Angiotensin II cyclic analogs as tools to investigate AT1R biased signaling mechanisms.

G protein coupled receptors (GPCRs) produce pleiotropic effects by their capacity to engage numerous signaling pathways once activated. Functional selectivity (also called biased signaling), where specific compounds can bring GPCRs to adopt conformations that enable selective receptor coupling to distinct signaling pathways, continues to be significantly investigated. However, an important but often overlooked aspect of functional selectivity is the capability of ligands such as angiotensin II (AngII) to adopt specific conformations that may preferentially bind to selective GPCRs structures. Understanding both receptor and ligand conformation is of the utmost importance for the design of new drugs targeting GPCRs. In this study, we examined the properties of AngII cyclic analogs to impart biased agonism on the angiotensin type 1 receptor (AT1R). Positions 3 and 5 of AngII were substituted for cysteine and homocysteine residues ([Sar1Hcy3,5]AngII, [Sar1Cys3Hcy5]AngII and [Sar1Cys3,5]AngII) and the resulting analogs were evaluated for their capacity to activate the Gq/11, G12, Gi2, Gi3, Gz, ERK and ß-arrestin (ßarr) signaling pathways via AT1R. Interestingly, [Sar1Hcy3,5]AngII exhibited potency and full efficacy on all pathways tested with the exception of the Gq pathway. Molecular dynamic simulations showed that the energy barrier associated with the insertion of residue Phe8 of AngII within the hydrophobic core of AT1R, associated with Gq/11 activation, is increased with [Sar1Hcy3,5]AngII. These results suggest that constraining the movements of molecular determinants within a given ligand by introducing cyclic structures may lead to the generation of novel ligands providing more efficient biased agonism.

Identification of Distinct Conformations of the Angiotensin-II Type 1 Receptor Associated with the Gq/11 Protein Pathway and the ß-Arrestin Pathway Using Molecular Dynamics Simulations.

Biased signaling represents the ability of G protein-coupled receptors to engage distinct pathways with various efficacies depending on the ligand used or on mutations in the receptor. The angiotensin-II type 1 (AT1) receptor, a prototypical class A G protein-coupled receptor, can activate various effectors upon stimulation with the endogenous ligand angiotensin-II (AngII), including the Gq/11 protein and ß-arrestins. It is believed that the activation of those two pathways can be associated with distinct conformations of the AT1 receptor. To verify this hypothesis, microseconds of molecular dynamics simulations were computed to explore the conformational landscape sampled by the WT-AT1 receptor, the N111G-AT1 receptor (constitutively active and biased for the Gq/11 pathway), and the D74N-AT1 receptor (biased for the ß-arrestin1 and -2 pathways) in their apo-forms and in complex with AngII. The molecular dynamics simulations of the AngII-WT-AT1, N111G-AT1, and AngII-N111G-AT1 receptors revealed specific structural rearrangements compared with the initial and ground state of the receptor. Simulations of the D74N-AT1 receptor revealed that the mutation stabilizes the receptor in the initial ground state. The presence of AngII further stabilized the ground state of the D74N-AT1 receptor. The biased agonist [Sar(1),Ile(8)]AngII also showed a preference for the ground state of the WT-AT1 receptor compared with AngII. These results suggest that activation of the Gq/11 pathway is associated with a specific conformational transition stabilized by the agonist, whereas the activation of the ß-arrestin pathway is linked to the stabilization of the ground state of the receptor.

Characterization of Angiotensin II Molecular Determinants Involved in AT1 Receptor Functional Selectivity.

The octapeptide angiotensin II (AngII) exerts a variety of cardiovascular effects through the activation of the AngII type 1 receptor (AT1), a G protein-coupled receptor. The AT1 receptor engages and activates several signaling pathways, including heterotrimeric G proteins Gq and G12, as well as the extracellular signal-regulated kinases (ERK) 1/2 pathway. Additionally, following stimulation, ßarrestin is recruited to the AT1 receptor, leading to receptor desensitization. It is increasingly recognized that specific ligands selectively bind and favor the activation of some signaling pathways over others, a concept termed ligand bias or functional selectivity. A better understanding of the molecular basis of functional selectivity may lead to the development of better therapeutics with fewer adverse effects. In the present study, we developed assays allowing the measurement of six different signaling modalities of the AT1 receptor. Using a series of AngII peptide analogs that were modified in positions 1, 4, and 8, we sought to better characterize the molecular determinants of AngII that underlie functional selectivity of the AT1 receptor in human embryonic kidney 293 cells. The results reveal that position 1 of AngII does not confer functional selectivity, whereas position 4 confers a bias toward ERK signaling over Gq signaling, and position 8 confers a bias toward ßarrestin recruitment over ERK activation and Gq signaling. Interestingly, the analogs modified in position 8 were also partial agonists of the protein kinase C (PKC)-dependent ERK pathway via atypical PKC isoforms PKCζ and PKCι.

STIM1 positively regulates the Ca2+ release activity of the inositol 1,4,5-trisphosphate receptor in bovine aortic endothelial cells.

The endothelium is actively involved in many functions of the cardiovascular system, such as the modulation of arterial pressure and the maintenance of blood flow. These functions require a great versatility of the intracellular Ca2+ signaling that resides in the fact that different signals can be encoded by varying the frequency and the amplitude of the Ca2+ response. Cells use both extracellular and intracellular Ca2+ pools to modulate the intracellular Ca2+ concentration. In non-excitable cells, the inositol 1,4,5-trisphosphate receptor (IP3R), located on the endoplasmic reticulum (ER), is responsible for the release of Ca2+ from the intracellular store. The proteins STIM1 and STIM2 are also located on the ER and they are involved in the activation of a store-operated Ca2+ entry (SOCE). Due to their Ca2+ sensor property and their close proximity with IP3Rs on the ER, STIMs could modulate the activity of IP3R. In this study, we showed that STIM1 and STIM2 are expressed in bovine aortic endothelial cells and they both interact with IP3R. While STIM2 appears to play a minor role, STIM1 plays an important role in the regulation of agonist-induced Ca2+ mobilization in BAECs by a positive effect on both the SOCE and the IP3R-dependent Ca2+ release.

Mechanism of dopamine D2 receptor-induced Ca(2+) release in PC-12 cells.

Intracellular Ca(2+) levels are tightly regulated in the neuronal system. The loss of Ca(2+) homeostasis is associated with many neurological diseases and neuropsychiatric disorders such as Parkinson's, Alzheimer's, and schizophrenia. We investigated the mechanisms involved in intracellular Ca(2+) signaling in PC-12 cells. The stimulation of NGF-differentiated PC-12 cells with 3µM ATP caused an early Ca(2+) release followed by a delayed Ca(2+) release. The delayed Ca(2+) release was dependent on prior ATP priming and on dopamine secretion by PC-12 cells. Delayed Ca(2+) release was abolished in the presence of spiperone, suggesting that it is due to the activation of D2 dopamine receptors (D2R) by dopamine secreted by PC-12 cells. This was shown to be independent of PKA activation but dependent on PLC activity. An endocytosis step was required for inducing the delayed Ca(2+) release. Given the importance of calcyon in clathrin-mediated endocytosis, we verified the role of this protein in the delayed Ca(2+) release phenomenon. siRNA targeting of calcyon blocked the delayed Ca(2+) release, decreased ATP-evoked IP3R-mediated Ca(2+) release, and impaired subsequent Ca(2+) oscillations. Our results suggested that calcyon is involved in an unknown mechanism that causes a delayed IP3R-mediated Ca(2+) release in PC-12 cells. In schizophrenia, Ca(2+) dysregulation may depend on the upregulation of calcyon, which maintains elevated Ca(2+) levels as well as dopamine signaling.

STIM1 participates in the contractile rhythmicity of HL-1 cells by moderating T-type Ca(2+) channel activity.

STIM1 plays a crucial role in Ca(2+) homeostasis, particularly in replenishing the intracellular Ca(2+) store following its depletion. In cardiomyocytes, the Ca(2+) content of the sarcoplasmic reticulum must be tightly controlled to sustain contractile activity. The presence of STIM1 in cardiomyocytes suggests that it may play a role in regulating the contraction of cardiomyocytes. The aim of the present study was to determine how STIM1 participates in the regulation of cardiac contractility. Atomic force microscopy revealed that knocking down STIM1 disrupts the contractility of cardiomyocyte-derived HL-1 cells. Ca(2+) imaging also revealed that knocking down STIM1 causes irregular spontaneous Ca(2+) oscillations in HL-1 cells. Action potential recordings further showed that knocking down STIM1 induces early and delayed afterdepolarizations. Knocking down STIM1 increased the peak amplitude and current density of T-type voltage-dependent Ca(2+) channels (T-VDCC) and shifted the activation curve toward more negative membrane potentials in HL-1 cells. Biotinylation assays revealed that knocking down STIM1 increased T-VDCC surface expression and co-immunoprecipitation assays suggested that STIM1 directly regulates T-VDCC activity. Thus, STIM1 is a negative regulator of T-VDCC activity and maintains a constant cardiac rhythm by preventing a Ca(2+) overload that elicits arrhythmogenic events.

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.

Breakthroughs in G protein-coupled receptor structure determination based on crystallography have been mainly obtained from receptors occupied in their transmembrane domain core by low molecular weight ligands, and we have only recently begun to elucidate how the extracellular surface of G protein-coupled receptors (GPCRs) allows for the binding of larger peptide molecules. In the present study, we used a unique chemoselective photoaffinity labeling strategy, the methionine proximity assay, to directly identify at physiological conditions a total of 38 discrete ligand/receptor contact residues that form the extracellular peptide-binding site of an activated GPCR, the angiotensin II type 1 receptor. This experimental data set was used in homology modeling to guide the positioning of the angiotensin II (AngII) peptide within several GPCR crystal structure templates. We found that the CXC chemokine receptor type 4 accommodated the results better than the other templates evaluated; ligand/receptor contact residues were spatially grouped into defined interaction clusters with AngII. In the resulting receptor structure, a ß-hairpin fold in extracellular loop 2 in conjunction with two extracellular disulfide bridges appeared to open and shape the entrance of the ligand-binding site. The bound AngII adopted a somewhat vertical binding mode, allowing concomitant contacts across the extracellular surface and deep within the transmembrane domain core of the receptor. We propose that such a dualistic nature of GPCR interaction could be well suited for diffusible linear peptide ligands and a common feature of other peptidergic class A GPCRs.

Critical hydrogen bond formation for activation of the angiotensin II type 1 receptor.

G protein-coupled receptors contain selectively important residues that play central roles in the conformational changes that occur during receptor activation. Asparagine 111 (N111(3.35)) is such a residue within the angiotensin II type 1 (AT(1)) receptor. Substitution of N111(3.35) for glycine leads to a constitutively active receptor, whereas substitution for tryptophan leads to an inactivable receptor. Here, we analyzed the AT(1) receptor and two mutants (N111G and N111W) by molecular dynamics simulations, which revealed a novel molecular switch involving the strictly conserved residue D74(2.50). Indeed, D74(2.50) forms a stable hydrogen bond (H-bond) with the residue in position 111(3.35) in the wild-type and the inactivable receptor. However, in the constitutively active mutant N111G-AT(1) receptor, residue D74 is reoriented to form a new H-bond with another strictly conserved residue, N46(1.50). When expressed in HEK293 cells, the mutant N46G-AT(1) receptor was poorly activable, although it retained a high binding affinity. Interestingly, the mutant N46G/N111G-AT(1) receptor was also inactivable. Molecular dynamics simulations also revealed the presence of a cluster of hydrophobic residues from transmembrane domains 2, 3, and 7 that appears to stabilize the inactive form of the receptor. Whereas this hydrophobic cluster and the H-bond between D74(2.50) and W111(3.35) are more stable in the inactivable N111W-AT(1) receptor, the mutant N111W/F77A-AT(1) receptor, designed to weaken the hydrophobic core, showed significant agonist-induced signaling. These results support the potential for the formation of an H-bond between residues D74(2.50) and N46(1.50) in the activation of the AT(1) receptor.

Type 1 inositol-1,4,5-trisphosphate receptor is a late substrate of caspases during apoptosis.

Apoptosis is characterized by the proteolytic cleavage of hundreds of proteins. One of them, the type 1 inositol-1,4,5-trisphosphate receptor (IP(3) R-1), a multimeric receptor located on the endoplasmic reticulum (ER) membrane that is critical to calcium homeostasis, was reported to be cleaved during staurosporine (STS) induced-apoptosis in Jurkat cells. Because the reported cleavage site separates the IP(3) binding site from the channel moiety, its cleavage would shut down a critical signaling pathway that is common to several cellular processes. Here we show that IP(3) R-1 is not cleaved in 293 cells treated with STS, TNFα, Trail, or ultra-violet (UV) irradiation. Further, it is not cleaved in Hela or Jurkat cells induced to undergo apoptosis with Trail, TNFα, or UV. In accordance with previous reports, we demonstrate that it is cleaved in a Jurkat cell line treated with STS. However its cleavage occurs only after poly(ADP-ribose) polymerase (PARP), which cleavage is a hallmark of apoptosis, and p23, a poor caspase-7 substrate, are completely cleaved, suggesting that IP(3) R-1 is a relatively late substrate of caspases. Nevertheless, the receptor is fully accessible to proteolysis in cellulo by ectopically overexpressed caspase-7 or by the tobacco etch virus (TEV) protease. Finally, using recombinant caspase-3 and microsomal fractions enriched in IP(3) R-1, we show that the receptor is a poor caspase-3 substrate. Consequently, we conclude that IP(3) R-1 is not a key death substrate.

The activation state of the inositol 1,4,5-trisphosphate receptor regulates the velocity of intracellular Ca2+ waves in bovine aortic endothelial cells.

Ca(2+) is a highly versatile second messenger that plays a key role in the regulation of many cell processes. This versatility resides in the fact that different signals can be encoded spatio-temporally by varying the frequency and amplitude of the Ca(2+) response. A typical example of an organized Ca(2+) signal is a Ca(2+) wave initiated in a given area of a cell that propagates throughout the entire cell or within a specific subcellular region. In non-excitable cells, the inositol 1,4,5-trisphosphate receptor (IP(3) R) is responsible for the release of Ca(2+) from the endoplasmic reticulum. IP(3) R activity can be directly modulated in many ways, including by interacting molecules, proteins, and kinases such as PKA, PKC, and mTOR. In the present study, we used a videomicroscopic approach to measure the velocity of Ca(2+) waves in bovine aortic endothelial cells under various conditions that affect IP(3) R function. The velocity of the Ca(2+) waves increased with the intensity of the stimulus while extracellular Ca(2+) had no significant impact on wave velocity. Forskolin increased the velocity of IP(3) R-dependent Ca(2+) waves whereas PMA and rapamycin decreased the velocity. We used scatter plots and Pearson's correlation test to visualize and quantify the relationship between the Ca(2+) peak amplitude and the velocity of Ca(2+) waves. The velocity of IP(3) R-dependent Ca(2+) waves poorly correlated with the amplitude of the Ca(2+) response elicited by agonists in all the conditions evaluated, indicating that the velocity depended on the activation state of IP(3) R, which can be modulated in many ways.

Positive regulation of inositol 1,4,5-trisphosphate-induced Ca2+ release by mammalian target of rapamycin (mTOR) in RINm5F cells.

The inositol 1,4,5-trisphosphate receptor (IP(3)R), a ligand-gated Ca(2+) channel, is the main regulator of intracellular Ca(2+) mobilization in non-excitable cells. An emerging body of evidence suggests that specific regulatory control of the Ca(2+) signaling pathway is modulated by the activation of additional signaling pathways. In the present study, we investigated the influence of the PI3-kinase/mammalian target of rapamycin (mTOR) pathway on the activity of the IP(3)R/Ca(2+) signaling pathway in RINm5F cells. We used a co-immunoprecipitation approach to show that mTOR physically interacts with IP(3)R-3 in an mTOR activity-dependent manner. We also showed that IP(3)R is phosphorylated by mTOR in cellulo. All the conditions known to modulate mTOR activity (IGF-1, wortmannin, rapamycin, PP242, and nutrient starvation) were shown to modify carbachol-induced Ca(2+) signaling in RINm5F cells. Lastly, we used an assay that directly measures the activity of IP(3)R, to show that mTOR increases the apparent affinity of IP(3)R. Given that mTOR controls cell proliferation and cell homeostasis, and that Ca(2+) plays a key role in these two phenomena, it follows that mTOR facilitates IP(3)R-mediated Ca(2+) release when the nutritional status of cells requires it.

Mammalian target of rapamycin (mTOR) phosphorylates inositol 1,4,5-trisphosphate receptor type 2 and increases its Ca(2+) release activity.

There is substantial evidence that crosstalk between the proliferation and Ca(2+)-signaling pathways plays a critical role in the regulation of normal physiological functions as well as in the pathogenesis of a variety of abnormal processes. In non-excitable cells, intracellular Ca(2+) is mobilized through inositol 1,4,5-trisphosphate sensitive Ca(2+) channels (IP(3)R) expressed on the endoplasmic reticulum. Here we report that mTOR, a point of convergence for signals from mitogenic growth factors, nutrients and cellular energy levels, phosphorylates the IP(3)R-2, the predominant isoform of IP(3)R in AR4-2J cells. Pretreatment with the mTOR inhibitor rapamycin, decreased carbachol-induced Ca(2+) release in AR4-2J cells. Rapamycin also decreased IP(3)-induced Ca(2+) release in permeabilized AR4-2J cells. We also showed that IGF-1 potentiates carbachol-induced Ca(2+) release in AR4-2J cells, an effect that was prevented by rapamycin. Rapamycin also decreased carbachol-induced Ca(2+) release in HEK 293A cells in which IP(3)R-1 and IP(3)R-3 had been knocked down. These results suggest that mTOR potentiates the activity of IP(3)R-2 by a phosphorylation mechanism. This conclusion supports the concept of crosstalk between Ca(2+) signaling and proliferation pathways and thus provides another way by which intracellular Ca(2+) signals are finely encoded.

The transcription factors NFAT and CREB have different susceptibilities to the reduced Ca2+ responses caused by the knock down of inositol trisphosphate receptor in HEK 293A cells.

BACKGROUND/AIMS: The inositol 1,4,5-trisphosphate receptor (IP(3)R), a ligand-gated Ca(2+) channel, plays an important role in the control of intracellular Ca(2+). Three isoforms of IP(3)R have been identified and most cell types express different proportions of these isoforms. The purpose of this study was to investigate how IP(3)R signalling is involved in the activation of the Ca(2+)-sensitive transcription factors NFAT and CREB. METHODS: Each IP(3)R isoform expressed in HEK 293A cells was knocked down using selective siRNA. Free intracellular Ca(2+) was monitored spectrofluometrically. NFAT and CREB activities were measured with luciferase reporter constructs. RESULTS: IP(3)R-2-knocked down HEK 293A cells showed a deficient CCh-induced Ca(2+) response that could be rescued by co-stimulation with VIP, a cAMP increasing agonist. NFAT transcriptional activity, but not CREB transcriptional activity, was significantly reduced in IP(3)R-2-knocked down HEK 293A cells. Overexpression of IP(3)R-1 could fully compensate for IP(3)R-2 knock down to mobilize Ca(2+) and to activate NFAT. CONCLUSION: Our results show that the knock down of IP(3)R-2 significantly reduced the intracellular Ca(2+) response of HEK 293 cells. This reduced Ca(2+) response did not affect the activation of CREB but significantly decreased the activation of NFAT, suggesting that the Ca(2+) signals required for the activation of NFAT are stronger than those required for the activation of CREB.

Temperature dependent photolabeling of the human angiotensin II type 1 receptor reveals insights into its conformational landscape and its activation mechanism.

We present a photoaffinity labeling study of the human Angiotensin II (AngII) type 1 receptor (hAT(1)) and a constitutively active mutant (CAM) N111G hAT(1) at multiple temperatures using a p-benzoyl-l-phenylalanine (Bpa) containing AngII analogue (125)I-[Sar(1), Bpa(8)] AngII and the Methionine Proximity Approach (MPA). By introducing Met residues, which react selectively with Bpa, by mutagenesis in hAT(1) and its CAM, we were able to identify the position of residues that surround the Bpa moiety in the receptor-ligand complexes. Here we refined this characterization by controlling and varying (from -20 to 50 degrees C) the temperature at which the photolabeling was carried out. The hAT(1) Met mutant, as well as CAM double mutant, photolabeled receptors were digested with CNBr and the fragmentation patterns were quantified by radioactive and densitometric analysis. Many important and significant changes in the fragmentation patterns were observed as function of both the temperature of photolysis and the context of constitutive activation. The ligand-receptor complex was increasingly flexible as temperature was increased, i.e. that the Bpa moiety could more easily label increasingly distant residues. These fragmentation patterns were converted into distance constraints that were included into a simulated annealing protocol in order to explore the extent of these conformational changes. In the context of constitutive activation, the 6th transmembrane domain (TM6) was found to exhibit a relative outward movement while TM2 and 5 were found to move closer to the ligand binding site. TM3 showed a slight displacement.

A single-nucleotide polymorphism of alanine to threonine at position 163 of the human angiotensin II type 1 receptor impairs Losartan affinity.

BACKGROUND AND OBJECTIVE: AT1 is the principal receptor for angiotensin II (AngII), which regulates blood pressure and osmotic homeostasis. Earlier studies have shown that position 163 interacts with the antihypertensive nonpeptide antagonist, Losartan. A recently discovered polymorphism found in humans (rs12721226) coding for residue 163 led us to determine whether this polymorphism would affect Losartan antihypertensive therapies. The pharmacological properties of the A163T hAT1 variant are described. METHOD AND RESULTS: The A163T hAT1 mutation was evaluated by testing its affinity by dose displacement of AngII analogs in COS-7 cells expressing either wild-type hAT1 or the A163T hAT1. The expressions of the receptors were evaluated by saturation binding and the efficacies were assessed by measuring the 3H-inositol phosphate production. The results showed that the A163T hAT1 receptor is comparable with the affinity, expression, and efficacy of native hAT1 towards peptide ligands. The affinities were also tested with nonpeptide antagonists Losartan, L-158 809, valsartan, telmisartan, irbesartan, candesartan, and EXP3174. Losartan and EXP3174 displayed a 7-fold loss in affinity towards A163T hAT1. The ability of Losartan to inhibit AngII-induced inositol triphosphate production also confirmed a loss in efficacy. Molecular modeling showed a higher steric and hydrophilic hindrance of the A163T hAT1-Losartan complex. CONCLUSION: The polymorphism that codes for the A163T hAT1 variant results in a receptor with normal physiological properties toward the endogenous hormone. However, the significant reduction in affinity to Losartan and its active metabolite, EXP3174, could significantly impair the clinical effectiveness of an antihypertensive therapy using Losartan with patients bearing the A163T polymorphism.

The amino-terminus of angiotensin II contacts several ectodomains of the angiotensin II receptor AT1.

G protein-coupled receptors (GPCRs) are the largest family of cell surface receptors and major targets for drug development. Herein, we sought to identify the regions of the human angiotensin II (AngII) type 1 (hAT(1)) receptor binding cleft that interact with all positions of the AngII using photoaffinity labeling. We conducted a complete iterative walk-through of the AngII sequence with either p-benzoyl-L-phenylalanine (Bpa) or p-[3-(trifluoromethyl)-3H-diazirin-3-yl]-L-phenylalanine (Tdf) to yield two series of eight photoreactive analogues. Pharmacological properties assessment of these sixteen analogues showed that the CAM receptor has a structure-activity relationship (SAR) more amenable to the amino acid substitutions at positions 1, 2, 3, and 5 of AngII than the WT receptor. Photoaffinity labeling of the CAM receptor with the selected analogues, which exhibit different but complementary photochemical properties, suggested that the AngII amino-terminus resides in a hydrophilic environment and interacts simultaneously with different regions of the hAT(1) receptor, including several ectodomains.

Analysis of transmembrane domains 1 and 4 of the human angiotensin II AT1 receptor by cysteine-scanning mutagenesis.

The octapeptide hormone angiotensin II (AngII) exerts a wide variety of cardiovascular effects through the activation of the AT(1) receptor, which belongs to the G protein-coupled receptor superfamily. Like other G protein-coupled receptors, the AT(1) receptor possesses seven transmembrane domains that provide structural support for the formation of the ligand-binding pocket. Here, we investigated the role of the first and fourth transmembrane domains (TMDs) in the formation of the binding pocket of the human AT(1) receptor using the substituted-cysteine accessibility method. Each residue within the Phe-28((1.32))-Ile-53((1.57)) fragment of TMD1 and Leu-143((4.40))-Phe-170((4.67)) fragment of TMD4 was mutated, one at a time, to a cysteine. The resulting mutant receptors were expressed in COS-7 cells, which were subsequently treated with the charged sulfhydryl-specific alkylating agent methanethiosulfonate ethylammonium (MTSEA). This treatment led to a significant reduction in the binding affinity of TMD1 mutants M30C((1.34))-AT(1) and T33C((1.37))-AT(1) and TMD4 mutant V169C((4.66))-AT(1). Although this reduction in binding of the TMD1 mutants was maintained when examined in a constitutively active receptor (N111G-AT(1)) background, we found that V169C((4.66))-AT(1) remained unaffected when treated with MTSEA compared with untreated in this context. Moreover, the complete loss of binding observed for R167C((4.64))-AT(1) was restored upon treatment with MTSEA. Our results suggest that the extracellular portion of TMD1, particularly residues Met-30((1.34)) and Thr-33((1.37)), as well as residues Arg-167((4.64)) and Val-169((4.66)) at the junction of TMD4 and the second extracellular loop, are important binding determinants within the AT(1) receptor binding pocket but that these TMDs undergo very little movement, if at all, during the activation process.

The fifth transmembrane domain of angiotensin II Type 1 receptor participates in the formation of the ligand-binding pocket and undergoes a counterclockwise rotation upon receptor activation.

The octapeptide hormone angiotensin II exerts a wide variety of cardiovascular effects through the activation of the angiotensin II Type 1 (AT(1)) receptor, which belongs to the G protein-coupled receptor superfamily. Like other G protein- coupled receptors, the AT(1) receptor possesses seven transmembrane domains that provide structural support for the formation of the ligand-binding pocket. The role of the fifth transmembrane domain (TMD5) was investigated using the substituted cysteine accessibility method. All of the residues within Thr-190 to Leu-217 region were mutated one at a time to cysteine, and after expression in COS-7 cells, the mutant receptors were treated with the sulfhydryl-specific alkylating agent methanethiosulfonate-ethylammonium (MTSEA). MTSEA reacts selectively with water-accessible, free sulfhydryl groups of endogenous or introduced point mutation cysteines. If a cysteine is found in the binding pocket, the covalent modification will affect the binding kinetics of the ligand. MTSEA substantially decreased the binding affinity of L197C-AT(1), N200C-AT(1), I201C-AT(1), G203C-AT(1), and F204C-AT(1) mutant receptors, which suggests that these residues orient themselves within the water-accessible binding pocket of the AT(1) receptor. Interestingly, this pattern of acquired MTSEA sensitivity was altered for TMD5 reporter cysteines engineered in a constitutively active N111G-AT(1) receptor background. Indeed, mutant I201C-N111G-AT(1) became more sensitive to MTSEA, whereas mutant G203C-N111G-AT(1) lost some sensitivity. Our results suggest that constitutive activation of AT(1) receptor causes an apparent counterclockwise rotation of TMD5 as viewed from the extracellular side.

Activation induces structural changes in the liganded angiotensin II type 1 receptor.

The octapeptide hormone angiotensin II (AngII) binds to and activates the human angiotensin II type 1 receptor (hAT(1)) of the G protein-coupled receptor class A family. Several activation mechanisms have been proposed for this family, but they have not yet been experimentally validated. We previously used the methionine proximity assay to show that 11 residues in transmembrane domain (TMD) III, VI, and VII of the hAT(1) receptor reside in close proximity to the C-terminal residue of AngII. With the exception of a single change in TMD VI, the same contacts are present on N111G-hAT(1), a constitutively active mutant; this N111G-hAT(1) is a model for the active form of the receptor. In this study, two series of 53 individual methionine mutations were constructed in TMD I, II, IV, and V on both receptor forms. The mutants were photolabeled with a neutral antagonist, (125)I-[Sar(1),p-benzoyl-L-Phe(8)]AngII, and the resulting complexes were digested with cyanogen bromide. Although no new contacts were found for the hAT(1) mutants, two were found in the constitutively active mutants, Phe-77 in TMD II and Asn-200 in TMD V. To our knowledge, this is the first time that a direct ligand contact with TMD II and TMD V has been reported. These contact point differences were used to identify the structural changes between the WT-hAT(1) and N111G-hAT(1) complexes through homology-based modeling and restrained molecular dynamics. The model generated revealed an important structural rearrangement of several TMDs from the basal to the activated form in the WT-hAT(1) receptor.

Identification of transmembrane domain 6 & 7 residues that contribute to the binding pocket of the urotensin II receptor.

Urotensin II (U-II), a cyclic undecapeptide, is the natural ligand of the urotensin II (UT) receptor, a G protein-coupled receptor. In the present study, we used the substituted-cysteine accessibility method to identify specific residues in transmembrane domains (TMDs) six and seven of the rat urotensin II receptor (rUT) that contribute to the formation of the binding pocket of the receptor. Each residue in the R256(6.32)-Q283(6.59) fragment of TMD6 and the A295(7.31)-T321(7.57) fragment of TMD7 was mutated, individually, to a cysteine. The resulting mutants were expressed in COS-7 cells, which were subsequently treated with the positively charged methanethiosulfonate-ethylammonium (MTSEA) or the negatively charged methanethiosulfonate-ethylsulfonate (MTSES) sulfhydryl-specific alkylating agents. MTSEA treatment resulted in a significant reduction in the binding of TMD6 mutants F268C(6.44) and W278C(6.54) and TMD7 mutants L298C(7.34), T302C(7.38), and T303C(7.39) to (125)I-U-II. MTSES treatment resulted in a significant reduction in the binding of two additional mutants, namely L282C(6.58) in TMD6 and Y300C(7.36) in TMD7. These results suggest that specific residues orient themselves within the water-accessible binding pocket of the rUT receptor. This approach, which allowed us to identify key determinants in TMD6 and TMD7 that contribute to the UT receptor binding pocket, enabled us to further refine our homology-based model of how U-II interacts with its cognate receptor.