Constitutive activation of angiotensin II type 1 receptor alters the orientation of transmembrane Helix-2

A key step in transmembrane (TM) signal transduction by G-protein-coupled receptors (GPCRs) is the ligand-induced conformational change of the receptor, which triggers the activation of a guanine nucleotide-binding protein. GPCRs contain a seven-TM helical structure essential for signal transduction in response to a large variety of sensory and hormonal signals. Primary structure comparison of GPCRs has shown that the second TM helix contains a highly conserved Asp residue, which is critical for agonist activation in these receptors. How conformational changes in TM2 relate to signal transduction by a GPCR is not known, because activation-induced conformational changes in TM2 helix have not been measured. Here we use modification of reporter cysteines to measure water accessibility at specific residues in TM2 of the type 1 receptor for the octapeptide hormone angiotensin II. Activation-dependent changes in the accessibility of Cys76 on TM2 were measured in constitutively activated mutants. These changes were directly correlated with measurement of function, establishing the link between physical changes in TM2 and function. Accessibility changes were measured at several consecutive residues on TM2, which suggest that TM2 undergoes a transmembrane movement in response to activation. This is the first report of in situ measurement of TM2 movement in a GPCR.     

Constitutive activation of the angiotensin II type 1 receptor alters the spatial proximity of transmembrane 7 to the ligand-binding pocket

Activation of G protein-coupled receptors by agonists involves significant movement of transmembrane domains (TM) following binding of agonist. The underlying structural mechanism by which receptor activation takes place is largely unknown but can be inferred by detecting variability within the environment of the ligand-binding pocket, which constitutes a water-accessible crevice surrounded by the seven TM helices. Using the substituted cysteine accessibility method, we initially identified those residues within the seventh transmembrane domain (TM7) of wild type angiotensin II type 1 (AT1) receptor that contribute to forming the binding site pocket. We have substituted successively TM7 residues ranging from Ile276 to Tyr302 to cysteine. Treatment of A277C, V280C, T282C, A283C, I286C, A291C, and F301C mutant receptors with the charged sulfhydryl-specific alkylating agent MTSEA significantly inhibited ligand binding, which suggests that these residues orient themselves within the water-accessible binding pocket of the AT1 receptor. Interestingly, this pattern of acquired MTSEA sensitivity was greatly reduced for TM7 reporter cysteines engineered in a constitutively active mutant of the AT1 receptor. Our data suggest that upon activation, TM7 of the AT1 receptor goes through a pattern of helical movements that results in its distancing from the binding pocket per se. These studies support accumulating evidence whereby elements of TM7 of class A GPCRs promote activation of the receptor through structural rearrangements.     

Evidence that the TM1-TM2 loop contributes to the rho1 GABA receptor pore

Considerable evidence indicates the second transmembrane domain (TM2) of the gamma-aminobutyric acid (GABA) receptor lines the integral ion pore. To further delineate the structures that constitute the ion pore and selectivity filter of the rho1 GABA receptor, we used the substituted cysteine accessibility method with charged reagents to identify anion- and cation-accessible surfaces. Twenty-one consecutive residues were mutated to cysteine, one at a time, in the presumed intracellular end of the first transmembrane domain (TM1; Ala(271)-Met(276)), the entire linker connecting TM1 to TM2 (Leu(277)-Arg(287)), and the presumed intracellular end of TM2 (Ala(288)-Ala(291)). Positively (MTSEA(+)) and negatively (pCMBS(-)) charged sulfhydryl reagents, as well as Cd(2+), were added extracellularly to test accessibility of the engineered cysteines. Four of the mutants, all at the intracellular end of TM2 (R287C, V289C, P290C, A291C), were accessible to positively charged reagents, whereas seven mutants (A271C, T272C, L277C, W279C, V280C, P290C, A291C) were functionally modified by negatively charged pCMBS(-). These seven modified residues were at the intracellular end of TM2, in the TM1-TM2 linker, and at the intracellular end of TM1. In nearly all cases (excluding P290C), the rate and the degree of modification were state-dependent, with greater accessibility in the presence of agonist. Select cysteine mutants were combined with a point mutation (A291E) that converted the pore from chloride- to non-selective. In this case, positively charged reagents could modify residues in the TM1-TM2 linker (Leu(277) and Val(280)), supporting the notion that the modifying reagents were reaching their target through the pore. Taken together, our results suggest that, up to its intracellular end, the TM2 domain is not charge selective. In addition, we propose that the TM1-TM2 linker and the intracellular end of TM1 are along the pathway of the permeating ion. These findings may lend new insights into the structure of the GABA receptor pore.     

The functional microdomain in transmembrane helices 2 and 7 regulates expression, activation, and coupling pathways of the gonadotropin-releasing hormone receptor.

Structural microdomains of G protein-coupled receptors (GPCRs) consist of spatially related side chains that mediate discrete functions. The conserved helix 2/helix 7 microdomain was identified because the gonadotropin-releasing hormone (GnRH) receptor appears to have interchanged the Asp(2.50) and Asn(7.49) residues which are conserved in transmembrane helices 2 and 7 of rhodopsin-like GPCRs. We now demonstrate that different side chains of this microdomain contribute specifically to receptor expression, heterotrimeric G protein-, and small G protein-mediated signaling. An Asn residue is required in position 2.50(87) for expression of the GnRH receptor at the cell surface, most likely through an interaction with the conserved Asn(1.50(53)) residue, which we also find is required for receptor expression. Most GPCRs require an Asp side chain at either the helix 2 or helix 7 locus of the microdomain for coupling to heterotrimeric G proteins, but the GnRH receptor has transferred the requirement for an acidic residue from helix 2 to 7. However, the presence of Asp at the helix 7 locus precludes small G protein-dependent coupling to phospholipase D. These results implicate specific components of the helix 2/helix 7 microdomain in receptor expression and in determining the ability of the receptor to adopt distinct activated conformations that are optimal for interaction with heterotrimeric and small G proteins.     

Conformational change of the transmembrane helices II and IV of metabotropic glutamate receptor involved in G protein activation

G protein-coupled receptors are classified into several families on the basis of their amino acid sequences and the members of the same family exhibit sequence similarity but those of different families do not. In family 1 GPCRs such as rhodopsin and adrenergic receptor, extensive studies have revealed the stimulus-dependent conformational change of the receptor: the rearrangement of transmembrane helices III and VI is essential for G protein activation. In contrast, in family 3 GPCRs such as metabotropic glutamate receptor (mGluR), the inter-protomer relocation upon ligand binding has been observed but there is much less information about the structural changes of the transmsmbrane helices and the cytoplasmic domains. Here we identified constitutively active mutation sites at the cytoplasmic borders of helices II and IV of mGluR8 and successfully inhibited the G protein activation ability by engineering disulfide cross-linking between these cytoplasmic regions. The analysis of all possible single substitution mutants of these residues revealed that some steric interactions around these sites would be important to keep the receptor protein inactive. These results provided the model that the conformational changes at the cytoplasmic ends of helices II and IV of mGluR are involved in the efficient G protein coupling.     

Characterization of a polyclonal anti-peptide antibody to the angiotensin II type-1 (AT1) receptor.

A polyclonal antibody has been prepared against a synthetic peptide corresponding to amino acids 14-23 of the angiotensin II type-1 (AT1) receptor. The antibody is of high titer and mono-specific. Western blot analysis of membranes from rat liver, kidney, and adrenal gland showed that the antibody specifically recognizes a protein band of MW 70,000 whose amounts are highest in the liver, followed by kidney and adrenals. In addition, a relatively less prominent band of MW 95,000 was also detected. The relative distribution of this protein correlates well with the values obtained for [3H]-DuP753 binding and AT1 receptor mRNA.     

Participation of transmembrane proline 82 in angiotensin II AT1 receptor signal transduction

Most of the classical physiological effects of the octapeptide angiotensin II (AngII) are produced by activating the AT1 receptor which belongs to the G-protein coupled receptor family (GPCR). Peptidic GPCRs may be functionally divided in three regions: (i) extracellular domains involved in ligand binding; (ii) intracellular domains implicated in agonist-induced coupling to G protein and (iii) seven transmembrane domains (TM) involved in signal transduction. The TM regions of such receptors have peculiar characteristics such as the presence of proline residues. In this project we aimed to investigate the participation of two highly conserved proline residues (Pro82 and Pro162), located in TM II and TM IV, respectively, in AT1 receptor signal transduction. Both mutations did not cause major alterations in AngII affinity. Functional assays indicated that the P162A mutant did not influence the signal transduction. On the other hand, a potent deleterious effect of P82A mutation on signal transduction was observed. We believe that the Pro82 residue is crucial to signal transduction, although it is not possible to say yet if this is due to a direct participation or if due to a structural rearrangement of TM II. In this last hypothesis, the removal of proline residue might be correlated to a removal of a kink, which in turn can be involved in the correct positioning of residues involved in signal transduction.     

Molecular modeling of transmembrane helices 6 and 7 of the heptahelical lutropin receptor

In response to ligand binding and activating mutations, the lutropin receptor undergoes a conformational change to trigger a cellular response. D556 is the most common locus for naturally occurring activating mutations of the lutropin receptor, and a D556A mutant is shown to be constitutively active. A water-mediated proton transfer is postulated as part of the transmembrane signaling mechanism. Using energy minimization and ab initio calculations, a hydrogen bonding network involving a highly constrained water molecule(s) and D556 (helix 6) and N593/N597/Y601 (helix 7) is presented.     

容量负荷性肥厚心肌中血管紧张素Ⅱ-1型受体mRNA表达的动态变化

本实验采用腹腔动－静脉瘘制造大鼠容易负荷增加所致心肌肥厚模型,应用反转录－聚梧酶链式反应及同位素掺入技术,检测手术后不同时间点左,右心室组织中ＡｎｇⅡ－１型受体的α亚型及ｂ亚型ｍＲＮＡ的表达。结果表明,术后早期虽反映心肌肥厚的心／体重比指标已有显著性升高、而ＬＶ和ＲＶ组织的ＡＴｌａ ｍＲＮＡ及ＡＴ１ｂ ｍＲＮＡ表达尚未见显著性改变。     

Role of transmembrane helix IV in G-protein specificity of the angiotensin II type 1 receptor

G-protein activation by G-protein coupled receptors (GPCRs) is accomplished through proper interaction with the cytoplasmic loops rather than through sequence-specific interactions. However, the mechanism by which a specific G-protein is selected by a GPCR is not known. In the current model of GPCR activation, agonist binding modulates helix-helix interactions, which is necessary for fully determining G-protein specificity and stimulation of GDP/GTP exchange. In this study, we report that a single-residue deletion in transmembrane helix IV leads the angiotensin II type 1 (AT(1)) receptor chimera CR17 to retain GTP-sensitive high affinity for the agonist angiotensin II but results in complete inactivation of intracellular inositol phosphate production. The agonist dissociation profile of CR17 in the presence of guanosine 5'-3-O-(thio)triphosphate suggests that the activation-induced conformational changes of the chimeric receptor itself remain intact. Insertion of an alanine at position 149 (CR17triangle down149A) in this chimera rescued the inactive phenotype, restoring intracellular inositol phosphate production by the chimera. This finding suggests that in the wild-type AT(1) receptor the orientation of transmembrane helix IV-residues following Cys(149) is a key determinant for effectively distinguishing among various structurally similar G-proteins. The results emphasize that the contacts within the membrane-embedded portion of transmembrane helix IV in the AT(1) receptor is important for specific G-protein selection.     

Role of the His273 located in the sixth transmembrane domain of the angiotensin II receptor subtype AT2 in ligand-receptor interaction

Angiotensin II receptor subtypes AT1 and AT2 are proteins with seven transmembrane domain (TMD) topology and share 34% homology. It was shown that His256, located in the sixth TMD of the AT1 receptor, is needed for the agonist activation by the Phe8 side chain of angiotensin II, although replacing this residue with arginine or glutamine did not significantly alter the affinity binding of the receptor. We hypothesized that the His273 located in the sixth transmembrane domain of the AT2 receptor may play a similar role in the functions of the AT2 receptor, although this residue was not identified as a conserved residue in the initial homology comparisions. Therefore, we replaced His273 of the AT2 receptor with arginine or glutamine and analyzed the ligand-binding properties of the mutant receptors using Xenopus oocytes as an expression system. Our results suggested that the AT2 receptor mutants His273Arg and His273 Glu have lost their affinity to [125I-Sar1-Ile8]Ang II, a peptidic ligand that binds both the AT1 and AT2 receptors and to 125I-CGP42112A, a peptidic ligand that binds specifically to the AT2 receptor. Thus, His273 located in the sixth TMD of the AT2 receptor seems to play an important role in determining the binding properties of this receptor. Moreover, these results along with our previous observation that the Lys215 located in the 5th TMD of the AT2 receptor is essential for its high affinity binding to [125I-Sar1-Ile8]Ang II indicate that key amino acids located in the 5th and 6th TMDs of the AT2 receptor are needed for high affinity binding of the AT2 to its ligands.     

Differential gene expression and regulation of type-1 angiotensin II receptor subtypes in the rat.

A simplified and sensitive method for measuring expression levels of type-1 angiotensin II (AT1) receptor subtypes, AT1A and AT1B, was established. The two receptor cDNAs were co-amplified and measured by polymerase chain reaction using primers based on the corresponding receptor subtype genes. Both AT1A and AT1B mRNAs were widely expressed in the rat tissues including adrenal gland, kidney, heart, aorta, lung, liver, testis, pituitary gland, cerebrum and cerebellum. AT1A mRNA was predominantly expressed in the rat tissues examined except adrenal gland and pituitary gland where AT1B mRNA was predominantly expressed. Sodium depletion did not change mRNA levels of AT1A and AT1B in the all tissues. However, both AT1A and AT1B mRNA levels in the heart and aorta were down-regulated by treatment with AT1 specific antagonist, TCV 116. In contrast, AT1B mRNA in the adrenal gland was mainly reduced by the treatment. These results suggest that the expression level of AT1B mRNA in the adrenal gland depends on the activity of the renin-angiotensin-aldosterone system (RAAS) and both receptor subtypes mediate contraction and hypertrophy of the smooth and cardiac muscles via the RAAS.     

Aldosterone-induced brain MAPK signaling and sympathetic excitation are angiotensin II type-1 receptor dependent

Angiotensin II (ANG II)-induced mitogen-activated protein kinase (MAPK) signaling upregulates angiotensin II type-1 receptors (AT(1)R) in hypothalamic paraventricular nucleus (PVN) and contributes to AT(1)R-mediated sympathetic excitation in heart failure. Aldosterone has similar effects to increase AT(1)R expression in the PVN and sympathetic drive. The present study was undertaken to determine whether aldosterone also activates the sympathetic nervous system via MAPK signaling and, if so, whether its effect is independent of ANG II and AT(1)R. In anesthetized rats, a 4-h intravenous infusion of aldosterone induced increases (P < 0.05) in phosphorylated (p-) p44/42 MAPK in PVN, PVN neuronal excitation, renal sympathetic nerve activity (RSNA), mean blood pressure (MBP), and heart rate (HR). Intracerebroventricular or bilateral PVN microinjection of the p44/42 MAPK inhibitor PD-98059 reduced the aldosterone-induced RSNA, HR, and MBP responses. Intracerebroventricular pretreatment (5 days earlier) with pooled small interfering RNAs targeting p44/42 MAPK reduced total and p-p44/42 MAPK, aldosterone-induced c-Fos expression in the PVN, and the aldosterone-induced increases in RSNA, HR, and MBP. Intracerebroventricular infusion of either the mineralocorticoid receptor antagonist RU-28318 or the AT(1)R antagonist losartan blocked aldosterone-induced phosphorylation of p44/42 MAPK and prevented the increases in RSNA, HR, and MBP. These data suggest that aldosterone-induced sympathetic excitation depends upon that AT(1)R-induced MAPK signaling in the brain. The short time course of this interaction suggests a nongenomic mechanism, perhaps via an aldosterone-induced transactivation of the AT(1)R as described in peripheral tissues.     

Identifying interactions between transmembrane helices from the adenosine A2A receptor

The human adenosine A(2A) receptor (A(2A)R) is an integral membrane protein and a member of the G-protein-coupled receptor (GPCR) superfamily, characterized by seven transmembrane (TM) helices. Although helix-helix association in the lipid bilayer is known to be an essential step in the folding of GPCRs, the determinants of their structures, folding, and assembly in the cell membrane are poorly understood. Previous studies in our group showed that while peptides corresponding to all seven TM domains of A(2A)R form stable helical structures in detergent micelles and lipid vesicles, they display significant variability in their helical propensity. This finding suggested to us that some TM domains might need to interact with other domains to properly insert and fold in hydrophobic environments. In this study, we assessed the ability of TM peptides to interact in pairwise combinations. We analyzed peptide interactions in hydrophobic milieus using circular dichroism spectroscopy and F?rster resonance energy transfer. We find that specific interactions between TM helices occur, leading to additional helical content, especially in weakly helical TM domains, suggesting that some TM domains need a partner for proper folding in the membrane. The approach developed in this study will enable complete analysis of the TM domain interactions and the modeling of a folding pathway for A(2A)R.     

A model for constitutive lutropin receptor activation based on molecular simulation and engineered mutations in transmembrane helices 6 and 7

Many naturally occurring and engineered mutations lead to constitutive activation of the G protein-coupled lutropin receptor (LHR), some of which also result in reduced ligand responsiveness. To elucidate the nature of interhelical interactions in this heptahelical receptor and changes thereof accompanying activation, we have utilized site-directed mutagenesis on transmembrane helices 6 and 7 of rat LHR to prepare and characterize a number of single, double, and triple mutants. The potent constitutively activating mutants, D556(6.44)H and D556(6.44)Q, were combined with weaker activating mutants, N593(7.45)R and N597(7.49)Q, and the loss-of-responsiveness mutant, N593(7.45)A. The engineered mutants have also been simulated using a new receptor model based on the crystal structure of rhodopsin. The results suggest that constitutive LHR activation by mutations at Asp-556(6.44) is triggered by the breakage or weakening of the interaction found in the wild type receptor between Asp-556(6.44) and Asn-593(7.45). Whereas this perturbation is unique to the activating mutations at Asp-556(6.44), common features to all of the most active LHR mutants are the breakage of the charge-reinforced H-bonding interaction between Arg-442(3.50) and Asp-542(6.30) and the increase in solvent accessibility of the cytosolic extensions of helices 3 and 6, which probably participate in the receptor-G protein interface. Asn-593(7.45) and Asn-597(7.49) also seem to be necessary for the high constitutive activities of D556(6.44)H and D556(6.44)Q and for full ligand responsiveness. The new theoretical model provides a foundation for further experimental work on the molecular mechanism(s) of receptor activation.     

Identification of structural determinants for G protein-independent activation of mitogen-activated protein kinases in the seventh transmembrane domain of the angiotensin II type 1 receptor

Although the intrareceptor mechanisms whereby the angiotensin II (AngII) type 1 receptor activates phospholipase C (PLC) have been extensively investigated, analogous studies of signaling through mitogen-activated protein kinases (MAPK) have been lacking. We investigated MAPK activation and traditional G(q)/PLC signaling in transfected cells using AngII and the signaling selective agonist [Sar(1),Ile(4),Ile(8)] AngII (SII). SII stimulated MAPK without inositol trisphosphate (IP(3)) production and thereby stabilizes an activated receptor state linked to G protein-independent MAPK signaling. Using receptor mutagenesis, we focused on the seventh transmembrane domain and identified three key residues-Tyr(292), Phe(293), and Thr(287). At least three distinct activated states were revealed: 1) an AngII-stabilized state linked to G(q)/PLC signaling, 2) an AngII-stabilized state connected to G protein-independent MAPK activation, and 3) a SII-stabilized state associated with G protein-independent MAPK signaling. The mutant Y292F failed to exhibit AngII-induced IP(3) turnover yet remained capable of AngII-induced MAPK activation. SII failed to stimulate MAPK in Y292F-transfected cells. Thus, Tyr(292) is a key epitope for activated states 1 and 3 but not required for activated state 2. Although the F293L mutant retained normal AngII responses, it also showed an IP(3) response to SII, indicating that Phe(293) may be involved in constraining the receptor to its inactive state. Mutations of Thr(287) abolished all SII-induced signaling without affecting any AngII responses. Thr(287) therefore represents a key residue for a SII-stabilized activated state. Taken together, the data identified a novel structural requirement (Thr(287)) for the SII-stabilized activated state and redefined the mechanistic roles for Tyr(292) and Phe(293).     

Conformational switch of angiotensin II type 1 receptor underlying mechanical stress-induced activation

The angiotensin II type 1 (AT(1)) receptor is a G protein-coupled receptor that has a crucial role in the development of load-induced cardiac hypertrophy. Here, we show that cell stretch leads to activation of the AT(1) receptor, which undergoes an anticlockwise rotation and a shift of transmembrane (TM) 7 into the ligand-binding pocket. As an inverse agonist, candesartan suppressed the stretch-induced helical movement of TM7 through the bindings of the carboxyl group of candesartan to the specific residues of the receptor. A molecular model proposes that the tight binding of candesartan to the AT(1) receptor stabilizes the receptor in the inactive conformation, preventing its shift to the active conformation. Our results show that the AT(1) receptor undergoes a conformational switch that couples mechanical stress-induced activation and inverse agonist-induced inactivation.     

C5a receptor activation. Genetic identification of critical residues in four transmembrane helices.

Hormones and sensory stimuli activate serpentine receptors, transmembrane switches that relay signals to heterotrimeric guanine nucleotide-binding proteins (G proteins). To understand the switch mechanism, we subjected 93 amino acids in transmembrane helices III, V, VI, and VII of the human chemoattractant C5a receptor to random saturation mutagenesis. A yeast selection identified 121 functioning mutant receptors, containing a total of 523 amino acid substitutions. Conserved hydrophobic residues are located on helix surfaces that face other helices in a modeled seven-helix bundle (Baldwin, J. M., Schertler, G. F., and Unger, V. M. (1997) J. Mol. Biol. 272, 144-164), whereas surfaces predicted to contact the surrounding lipid tolerate many substitutions. Our analysis identified 25 amino acid positions resistant to nonconservative substitutions. These appear to comprise two distinct components of the receptor switch, a surface at or near the extracellular membrane interface and a core cluster in the cytoplasmic half of the bundle. Twenty-one of the 121 mutant receptors exhibit constitutive activity. Amino acids substitutions in these activated receptors predominate in helices III and VI; other activating mutations truncate the receptor near the extracellular end of helix VI. These results identify key elements of a general mechanism for the serpentine receptor switch.     

Central angiotensin II stimulates cutaneous water intake behavior via an angiotensin II type-1 receptor pathway in the Japanese tree frog Hyla japonica

Angiotensin II (Ang II) stimulates oral water intake by causing thirst in all terrestrial vertebrates except anurans. Anuran amphibians do not drink orally but absorb water osmotically through ventral skin. In this study, we examined the role of Ang II on the regulation of water-absorption behavior in the Japanese tree frog (Hyla japonica). In fully hydrated frogs, intracerebroventricular (ICV) and intralymphatic sac (ILS) injection of Ang II significantly extended the residence time of water in a dose-dependent manner. Ang II-dependent water uptake was inhibited by ICV pretreatment with an angiotensin II type-1 (AT₁) receptor antagonist but not a type-2 (AT₂) receptor antagonist. These results suggest that Ang II stimulates water-absorption behavior in the tree frog via an AT₁-like but not AT₂-like receptor. We then cloned and characterized cDNA of the tree frog AT₁ receptor from the brain. The tree frog AT₁ receptor cDNA encodes a 361 amino acid residue protein, which is 87% identical to the toad (Bufo marinus) AT₁ receptor and exhibits the functional characteristics of an Ang II receptor. AT₁ receptor mRNAs were found to be present in a number of tissues including brain (especially in the diencephalon), lung, large intestine, kidney and ventral pelvic skin. When tree frogs were exposed to dehydrating conditions, AT₁ receptor mRNA significantly increased in the diencephalon and the rhombencephalon. These data suggest that central Ang II may control water intake behavior via an AT₁ receptor on the diencephalon and rhombencephalon in anuran amphibians and may have implications for water consumption in vertebrates.