The amino-terminal region of the luteinizing hormone/choriogonadotropin receptor contacts both subunits of human choriogonadotropin. II. Photoaffinity labeling

The luteinizing hormone/choriogonadotropin receptor, a seven-transmembrane receptor, is composed of two equal halves, the N-terminal extracellular exodomain and the C-terminal membrane-associated endodomain. Unlike most seven-transmembrane receptors, the exodomain alone is responsible for high affinity hormone binding, whereas signal is generated in the endodomain. These physical separations of hormone-binding and receptor activation sites are attributed to unique mechanisms for hormone binding and receptor activation of this receptor and its subfamily members. However, the precise hormone contact sites in the exodomain are unclear. In the preceding article (Hong, S., Phang, T., Ji, I., and Ji, T. H. (1998) J. Biol. Chem. 273, 13835-13840), a region immediately downstream of the N terminus of the exodomain was shown to be crucial for hormone binding. To test if the region interacts with the hormone, human choriogonadotropin (hCG) was photoaffinity-labeled with a peptide mimic corresponding to Gly18-Tyr36 of the receptor. This peptide mimic specifically photoaffinity-labeled both the alpha- and beta-subunits of hCG. Interestingly, hCGalpha was preferentially labeled. On the other hand, denatured hCG was not labeled, and a mutant analog of the peptide failed to label hCG. Furthermore, the affinity labeling was UV-dependent and saturable, indicating the specificity of the photoaffinity labeling. Our results indicate that the region of the exodomain interacts with hCG and that the contact points are near both subunits of hCG. Particularly, the alternate residues (Leu20, Cys22, and Gly24) are crucial for hCG binding. In addition, the results underscore the fact that there is a crucial hormone contact site outside of the popularly believed primary hormone-binding site that is composed of Leu-rich repeats and is located in the middle of the exodomain. Our observations are crucial for understanding the molecular mechanism through which the initial high affinity hormone binding leads to receptor activation in the endodomain.     

Importance of extracellular domains for ligand binding in the thyrotropin-releasing hormone receptor

The role of putative extracellular sequences for ligand binding in the TRH receptor was examined using deletion or substitution mutations. Each mutant receptor was transiently expressed in TRH receptor-minus GH(1)2C(1)b rat pituitary cells, and binding of 4 Nu Mu [3H]pGlu-N(tau)-MeHis-Pro-NH2 ([3H] MeTRH) was measured. When binding was not detected, signal transduction at 10 microM MeTRH was measured to assess receptor expression. Deletion of most of the N-terminal sequences (Glu(2)-Leu(22)), including two potential glycosylation sites, had no effect on the affinity of the receptor for MeTRH. Segmental deletions or simultaneous substitution of multiple amino acid residues in the first, second, or third extracellular loop (EL1, EL2, or EL3) resulted, however, in total loss of [3H]MeTRH binding, suggesting important roles for the loop sequences in either receptor expression or ligand binding. Individual substitutions were made to test further the role of the specific extracellular loop sequences in TRH binding. In EL1, conversion of Tyr93 to Ala resulted in more than 20-fold decrease in affinity for MeTRH. In EL2 and the top portion of the fifth transmembrane helix, conversion of Tyr181 to Phe, Tyr188 to Ala, and Phe199 to Ala resulted in a large ( > 100-fold) decrease in affinity for MeTRH, and conversion of Tyr 188 to Phe and Phe196 to Ala caused an agonist-specific 4- to 5-fold decrease in affinity. In EL3, conversion of Asn289 to Ala and of Ser290 to Ala caused a large ( > 100-fold) decrease in affinity for MeTRH. These results suggest important roles for the extracellular loops in high affinity TRH binding and lead us to propose a model in which TRH binds to the extra-cellular domain of its receptor.     

Transmembrane residues of the parathyroid hormone (PTH)/PTH-related peptide receptor that specifically affect binding and signaling by agonist ligands

Polar residues within the transmembrane domains (TMs) of G protein-coupled receptors have been implicated to be important determinants of receptor function. We have identified mutations at two polar sites in the TM regions of the rat parathyroid hormone (PTH)/PTH-related peptide receptor, Arg-233 in TM 2 and Gln-451 in TM 7, that caused 17-200-fold reductions in the binding affinity of the agonist peptide PTH-(1-34) without affecting the binding affinity of the antagonist/partial agonist PTH-(3-34). When mutations at the TM 2 and TM 7 sites were combined, binding affinity for PTH-(1-34) was restored to nearly that of the wild type receptor. The double mutant receptors, however, were completely defective in signaling cAMP or inositol phosphate production in response to PTH-(1-34) agonist ligand. The results demonstrate that Arg-233 and Gln-451 have important roles in determining agonist binding affinity and transmembrane signaling. Furthermore, the finding that residues in TM 2 and TM 7 are functionally linked suggests that the TM domain topology of the PTH/PTH-related peptide receptor may resemble that of receptors in the rhodopsin/beta-adrenergic receptor family, for which structural and mutagenesis data suggest interactions between TMs 2 and 7.     

The two mannose 6-phosphate binding sites of the insulin-like growth factor-II/mannose 6-phosphate receptor display different ligand binding properties

The two mannose 6-phosphate (Man-6-P) binding sites of the insulin-like growth factor-II/mannose 6-phosphate receptor (IGF-II/MPR) have been localized to domains 1-3 and 7-9, and studies have shown that Arg435 in domain 3 and Arg 1334 in domain 9 are essential for Man-6-P binding. To determine whether the IGF-II/MPR containing a single Man-6-P binding site is functional, clonal mouse L cell lines stably transfected with either mutant bovine IGF-II/MPR cDNA, containing substitutions at position 435 and/or 1334, or the wild type receptor cDNA were assayed for their ability to sort lysosomal enzymes to the lysosome. Mutant receptors containing a single Man-6-P binding site were approximately 50% less efficient than the wild type receptor in the overall targeting of lysosomal enzymes to the lysosome. Mutant receptors containing a substitution at Arg1334 (Dom9(Ala)), in contrast to those containing a substitution at Arg435 (Dom3(Ala)), were unable to target cathepsin D and beta-hexosaminidase to the lysosome. Equilibrium binding assays using 125I-labeled beta-glucuronidase demonstrated that Dom3(Ala) and Dom9(Ala) had a Kd of 2.0 and 4.3 nM, respectively. In addition, Dom3(Ala), unlike Dom9(Ala), was unable to completely dissociate from ligand under acidic pH conditions. These data indicate that the two Man-6-P binding sites of the IGF-II/MPR are not functionally equivalent.     

Identification of transmembrane domain residues determinant in the structure-function relationship of the human platelet-activating factor receptor by site-directed mutagenesis

Platelet-activating factor (PAF) is a potent phospholipid mediator that produces a wide range of biological responses. The PAF receptor is a member of the seven-transmembrane GTP-binding regulatory protein-coupled receptor superfamily. This receptor binds PAF with high affinity and couples to multiple signaling pathways, leading to physiological responses that can be inhibited by various structurally distinct PAF antagonists. We have used site-directed mutagenesis and functional expression studies to examine the role of the Phe97 and Phe98 residues located in the third transmembrane helix and Asn285 and Asp289 of the seventh transmembrane helix in ligand binding and activation of the human PAF receptor in transiently transfected COS-7 cells. The double mutant FFGG (Phe97 and Phe98 mutated into Gly residues) showed a 3-4-fold decrease in affinity for PAF, but not for the specific antagonist WEB2086, when compared with the wild-type (WT) receptor. The FFGG mutant receptor, however, displayed normal agonist activation, suggesting that these two adjacent Phe residues maintain the native PAF receptor conformation rather than interacting with the ligand. On the other hand, substitution of Ala for Asp289 increased the receptor affinity for PAF but abolished PAF-dependent inositol phosphate accumulation; it did not affect WEB2086 binding. Substitution of Asn for Asp289, however, resulted in a mutant receptor with normal binding and activation characteristics. When Asn285 was mutated to Ala, the resulting receptor was undistinguishable from the WT receptor. Surprisingly, substitution of Ile for Asn285 led to a loss of ligand binding despite normal cell surface expression levels of this mutant, as verified by flow cytometric analysis. Our data suggest that residues 285 and 289 are determinant in the structure and activation of the PAF receptor but not in direct ligand binding, as had been recently proposed in a PAF receptor molecular model.     

Intracellular retention of mutant gonadotropin receptors results in loss of hormone binding activity of the follitropin receptor but not of the lutropin/choriogonadotropin receptor

It has recently been reported that Asp 397 of the rat lutropin/ choriogonadotropin receptor (rLHR) may be involved in transducing the signal from hormone binding to the stimulation of cAMP production. We examined the analogous region in the rat follitropin receptor (rFSHR) by substituting the Asp at position 404 (D404) of the rFSHR with either Glu (D404E), Ala (D404A), or Lys (D404K). Both in intact 293 cells and in detergent-solubilized extracts of 293 cells transiently transfected with the rFSHR constructs, only the wild type rFSHR exhibited detectable binding activity. Although the D404-substituted rFSHR mutants were visible on Western blots, in contrast to the wild type rFSHR which is present on Western blots as both mature and immature forms, only a single band comigrating with immature receptor was observed for the mutants. Furthermore, these mutants were sensitive to endoglycosidase H (Endo H), thus indicating that the mutant receptor proteins were retained intracellularly in the endoplasmic reticulum. To test whether the lack of binding of the D404-substituted rFSHR mutants was due to a perturbation of a binding site or to the intracellular retention of the mutants, a truncated rFSHR(t637) mutant, containing a cytoplasmic truncation that should not directly affect FSH binding, was examined. As with the D404-substitution mutants, rFSHR(t637) was stably expressed but sensitive to Endo H. Significantly, detergent-soluble extracts of cells expressing rFSHR(t637) were unable to bind FSH. From these results, we conclude that substitution of D404 of the rFSHR prevents hormone binding as a result of the intracellular retention of the mutants in the endoplasmic reticulum presumably in an incompletely folded state, as opposed to disruption of a hormone-binding site at D404. Comparable rLHR substitution (D397K) and truncation (t616) mutants were constructed and used to transfect 293 cells. For both rLHR(D397K) and rLHR(t616), human CG (hCG) binding to intact cells was not detectable, but high affinity hCG binding was observed in detergent-soluble extracts of the cells. Therefore, the rLHR differs from the rFSHR in that mutants of the rLHR that are retained in the endoplasmic reticulum have already been folded correctly and can bind hCG with high affinity as long as a hormone-binding site has not been perturbed by the mutation. In contrast, mutants of the rFSHR that are retained in the endoplasmic reticulum have not yet folded into a conformation that can bind hormone. This suggests a difference in the temporal pattern of folding between the two structurally related gonadotropin receptors. Our studies also demonstrate how mutagenesis studies of the rFSHR must be interpreted with caution, as FSHR mutants that are expressed but are retained intracellularly will most likely not be able to bind FSH even when a hormone-binding site has not been altered.     

Mediation of cyclic AMP signaling by the first intracellular loop of the gonadotropin-releasing hormone receptor

The gonadotropin-releasing hormone (GnRH) receptor, which is a unique G protein-coupled receptor without a C-terminal cytoplasmic domain, activates both inositol phosphate (InsP) and cAMP signaling responses. The function of the highly basic first intracellular (1i) loop of the GnRH receptor in signal transduction was evaluated by mutating selected residues located in its N and C termini. Replacements of Leu58, Lys59, Gln61, and Lys62 at the N terminus, and Leu73, Ser74, and Leu80 at the C terminus, caused no change in binding affinity. The agonist-induced InsP and cAMP responses of the Q61E and K59Q,K62Q receptors were also unaffected, but the L58A receptor showed a normal InsP response and an 80% decrease in cAMP production. At the C terminus, the InsP response of the L73R receptor was normal, but cAMP production was reduced by 80%. The EC50 for GnRH-induced InsP responses of the S74E and L80A receptors was increased by about one order of magnitude, and the cAMP responses were essentially abolished. These findings indicate that cAMP signaling from the GnRH receptor is dependent on specific residues in the 1i loop that are not essential for activation of the phosphoinositide signaling pathway.     

A hydrophobic cluster between transmembrane helices 5 and 6 constrains the thyrotropin-releasing hormone receptor in an inactive conformation

We have studied the role of a highly conserved tryptophan and other aromatic residues of the thyrotropin-releasing hormone (TRH) receptor (TRH-R) that are predicted by computer modeling to form a hydrophobic cluster between transmembrane helix (TM)5 and TM6. The affinity of a mutant TRH-R, in which Trp279 was substituted by alanine (W279A TRH-R), for most tested agonists was higher than that of wild-type (WT) TRH-R, whereas its affinity for inverse agonists was diminished, suggesting that W279A TRH-R is constitutively active. We found that W279A TRH-R exhibited 3.9-fold more signaling activity than WT TRH-R in the absence of agonist. This increased basal activity was inhibited by the inverse agonist midazolam, confirming that the mutant receptor is constitutively active. Computer-simulated models of the unoccupied WT TRH-R, the TRH-occupied WT TRH-R, and various TRH-R mutants predict that a hydrophobic cluster of residues, including Trp279 (TM6), Tyr282, and Phe199 (TM5), constrains the receptor in an inactive conformation. In support of this model, we found that substitution of Phe199 by alanine or of Tyr282 by alanine or phenylalanine, but not of Tyr200 (by alanine or phenylalanine), resulted in a constitutively active receptor. We propose that a hydrophobic cluster including residues in TM5 and TM6 constrains the TRH-R in an inactive conformation via interhelical interactions. Disruption of these constraints by TRH binding or by mutation leads to changes in the relative positions of TM5 and TM6 and to the formation of an active form of TRH-R.     

Site-directed mutagenesis of the human A1 adenosine receptor: influences of acidic and hydroxy residues in the first four transmembrane domains on ligand binding

To provide new insights into ligand/A1 adenosine receptor (A1 AR) interactions, site-directed mutagenesis was used to test the role of several residues in the first four transmembrane (TM) domains of the human A1 AR. Based on multiple sequence analysis of all known ARs, both acidic (glutamic acid and aspartic acid) and polar hydroxy (serine and threonine) amino acids were identified that could potentially play a role in binding adenosine. Glu16 (TM1), Asp55 (TM2), Ser93 and Ser94 (TM3), Ser135 (TM4), and Thr 141 (TM4) were identified in all ARs, and Ser6 and Ser23 (TM1) were identified in all A1 ARs. To test the role of these residues, each was individually mutated to alanine. When Ala6, Ala23, Ala50, Ala93, Ala135, and Ala141 constructs were tested, affinities for [3H]2-chloro-N6-cyclopentyladenosine (CCPA) and [3H]1,3-dipropyl-8-cyclopentylxanthine (DPCPX) were similar to those seen for the wild-type receptor. After conversion of Glu16 to Ala16, the affinity for [3H]CCPA and other agonists fell 10-100-fold, whereas the affinity for [3H]DPCPX and other antagonists was not affected. After conversion of Asp55 to Ala55, the affinity for [3H]CCPA and other agonists increased < or = 100-fold, whereas the affinity for [3H]DPCPX and other antagonists was not affected. Studies of the Ala55 construct also revealed that Asp55 is responsible for allosteric regulation of binding by sodium because the affinity for [3H]CCPA did not change over broad ranges of sodium concentrations. When Ser94 was converted to Ala94, A1 AR immunoreactivity was present on stable cell lines; however, functional binding sites could not be detected. When Ser94 was converted to Thr94, the affinity for some xanthine antagonists fell. These data show that Glu16 in TM1 and Asp55 in TM2 play important roles in agonist/A1 AR interactions and show that Asp55 is responsible for allosteric regulation of ligand/A1 AR binding by sodium. We also identify Ser94 as an important site for ligand binding.     

Identification of binding domains of the growth hormone-releasing hormone receptor by analysis of mutant and chimeric receptor proteins

The hypothalamic peptide GH-releasing hormone (GHRH) stimulates the release of GH from the pituitary through binding and activation of the GHRH receptor, which belongs to the family of G protein-coupled receptors. The objective of this study was to identify regions of the receptor critical for interaction with the ligand by expressing and analyzing truncated and chimeric epitope-tagged GHRH receptors. Two truncated receptors, GHRHdeltaN, in which part of the N-terminal domain between the putative signal sequence and the first transmembrane domain was deleted, and GHRHdeltaC, which was truncated downstream of the first intracellular loop, were generated. Both the receptors were deficient in ligand binding, indicating that neither the N-terminal extracellular domain (N terminus) nor the membrane-spanning domains with the associated extracellular loops (C terminus) are alone sufficient for interaction with GHRH. In subsequent studies, chimeric proteins between the receptors for GHRH and vasoactive intestinal peptide (VIP) or secretin were generated, using the predicted start of the first transmembrane domain as the junction for the exchange of the N terminus between receptors. The chimeras having the N terminus of the GHRH receptor and the C terminus of either the VIP or secretin receptor (GNVC and GNSC) did not bind GHRH or activate adenylate cyclase after GHRH treatment. The reciprocal chimeras having the N terminus of either the VIP or secretin receptors and the C terminus of the GHRH receptor (VNGC and SNGC) bound GHRH and stimulated cAMP accumulation after GHRH treatment. These results suggest that although the N-terminal extracellular domain is essential for ligand binding, the transmembrane domains and associated extracellular loop regions of the GHRH receptor provide critical information necessary for specific interaction with GHRH.     

High potency antagonists of the pancreatic glucagon-like peptide-1 receptor

GLP-1-(7-36)-amide and exendin-4-(1-39) are glucagon-like peptide-1 (GLP-1) receptor agonists, whereas exendin-(9-39) is the only known antagonist. To analyze the transition from agonist to antagonist and to identify the amino acid residues involved in ligand activation of the GLP-1 receptor, we used exendin analogs with successive N-terminal truncations. Chinese hamster ovary cells stably transfected with the rat GLP-1 receptor were assayed for changes in intracellular cAMP caused by the test peptides in the absence or presence of half-maximal stimulatory doses of GLP-1. N-terminal truncation of a single amino acid reduced the agonist activity of the exendin peptide, whereas N-terminal truncation of 3-7 amino acids produced antagonists that were 4-10-fold more potent than exendin-(9-39). N-terminal truncation of GLP-1 by 2 amino acids resulted in weak agonist activity, but an 8-amino acid N-terminal truncation inactivated the peptide. Binding studies performed using 125I-labeled GLP-1 confirmed that all bioactive peptides specifically displaced tracer with high potency. In a set of exendin/GLP-1 chimeric peptides, substitution of GLP-1 sequences into exendin-(3-39) produced loss of antagonist activity with conversion to a weak agonist. The results show that receptor binding and activation occur in separate domains of exendin, but they are more closely coupled in GLP-1.     

Amino acid residues in third intracellular loop of melanocortin 1 receptor are involved in G-protein coupling

To delineate domains essential for G-protein coupling in melanocortin 1 receptor (MC1R), we mutated polar and basic residues to alanine at eleven positions in the putative third intracellular loop and determined consequent changes in the ligand binding and generation of second messenger cAMP. Results demonstrate that ligand binding affinity was not affected by any of the mutations. However, every mutant displayed reduced functional response as compared to the wild type receptor. Replacement of residues (K226, R227, Q228, R229, H232, Q233 and K238) present in second half of third intracellular loop resulted in an almost complete loss of functional response. The results have demonstrated that the amino acid residues present in C-terminal portion of third intracellular loop of MC1R are involved in coupling to G-protein and that a region of four amino acids, K226-R227-Q228-R229 is essential for coupling of MC1R to G-protein.     

Separate agonist and peptide antagonist binding sites of the oxytocin receptor defined by their transfer into the V2 vasopressin receptor

The neurohypophyseal nonapeptide oxytocin (OT) is the main hormone responsible for the initiation of labor; uterus contraction can be enhanced by application of oxytocin or suppressed by oxytocin antagonists. By transfer of domains from the G protein-coupled OT receptor into the related V2 vasopressin receptor, chimeric "gain in function" V2/OT receptors were produced that were able to bind either OT receptor agonists or a competitive peptide antagonist with high affinity. The binding site for the OT antagonist d(CH2)5[Tyr(Me)2,Thr4,Orn8,Tyr9]vasotocin was found to be formed by transmembrane helices 1, 2, and 7 with a major contribution to binding affinity by the upper part of helix 7. These transmembrane receptor regions could be excluded from participating in OT binding. For agonist binding and selectivity the first three extracellular receptor domains were most important. The interaction of the N-terminal domain and of the first extracellular loop of the OT receptor with the linear C-terminal tripeptidic part of oxytocin was demonstrated. Furthermore, the second extracellular loop of the OT receptor could be identified to interact with the cyclic hormone part. These three domains contribute to OT binding by synergistic interaction with oxytocin but not with the competitive antagonist. Our results provide evidence for the existence of separate domains and different conformations of a peptide hormone receptor involved in binding and selectivity for agonists and peptide antagonists.     

Roles of transmembrane prolines and proline-induced kinks of the lutropin/choriogonadotropin receptor

The lutropin/choriogonadotropin receptor is a seven-helix transmembrane (TM) receptor. A unique feature of TM helices is the content of Pro, which generally is absent in alpha helices of globular proteins. Because Pro disrupts helices and introduces a approximately 26 degrees kink, it has been speculated that Pro plays a crucial role in the structure of TM helices, exoloops, and cytoloops of TM receptors. To examine the roles of the five TM Pros of the lutropin/choriogonadotropin receptor, these residues were individually substituted. Mutant receptors were examined for surface expression, hormone binding, and cAMP induction. Surface expression was monitored after introducing the flag epitope into the receptors. Flag epitopes slightly affected cAMP induction but not hormone binding or surface expression of receptors as monitored by immunofluorescence microscopy and 125I-anti-flag antibody. The results indicate that Pro479 in TM 4 and Pro598 in TM 7 play important yet contrasting roles. Pro479 is crucial for hormone binding at the cell surface but not after solubilization of the receptor. This is more likely due to the Pro side chain than the Pro-induced kink. Pro598 is important for surface expression. The kinks of Pro463 of TM 4, Pro562 of TM 6, or Pro591 of TM 7 are not important because the substitution of Phe for these residues did not significantly impact surface expression, hormone binding, and cAMP induction.     

The unique nature of the serine interactions for alpha 1-adrenergic receptor agonist binding and activation

Activation of the beta2- and alpha2-adrenergic receptors (AR) involves hydrogen bonding of serine residues in the fifth transmembrane segment (TMV) to the catechol hydroxyls of the endogenous agonists, epinephrine and norepinephrine. With the beta2-AR both Ser204 and Ser207 but not a third TMV serine (Ser203) are required for binding and full agonist activity. However, with the alpha2a-AR only one of two TMV serines (Ser204, equivalent to Ser207 in the beta-AR) appears to contribute partially to agonist-binding and activation. Because the alpha1a-AR uniquely contains only two TMV serines, this subtype was used to systematically evaluate the role of hydrogen bonding in alpha1-AR activation. Binding of epinephrine or its monohydroxyl congeners, phenylephrine and synephrine, was not decreased when tested with alanine- substitution mutants that lacked either Ser188 (Ser188--> Ala) or Ser192 (Ser192-->Ala). With the substitution of both serines in the double mutant, Ser188/192-->Ala, binding of all three ligands was significantly reduced (10- 100-fold) consistent with a single hydrogen bond interaction. However, receptor-mediated inositol phosphate production was markedly attenuated only with the Ser188-->Ala mutation and not with Ser192-->Ala. In support of the importance of Ser188, binding of phenylephrine (meta-hydroxyl only) by Ser192-->Ala increased 7-fold over that observed with either the wild type receptor or the Ser188-->Ala mutation. Binding of synephrine (para-hydroxyl only) was unchanged with the Ser192-->Ala mutation. In addition, when combined with a recently described constitutively active alpha1a-AR mutation (Met292-->Leu), only the Ser188-->Ala mutation and not Ser192-->Ala relieved the high affinity binding and increased agonist potency observed with the Met292-->Leu mutation. A simple interpretation of these findings is that the meta-hydroxyl of the endogenous agonists preferentially binds to Ser188, and it is this hydrogen bond interaction, and not that between the para-hydroxyl and Ser192, that allows receptor activation. Furthermore, since Ser188 and Ser192 are separated by three residues on the TMV alpha-helix, whereas Ser204 and Ser207 of the beta2-AR are separated by only two residues, the orientation of the catechol ring in the alpha1-AR binding pocket appears to be unique and rotated approximately 120 degrees to that in the beta2-AR.     

Indirect mitogenic effect of transforming growth factor-beta on cell proliferation of subconjunctival fibroblasts

Single amino acid replacement analogs of Manduca adipokinetic hormone (M-AKH) pGlu-Leu-Thr-Phe-Thr-Ser-Ser-Trp-GlyNH2 were tested for activity in bioassays as well as receptor binding assays. Amino acids were replaced by Ala and by D-analogs. In addition an extended M-AKH and analogs containing photo affinity labels were tested. All analogs had reduced activity. All the peptides which had enough activity to allow a full dose response curve reached the same maximal activity as native M-AKH. The use of analogs, in which L-Phe4 was replaced by Ala or by D-Phe and of L-Thr3 replaced by D-Thr, as competitors led to improved binding of M-AKH in our competitive receptor binding assay. In the bioassay an inactive concentration of Ala4 M-AKH increased the activity of a half optimal concentration of native M-AKH.     

Differential effects of integrin alpha chain mutations on invasin and natural ligand interaction

To determine if recognition of the Yersinia pseudotuberculosis invasin protein and natural substrates requires identical integrin residues, a region of the human alpha3 integrin chain predicted to be involved in substrate adhesion was targeted for mutation. One point mutation located in a region of the third N-terminal repeat of the alpha3 chain, alpha3-W220A, failed to promote adhesion to the natural alpha3 beta1 substrate epiligrin but maintained near wild type levels of adhesion to invasin. A second nearby mutation, alpha3-Y218A, which showed no detectable adhesion to epiligrin, was only partially attenuated for invasin binding as well as invasin-mediated bacterial uptake. A third substitution, alpha3-D154A, predicted to be in the second N-terminal repeat not known to be implicated in cell adhesion, was competent for invasin-promoted adhesion events and appeared to encode a receptor of increased activity, as it had a higher efficiency than wild type receptor for adhesion to epiligrin. Cell lines expressing this derivative were not recognized by a function blocking anti-alpha3 antibody, indicating that the second and third repeats of the alpha3 chain are either closely linked in space or the second repeat can modulate activity of the third. Differential effects on substrate adhesion do not appear to be associated with all integrin alpha chain mutations, as alpha4 chain mutations affecting the divalent cation binding domains depressed adhesion to invasin to a significant extent.     

The regulation of the binding affinity of the luteinizing hormone/choriogonadotropin receptor by sodium ions is mediated by a highly conserved aspartate located in the second transmembrane domain of G protein-coupled receptors

Sequence alignment shows that there is a highly conserved aspartate in the second transmembrane helix of virtually all G protein-coupled receptors. A previous study on the alpha 2-adrenergic receptor demonstrated that substitution of this acidic residue for the corresponding amide slightly decreases the affinity of the receptor for agonists and completely abolishes the effect of Na+ on the affinity for agonists. Since we have previously shown that Na+ modulates the binding affinity of the LH/CG receptor for ovine LH (oLH) [but not for human CG (hCG)], the experiments described here were designed to determine if the corresponding residue (D383) of the rat LH/CG receptor also mediates this Na+ effect. We used site-directed mutagenesis to create an LH/CG receptor mutant in which D383 was substituted by N. The wild type and mutant receptor [designated rLHR(D383N)] were expressed in human embryonic kidney 293 cells, and the transfected cells were tested for their ability to bind hCG and oLH in medium containing Na+ or an isoosmolar concentration of an appropriate sodium substitute. The results presented here show that this single point mutation of the LH/CG receptor leads to a slight reduction in affinity for hCG and oLH but completely abolishes the effects of Na+ removal on the affinity for oLH. Thus, regardless of the presence or absence of Na+, cells expressing rLHR(D383N) bind oLH with a low affinity comparable to that of the wild type receptor assayed in the presence of Na+. We also measured the ability of hCG and oLH to increase cAMP accumulation in cells expressing the wild type and mutant receptors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Residues in the membrane-spanning and extracellular loop regions of the parathyroid hormone (PTH)-2 receptor determine signaling selectivity for PTH and PTH-related peptide

The parathyroid hormone (PTH)-2 receptor displays strong ligand selectivity in that it responds fully to PTH but not at all to PTH-related peptide (PTHrP). In contrast, the PTH-1 receptor (PTH/PTHrP receptor) responds fully to both ligands. Previously it was shown that two divergent residues in PTH and PTHrP account for PTH-2 receptor selectivity; position 23 (Trp in PTH and Phe in PTHrP) determines binding selectivity and position 5 (Ile in PTH and His in PTHrP) determines signaling selectivity. To identify sites in the PTH-2 receptor involved in discriminating between His5 and Ile5, we constructed PTH-2 receptor/PTH-1 receptor chimeras, expressed them in COS-7 cells, and tested for cAMP responsiveness to [Trp23] PTHrP-(1-36), and to the nondiscriminating peptide [Ile5, Trp23]PTHrP-(1-36) (the Phe23 --> Trp modification enabled high affinity binding of each ligand to the PTH-2 receptor). The chimeras revealed that the membrane-spanning/loop region of the receptor determined His5/Ile5 signaling selectivity. Subsequent analysis of smaller cassette substitutions and then individual point mutations led to the identification of two single residues that function as major determinants of residue 5 signaling selectivity. These residues, Ile244 at the extracellular end of transmembrane helix 3, and Tyr318 at the COOH-terminal portion of extracellular loop 2, are replaced by Leu and Ile in the PTH-1 receptor, respectively. The results thus indicate a functional interaction between two residues in the core region of the PTH-2 receptor and residue 5 of the ligand.