Identification of amino acid residues of rat angiotensin II receptor for ligand binding by site directed mutagenesis

Comparative analysis of amphibian and mammalian angiotensin receptors

Amphibian angiotensin receptors (xAT receptors) share many similarities with mammalian type 1 angiotensin receptors (AT(1) receptors). Both xAT and AT(1) receptors belong to the super family of seven transmembrane spanning G protein-coupled receptors and share approximately 60% amino acid homology. Highly stable secondary structure in the 5' leader sequences and the presence of the mRNA destabilizing sequence (AUUUA) in the 3' untranslated region (3'UTR) of the xAT and AT(1) receptor mRNAs suggest similar mechanisms exist for regulating gene expression. Amphibian and mammalian AT receptors bind angiotensin with equivalent affinities but show marked differences in their affinities towards mammalian AT(1) receptor subtype selective non-peptide ligands. Both xAT and AT(1) receptors couple to G proteins and to the phospholipase C (PLC) signal transduction pathway. Mammalian AT(1) receptors play a key role in maintaining blood pressure and fluid homeostasis and there is considerable evidence that xAT receptors play a similarly important role in amphibians. This review focuses on the comparison of amphibian xAT receptors with mammalian AT(1) receptors in terms of their structure, pharmacology, signaling, and function.

Angiotensin II mediated signal transduction. Important role of tyrosine kinases

It has been 100 years since the discovery of renin by Bergman and Tigerstedt. Since then, numerous studies have advanced our understanding of the renin-angiotensin system. A remarkable aspect was the discovery that angiotensin II (AngII) is the central product of the renin-angiotensin system and that this octapeptide induces multiple physiological responses in different cell types. In addition to its well known vasoconstrictive effects, growing evidence supports the notion that AngII may play a central role not only in hypertension, but also in cardiovascular and renal diseases. Binding of AngII to the seven-transmembrane angiotensin II type 1 receptor is responsible for nearly all of the physiological actions of AngII. Recent studies underscore the new concept that activation of intracellular second messengers by AngII requires tyrosine phosphorylation. An increasing number of tyrosine kinases have been shown to be activated by AngII, including the Src kinase family, the focal adhesion kinase family, the Janus kinases and receptor tyrosine kinases. These actions of AngII contribute to the pathophysiology of cardiac hypertrophy and remodeling, vascular thickening, heart failure and atherosclerosis. In this review, we discuss the important role of tyrosine kinases in AngII-mediated signal transduction. Understanding the importance of tyrosine phosphorylation in AngII-stimulated signaling events may contribute to new therapies for cardiovascular and renal diseases.

mu Opioid receptor: role for the amino terminus as a determinant of ligand binding affinity

The importance of the amino-terminal domain of the mu opioid receptor (MOR) as a component of the high affinity ligand-binding pocket was evaluated. A deletion mutant lacking 64 amino acids from the amino-terminus of MOR (DeltaN64) was constructed and expressed in HEK 293 cells. The affinities of bremazocine and cyclazocine were similar for the truncated and full-length MORs. Affinities of the mu receptor antagonist, naloxone, and the mu receptor agonist, morphine, were decreased 3.5-fold and 6-fold, respectively, for the truncated receptor relative to the wild-type MOR. Similarly, the affinities of the opioid peptide agonists, DAMGO (Tyr-D-Ala-Gly-MePhe-Gly-ol), beta-endorphin, and DADL (Tyr-D-Ala-Gly-Phe-D-Leu), for the DeltaN64 receptor were decreased from 3- to 8-fold as a result of the deletion. In contrast, the affinities of the alkaloid agonists, methadone and fentanyl, and the peptide agonists, endomorphin 1 and endomorphin 2, for the truncated receptor relative to MOR were reduced dramatically by 20- to 60-fold. MOR is glycosylated when expressed in HEK 293 cells; however, analysis of N-glycosidase F-treated membranes indicated that N-glycan chains within the amino-terminal domain of MOR do not contribute significantly to ligand affinities. These results indicate that amino acid residues within the amino-terminal domain of MOR play a crucial role in the composition of the binding pocket for a select group of agonists.

Modelling G-protein-coupled receptors for drug design

The G-protein coupled receptors form a large and diverse multi-gene superfamily with many important physiological functions. As such, they have become important targets in pharmaceutical research. Molecular modelling and site-directed mutagenesis have played an important role in our increasing understanding of the structural basis of drug action at these receptors. Aspects of this understanding, how these techniques can be used within a drug-design programme, and remaining challenges for the future are reviewed.

Role of Arg182 in the second extracellular loop of angiotensin II receptor AT2 in ligand binding

The phenolic side chain of Tyr(4) present in Ang II is proposed to interact with the side chain of Arg 167 of the AT1 receptor. To determine the contribution of the analogous Arg182 in the ligand-binding properties of the AT2, we replaced the Arg182 with Glu and Ala, and analyzed the ligand-binding properties. Our results suggest that replacing Arg182 with either Glu or Ala abolished the ability of the AT2 receptor to bind the nonspecific peptidic ligands, (125)I-Ang II and [(125)I-Sar(1)-Ile(8)]Ang II, as well as the AT2 receptor-specific peptidic ligand (125)I-CGP42112A. We have shown previously that replacing the positively charged side chain of Lys215 with the negatively charged side chain of Glu in the fifth TMD did not alter the high affinity binding of (125)I-CGP42112A to the AT2 receptor. However, ligand-binding properties of the Arg182Glu mutant suggest that positively charged side chain of Arg182 located in the junction of second ECL and the fourth TMD is critical for high affinity binding of all three peptidic ligands to the AT2 receptor.

Ligand binding sites on guinea pig C3aR: point and deletion mutations in the large extracellular loop and vicinity

Human C3a receptor (huC3aR) belongs to the G-protein coupled receptor family chacterized by having seven transmembrane domains. The huC3aR is a unique member of this family having a large extracellular (EC) loop of 175 amino acids between the 4th and 5th transmembrane domains. Based on a comparison of C3aR sequences from several species, a number of charged and conserved amino acids (Asp182, Asp309, Asp310, and Arg331) in and near the large EC loop of guinea pig C3aR were replaced using site-directed mutagenesis. Competitive binding assays showed that changing Arg331 in guinea pig C3aR to Ala (or Gln), but not changing Asp182, Asp309, or Asp310 to Ala, resulted in complete loss of ligand binding activity. These results and major EC loop deletions demonstrated that an essential C3a binding site is present in the transmembrane portion of C3aR, but not in the large EC loop. Replacement of Arg331 by a noncharged residue was sufficient to eliminate ligand-receptor interactions.

N-linked glycosylation is required for optimal AT1a angiotensin receptor expression in COS-7 cells

The nature and role of glycosylation in AT1 angiotensin receptor (AT1-R) function were investigated by expressing glycosylation-deficient influenza hemagglutinin (HA) epitope-tagged rat AT1a-Rs (HA-AT1a-Rs) in COS-7 cells. All three asparagine residues (Asn4, Asn176, Asn188) contained within consensus sites for N-linked glycosylation could be glycosylated in Cos-7 cells and appeared to be glycosylated on the endogenous AT1-R in bovine adrenal glomerulosa cells. Heterogeneity of glycosylation at each site accounted for the broad migration pattern of the AT1-R in SDS-PAGE. Mutation at each glycosylation site, either alone or in combination, had little effect on ligand binding parameters (although the N4K mutant had higher affinity) or signaling activity. However, an increasing number of mutated glycosylation sites was associated with decreasing cell surface receptor expression, which was minimal for the unglycosylated N4K/N176Q/N188Q receptor. Decreased surface expression of mutant HA-AT1a-Rs was correlated with decreased total cell receptor content as revealed by immunoblotting with an anti-HA antibody. These findings suggest that glycosylation enhances receptor stability, possibly by protecting nascent receptors from proteolytic degradation.

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.

Role of the extracellular loops of G protein-coupled receptors in ligand recognition: a molecular modeling study of the human P2Y1 receptor

The P2Y1 receptor is a G protein-coupled receptor (GPCR) and is stimulated by extracellular ADP and ATP. Site-directed mutagenesis of the three extracellular loops (ELs) of the human P2Y1 receptor indicates the existence of two essential disulfide bridges (Cys124 in EL1 and Cys202 in EL2; Cys42 in the N-terminal segment and Cys296 in EL3) and several specific ionic and H-bonding interactions (involving Glu209 and Arg287). Through molecular modeling and molecular dynamics simulations, an energetically sound conformational hypothesis for the receptor has been calculated that includes transmembrane (TM) domains (using the electron density map of rhodopsin as a template), extracellular loops, and a truncated N-terminal region. ATP may be docked in the receptor, both within the previously defined TM cleft and within two other regions of the receptor, termed meta-binding sites, defined by the extracellular loops. The first meta-binding site is located outside of the TM bundle, between EL2 and EL3, and the second higher energy site is positioned immediately underneath EL2. Binding at both the principal TM binding site and the lower energy meta-binding sites potentially affects the observed ligand potency. In meta-binding site I, the side chain of Glu209 (EL2) is within hydrogen-bonding distance (2.8 A) of the ribose O3', and Arg287 (EL3) coordinates both alpha- and beta-phosphates of the triphosphate chain, consistent with the insensitivity in potency of the 5'-monophosphate agonist, HT-AMP, to mutation of Arg287 to Lys. Moreover, the selective reduction in potency of 3'NH2-ATP in activating the E209R mutant receptor is consistent with the hypothesis of direct contact between EL2 and nucleotide ligands. Our findings support ATP binding to at least two distinct domains of the P2Y1 receptor, both outside and within the TM core. The two disulfide bridges present in the human P2Y1 receptor play a major role in the structure and stability of the receptor, to constrain the loops within the receptor, specifically stretching the EL2 over the opening of the TM cleft and thus defining the path of access to the binding site.

Role of aromaticity of agonist switches of angiotensin II in the activation of the AT1 receptor

We have shown previously that the octapeptide angiotensin II (Ang II) activates the AT1 receptor through an induced-fit mechanism (Noda, K., Feng, Y. H., Liu, X. P., Saad, Y., Husain, A., and Karnik, S. S. (1996) Biochemistry 35, 16435-16442). In this activation process, interactions between Tyr4 and Phe8 of Ang II with Asn111 and His256 of the AT1 receptor, respectively, are essential for agonism. Here we show that aromaticity, primarily, and size, secondarily, of the Tyr4 side chain are important in activating the receptor. Activation analysis of AT1 receptor position 111 mutants by various Ang II position 4 analogues suggests that an amino-aromatic bonding interaction operates between the residue Asn111 of the AT1 receptor and Tyr4 of Ang II. Degree and potency of AT1 receptor activation by Ang II can be recreated by a reciprocal exchange of aromatic and amide groups between positions 4 and 111 of Ang II and the AT1 receptor, respectively. In several other bonding combinations, set up between Ang II position 4 analogues and receptor mutants, the gain of affinity is not accompanied by gain of function. Activation analysis of position 256 receptor mutants by Ang II position 8 analogues suggests that aromaticity of Phe8 and His256 side chains is crucial for receptor activation; however, a stacked rather than an amino-aromatic interaction appears to operate at this switch locus. Interaction between these residues, unlike the Tyr4:Asn111 interaction, plays an insignificant role in ligand docking.

Angiotensin II type 1 and type 2 receptors bind angiotensin II through different types of epitope recognition

OBJECTIVE

This study was designed to demonstrate that the principle of molecular recognition underlying high-affinity binding of angiotensin II to the type 2 (AT2) receptor is distinct from that of the type 1 (AT1) receptor. In general, the same functional pharmacophores in hormones are used to bind and activate different subtypes of cell surface receptors. However, the binding of angiotensin II to the AT2 receptor is distinct from that of the AT1 receptor.

DESIGN AND METHODS

To systematically evaluate the effect of modification of angiotensin II side chains on binding to both the receptors, several analogs of angiotensin II were synthesized. Rat AT1 or AT2 receptors expressed in COS1 cell membranes were used to determine the affinity of analogs using radioligand competition binding experiments under equilibrium conditions.

RESULTS

Modifications of all angiotensin II side chains affected binding to the AT2 receptor to nearly similar extents. In contrast, binding to the AT1 receptor was significantly affected by modifications at side chain positions 2, 4, 6 and 7. In accordance with previous observations that Tyr4- or Phe8-modified angiotensin II analogs antagonized vasoconstriction mediated exclusively by the AT1 receptor, binding to the AT1 receptor was significantly dependent on Tyr4 or Phe8 of angiotensin II whereas binding to the AT2 receptor was not. Rather surprisingly, the affinity profile of several angiotensin II analogs towards the AT2 receptor was similar to the measured affinity of the constitutively active N111G mutant AT1 receptor.

CONCLUSIONS

These results suggest that the AT2-receptor pharmacophore is very distinct from that of the AT1 receptor. The AT1 receptor is in a constrained conformation and is activated only when bound to angiotensin II. In contrast, the AT2 receptor is 'relaxed' in that no single interaction is critical for binding, like the N111G mutant AT1 receptor, which is constitutively active.

Mechanism of constitutive activation of the AT1 receptor: influence of the size of the agonist switch binding residue Asn(111)

The AT1 receptor is a G-protein-coupled receptor (GPCR); its activation from the basal state (R) requires an interaction between Asn111 in transmembrane helix III (TM-III) of the receptor and the Tyr4 residue of angiotensin II (Ang II). Asn111 to Gly111 mutation (N111G) results in constitutive activation of the AT1 receptor (Noda et al. (1996) Biochemistry, 35, 16435-16442). We show here that replacement of the AT1 receptors TM-III with a topologically identical 16-residue segment (Cys101-Val116) from the AT2 receptor induces constitutive activity, although Asn111 is preserved in the resulting chimera, CR18. Effects of CR18 and N111G mutations are neither additive nor synergistic. The conformation(s) induced in either mutant mimics the partially activated state (R'), and transition to the fully activated R conformation in both no longer requires the Tyr4 of Ang II. Both the R state of the receptor and the Tyr4 Ang II dependence of receptor activation can be reinstated by introduction of a larger sized Phe side chain at the 111 position in CR18, suggesting that the CR18 mutation generated an effect similar to the reduction of side chain size in the N111G mutation. Consistently in the native AT1 receptor, R' conformation is generated by replacement with residues smaller but not larger than the Asn111. However, size substitution of several other TM-III residues in both receptors did not affect transitions between R, R', and R states. Thus, the property responsible for Asn111 function as a conformational switch is neither polarity nor hydrogen bonding potential but the side chain size. We conclude that the fundamental mechanism responsible for constitutive activation of the AT1 receptor is to increase the entropy of the key agonist-switch binding residue, Asn111. As a result, the normally agonist-dependent R --> R' transition occurs spontaneously. This mechanism may be applicable to many other GPCRs.

Molecular cloning and pharmacological characterization of an atypical gerbil angiotensin II type-1 receptor and its mRNA expression in brain and peripheral tissues

In the gerbil brain, most of the [125I]Sarcosine1-Angiotensin II binding sites are atypical, not sensitive to displacement with selective Angiotensin II AT1 and AT2 receptor ligands. A similar atypical binding profile exists in the gerbil kidney, where binding is highly expressed. We isolated a 2197 base pair clone from a gerbil kidney cDNA library which encodes a 359 amino acid protein with higher than 90% homology to other mammalian angiotensin II AT1 receptors. When expressed in COS-7 cells, stimulation by Angiotensin II of both the cloned gerbil receptor or the human AT1 receptor enhanced IP3 production to a similar degree. In COS-7 cells, the gerbil receptor also had a ligand affinity profile similar to that of the human AT1 receptor, but showed greatly reduced affinity for losartan (IC50=3480+/-174 nM). In the gerbil brain, in situ hybridization revealed receptor mRNA in circumventricular organs, selective hypothalamic, midbrain and brain stem areas, and in the hippocampus, where high mRNA expression was detected in the stratum pyramidale of the CA1 and CA2 subfields, and in the stratum granulosum of the dentate gyrus. The expression pattern of receptor mRNA corresponded well with that of atypical [125I]Sar1-Ang II binding. In situ hybridization and Southern blot experiments using riboprobes against the open reading frame and the 3'-untranslated region of the cloned gerbil Ang II receptor cDNA suggest that gerbils have, like other rodents, two AT1 receptor subtypes. The receptor mRNA distribution of the cloned gerbil Ang II receptor corresponds to the distribution of AT1A receptors described in other rodent species.

Role of the amino terminus in ligand binding for the angiotensin II type 2 receptor

Key amino terminal residues in type 1 (AT1) angiotensin II (AngII) receptors are not conserved within type 2 (AT2) receptors. We therefore characterized amino terminal mutants that are transiently expressed in COS-3 membranes. AT2 amino terminal deletion drastically reduced affinity for AngII, suggesting its importance for this subtype. AT1-AT2 amino terminal exchanges retained wild type AngII affinities (Kd ranging from 3-5 nM), indicating compensation despite substantial sequence dissimilarities. Finally, binding of AT2 selective ligands (CGP42112A and PD123319) was not dependent on the amino terminus.

Role of Lys215 located in the fifth transmembrane domain of the AT2 receptor in ligand-receptor interaction

Studies on ligand-receptor interaction of Angiotensin II (Ang II) receptor type 1 have shown that for peptidic ligands to bind this receptor they must interact via their C-terminal carboxylate group to the positively charged side chain of the Lysine residue 199 located in the fifth transmembrane domain of this receptor. In the Ang II receptor type AT2, this Lysine residue is conserved at position 215 in the fifth transmembrane domain. To determine the specific mechanism of ligand binding to the Angiotensin II receptor type AT2, mutated AT2 receptors were generated in which the Lys215 was replaced with glutamic acid, glutamine, alanine and arginine. The ability of these mutated receptors to bind peptidic ligands 125I-[Sar1-Ile8]Ang II (non-specific for AT2 receptor type), 125I-CGP42112A (AT2 receptor specific) and the non-peptidic ligand PD123319 (AT2 receptor specific) was evaluated by expressing these receptors in Xenopus oocytes and performing binding assays. The Lys215Glu and Lys215Gln mutants of AT2 receptor lost their affinity to 125I-[Sar1-Ile8]Ang II, but retained their affinity to 125I-CGP42112A and PD123319. In contrast, Lys215Arg mutant retained its affinity to 125I-[Sar1-Ile8]Ang II, but exhibited lower affinity to 125I-CGP42112A. The Lys215Ala mutant lost its affinity to both 125I-[Sar1-Ile8]Ang II and 125I-CGP42112A. These results suggest that the binding mechanism of 125I-[Sar1-Ile8]Ang II to AT2 receptor is similar to that of AT1 receptor since an amino acid with positively charged side chain (Lys or Arg) located in the fifth transmembrane domain is required for this ligand to bind AT2 receptor. In contrast, although CGP42112A is a peptidic ligand, it does not require an interaction between its C-terminal carboxylate group and the positively charged side-chain of an amino acid in the fifth transmembrane domain for its binding to AT2 receptor.

Young SHR express increased type 1 angiotensin II receptors in renal proximal tubule

A potential role for the renin-angiotensin system (RAS) in the development and/or maintenance of hypertension in the genetic model of rat hypertension, spontaneously hypertensive rats (SHR), has been suggested by studies indicating that treatment of immature animals with angiotensin-converting enzyme (ACE) inhibitors prevents subsequent development of hypertension. Because young SHR also demonstrate RAS-dependent increased sodium retention, we examined proximal tubule type 1 angiotensin II receptor (AT1R) mRNA expression in young (4 wk) or adult (14 wk) SHR compared with age-matched Wistar-Kyoto (WKY) rats. Proximal tubules were isolated by Percoll gradient centrifugation, and AT1R mRNA expression was measured by quantitative reverse transcription-polymerase chain reaction (RT-PCR). At 14 wk, when SHR had established hypertension [mean arterial blood pressure (MAP) of SHR vs. WKY: 145 +/- 6 vs. 85 +/- 5 mmHg, n = 14-15], there were no differences in proximal tubule AT1R mRNA levels [SHR vs. WKY: 79 +/- 14 vs. 72 +/- 14 counts/min (cpm) per cpm mutant AT1R per cpm beta-actin x 10(-6), n = 6; not significant (NS)]. In contrast, in 4 wk SHR, at a time of minimal elevations in blood pressure (MAP: 70 +/- 8 vs. 63 +/- 3), SHR proximal tubule AT1R mRNA levels were 263 +/- 30% that of WKY (143 +/- 18 vs. 60 +/- 11 cpm per cpm of mutant AT1R per cpm beta-actin x 10(-6), n = 8; P < 0.005). We have recently shown that chronic ACE inhibition decreases proximal tubule AT1R expression and have also shown that chronic L-3,4-dihydroxyphenylalamine (L-DOPA) administration inhibits AT1R expression in adult Sprague-Dawley proximal tubule and cultured proximal tubule, and this inhibition is mediated via Gs-coupled DA1 receptors. When 3-wk-old animals were given L-DOPA or captopril for 1 wk, MAP was not altered (70 +/- 8 vs. 60 +/- 4 or 61 +/- 5 mmHg), but proximal tubule AT1R mRNA was no longer significantly different between SHR and WKY (68 +/- 9 vs. 38 +/- 7 or 20 +/- 3 vs. 47 +/- 15 cpm per cpm of mutant AT1R per cpm beta-actin x 10(-6)), due to a significant decrease in proximal tubule AT1R expression in SHR (P < 0.005, compared with untreated SHR). Immunoreactive proximal tubule AT1R expression also was increased in 4 wk SHR and was reversed with captopril or L-DOPA treatment. Therefore, these results indicate that young, but not adult, SHR have increased expression of proximal tubule AT1R and that chronic L-DOPA or captopril treatment decreased the elevated AT1R expression to control levels. These results provide further support for an important role of the RAS in the development of hypertension in SHR.

Renin-angiotensin system genes in kidney development

The renin-angiotensin system (RAS) plays a key role in cardiovascular homeostasis through the interactions of angiotensin II with its receptors. All components of the RAS are developmentally regulated in the kidney. The functions of the system in the maturing kidney overlap those of the adult, but higher levels of expression and novel locations of expression in the fetus suggest that the RAS has alternate functions as well. Increasing evidence suggests that the RAS may regulate renal growth and development by initiating a complex cascade of events, involving growth factors and proto-oncogenes and other unidentified factors. These same cascades may also be important in renal disease states. Recent advances in the field of molecular and cell biology are providing new tools and strategies to elucidate the intimate mechanism whereby the RAS regulates growth processes and disease states.

Mutation of a conserved fifth transmembrane domain lysine residue (Lys215) attenuates ligand binding in the angiotensin II type 2 receptor

A fifth transmembrane domain lysine residue is conserved in both the type 1 (AT1) and type 2 (AT2) angiotensin II (AngII) receptors. This lysine (Lys199) is believed to play a critical role in peptide binding for the AT1 receptor. To evaluate its possible role in the AT2 receptor, the analogous AT2 residue (Lys199) was changed to glutamine. This mutation greatly reduced the affinity for both 125I-AngII and 125I-Sar1,Ile8-AngII and abolished binding to the non-peptide 125I-PD122979. These data indicate that despite a relatively low homology of 34%, some commonalities in the binding mechanism for AngII may exist between the two subtypes.

Mutational analysis of the angiotensin II type 2 receptor: contribution of conserved extracellular amino acids

While much work has been done examining the ligand-binding characteristics of the AT1 receptor, very little attention has been focused on the AT2 receptor. Both receptors bind angiotensin II (AngII) with identical affinities, but share only 34% homology. Although it is tempting to assume that conserved residues between the two subtypes are responsible for the binding of AngII, there is little data to support this view. To determine the commonalities in ligand binding of the AT1 and AT2 receptors, we have chosen several conserved extracellular amino acids which have been shown to be important in AngII binding [1,2] to the AT1 receptor for mutational studies of the AT2 receptor. Specifically, we have mutated tyrosine108 in extracellular loop 1 (ECL1), arginine182 in ECL2, and aspartate297 in ECL3 of the AT2 receptor in order to determine their contribution to AngII binding. In the AT2 receptor, mutation of tyrosine108 to an alanine resulted in a receptor with wild-type binding for AngII, while mutation of either arginine182 or aspartate297 drastically impaired AngII binding ( > 100 nM). These results demonstrate both similarities as well as clear differences between receptor subtypes in the contributions to AngII binding of several conserved extracellular amino acid residues.

The amino-terminal domain of CCR2 is both necessary and sufficient for high affinity binding of monocyte chemoattractant protein 1. Receptor activation by a pseudo-tethered ligand

High affinity binding of monocyte chemoattractant protein 1 (MCP-1) requires the presence of the amino-terminal domain of CCR2, the MCP-1 receptor. Here we report that the 35 amino-terminal residues of CCR2, expressed as a membrane-bound fusion protein, bound MCP-1 with an affinity similar to that of the intact, wild-type receptor. Furthermore, the amino-terminal fusion protein enhanced, in trans, agonist-dependent activation of a CCR2 variant that was engineered to lack the high affinity binding sites for MCP-1. Mutation of highly conserved cysteines in the amino-terminal domain and third extracellular loop of CCR2, but not in the fusion protein, resulted in a dramatic loss of MCP-1 binding, suggesting the existence of a critical intramolecular disulfide bond that positions the amino-terminal protein for ligand interaction. These data indicate that the amino-terminal region of CCR2 is both necessary and sufficient for the high affinity binding of MCP-1 and provide the first direct evidence for activation of a chemokine receptor by a pseudo-tethered ligand. In this model, high affinity binding by the relatively short amino-terminal domain of CCR2 serves to tether MCP-1 and enhance low affinity interactions with distal regions of the receptor.

Modes of peptide binding in G protein-coupled receptors

The G-protein coupled seven transmembrane domain receptors bind a wide variety of ligands of different molecular size ranging from small monoamines to large neuropeptides and peptide hormones. This review summarises data from studies on the localisation of the binding site for a few neuropeptides in their receptors and compares this to the binding pockets for non peptide ligands. The main conclusion is that neuropeptide binding involves residues on the top of several transmembrane domains and in extracellular loops of the receptors while the non peptide type ligands to the same receptors tend to bind deeper in the plane of the membrane, between several transmembrane domains--similarly to monoamines. Thus the antagonism exerted by most of the non peptide type ligands is an allosteric phenomenon whereby binding of these to another site than the peptide binding site stablises a "non agonist" binding, and for signalling inactive, conformation of the 7 TM receptor.

A review of mutagenesis studies of angiotensin II type 1 receptor, the three-dimensional receptor model in search of the agonist and antagonist binding site and the hypothesis of a receptor activation mechanism

OBJECTIVE

To seek the mechanism whereby agonists, competitive antagonists and insurmountable antagonists affect the receptor function differently, by reviewing recent mutagenesis studies of angiotensin II type 1 receptor (AT1) in which the binding of the agonist and antagonists and receptor signaling were affected.

AT1 RECEPTOR STRUCTURE AND LIGAND BINDING SITES

We built a model of seven transmembrane spanning domains of the AT1 receptors using bacteriorhodopsin as a template. The carboxy terminal of angiotensin II binds to Lys199 in transmembrane domain 5, whereas the guanidinium group of Arg2 binds to Asp281 in transmembrane domain 7. Results of studies using mutagenesis supporting proposed ligand-docking models are discussed. HYPOTHESIS FOR THE LIGAND-INDUCED RECEPTOR SIGNALING MECHANISM: We submit a set of hypotheses for a mechanism whereby the ligand binding induces changes in the receptor conformation by the rotation of transmembrane helices as the initial event for the subsequent activation of a G protein. In this mechanism antagonists are not capable of rotating the helices but agonists are able to do so, which results in the formation of a hydrogen bond between Asp74 in transmembrane domain 2 and Tyr292 in transmembrane domain 7. This mechanism also provides plausible explanation for the activation of monoamine receptors.

COMPETITIVE AND INSURMOUNTABLE ANTAGONISTS

Competitive antagonists share the same binding sites with agonists, but insurmountable antagonists do not, and binding of the latter does not preclude agonist binding, for example, to Asp281.

CONCLUSION

This hypothesis of the intrareceptor signaling mechanism and the receptor model indicate that some amino acid residues essential for the signaling play their roles in the intrareceptor activation mechanism, whereas others participate directly in ligand binding.

Dual agonistic and antagonistic property of nonpeptide angiotensin AT1 ligands: susceptibility to receptor mutations

Two nonpeptide ligands that differ chemically by only a single methyl group but have agonistic (L-162,782) and antagonistic (L-162,389) properties in vivo were characterized on the cloned angiotensin AT1 receptor. Both compounds bound with high affinity (K(I) = 8 and 28 nM, respectively) to the AT1 receptor expressed transiently in COS-7 cells as determined in radioligand competition assays. L-162,782 acted as a powerful partial agonist, stimulating phosphatidylinositol turnover with a bell-shaped dose-response curve to 64% of the maximal level reached in response to angiotensin II. Surprisingly, L-162,389 also stimulated phosphatidylinositol turnover, albeit only to a small percentage of the angiotensin response. The prototype nonpeptide AT1 agonist L-162,313 gave a response of approximately 50%. The apparent EC50 values for all three compounds in stimulating phosphatidylinositol turnover were similar, approximately 30 nM, corresponding to their binding affinity. Each of the three compounds also acted as angiotensin antagonists, yet in this capacity the compounds differed markedly, with IC50 values ranging from 1.05 x 10(-7) M for L-162,389 to 6.5 x 10(-6) for L-162,782. A series of point mutations in the transmembrane segments (TMs) of the AT1 receptor had only minor effect on the binding affinity of the nonpeptide compounds, with the exception of A104V at the top of TM III, which selectively impaired the binding of L-162,782 and L-162,389. Substitutions in the middle of TM III, VI, or VII, which did not affect the binding affinity of the compounds, impaired or eliminated the agonistic efficacy of the nonpeptides but with only minor or no effect on the angiotensin potency or efficacy. Thus, in the N295D rat AT1 construct, L-162,782, L-162,313, and L-162,389 all antagonized the angiotensin-induced phosphatidylinositol turnover with surprisingly similar IC50 values (90-180 nM), and they all bound with unaltered, high affinity (22-36 nM). However, L-162,313 and L-162,782 could stimulate phosphatidylinositol turnover to only 20% of that of angiotensin. It is concluded that minor chemical modifications of either the compound or the receptor can dramatically alter the agonistic efficacy of biphenyl imidazole compounds on the AT1 receptor without affecting their affinity, as determined in binding assays, and that a number of substitutions in the middle of the TM segments affect the efficacy of nonpeptide agonists as opposed to angiotensin.

Candesartan (CV-11974) dissociates slowly from the angiotensin AT1 receptor

The mechanisms of the insurmountable antagonism of 2-ethoxy-1-[[2'-(1H-tetrazol-5-yl)biphenyl-4-yl]methyl]1H-benzimid azole -7-carboxylic acid, candesartan (CV-11974), an angiotensin AT1 receptor antagonist, on angiotensin II-induced rabbit aortic contraction were examined in contraction and binding studies. Preincubation of the rabbit aorta with CV-11974 (0.1 nM) for 30 min reduced the maximal contractile response to angiostensin II by approximately 50%. This insurmountable antagonism of CV-11974 was reversed in the presence of losartan (1 microM), a surmountable angiotensin AT1 receptor antagonist. The inhibitory effect of CV-11974 on angiotensin II-induced contraction persisted longer after washing than did that of losartan but was irreversible. Scatchard analysis of [3H]CV-11974 binding in bovine adrenal cortical membranes indicated the existence of a single class of binding sites (Kd = 7.4 nM). Competition binding studies using angiotensin II receptor agonists and antagonists have demonstrated that [3H[CV-11974 binding sites may be identical to angiotensin AT1 receptors. The dissociation rate of [3H]CV-11974 binding (t1/2 = 66 min) was 5 times slower than that of [125I]angiotensin II binding (t1/2 = 12 min). These results suggest that the insurmountable antagonism by CV-11974 is due to its slow dissociation from angiotensin AT1 receptors.

The N terminus of bradykinin when bound to the human bradykinin B2 receptor is adjacent to extracellular Cys20 and Cys277 in the receptor

Chemical cross-linking combined with site-directed mutagenesis was used to evaluate the role of extracellular cysteines and their positions relative to the binding site for the agonist bradykinin (BK) in the human BK B2 receptor. All extracellular cysteines, Cys20, Cys103, Cys184, and Cys277, in the receptor were mutated to serines, and single and double mutants were transfected into COS-7 cells. The Ser20 and Ser277 single mutants and the Ser20/Ser277 double mutant bound [3H]BK and the antagonist [3H]NPC17731 with pharmacological profiles identical to the wild-type B2 receptor. In contrast, the Ser103 and Ser184 single mutants were unable to bind either of the two radioligands. However, these mutants were still expressed as determined by immunoblotting with anti-B2 receptor antibodies. Previous studies on the bovine B2 receptor showed that bifunctional reagents, which are reactive to amines at one end and to free sulfhydryls in the opposite end, cross-link the N terminus of receptor-bound BK to a sulfhydryl in the receptor (Herzig, M. C. S., and Leeb-Lundberg, L. M. F. (1995) J. Biol. Chem. 270, 20591-20598). Here, we show that m-maleimidobenzoyl-N-hydroxysuccinimide ester and 1,5-difluoro-2, 4-dinitrobenzene cross-linked BK to the wild-type human B2 receptor and the Ser20 and Ser277 single mutant receptors, whereas these reagents were unable to cross-link BK to the Ser20/Ser277 double mutant. These results show that Cys103 and Cys184 are both required for expression of high affinity agonist and antagonist binding sites in the human B2 receptor, while Cys20 and Cys277 are not required. Furthermore, the results provide direct biochemical evidence that the N terminus of BK, when bound to the B2 receptor, is adjacent to Cys277 in extracellular domain 4 and Cys20 in extracellular domain 1 of the receptor.

Phosphorylation of the type 1A angiotensin II receptor by G protein-coupled receptor kinases and protein kinase C

The type 1A angiotensin II receptor (AT1A-R), which mediates cardiovascular effects of angiotensin II, has been shown to undergo rapid agonist-induced desensitization. We investigated the potential role of second messenger-activated kinases and G protein-coupled receptor kinases (GRKs) in the regulation of this receptor. In 293 cells transfected with the AT1A-R, a 3-min challenge with angiotensin II engendered a 46% decrease in subsequent angiotensin II-stimulated phosphoinositide hydrolysis in intact cells. This agonist-induced desensitization correlated temporally and dose-dependently with the phosphorylation of the receptor to a stoichiometry of 1 mol of phosphate/mol of receptor, as assessed by immunoprecipitation of receptors from cells metabolically labeled with 32Pi. Agonist-induced receptor phosphorylation was reduced by 40-50% by either overexpression of a dominant negative K220R mutant GRK2 or treatment of the cells with the protein kinase C (PKC) inhibitor staurosporine, in a virtually additive fashion. Cellular overexpression of GRK2K220R not only inhibited agonist-induced AT1A-R phosphorylation, but also prevented receptor desensitization, as assessed by angiotensin II-stimulated GTPase activity in membranes prepared from agonist-treated and control cells. In contrast, PKC inhibition by staurosporine did not affect homologous desensitization of the AT1A-R. Overexpression of GRKs 2, 3, or 5 significantly augmented the agonist-induced AT1A-R phosphorylation 1.5- to 1.7-fold (p < 0.001). These findings suggest a role for receptor phosphorylation by one or several GRKs in the rapid agonist-induced desensitization of the AT1A-R.

The ligand binding site of the angiotensin AT1 receptor

The angiotensin AT1 receptor mediates numerous physiological actions of the octapeptide hormone, angiotensin II, in its cardiovascular and other target tissues. The binding of angiotensin II to the AT1 receptor is dependent on both intramembrane and extracellular regions of the receptor molecule. Non-peptide antagonists that block angiotensin binding and action interact exclusively with residues located within the intramembrane binding pocket of the AT1 receptor. However, peptide ligands also interact with extracellular residues to form additional bonds that stabilize their binding to the receptor. Here, László Hunyady, Tamás Balla and Kevin Catt describe how these and other studies have shown that interaction of ligands with residues in the intramembrane binding pocket is the conserved mechanism required for agonist activation of G protein-coupled receptors.

Polar residues in the transmembrane domains of the type 1 angiotensin II receptor are required for binding and coupling. Reconstitution of the binding site by co-expression of two deficient mutants

Type 1 angiotensin receptors (AT1) are G-protein coupled receptors, mediating the physiological actions of the vasoactive peptide angiotensin II. In this study, the roles of 7 amino acids of the rat AT1A receptor in ligand binding and signaling were investigated by performing functional assays of individual receptor mutants expressed in COS and Chinese hamster ovary cells. Substitutions of polar residues in the third transmembrane domain with Ala indicate that Ser105, Ser107, and Ser109 are not essential for maintenance of the angiotensin II binding site. Replacement of Asn111 or Ser115 does not alter the binding affinity for peptidic analogs, but modifies the ability of the receptor to interact with AT1 (DuP753)- or AT2 (CGP42112A)-specific ligands. These 2 residues are probably involved in determining the binding specificity for these analogs. The absence of G-protein coupling to the Ser115 mutant suggests that this residue, in addition to previously identified residues, Asp74 and Tyr292, participates in the receptor activation mechanism. Finally, Lys102 (third helix) and Lys199 (fifth helix) mutants do not bind angiotensin II or different analogs. Co-expression of these two deficient receptors permitted the restoration of a normal binding site. This effect was not due to homologous recombination of the cDNAs but to protein trans-complementation.

Site-directed mutagenesis of conserved charged residues in the helical region of the human C5a receptor. Arg2O6 determines high-affinity binding sites of C5a receptor

The human C5a receptor (C5aR) belongs to the family of G-protein-coupled receptors with seven transmembrane helices. This part of the molecule is thought to contain part of the ligand-binding pocket, specifically to bind the C-terminal Arg of human C5a. Guided by sequence similarity and molecular modelling studies, several residues including polar (Asn119, Thr168, Gln259) as well as all conserved charged amino acids in the upper transmembrane region of the C5aR (Asp37, Asp82, Arg175, Arg2O6, Asp282) were exchanged by site-directed mutagenesis. Receptor mutants were transiently expressed in COS cells and analyzed for altered binding behaviour and/or localization at the cell surface by immunofluorescence. For all residues, suitable mutants could be found that exhibited wild-type affinity towards the ligand, providing evidence against a major contribution of these residues to high-affinity ligand binding. Some mutants, however, exhibited a complete (Asp282-->Ala) or partial loss of ligand-binding capacity (Arg175-->Ala, Arg2O6-->Gln) despite adequate expression levels on the cell surface. This phenotype was further analyzed in the [Gln2O6]C5aR mutant: quantitative flow cytometric analysis of epitope-tagged receptor derivatives in 293 cells confirmed an equal level of wild-type and mutant C5aR on the cell surface. Competitive binding curves revealed the presence of only a small population (<10%) of high-affinity sites (Kd approximately 2 nM), which was functionally active at 20 nM in the heterologous Xenopus oocyte expression system after coexpression of G alpha-16. The number of high-affinity sites of wild-type and [Gln2O6]C5aR in 293 cells could be up-regulated by coexpression of Gi alpha-2 and down-regulated by GTP[gamma S]-mediated uncoupling of the G-protein receptor interaction in membrane preparations. These findings are compatible with a model in which the Arg2O6 residue located in the upper third of transmembrane helix V determines high-affinity binding in the human C5aR by affecting the intracellular G-protein coupling.

Analysis of the role of N-glycosylation in cell-surface expression and binding properties of angiotensin II type-2 receptor of rat pheochromocytoma cells

We previously demonstrated that the AT2 receptor is a glycoprotein containing N-linked oligosaccharide side chains and that the marked disparity between the sizes of AT2 receptors from different tissues was related to different degrees of N-glycosylation. In the present study, we used an inhibitor of N-glycosylation, tunicamycin, as well as an endoglycosidase, glycopeptidase-F, to examine the contribution of carbohydrate moieties to the ligand-binding properties, cell-surface expression and apparent molecular mass of AT2 receptors of rat pheochromocytoma cells (PC-12 cells). Photoaffinity labelling of cell-surface AT2 receptors revealed that PC-12 cells grown in the presence of tunicamycin expressed, in addition to the previously described 140 kDa receptor, lower-molecular-mass receptors of 63 kDa, 47 kDa and 32 kDa. Lectin affinity chromatography revealed that the 63 kDa and the 47 kDa receptors are partially glycosylated and that the 32 kDa receptor is completely deglycosylated. Competitive binding experiments were carried out on tunicamycin-treated cells that expressed predominantly the 63 kDa or the 47 kDa receptors. Both receptor forms exhibited a high affinity for angiotensin II, although a slight decrease (of about 2-fold) was consistently observed on tunicamycin-treated cells as compared with control cells. Endoglycosidase digestion of AT2 receptors of PC-12 cells also yielded smaller receptor forms of 47 kDa and 32 kDa. Similarly, angiotensin II showed a high but slightly decreased binding affinity (of about 2-fold) for deglycosylated membranes as compared with control membranes. In conclusion, the stepwise action of tunicamycin suggests the presence of at least three N-linked oligosaccharide side chains on the AT2 receptor of PC-12 cells. These oligosaccharide side chains have a minor contribution to the affinity of the receptor. Interestingly, glycosylation is not an essential requirement for the expression of AT2 receptor at the surface of PC-12 cells.

A disulfide bond between conserved extracellular cysteines in the thyrotropin-releasing hormone receptor is critical for binding

The assumption that a disulfide bond is present between two highly conserved cysteines in the extracellular loops of G protein-coupled receptors and is critical for receptor function has been cast in doubt. We undertook to determine whether a disulfide bond important for binding or activation is present in the thyrotropin-releasing hormone (TRH) receptor (TRH-R). Studies were performed with cells expressing wild-type (WT) and mutant receptors in the absence or presence of the reducing agent dithiothreitol (DTT). The affinity of WT TRH-R was 16-22-fold lower in the presence of DTT than in the absence of DTT. Mutant receptors were constructed in which Ala was substituted for conserved Cys-98 and Cys-179 of extracellular loops 1 and 2, respectively, and for the nonconserved Cys-100. C98A and C179A TRH-Rs did not exhibit high affinity binding. These mutant receptors were capable of stimulating inositol phosphate second messenger formation to the same extent as WT TRH-Rs but with a markedly lower potency. The affinities of C98A and C179A TRH-Rs, estimated from their potencies, were 4400- and 640-fold lower, respectively, than WT TRH-R. The estimated affinities of neither C98A nor C179A TRH-R were decreased by DTT. In contrast, the estimated affinity of C100A TRH-R was not different from WT TRH-R and was DTT sensitive. Moreover, the effect of mutating both Cys-98 and Cys-179 was not additive with the effects of the individual mutations. These data provide strong evidence that Cys-98 and Cys-179 form a disulfide bond. This interaction is not involved in receptor activation but is critical for maintaining the high affinity conformation of TRH-R.

Developmental consequences of the renin-angiotensin system

Molecular, cellular, and physiological studies indicate that the renin-angiotensin system (RAS) is highly expressed during early kidney development. We propose that a major function of the RAS during early embryonic development is the modulation of growth processes that lead the primitive kidney into a properly differentiated and architecturally organized organ suited for independent extrauterine life. As development progresses, the RAS acquires new and overlapping functions such as the endocrine and paracrine regulation of blood pressure and renal hemodynamics. Disease states in adult mammals often result in expression of RAS genes and phenotypic changes resembling the embryonic pattern, emphasizing the importance of undertaking developmental studies. Because of their importance in health and disease, the immediate challenge is to identify the mechanisms that regulate the unique development of the RAS and its role(s) in normal and abnormal growth processes.

A conserved NPLFY sequence contributes to agonist binding and signal transduction but is not an internalization signal for the type 1 angiotensin II receptor

A conserved NPX2-3Y sequence that is located in the seventh transmembrane helix of many G protein-coupled receptors has been predicted to participate in receptor signaling and endocytosis. The role of this sequence (NPLFY) in angiotensin II receptor function was studied in mutant and wild-type rat type 1a angiotensin II receptors transiently expressed in COS-7 cells. The ability of the receptor to interact with G proteins and to stimulate inositol phosphate responses was markedly impaired by alanine replacement of Asn298 and was reduced by replacement of Pro299 or Tyr302. The F301A mutant receptor exhibited normal G protein coupling and inositol phosphate responses, and the binding of the peptide antagonist, [Sar1,Ile8]angiotensin II, was only slightly affected. However, its affinity for angiotensin II and the nonpeptide antagonist losartan was reduced by an order of a magnitude, suggesting that angiotensin II and losartan share an intramembrane binding site, possibly through their aromatic moieties. None of the agonist-occupied mutant receptors, including Y302A and triple alanine replacements of Phe301, Tyr302, and Phe304, showed substantial changes in their internalization kinetics. These findings demonstrate that the NPLFY sequence of the type 1a angiotensin II receptor is not an important determinant of agonist-induced internalization. However, the Phe301 residue contributes significantly to agonist binding, and Asn298 is required for normal receptor activation and signal transduction.

Arginine 206 of the C5a receptor is critical for ligand recognition and receptor activation by C-terminal hexapeptide analogs

C5a is a 74-amino-acid glycoprotein whose receptor is a member of the rhodopsin superfamily. While antagonists have been generated to many of these receptors, similar efforts directed at family members whose natural ligands are proteins have met with little success. The recent development of hexapeptide analogs of C5a has allowed us to begin elucidation of the molecular events that lead to activation by combining a structure/activity study of the ligand with receptor mutagenesis. Removal of the hexapeptide's C-terminal arginine reduces affinity by 100-fold and eliminates the ability of the ligand to activate the receptor. Both the guanidino side chain and the free carboxyl of the arginine participate in the interaction. The guanidino group makes the energy-yielding contact with the receptor, while the free carboxylate negates "electrostatic" interference with Arg-206 of the receptor. It is the apparent movement Arg-206 induced by this set of interactions that is responsible for activation, since conversion of Arg-206 to alanine eliminates the agonist activity of the hexapeptides. Surprisingly, activation is a nearly energy-neutral event and may reflect the binding process rather than the final resting site of the ligand.

A computer modeling postulated mechanism for angiotensin II receptor activation

The angiotensin II receptor of the AT1-type has been modeled starting from the experimentally determined three-dimensional structure of bacteriorhodopsin as the template. Intermediate 3D structures of rhodopsin and beta 2-adrenergic receptors were built because no direct sequence alignment is possible between the AT1 receptor and bacteriorhodopsin. Docking calculations were carried out on the complex of the modeled receptor with AII, and the results were used to analyze the binding possibilities of DuP753-type antagonistic non-peptide ligands. We confirm that the positively charged Lys199 on helix 5 is crucial for ligand binding, as in our model; the charged side chain of this amino acid interacts strongly with the C-terminal carboxyl group of peptide agonists or with the acidic group at the 2'-position of the biphenyl moiety of DuP753-type antagonists. Several other receptor residues which are implicated in the binding of ligands and the activation of receptor by agonists are identified, and their functional role is discussed. Therefore, a plausible mechanism of receptor activation is proposed. The three-dimensional docking model integrates most of the available experimental observations and helps to plan pertinent site-directed mutagenesis experiments which in turn may validate or modify the present model and the proposed mechanism of receptor activation.

Mutagenesis and the molecular modeling of the rat angiotensin II receptor (AT1)

The molecular interaction involved in the ligand binding of the rat angiotensin II receptor (AT1A) was studied by site-directed mutagenesis and receptor model building. The three-dimensional structure of AT1A was constructed on the basis of a multiple amino acid sequence alignment of seven transmembrane domain receptors and angiotensin II receptors and after the beta 2 adrenergic receptor model built on the template of the bacteriorhodopsin structure. These data indicated that there are conserved residues that are actively involved in the receptor-ligand interaction. Eleven conserved residues in AT1, His166, Arg167, Glu173, His183, Glu185, Lys199, Trp253, His256, Phe259, Thr260, and Asp263, were targeted individually for site-directed mutation to Ala. Using COS-7 cells transiently expressing these mutated receptors, we found that the binding of angiotensin II was not affected in three of the mutations in the second extracellular loop, whereas the ligand binding affinity was greatly reduced in mutants Lys199-->Ala, Trp253-->Ala, Phe259-->Ala, Asp263-->Ala, and Arg167-->Ala. These amino acid residues appeared to provide binding sites for Ang II. The molecular modeling provided useful structural information for the peptide hormone receptor AT1A. Binding of EXP985, a nonpeptide angiotensin II antagonist, was found to be involved with Arg167 but not Lys199.

Disulfide bridges in extracellular domains of angiotensin II receptor type IA

Angiotensin II receptor type IA (AT1A) has a cysteine (Cys) residue in each of four extracellular domains, and these Cys residues are believed to form two disulfide bridges. However, the question as to which pairs of Cys residues form disulfide bridges have not been experimentally determined. We constructed four mutants of rat AT1A, in which extracellular Cys residues were individually replaced by glycine (mutant C-1, C-2, C-3 and C-4). Further, we constructed two double mutants, in which two extracellular Cys residues were simultaneously substituted for by glycine. The binding affinity for angiotensin II in a double mutant C-1 + 4 (Cys18,274Gly) was similar to that in individually substituted mutants (C-1, C-2, C-3 and C-4) whereas the ligand binding of a double mutant C-2 + 4 (Cys101,274Gly) was completely abolished. The bindings of the non-peptide AT1A antagonist [125I]EXP-985 to mutants C-1, C-4 and C-1 + 4 were only slightly reduced whereas in mutant C-2, C-3 and C-2 + 4 the specific binding for [125I]EXP-985 was completely abolished. These results suggest that disulfide bridges in AT1A are formed between Cys18 and Cys274, and between Cys101 and Cys180, and the latter disulfide bond is essential for the binding of the non-peptidic antagonists [125I]EXP-985 or losartan.

The docking of Arg2 of angiotensin II with Asp281 of AT1 receptor is essential for full agonism

The structural model of AT1 angiotensin receptor contains seven-transmembrane alpha-helices with three interhelical loops on either side of the membrane. The angiotensin II binding pocket within the receptor is not clearly defined. We showed earlier that Lys199 in transmembrane-helix-5 of the AT1 receptor binds the COOH-terminal alpha-carboxyl group of angiotensin II (Noda, K., Saad, Y., Kinoshita, A., Boyle, T. P., Graham, R. M., Husain, A., and Karnik, S. S. (1995) J. Biol. Chem. 270, 2284-2289). We now show that His183 and Asp281, both located in the extracellular domain of the AT1 receptor, are involved in binding the NH2-terminal Asp1 and Arg2 residues of angiotensin II, respectively. The Asp1/His183 interaction appears to be weak and is unlikely to be important for agonism. But the loss of Arg2/Asp281 interaction leads to partial agonism of the receptor. The action of non-peptide agonists is not affected by Asp281 mutations. These results suggest that several independent interactions between angiotensin II and AT1 receptor are necessary for full agonism. Since L-162,313 the non-peptide agonist of the AT1 receptor is a partial agonist that does not make contact with Asp281, we speculate that the degree of agonism may be increased if it is redesigned to make contacts with Asp281.

Tetrazole and carboxylate groups of angiotensin receptor antagonists bind to the same subsite by different mechanisms

To identify specific interactions between either the tetrazole or carboxylate pharmacophores of non-peptide antagonists and the rat AT1 receptor, 6 basic residues were examined by site-directed mutagenesis. Three of the mutants (H183Q, H256Q, and H272Q) appeared to be like wild type. Lys102 and Arg167 mutants displayed reduced binding of the non-peptide antagonist losartan. Examination of their properties employing group-specific angiotensin II analogues indicated that their effects on binding were indirect. Interestingly, the affinity of losartan was not altered by a K199Q mutation, but the same mutation reduced the affinity of angiotensin II, the antagonist [Sar1,Ile8]angiotensin II, and several carboxylate analogues of losartan. An Ala199 substitution reduced the affinity of peptide analogues to a larger extent as compared to the affinity of losartan. Thus, the crucial acidic pharmacophores of angiotensin and losartan appear to occupy the same space within the receptor pocket, but the protonated amino group of Lys199 is not essential for binding the tetrazole anion. The binding of the tetrazole moiety with the AT1 receptor involves multiple contacts with residues such as Lys199 and His256 that constitute the same subsite of the ligand binding pocket. However, this interaction does not involve a conventional salt bridge, but rather an unusual lysine-aromatic interaction.

The angiotensin type 1 and type 2 receptor families. Siblings or cousins?

The diverse actions of angiotensin II (AngII) are mediated by cell surface receptors. Molecular cloning techniques have identified two distinct subtypes of AngII receptors referred to as AT1 and AT2. It is now well accepted that multiple forms of the AT1 receptor exist, but similar diversity of the AT2 subtype has not been conclusively demonstrated. Nonetheless, several converging lines of evidence do suggest that multiple AT2 receptors may be present in brain and cultured neuron-like cells lines. For instance, some AT2 receptors are regulated by guanine nucleotides and sulfhydryl-reducing agents, whereas others are insensitive. AT2 receptor populations also exhibit differing pharmacological profiles particularly with respect to their affinity for peptidic and non-peptidic ligands. Moreover, a recently developed anti-AT2 polyclonal antisera reveals a unique pattern of immunohistochemical staining in brain and it does not immunoreact with the recently cloned AT2 receptor. Collectively, these results support the hypothesis of multiple AT2 receptors at least within the CNS. Future studies should reveal whether these putative AT2 receptor subtypes result from unique genes or cell-specific post-translational modifications of a single gene product.

Role of carboxyl tail of the rat angiotensin II type 1A receptor in agonist-induced internalization of the receptor

Binding of angiotensin II (Ang II) to its receptor type 1A (AT1A) is known to trigger its internalization. We studied the role of cytosolic segments of AT1A in the internalization, and obtained results indicating a functional role of the cytosolic carboxyl terminal tail of AT1A in the internalization. Deletion of 50 amino acids from the carboxyl terminus abolished the receptor internalization. Deletion mutants lacking 13 and 32 amino acid residues in the carboxyl terminal cytosolic region were internalized to the same extent as wild type AT1A; however, internalization of a mutant lacking the last 42 residues was partially suppressed. Thus, residues 310 through 327 were shown to be essential for the internalization. We propose that a short domain in the cytoplasmic tail (residues 310 to 327) may play a dominant role in the agonist-induced receptor internalization of AT1A. Our results also suggest that the molecular determinants of the AT1A receptor involved in receptor internalization are distinct from those participating in the desensitization process.

Structural model of antagonist and agonist binding to the angiotensin II, AT1 subtype, G protein coupled receptor

BACKGROUND

The family of G protein coupled receptors is the largest and perhaps most functionally diverse class of cell-surface receptors. Due to the difficulty of obtaining structural data on membrane proteins there is little information on which to base an understanding of ligand structure-activity relationships, the effects of receptor mutations and the mechanism(s) of signal transduction in this family. We therefore set out to develop a structural model for one such receptor, the human angiotensin II receptor.

RESULTS

An alignment between the human angiotensin II (type 1; hAT1), human beta 2 adrenergic, human neurokinin-1, and human bradykinin receptors, all of which are G protein coupled receptors, was used to generate a three-dimensional model of the hAT1 receptor based on bacteriorhodopsin. We observed a region within the model that was congruent with the biogenic amine binding site of beta 2, and were thus able to dock a model of the hAT1 antagonist L-158,282 (MK-996) into the transmembrane region of the receptor model. The antagonist was oriented within the helical domain by recognising that the essential acid functionality of this antagonist interacts with Lys199. The structural model is consistent with much of the information on structure-activity relationships for both non-peptide and peptide ligands.

CONCLUSIONS

Our model provides an explanation for the conversion of the antagonist L-158,282 (MK-996) to an agonist by the addition of an isobutyl group. It also suggests a model for domain motion during signal transduction. The approach of independently deriving three-dimensional receptor models and pharmacophore models of the ligands, then combining them, is a powerful technique which helps validate both models.