Molecular mechanism of Zn2+ agonism in the extracellular domain of GPR39

Ala substitution of potential metal-ion binding residues in the main ligand-binding pocket of the Zn2+-activated G protein-coupled receptor 39 (GPR39) receptor did not decrease Zn2+ potency. In contrast, Zn2+ stimulation was eliminated by combined substitution of His17 and His19, located in the N-terminal segment. Surprisingly, substitution of Asp313 located in extracellular loop 3 greatly increased ligand-independent signaling and apparently eliminated Zn2+-induced activation. It is proposed that Zn2+ acts as an agonist for GPR39, not in the classical manner by directly stabilizing an active conformation of the transmembrane domain, but instead by binding to His17 and His19 in the extracellular domain and potentially by diverting Asp313 from functioning as a tethered inverse agonist through engaging this residue in a tridentate metal-ion binding site.     

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.     

Identification of acidic residues in the extracellular loops of the seven-transmembrane domain of the human Ca2+ receptor critical for response to Ca2+ and a positive allosteric modulator

We investigated the role of the eight acidic residues in the extracellular loops (exo-loops) of the seven-transmembrane domain of the human Ca(2+) receptor (hCaR) in receptor activation by Ca(2+) and in response to a positive allosteric modulator, NPS R-568. Both in the context of the full-length receptor and of a truncated receptor lacking the extracellular domain (Rho-C-hCaR), we mutated each acidic residue to alanine, singly and in combination, and tested the effect on expression of the receptor, on activation by Ca(2+), and on NPS R-568 augmentation of sensitivity to Ca(2+). Of the eight acidic residues, mutation of any of three in exo-loop 2, Asp(758), Glu(759), and Glu(767), increased the sensitivity of both the full-length hCaR and of Rho-C-hCaR to activation by Ca(2+). Mutation of all five acidic residues in exo-loop 2, whether in the full-length receptor or in Rho-C-hCaR, impaired cell surface expression of the mutant receptor and thereby largely abolished response to Ca(2+). Mutation of Glu(837) in exo-loop 3 to alanine did not alter Ca(2+) sensitivity of the full-length receptor, but in both the latter context and in Rho-C-hCaR, alanine substitution of Glu(837) drastically reduced sensitivity to NPS R-568. Our data point to a key role of three specific acidic residues in exo-loop 2 in hCaR activation and to Glu(837) at the junction between exo-loop 3 and transmembrane helix seven in response to NPS R-568. We speculate on the basis of these results that the three acidic residues we identified in exo-loop 2 help maintain an inactive conformation of the seven-transmembrane domain of the hCaR.     

Essential role for the second extracellular loop in C5a receptor activation

More than 90% of G protein-coupled receptors (GPCRs) contain a disulfide bridge that tethers the second extracellular loop (EC2) to the third transmembrane helix. To determine the importance of EC2 and its disulfide bridge in receptor activation, we subjected this region of the complement factor 5a receptor (C5aR) to random saturation mutagenesis and screened for functional receptors in yeast. The cysteine forming the disulfide bridge was the only conserved residue in the EC2-mutated receptors. Notably, approximately 80% of the functional receptors exhibited potent constitutive activity. These results demonstrate an unexpected role for EC2 as a negative regulator of C5a receptor activation. We propose that in other GPCRs, EC2 might serve a similar role by stabilizing the inactive state of the receptor.     

Asp383 in the second transmembrane domain of the lutropin receptor is important for high affinity hormone binding and cAMP production.

The lutropin (LH), follitropin, and thyrotropin receptors belong to the superfamily of G-protein coupled receptors and have some unique structural features. These glycoprotein hormone receptors comprise a C-terminal half and an N-terminal half of similar size. The C-terminal half is equivalent to the entire structure of other G-protein coupled receptors and has seven transmembrane domains, three cytoplasmic loops, three exoplasmic loops, and a C terminus. In contrast, the hydrophilic N-terminal half is exoplasmic and unique to the glycoprotein hormone receptors. This large N-terminal half of the LH receptor has recently been shown to be capable of binding the hormone. Therefore, these glycoprotein hormone receptors are structurally and functionally different from other G-protein coupled receptors. In an attempt to define the role of the membrane-associated C-terminal half of the LH receptor, we have prepared several mutant receptors in which an Asp or Glu in the seven transmembrane domains has been converted to Asn or Gln, respectively. These include Asp383----Asn in the second transmembrane domain, Glu410----Gln in the third transmembrane domain, and Asp556----Asn in the sixth transmembrane domain. All these mutant receptors were successfully expressed in Cos 7A cells. The Glu410----Gln and Asp556----Asn mutants maintained normal affinities for hormone binding and cAMP production, but the Asp383----Asn mutant showed significantly lower affinities. Although Asp383 of the LH receptor is conserved in all G-protein coupled receptors cloned to date except the substance P receptor, which has Glu in the place of the Asp residue, this is the first observation of the critical role of the Asp in hormone binding and subsequent stimulation of cAMP production.     

From molecular details of the interplay between transmembrane helices of the thyrotropin receptor to general aspects of signal transduction in family a G-protein-coupled receptors (GPCRs)

Transmembrane helices (TMHs) 5 and 6 are known to be important for signal transduction by G-protein-coupled receptors (GPCRs). Our aim was to characterize the interface between TMH5 and TMH6 of the thyrotropin receptor (TSHR) to gain molecular insights into aspects of signal transduction and regulation. A proline at TMH5 position 5.50 is highly conserved in family A GPCRs and causes a twist in the helix structure. Mutation of the TSHR-specific alanine (Ala-593^5.50) at this position to proline resulted in a 20-fold reduction of cell surface expression. This indicates that TMH5 in the TSHR might have a conformation different from most other family A GPCRs by forming a regular α-helix. Furthermore, linking our own and previous data from directed mutagenesis with structural information led to suggestions of distinct pairs of interacting residues between TMH5 and TMH6 that are responsible for stabilizing either the basal or the active state. Our insights suggest that the inactive state conformation is constrained by a core set of polar interactions among TMHs 2, 3, 6, and 7 and in contrast that the active state conformation is stabilized mainly by non-polar interactions between TMHs 5 and 6. Our findings might be relevant for all family A GPCRs as supported by a statistical analysis of residue properties between the TMHs of a vast number of GPCR sequences.     

A pH-dependent variation in alpha-helix structure of the S-peptide of ribonuclease A studied by Monte Carlo simulated annealing.

Low-energy conformations of the S-peptide fragment (20 amino acid residues long) of ribonuclease A were studied by Monte Carlo simulated annealing. The obtained lowest-energy structures have alpha-helices with different size and location, depending distinctively on the ionizing states of acidic amino acid residues. The simulation started from completely random initial conformation and was performed without any bias toward a particular structure. The most conspicuous alpha-helices arose from the simulation when both Glu 9 and Asp 14 were assumed to be electrically neutral, whereas the resulting conformations became much less helical when Asp 14 rather than Glu 9 was allowed to have a negative charge. Together with experimental evidence that the alpha-helix in the S-peptide is most stable at pH 3.8, we consider the helix formation need the carboxyl group of Asp 14 to be electrically neutral in this weakly acidic condition. In contrast, a negative charge at Asp 14 appears to function in support of a view that this residue is crucial to helix termination owing to its possibility to form a salt bridge with His 12. These results indicate that the conformation of the S-peptide depends considerably on the ionizing state of Asp 14.     

The Arginine of the DRY Motif in Transmembrane Segment III Functions as a Balancing Micro-switch in the Activation of the β2-Adrenergic Receptor

Recent high resolution x-ray structures of the β2-adrenergic receptor confirmed a close salt-bridge interaction between the suspected micro-switch residue ArgIII:26 (Arg3.50) and the neighboring AspIII:25 (Asp3.49). However, neither the expected "ionic lock" interactions between ArgIII:26 and GluVI:-06 (Glu6.30) in the inactive conformation nor the interaction with TyrV:24 (Tyr5.58) in the active conformation were observed in the x-ray structures. Here we find through molecular dynamics simulations, after removal of the stabilizing T4 lysozyme, that the expected salt bridge between ArgIII:26 and GluVI:-06 does form relatively easily in the inactive receptor conformation. Moreover, mutational analysis of GluVI:-06 in TM-VI and the neighboring AspIII:25 in TM-III demonstrated that these two residues do function as locks for the inactive receptor conformation as we observed increased G(s) signaling, arrestin mobilization, and internalization upon alanine substitutions. Conversely, TyrV:24 appears to play a role in stabilizing the active receptor conformation as loss of function of G(s) signaling, arrestin mobilization, and receptor internalization was observed upon alanine substitution of TyrV:24. The loss of function of the TyrV:24 mutant could partly be rescued by alanine substitution of either AspIII:25 or GluVI:-06 in the double mutants. Surprisingly, removal of the side chain of the ArgIII:26 micro-switch itself had no effect on G(s) signaling and internalization and only reduced arrestin mobilization slightly. It is suggested that ArgIII:26 is equally important for stabilizing the inactive and the active conformation through interaction with key residues in TM-III, -V, and -VI, but that the ArgIII:26 micro-switch residue itself apparently is not essential for the actual G protein activation.     

A conserved Asn in transmembrane helix 7 is an on/off switch in the activation of the thyrotropin receptor

The thyrotropin (TSH) receptor is an interesting model to study G protein-coupled receptor activation as many point mutations can significantly increase its basal activity. Here, we identified a molecular interaction between Asp(633) in transmembrane helix 6 (TM6) and Asn(674) in TM7 of the TSHr that is crucial to maintain the inactive state through conformational constraint of the Asn. We show that these residues are perfectly conserved in the glycohormone receptor family, except in one case, where they are exchanged, suggesting a direct interaction. Molecular modeling of the TSHr, based on the high resolution structure of rhodopsin, strongly favors this hypothesis. Our approach combining site-directed mutagenesis with molecular modeling shows that mutations disrupting this interaction, like the D633A mutation in TM6, lead to high constitutive activation. The strongly activating N674D (TM7) mutation, which in our modeling breaks the TM6-TM7 link, is reverted to wild type-like behavior by an additional D633N mutation (TM6), which would restore this link. Moreover, we show that the Asn of TM7 (conserved in most G protein-coupled receptors) is mandatory for ligand-induced cAMP accumulation, suggesting an active role of this residue in activation. In the TSHr, the conformation of this Asn residue of TM7 would be constrained, in the inactive state, by its Asp partner in TM6.     

An activation switch in the rhodopsin family of G protein-coupled receptors: the thyrotropin receptor

We aimed at understanding molecular events involved in the activation of a member of the G protein-coupled receptor family, the thyrotropin receptor. We have focused on the transmembrane region and in particular on a network of polar interactions between highly conserved residues. Using molecular dynamics simulations and site-directed mutagenesis techniques we have identified residue Asn-7.49, of the NPxxY motif of TM 7, as a molecular switch in the mechanism of thyrotropin receptor (TSHr) activation. Asn-7.49 appears to adopt two different conformations in the inactive and active states. These two states are characterized by specific interactions between this Asn and polar residues in the transmembrane domain. The inactive gauche+ conformation is maintained by interactions with residues Thr-6.43 and Asp-6.44. Mutation of these residues into Ala increases the constitutive activity of the receptor by factors of approximately 14 and approximately 10 relative to wild type TSHr, respectively. Upon receptor activation Asn-7.49 adopts the trans conformation to interact with Asp-2.50 and a putatively charged residue that remains to be identified. In addition, the conserved Leu-2.46 of the (N/S)LxxxD motif also plays a significant role in restraining the receptor in the inactive state because the L2.46A mutation increases constitutive activity by a factor of approximately 13 relative to wild type TSHr. As residues Leu-2.46, Asp-2.50, and Asn-7.49 are strongly conserved, this molecular mechanism of TSHr activation can be extended to other members of the rhodopsin-like family of G protein-coupled receptors.     

Modulation of Constitutive Activity and Signaling Bias of the Ghrelin Receptor by Conformational Constraint in the Second Extracellular Loop

Based on a rare, natural Glu for Ala-204(C+6) variant located six residues after the conserved Cys residue in extracellular loop 2b (ECL2b) associated with selective elimination of the high constitutive signaling of the ghrelin receptor, this loop was subjected to a detailed structure functional analysis. Introduction of Glu in different positions demonstrated that although the constitutive signaling was partly reduced when introduced in position 205(C+7) it was only totally eliminated in position 204(C+6). No charge-charge interaction partner could be identified for the Glu(C+6) variant despite mutational analysis of a number of potential partners in the extracellular loops and outer parts of the transmembrane segments. Systematic probing of position 204(C+6) with amino acid residues of different physicochemical properties indicated that a positively charged Lys surprisingly provided phenotypes similar to those of the negatively charged Glu residue. Computational chemistry analysis indicated that the propensity for the C-terminal segment of extracellular loop 2b to form an extended α-helix was increased from 15% in the wild type to 89 and 82% by introduction in position 204(C+6) of a Glu or a Lys residue, respectively. Moreover, the constitutive activity of the receptor was inhibited by Zn²⁺ binding in an engineered metal ion site, stabilizing an α-helical conformation of this loop segment. It is concluded that the high constitutive activity of the ghrelin receptor is dependent upon flexibility in the C-terminal segment of extracellular loop 2 and that mutations or ligand binding that constrains this segment and thereby conceivably the movements of transmembrane domain V relative to transmembrane domain III inhibits the high constitutive signaling.     

Site-directed disulfide mapping of residues contributing to the Ca2+ and K+ binding pocket of the NCKX2 Na+/Ca2+-K+ exchanger

The Na+/Ca2+-K+ exchanger (NCKX) gene products are polytopic membrane proteins that utilize the existing cellular Na+ and K+ gradients to extrude cytoplasmic Ca2+. NCKX proteins are made up of two clusters of hydrophobic segments, both thought to consist of five putative membrane-spanning alpha-helices, and separated by a large cytoplasmic loop. The two most conserved regions within the NCKX sequence are known as the alpha1 and alpha2 repeats, and are found within the first and second set of transmembrane domains, respectively. The alpha repeats have previously been shown to contain residues critical for transport function. Here we used site-directed disulfide mapping to report that the alpha repeats are found in close proximity in three-dimensional space, bringing together key functional NCKX residues, e.g., the two critical acidic residues, Glu188 and Asp548. Glu188Cys in the alpha1 repeat could form a disulfide cross-link with Asp548Cys in the alpha2 repeat. Surprisingly, cysteine substitutions of Ser185 in the alpha1 repeat could form disulfide cross-links with cysteine substitutions of three residues in the alpha2 repeat (Ser545, Asp548, and Ser552), thought to cover close to two full turns of an alpha helix, implying an area of increased flexibility. Using the same method, Asp575, a residue critical for the K+ dependence of NCKX, was shown to be in the proximity of Ser185 and Glu188, consistent with its role in enabling K+ to bind to a single Ca2+ and K+ binding pocket.     

Mitochondrial phosphate transport protein. Reversions of inhibitory conservative mutations identify four helices and a nonhelix protein segment with transmembrane interactions and Asp39, Glu137, and Ser158 as nonessential for transport

The mitochondrial phosphate transport protein (PTP) has six (A--F) transmembrane (TM) helices per subunit of functional homodimer with all mutations referring to the subunit of the homodimer. In earlier studies, conservative replacements of several residues located either at the matrix end (Asp39/helix A, Glu137/helix C, Asp236/helix E) or at the membrane center (His32/helix A, Glu136/helix C) of TM helices yielded inactive single mutation PTPs. Some of these residues were suggested to act as phosphate ligands or as part of the proton cotransport path. We now show that the mutation Ser158Thr, not part of a TM helix but located near the center of the matrix loop (Ile141--Ser171) between TM helices C and D, inactivates PTP and is thus also functionally relevant. On the other side of the membrane, the single mutation Glu192Asp at the intermembrane space end of TM helix D yields a PTP with 33% wild-type activity. We constructed double mutants by adding this mutation to the six transport-inactivating mutations. Transport was detected only in those with Asp39Asn, Glu137Gln, or Ser158Thr. We conclude that TM helix D can interact with TM helices A and C and matrix loop Ile141--Ser171 and that Asp39, Glu137, and Ser158 are not essential for phosphate transport. Since our results are consistent with residues present in all 12 functionally identified members of the mitochondrial transport protein (MTP) family, they lead to a general rule that specifies MTP residue types at 7 separate locations. The conformations of all the double mutation PTPs (except that with the matrix loop Ser158Thr) are significantly different from those of the single mutation PTPs, as indicated by their very low liposome incorporation efficiency and their requirement for less detergent (Triton X-100) to stay in solution. These dramatic conformational differences also suggest an interaction between TM helices D and E. The results are discussed in terms of TM helix movements and changes in the PTP monomer/dimer ratio.     

Ligand-mimicking Receptor Variant Discloses Binding and Activation Mode of Prolactin-releasing Peptide

The prolactin-releasing peptide receptor and its bioactive RF-amide peptide (PrRP20) have been investigated to explore the ligand binding mode of peptide G-protein-coupled receptors (GPCRs). By receptor mutagenesis, we identified the conserved aspartate in the upper transmembrane helix 6 (Asp(6.59)) of the receptor as the first position that directly interacts with arginine 19 of the ligand (Arg(19)). Replacement of Asp(6.59) with Arg(19) of PrRP20 led to D6.59R, which turned out to be a constitutively active receptor mutant (CAM). This suggests that the mutated residue at the top of transmembrane helix 6 mimics Arg(19) by interacting with additional binding partners in the receptor. Next, we generated an initial comparative model of this CAM because no ligand docking was required, and we selected the next set of receptor mutants to find the engaged partners of the binding pocket. In an iterative process, we identified two acidic residues and two hydrophobic residues that form the peptide ligand binding pocket. As all residues are localized on top or in the upper part of the transmembrane domains, we clearly can show that the extracellular surface of the receptor is sufficient for full signal transduction for prolactin-releasing peptide, rather than a deep, membrane-embedded binding pocket. This contributes to the knowledge of the binding of peptide ligands to GPCRs and might facilitate the development of GPCR ligands, but it also provides new targeting of CAMs involved in hereditary diseases.     

A Conserved Protonation-Induced Switch can Trigger “Ionic-Lock” Formation in Adrenergic Receptors

The mechanism of signal transduction in G-protein-coupled receptors (GPCRs) is a crucial step in cell signaling. However, the molecular details of this process are still largely undetermined. Carrying out submicrosecond molecular dynamics simulations of β-adrenergic receptors, we found that cooperation between a number of highly conserved residues is crucial to alter the equilibrium between the active state and the inactive state of diffusible ligand GPCRs. In particular, “ionic-lock” formation in β-adrenergic receptors is directly correlated with the protonation state of a highly conserved aspartic acid residue [Asp(2.50)] even though the two sites are located more than 20 Å away from each other. Internal polar residues, acting as local microswitches, cooperate to propagate the signal from Asp(2.50) to the G-protein interaction site at the helix III-helix VI interface. Evolutionarily conserved differences between opsin and non-opsin GPCRs in the surrounding of Asp(2.50) influence the acidity of this residue and can thus help in rationalizing the differences in constitutive activity of class A GPCRs.     

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.     

Structural requirements for N-trimethylation of lysine 115 of calmodulin

Calmodulin is trimethylated at lysine 115 by a highly specific methyltransferase that utilizes S-adenosylmethionine as a co-substrate. Lysine 115 is found within a highly conserved six-amino acid loop (LGEKLT) that forms a 90 degrees turn between EF-hand III and EF-hand IV in the carboxyl-terminal lobe. In the present work a mutagenesis approach was used to investigate the structural features of the carboxyl-terminal lobe that lead to the specificity of calmodulin methylation. Three structural regions within the carboxyl-terminal lobe appear to be involved in methyltransferase recognition: the highly conserved six-amino acid loop-turn region that contains lysine 115 as well as the adjacent alpha-helices (helix 6 and helix 7) from EF-hands III and IV. Site-directed mutagenesis of residues in the loop show that three residues, glycine 113, glutamate 114, and leucine 116 are essential for methylation. In addition, subdomain (individual helix or Ca(2+) binding loop) exchange mutants show that the substitutions of either helix 6 (EF-hand III) with helix 2 (EF-hand I) or helix 7 (EF-hand IV) with helix 3 (EF-hand II) compromises methylation. Charge-to-alanine mutations in helix 7 show that substitution of conserved charged residues at positions 118, 120, 122, 126, and 127 reduced lysine 115 methylation rates, suggesting possible electrostatic interactions between this helix and the methyltransferase. Single substitutions in helix 6 did not affect calmodulin methylation, suggesting this region may play a more indirect role in stabilizing the conformation of the methyltransferase recognition sequence.     

Helix packing moments reveal diversity and conservation in membrane protein structure

Helical membrane proteins are more tightly packed and the packing interactions are more diverse than those found in helical soluble proteins. Based on a linear correlation between amino acid packing values and interhelical propensity, we propose the concept of a helix packing moment to predict the orientation of helices in helical membrane proteins and membrane protein complexes. We show that the helix packing moment correlates with the helix interfaces of helix dimers of single pass membrane proteins of known structure. Helix packing moments are also shown to help identify the packing interfaces in membrane proteins with multiple transmembrane helices, where a single helix can have multiple contact surfaces. Analyses are described on class A G protein-coupled receptors (GPCRs) with seven transmembrane helices. We show that the helix packing moments are conserved across the class A family of GPCRs and correspond to key structural contacts in rhodopsin. These contacts are distinct from the highly conserved signature motifs of GPCRs and have not previously been recognized. The specific amino acid types involved in these contacts, however, are not necessarily conserved between subfamilies of GPCRs, indicating that the same protein architecture can be supported by a diverse set of interactions. In GPCRs, as well as membrane channels and transporters, amino acid residues with small side-chains (Gly, Ala, Ser, Cys) allow tight helix packing by mediating strong van der Waals interactions between helices. Closely packed helices, in turn, facilitate interhelical hydrogen bonding of both weakly polar (Ser, Thr, Cys) and strongly polar (Asn, Gln, Glu, Asp, His, Arg, Lys) amino acid residues. We propose the use of the helix packing moment as a complementary tool to the helical hydrophobic moment in the analysis of transmembrane sequences.     

Common structural requirements for heptahelical domain function in class A and class C G protein-coupled receptors

G protein-coupled receptors (GPCRs) are key players in cell communication. Several classes of such receptors have been identified. Although all GPCRs possess a heptahelical domain directly activating G proteins, important structural and sequence differences within receptors from different classes suggested distinct activation mechanisms. Here we show that highly conserved charged residues likely involved in an interaction network between transmembrane domains (TM) 3 and 6 at the cytoplasmic side of class C GPCRs are critical for activation of the gamma-aminobutyric acid type B receptor. Indeed, the loss of function resulting from the mutation of the conserved lysine residue into aspartate or glutamate in the TM3 of gamma-aminobutyric acid type B(2) can be partly rescued by mutating the conserved acidic residue of TM6 into either lysine or arginine. In addition, mutation of the conserved lysine into an acidic residue leads to a nonfunctional receptor that displays a high agonist affinity. This is reminiscent of a similar ionic network that constitutes a lock stabilizing the inactive state of many class A rhodopsin-like GPCRs. These data reveal that despite their original structure, class C GPCRs share with class A receptors at least some common structural feature controlling G protein activation.     

Molecular dynamics simulations reveal insights into key structural elements of adenosine receptors

The crystal structure of the human A(2A) adenosine receptor, a member of the G protein-coupled receptor (GPCR) family, is used as a starting point for the structural characterization of the conformational equilibrium around the inactive conformation of the human A(2) (A(2A) and A(2B)) adenosine receptors (ARs). A homology model of the closely related A(2B)AR is reported, and the two receptors were simulated in their apo form through all-atom molecular dynamics (MD) simulations. Different conditions were additionally explored in the A(2A)AR, including the protonation state of crucial histidines or the presence of the cocrystallized ligand. Our simulations reveal the role of several conserved residues in the ARs in the conformational equilibrium of the receptors. The "ionic lock" absent in the crystal structure of the inactive A(2A)AR is rapidly formed in the two simulated receptors, and a complex network of interacting residues is presented that further stabilizes this structural element. Notably, the observed rotameric transition of Trp6.48 ("toggle switch"), which is thought to initiate the activation process in GPCRs, is accompanied by a concerted rotation of the conserved residue of the A(2)ARs, His6.52. This new conformation is further stabilized in the two receptors under study by a novel interaction network involving residues in transmembrane (TM) helices TM5 (Asn5.42) and TM3 (Gln3.37), which resemble the conformational changes recently observed in the agonist-bound structure of β-adrenoreceptors. Finally, the interaction between Glu1.39 and His7.43, a pair of conserved residues in the family of ARs, is found to be weaker than previously thought, and the role of this interaction in the structure and dynamics of the receptor is thoroughly examined. All these findings suggest that, despite the commonalities with other GPCRs, the conformational equilibrium of ARs is also modulated by specific residues of the family.