type 2 Receptor Bound to an Angiotensin II Analog Structural Basis for Selectivity and Diversity in Angiotensin II Receptors The Crystal Structure of Angiotensin II Type 2 Receptor With Endogenous Peptide Hormone Crystal Structure of Human Endothelin ETB Receptor in Complex With Peptide Inverse Agonist IRL2500 X-Ray Structures of Endothelin ETB Receptor Bound to Clinical Antagonist Bosentan and its Analog Activation Mechanism of Endothelin ETB Receptor by Endothelin-1 Crystal Structures of Human ETB Receptor Provide Mechanistic Insight Into Receptor Activation and Partial Activation Crystal Structure of Human Endothelin ETB Receptor in Complex With Sarafotoxin S6b Crystal Structure of the Ligand-Free G-Protein-Coupled Receptor Opsin Molecular Mechanism of 7TM Receptor Activation-A Global Toggle Switch Model Integrated Methods for the Construction of Three-Dimensional Models and Computational Probing of Structure-Function Relationships in G-Protein Coupled Receptors The G-Protein-Coupled Receptors in the Human Genome Form Five Main Families. Phylogenetic Analysis, Paralogon Groups, and Fingerprints The Hunchback and its Neighbours: Proline as an Environmental Modulator The Evolution of Transmembrane Helix Kinks and the Structural Diversity of G-Protein-Coupled Receptors Allosteric Sodium in Class A GPCR Signaling The Protein Data Bank Molecular Switches in GPCRs Three-Dimensional Representations of G-Protein-Coupled Receptor Structures and Mechanisms Ligand Binding and Micro-Switches in 7TM Receptor Structures Beta2 Adrenergic Receptor Activation. Modulation of the Proline Kink in Transmembrane 6 by a Rotamer Toggle Switch Stabilization of G-Protein-Coupled Receptors by Point Mutations A Mutagenesis and Screening Strategy to Generate Optimally Thermostabilized Membrane Proteins for Structural Studies Selectivity Determinants of GPCR-G-Protein Binding Recognition Sites of Endothelin Receptor Type A by the Directed-Degeneration Method Structural Determinants for Selective Recognition of Peptide Ligands for Endothelin Receptor Subtypes ETA and ETB Autoantibodies as Endogenous Modulators of GPCR Signaling A Human Antibody Against Human Endothelin Receptor Type A That Exhibits Antitumor Potency Non-HLA Agonistic Anti-Angiotensin II Type 1 Receptor Antibodies Induce a Distinctive Phenotype of Antibody-Mediated Rejection in Kidney Transplant Recipients Angiotensin II Type 1 Receptor Expression in Renal Transplant Biopsies and Anti-AT1R Antibodies in Serum Indicates the Risk of Transplant Loss Angiotensin II Type-1 Receptor Antibodies Are Associated With Active Allograft Dysfunction Following Pediatric Liver Transplantation Obliterative Vasculopathy in Systemic Sclerosis: Endothelial Precursor Cells as Novel Targets for Therapy Increase in Circulating Endothelial Precursors by Atorvastatin in Patients With Systemic Sclerosis Non-HLA Antibodies Against Endothelial Targets Bridging Allo-and Autoimmunity The Significance of Angiotensin II Type 1 Receptor (AT1 Receptor) in Renal Transplant Injury Angiotensin II Type 1 Receptor Antibodies in Kidney Transplantation: An Evidence-Based Comprehensive Review Angiotensin II Type I Receptor Antibodies in Thoracic Transplantation Impact and Production of Non-HLA-Specific Antibodies in Solid Organ Transplantation Role of Agonistic Autoantibodies Against Type-1 Angiotensin II Receptor in the Pathogenesis of Retinopathy in Preeclampsia Angiotensin Receptor Agonistic Autoantibody-Mediated Soluble Fms-Like Tyrosine Kinase-1 Induction Contributes to Impaired Adrenal Vasculature and Decreased Aldosterone Production in Preeclampsia Autoantibody From Women With Preeclampsia Induces Soluble Fms-Like Tyrosine Kinase-1 Production via Angiotensin Type 1 Receptor and Calcineurin/ Nuclear Factor of Activated T-Cells Signaling Toward a Better Understanding of the Basis of the Molecular Mimicry of Polysaccharide Antigens by Peptides: The Example of Shigella Flexneri 5a Structure of the Human Angiotensin II Type 1 (AT1) Receptor Bound to Angiotensin II From Multiple Chemoselective Photoprobe Contacts Reveals a Unique Peptide Binding Mode Determination of Peptide Contact Points in the Human Angiotensin II Type I Receptor (AT1) With Photosensitive Analogs of Angiotensin II Ligand-Specific Conformation of Extracellular Loop-2 in the Angiotensin II Type 1 Receptor Long Range Effect of Mutations on Specific Conformational Changes in the Extracellular Loop 2 of Angiotensin II Type 1 Receptor Amino-Terminal Substitutions in the CCR5 Coreceptor Impair Gp120 Binding and Human Immunodeficiency Virus Type 1 Entry Epitope Mapping of CCR5 Reveals Multiple Conformational States and Distinct But Overlapping Structures Involved in Chemokine and Coreceptor Function Structural Interlock Between Ligand-Binding Site and Stalk-Like Region of Beta1 Integrin Revealed by a Monoclonal Antibody Recognizing Conformation-Dependent Epitope History and Biological Significance of GPCR Heteromerization in the Neuroendocrine System Time-Resolved FRET Between GPCR Ligands Reveals Oligomers in Native Tissues Oligomerization of G-Protein-Coupled Transmitter Receptors Exploring a Role for Heteromerization in GPCR Signalling Specificity A Monomeric G-Protein-Coupled Receptor Isolated in a High-Density Lipoprotein Particle Efficiently Activates its G-Protein Lighting Up Multiprotein Complexes: Lessons From GPCR Oligomerization Dimerization of the Class A G-Protein-Coupled Neurotensin Receptor NTS1 Alters G-Protein Interaction Pattern of Intra-Family Hetero-Oligomerization Involving the G-Protein-Coupled Secretin Receptor Human Receptors for Sweet and Umami Taste Oligomerization of Family B GPCRs: Exploration in Inter-Family Oligomer Formation Structure of the Class D GPCR Ste2 Dimer Coupled to Two G-Proteins A Heterodimer-Selective Agonist Shows In Vivo Relevance of G-Protein-Coupled Receptor Dimers International Union of Basic and Clinical Pharmacology. LXVII. Recommendations for the Recognition and Nomenclature of G-Protein-Coupled Receptor Heteromultimers Multiple Interactions Between Transmembrane Helices Generate the Oligomeric Alpha1b-Adrenoceptor Dopamine D2 Receptors Form Higher Order Oligomers at Physiological Expression Levels Ligand Sensitivity in Dimeric Associations of the Serotonin 5HT2c Receptor A Peptide Derived From a Beta2-Adrenergic Receptor Transmembrane Domain Inhibits Both Receptor Dimerization and Activation Comparative Fluorescence Resonance Energy Transfer Analysis of Metabotropic Glutamate Receptors: Implications About the Dimeric Arrangement and Rearrangement Upon Ligand Bindings Prediction and Targeting of Interaction Interfaces in G-Protein Coupled Receptor Oligomers Novel Structural and Functional Insights Into M3 Muscarinic Receptor Dimer/Oligomer Formation The Orphan GPR50 Receptor Specifically Inhibits MT1 Melatonin Receptor Function Through Heterodimerization Dimerization in GPCR Mobility and Signaling Heterodimerization With Beta2-Adrenergic Receptors Promotes Surface Expression and Functional Activity of Alpha1d-Adrenergic Receptors Oligomerization of G-Protein-Coupled Receptors: Still Doubted? The G-Protein-Coupled Receptor Heterodimer Network (GPCR-HetNet) and its Hub Components Synergistic Activation of Thrombin and Angiotensin II Receptors Revealed by Bioluminescence Resonance Energy Transfer Angiotensin II Inhibits DDAH1-nNOS Signaling via AT1R and muOR Dimerization to Modulate Blood Pressure Control in the Central Nervous System Asymmetric Recruitment of Beta-Arrestin1/2 by the Angiotensin II Type I and Prostaglandin F2alpha Receptor Dimer Altered AT1 Receptor Regulation of ETB Receptors in Renal Proximal Tubule Cells of Spontaneously Hypertensive Rats Relaxin Requires the Angiotensin II Type 2 Receptor to Abrogate Renal Interstitial Fibrosis AT1R-AT2R-RXFP1 Functional Crosstalk in Myofibroblasts: Impact on the Therapeutic Targeting of Renal and Cardiac Fibrosis Dual Inhibition of Beta-Adrenergic and Angiotensin II Receptors by a Single Antagonist: A Functional Role for Receptor-Receptor Interaction In Vivo Heteromerization of Angiotensin Receptors Changes Trafficking and Arrestin Recruitment Profiles AT1R-Cb(1)R Heteromerization Reveals a New Mechanism for the Pathogenic Properties of Angiotensin II Transmembrane Peptides as Unique Tools to Demonstrate the In Vivo Action of a Cross-Class GPCR Heterocomplex Pathological AT1R-B2R Protein Aggregation and Preeclampsia Aldosterone Nongenomically Induces Angiotensin II Receptor Dimerization in Rat Kidney: Role of Mineralocorticoid Receptor and NADPH Oxidase Angiotensin II Type 2 Receptor-Bradykinin B2 Receptor Functional Heterodimerization Renal D3 Dopamine Receptor Stimulation Induces Natriuresis by Endothelin B Receptor Interactions Ligand-Dependent Differences in the Internalization of Endothelin A and Endothelin B Receptor Heterodimers C-Terminus of ETA/ ETB Receptors Regulate Endothelin-1 Signal Transmission Orthogonal Peptide-Templated Labeling Elucidates Lateral ETA R/ETB R Proximity and Reveals Altered Downstream Signaling Inhibition of Endothelin A Receptor by a Novel, Selective Receptor Antagonist Enhances Morphine-Induced Analgesia: Possible Functional Interaction of Dimerized Endothelin A and Mu-Opioid Receptors Oligomerization of Wild Type and Nonfunctional Mutant Angiotensin II Type I Receptors Inhibits Galphaq Protein Signaling But Not ERK Activation Identifying G-Protein-Coupled Receptor Dimers From Crystal Packings GPCR Interaction as a Possible Way for Allosteric Control Between Receptors Toward Understanding the Impact of Dimerization Interfaces in Angiotensin II Type 1 Receptor Antibodies Against Angiotensin II Receptor Type 1 and Endothelin A Receptor Are Associated With an Unfavorable COVID19 Disease Course Antibodies Against Angiotensin II Type 1 and Endothelin A Receptors: Relevance and Pathogenicity Bivalent Ligands as Specific Pharmacological Tools for G-Protein-Coupled Receptor Dimers Design of Bivalent Ligands Targeting Putative GPCR Dimers Molecular Alliance-From Orthosteric and Allosteric Ligands to Dualsteric/Bitopic Agonists at G-Protein Coupled Receptors G-Protein-Coupled Receptor Oligomerization and its Potential for Drug Discovery Receptor Heteromerization and Drug Discovery Structure Determination of GPCRs: Cryo-EM Compared With X-Ray Crystallography this article, or claim that may be made by its manufacturer, is not guaranteed or The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.Publisher's Note: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in