Genetics of ncHH: from a peculiar inheritance of a novel GNRHR mutation to a comprehensive review of the literature.

BACKGROUND: Normosmic congenital hypogonadotropic hypogonadism (ncHH) is caused by the deficient production, secretion, or action of gonadotropin-releasing hormone (GnRH). Its typical clinical manifestation is delayed puberty and azoospermia. Homozygous and compound heterozygous mutations in the GNRHR gene (4q13.2) are the most frequent genetic causes of ncHH. OBJECTIVES: (i) Characterization at the molecular level (genetic origin and functional effect) of a unique homozygous mutation (p.Gly99Glu) in a ncHH man; (ii) to provide a comprehensive catalog of GNRHR mutations with genotype-phenotype correlation and comparison of in vitro studies vs. in silico prediction tools. MATERIAL AND METHODS: A ncHH man and his parents, in whom we performed the following: (i) Sanger sequencing, qPCR of the GNRHR gene; (ii) chromosome 4 SNP array; and (iii) competition binding assay and inositol phosphate signaling assay. PubMed and Human Genome Mutation Database (HGMD) search for GNRHR mutations. Bioinformatic analysis of 55 reported variants. RESULTS: qPCR showed two GNRHR copies in the index case. SNP array revealed the inheritance of two homologous chromosomes 4 from the mother (maternal heterodisomy; hUPD) with two loss of heterozygosity regions, one of them containing the mutated gene (maternal isodisomy; iUPD). Functional studies for the p.Gly99Glu mutation demonstrated a right-shifted GnRH-stimulated signaling response. Bioinformatic tools show that commonly used in silico tools are poor predictors of the function of ncHH-associated GNRHR variants. DISCUSSION: Functional analysis of the p.Gly99Glu mutation is consistent with severely decreased GnRH binding affinity (a severe partial loss-of-function mutation). Complete LOF variants are associated with severe and severe/moderate phenotype, whereas partial LOF variants show wide range of clinical manifestations. CONCLUSION: This is the first ncHH patient carrying a novel causative missense mutation of GNRHR with proven 'severe pLOF' due to maternal hUPD/iUPD of chromosome 4. Our literature review shows that functional studies remain essential both for diagnostic and potential therapeutic purposes.

Role of aspartate7.32(302) of the human gonadotropin-releasing hormone receptor in stabilizing a high-affinity ligand conformation.

Mammalian gonadotropin-releasing hormone (GnRH) receptors preferentially bind mammalian GnRH, which has Arg in position eight. The Glu(7.32(301)) residue, which determines selectivity of the mouse GnRH receptor for Arg(8)-containing GnRH, is Asp(7.32(302)) in the human GnRH receptor. We have confirmed that Asp(7.32(302)) confers selectivity of the human GnRH receptor for Arg(8) of GnRH and investigated the mechanism of this specificity using site-directed mutagenesis and ligand modification. We find that although Arg(8) and Asp(7.32(302)) are required for high-affinity binding of GnRH, conformationally constrained peptides, with D-amino acid substitutions in position six or with a 6,7 gamma-lactam, bind the human GnRH receptor with high affinity, which is independent of the presence of Asp(7.32(302)) in the receptor or Arg(8) in the ligand. The ability of the ligand constraints to compensate for the absence of both Arg(8) and Asp(7.32(302)) indicates that these residues both have roles in stabilizing a high affinity ligand conformation and that their roles are complementary. This suggests that the Arg(8) and Asp(7.32(302)) side chains interact to induce a high affinity conformation of native GnRH. Thus, Asp(7.32(302)) of the human GnRH receptor determines selectivity for mammalian GnRH by its ability to induce a high affinity conformation of its native ligand. However, this initial interaction seems not to contribute to the final ligand-receptor complex. We propose that Arg(8) interacts transiently with Asp(7.32(302)) to induce a high-affinity ligand conformation of GnRH, which then interacts with a binding pocket that is common for both constrained and unconstrained analogs of GnRH.

Insertional mutagenesis of the arginine cage domain of the gonadotropin-releasing hormone receptor.

The pattern of side-chain conservation at the cytoplasmic side of the third transmembrane domain of rhodopsin family G protein-coupled receptors, Asp/Glu-Arg-Tyr/X-X-X-Ile/Val, defines a structural "arginine cage" domain. Previous computational and mutagenesis studies of the GnRH receptor indicated an important contribution of local interactions to the function of this domain. We have investigated the functional importance of the intrahelical position and orientation of the arginine cage using insertional mutagenesis. Introduction of a single Ala proximal to the conserved Asp-Arg of this domain caused loss of detectable ligand binding. Inserting a second Ala, however, restored high-affinity agonist binding. Further insertion of three or four Ala residues at this site generated receptors that bound agonist with an affinity 3- to 10-fold higher than that of the wild-type receptor. Loss of detectable coupling to inositol phosphate turnover in all these mutant receptors confirms that the structure required in this region for efficient signaling is highly constrained. In contrast, the recovery of agonist binding with the progressive insertion of two to four Ala residues indicates that specific orientations of this segment can stabilize high-affinity receptor conformations that are uncoupled from signal transduction.

A chicken gonadotropin-releasing hormone receptor that confers agonist activity to mammalian antagonists. Identification of D-Lys(6) in the ligand and extracellular loop two of the receptor as determinants.

Mammalian receptors for gonadotropin-releasing hormone (GnRH) have over 85% sequence homology and similar ligand selectivity. Biological studies indicated that the chicken GnRH receptor has a distinct pharmacology, and certain antagonists of mammalian GnRH receptors function as agonists. To explore the structural determinants of this, we have cloned a chicken pituitary GnRH receptor and demonstrated that it has marked differences in primary amino acid sequence (59% homology) and in its interactions with GnRH analogs. The chicken GnRH receptor had high affinity for mammalian GnRH (K(i) 4.1 +/- 1.2 nM), similar to the human receptor (K(i) 4.8 +/- 1.2 nM). But, in contrast to the human receptor, it also had high affinity for chicken GnRH ([Gln(8)]GnRH) and GnRH II ([His(5),Trp(7),Tyr(8)]GnRH) (K(i) 5.3 +/- 0.5 and 0.6 +/- 0.01 nM). Three mammalian receptor antagonists were also pure antagonists in the chicken GnRH receptor. Another three, characterized by D-Lys(6) or D-isopropyl-Lys(6) moieties, functioned as pure antagonists in the human receptor but were full or partial agonists in the chicken receptor. This suggests that the Lys side chain interacts with functional groups of the chicken GnRH receptor to stabilize it in the active conformation and that these groups are not available in the activated human GnRH receptor. Substitution of the human receptor extracellular loop two with the chicken extracellular loop two identified this domain as capable of conferring agonist activity to mammalian antagonists. Although functioning of antagonists as agonists has been shown to be species-dependent for several GPCRs, the dependence of this on an extracellular domain has not been described.

Multiple interactions of the Asp(2.61(98)) side chain of the gonadotropin-releasing hormone receptor contribute differentially to ligand interaction.

Mutation of Asp(2.61(98)) at the extracellular boundary of transmembrane helix 2 of the gonadotropin-releasing hormone (GnRH) receptor decreased the affinity for GnRH. Using site-directed mutagenesis, ligand modification, and computational modeling, different side chain interactions of Asp(2.61(98)) that contribute to high-affinity binding were investigated. The conservative Asp(2. 61(98))Glu mutation markedly decreased the affinity for a series of GnRH analogues containing the native His(2) residue. This mutant showed smaller decreases in affinity for His(2)-substituted ligands. The loss of preference for His(2)-containing ligands in the mutant receptor shows that Asp(2.61(98)) determines the specificity for His(2). Analysis of the affinities of a series of position 2-substituted ligands suggests that a hydrogen bond forms between Asp(2.61(98)) and the delta NH group of His(2) and that Asp(2. 61(98)) forms a second hydrogen bond with the ligand. Substitution of Asp(2.61(98)) with an uncharged residue further decreased the affinity for all ligands and also decreased receptor expression. Computational modeling indicates an intramolecular ionic interaction of Asp(2.61(98)) with Lys(3.32(121)) in transmembrane helix 3. The uncharged, Lys(3.32(121))Gln mutation also markedly decreased agonist affinity. The modeling and the similar phenotypes of mutants with uncharged substitutions for Asp(2.61(98)) or Lys(3.32(121)) are consistent with the presence of this helix 2-helix 3 interaction. These studies support a dual role for Asp(2.61(98)): formation of an interhelical interaction with Lys(3.32(121)) that contributes to the structure of the agonist binding pocket and an interaction with His(2) of GnRH that helps stabilize agonist complexing.

A new photoreactive antagonist cross-links to the N-terminal domain of the gonadotropin-releasing hormone receptor.

A new photoreactive gonadotropin-releasing hormone (GnRH) antagonist [Ac-(4-azidobenzoyl)-D-Lys1, D-4-Cl-Phe2, D-Trp3, D-Arg6, D-Ala10]GnRH (PAnt-1) was synthesized and shown to bind covalently to mouse and human GnRH receptors after ultraviolet irradiation. PAnt-1 exhibited high binding affinity (Ki = 3.1 +/- 0.8 nM), and high crosslinking efficiency as shown by loss of 78% of binding sites following crosslinking at saturating concentration. Crosslinking resulted in irreversible receptor blockade as shown by inhibition of GnRH-stimulated inositol phosphate production. PAnt-1 has a photoreactive group at residue 1 of the peptide, a region believed to be critical in determining antagonist versus agonist properties of GnRH analogues. The attachment site of PAnt- to the receptor was localized between residues 11 and 19 of the extracellular N-terminal domain of the receptor by peptide mapping studies using natural sequence differences between human, mouse and sheep GnRH receptors, as well as a panel of GnRH receptor constructs with a series of engineered protease cleavage sites. A disulphide bridge between Cys14 and Cys200 was cleaved during crosslinking, suggesting that Cys14 is the crosslinked residue. These results suggest that peptide GnRH antagonists bind to the receptor with the N-terminal end of the peptide positioned in a site comprising the constrained regions of the N-terminal domain and second extracellular loop in the vicinity of the Cys14-Cys200 disulphide bridge.

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.

Adolescents' explanations for political issues: concordance with their views of self and society.

The relationships between adolescents' explanations for unemployment, poverty, and homelessness and their beliefs about opportunity, reports of family values, and personal aspirations were tested for 434 teenagers (mean age = 16 years 4 months). Explanations were coded for references to individual causes, societal causes, or both. Higher maternal education and average household income in the adolescent's school district were positively related to the likelihood of attributing all three problems to societal causes. When explaining unemployment, older adolescents noted both causes, and boys mentioned individual factors whereas girls mentioned societal factors. After adjustment for background factors, those endorsing individual causes were more likely to believe that all Americans enjoyed equal opportunity and that government support encouraged dependency, and they were more committed to materialist goals. In contrast, youth endorsing societal or situational causes had more altruistic life goals and reported that compassion was emphasized in their families.

A single amino acid substitution in transmembrane helix VI results in overexpression of the human GnRH receptor.

OBJECTIVE: Construction of constitutively active mutants of the GnRH receptor, a member of the G-protein coupled receptor superfamily, would facilitate investigation of the mechanism of receptor activation. DESIGN: Point mutations were introduced in the human GnRH receptor in positions corresponding to those which caused constitutive activity in other G-protein coupled receptors. The effects of these mutations on ligand binding, receptor intracellular signaling and receptor expression were determined. METHODS: Wild type and mutated receptor cDNAs were expressed in COS-1 cells. Basal and agonist-stimulated inositol phosphate production and ligand binding were determined. In addition, receptor mRNA levels, cell surface receptor stability and rate of internalization were measured. RESULTS AND CONCLUSIONS: Although none of the mutant receptors exhibited constitutive activity, mutation of Phe-2 72 in transmembrane helix VI to Leu increased cell surface receptor numbers, with unchanged affinities for radiolabeled agonist, superagonist and antagonist peptides compared with wild type receptor. The cell surface receptor stability and rate of internalization were similar for wild type and F272L GnRH receptors. Thus a single amino acid mutation in transmembrane helix VI causes an increase in cell surface receptor numbers, which appears to result from an increased rate of receptor protein translation, processing or insertion into membranes.

A high affinity gonadotropin-releasing hormone (GnRH) tracer, radioiodinated at position 6, facilitates analysis of mutant GnRH receptors.

Cloning of GnRH receptors from several animal species has made it possible to investigate receptor function using site-directed mutagenesis. However, many mutant GnRH receptors exhibit decreased ligand binding, which makes analysis of their ligand binding characteristics technically difficult. To increase the affinity of binding to the GnRH receptor, a novel tracer ligand, 125I-[His5,D-Tyr6]GnRH, was designed and synthesized to allow radioiodination at position 6 rather than the usual position 5. In competition binding assays, total binding of 125I-[His5,D-Tyr6]GnRH was higher than binding of a conventional tracer ligand, 125I-[D-Ala6,N-MeLeu7,Pro9NHEt]GnRH. The bindable fractions and specific activities of both peptides were similar, and the receptor binding affinities of the unlabeled peptides were indistinguishable. However, comparison of the radiolabeled peptides in saturation binding assays showed that the affinity of the peptide, 125I-[His5,D-Tyr6]GnRH, (Kd, 0.19 nM), was approximately 2-fold higher than that of the conventional tracer. The increased binding of 125I-[His5,D-Tyr6] GnRH has allowed the development of a sensitive GnRH receptor binding assay for analysis of mutant GnRH receptors that exhibit decreased ligand binding.

Advances in understanding gonadotrophin-releasing hormone receptor structure and ligand interactions.

Gonadotrophin-releasing hormone (GnRH) is the central regulator of the reproductive system and its analogues are used widely in the treatment of diverse diseases. The GnRH receptor is a member of the large family of G-protein-coupled receptors (GPCRs) which have seven transmembrane domains. Knowledge of these receptors has assisted the development of molecular models of the GnRH receptor that allow prediction of its three-dimensional configuration and the way GnRH binds and activates its receptor. Comparison with other GPCRs led to the discovery that Lys121, in the third transmembrane domain, has a role in agonist binding. The history of GnRH structure-activity studies has allowed the identification of an acidic residue in the third extracellular loop of the receptor that is required for binding of mammalian GnRH, while synthetic GnRH analogues have showed that Asn102, in the second extracellular loop, may interact with the carboxy-terminus of GnRH. These residues can now be incorporated into the receptor models that are being used to design orally active non-peptide GnRH analogues for contraception and treatment of a variety of reproductive disorders.

Specific expression of the AGL1 MADS-box gene suggests regulatory functions in Arabidopsis gynoecium and ovule development.

Several members of the MADS-box gene family have been shown to be important regulators of flower development, controlling such well-studied early events as the formation of the floral meristem and the specification of floral organ identity. Other floral-specific MADS-box genes, of as yet unknown function, have been isolated by homology and are proposed to be part of a regulatory hierarchy controlling flower development. Some of these genes might regulate later aspects of flower development, such as development of individual floral organs, which is less well studied at the molecular level. This paper presents a detailed analysis of the expression pattern of one such gene from Arabidopsis, AGL1, using RNA in situ hybridization. It is found that AGL1 is specifically expressed in particular regions of the gynoecium and ovule, only during and after floral development stage 7. AGL1 expression at the tip of the growing carpel primordia, along the margins of the ovary valves in developing and mature gynoecia and in specific regions of developing and mature ovules provides important insights into the possible roles of AGL1. It is proposed that AGL1 may have regulatory functions in the structural definition and/or function of the valve margins, in axis maintenance during ovule development, in nutritional supply to the growing ovule and embryo sac, and in pollen tube guidance. In the floral homeotic mutants ag-1, ap3-3 and ap2-2, AGL1 mRNA is expressed in an organ-dependent manner, suggesting that AGL1 is a carpel-specific gene and as such ultimately depends upon the carpel identity gene AG for proper gene expression.

Asn102 of the gonadotropin-releasing hormone receptor is a critical determinant of potency for agonists containing C-terminal glycinamide.

We demonstrate a critical role for Asn102 of the human gonadotropin-releasing hormone (GnRH) receptor in the binding of GnRH. Mutation of Asn102, located at the top of the second transmembrane helix, to Ala resulted in a 225-fold loss of potency for GnRH. Eight GnRH analogs, all containing glycinamide C termini like GnRH, showed similar losses of potency between 95- and 750-fold for the [Ala102]GnRHR, compared with wild-type receptor. In contrast, four GnRH analogs that had ethylamide in place of the C-terminal glycinamide residue, showed much smaller decreases in potency between 2.4- and 11-fold. In comparisons of three agonist pairs, differing only at the C terminus, glycinamide derivatives showed an 11-20-fold greater loss of potency for the mutant receptor than their respective ethylamide derivatives. Thus Asn102 is a critical determinant of potency specifically for ligands with C-terminal glycinamide, while ligands with C-terminal ethylamide are less dependent on Asn102. These findings indicate a role for Asn102 in the docking of the glycinamide C terminus and are consistent with hydrogen bonding of the Asn102 side chain with the C-terminal amide moiety. Taken with previous data, they suggest a region of the GnRH receptor formed by the top of helices 2 and 7 as a binding pocket for the C-terminal part of the ligand.

Development of methods for purification of membrane associated gonadotropin-releasing hormone binding proteins.

Gonadotropin-releasing hormone (GnRH) is the primary regulator of mammalian reproduction. It stimulates the release of luteinizing hormone and follicle stimulating hormone via receptors on the cell membranes of pituitary gonadotrope cells. This paper describes the development of a protocol for purification of GnRH binding proteins from sheep pituitary membranes. Membranes were best solubilized using a zwitterionic detergent. Solubilized membranes were applied to an affinity column prepared with a GnRH analogue. The most effective analogue was the agonist [D-Lys6,Pro9-NHEt]-GnRH. The column was washed with a gradient of sodium chloride up to 0.4 M and GnRH binding activity was eluted from the column using the acidic buffer. Eluted fractions bound labelled GnRH agonist after neutralization of the buffer. Sodium dodecyl sulphate polyacrylamide gel electrophoresis analysis revealed a major protein band with a relative molecular weight of 67 kD. Amino acid sequence analysis showed that the protein is different from the cloned GnRH receptor, but homologous with a similar protein recently purified from bovine pituitary. This protein may have a function which is modulated by binding of GnRH, GnRH fragments or GnRH-related peptides.

Incorporation of an additional glycosylation site enhances expression of functional human gonadotropin-releasing hormone receptor.

Mutation ofN-glycosylation sites in the mouse gonadotropin-releasing hormone receptor was previously shown to impair its expression in COS-1 cells. We therefore investigated the effects of adding an extra glycosylation site to the human gonadotropin-releasing hormone receptor, as a means for increasing its expression. Covalent labeling of the mutant receptor expressed in COS-1 cells with a gonadotropin-releasing hormone (GnRH) photoreactive analog demonstrated a shift in apparent molecular weight, indicating that the new site was in fact glycosylated. The receptor with extra glycosylation site displayed normal binding affinities for agonists buserelin and [D: -Ala(6)-Pro(9)-NHEt]-GnRH, and the antagonist antide, and a slightly increased affinity for GnRH. Receptor number was increased by 1.7-fold in membrane preparations from cells expressing the mutant receptor, compared with wild-type. Photoaffinity labeling of cell-surface receptors in intact cells demonstrated a 1.8-fold increase in binding sites on the cell surface. The GnRH receptor (GnRHR) with extra glycosylation site conferred a markedly enhanced signaling response to agonist. Dose-response curves for GnRH-stimulated inositol phosphate production were left-shifted by an average of 4.4-fold, and maximal inositol phosphate responses were increased by 1.2 fold, in cells transfected with mutant compared with wild-type receptor, indicating that the increase in binding sites represented functional receptors. These results demonstrate that addition of an extra glycosylation site enhances expression of the human GnRHR, a strategy that may be applicable to other cell-surface receptors.

A locus of the gonadotropin-releasing hormone receptor that differentiates agonist and antagonist binding sites.

The decapeptide gonadotropin-releasing hormone controls reproductive function via interaction with a heptahelical G protein-coupled receptor. Because of molecular model of the receptor predicts that Lys121 in the third transmembrane helix contributes to the binding pocket, the function of this side chain was studied by site-directed mutagenesis. Substitution of Arg at this position preserved high affinity agonist binding, whereas Gln at this position reduced binding below the limits of detection. Leu and Asp at this locus abolished both binding and detectable signal transduction. The EC50 of concentration-response curves for coupling to phosphatidyl inositol hydrolysis obtained with the Gln121 receptor was more than 3 orders of magnitude higher than that obtained for the wild-type receptor. In order to determine whether the increased EC50 obtained with this mutant reflects an altered receptor affinity, the effect of decreases in wild-type receptor density on concentration-response curves was determined by irreversible antagonism. Progressively decreasing the concentration of the wild-type receptor increased the EC50 values obtained to a maximal level of 2.4 +/- 0.2 nM. Comparison of this value with the EC50 of 282 +/- 52 nM observed with the Gln121 receptor mutant indicates that the agonist affinity for this mutant is reduced more than 100-fold. In contrast, antagonist had comparable high affinities for the wild-type, Arg121, and Gln121 mutants. The results indicate that a charge-strengthened hydrogen bond donor is required at this locus for high affinity agonist binding but not for high affinity antagonist binding.

Agonist activity of mammalian gonadotropin-releasing antagonists in chicken gonadotropes reflects marked differences in vertebrate gonadotropin-releasing receptors.

The pharmacology of mammalian and avian gonadotropin-releasing (GnRH) receptors differs for agonist analogues. We have therefore compared the activities of mammalian-based GnRH antagonists in sheep and chicken gonadotropes to further elucidate the different structural requirements of the receptors. The antagonist activities of ten GnRH analogues were compared in cultured sheep and chicken pituitary cells by determining the dose required to cause a 50% inhibition of luteinizing hormone secretion (IC50) induced by GnRH at its half-maximal concentration (EC50). Nine analogues showed high antagonist activity in the sheep bioassay. Analogue IC50s varied between half and twice ((1.22-6.06) x 10(-10) M) the GnRH EC50 (3 x 10(-10) M). One of these peptides exhibited partial agonist activity. In contrast, eight of the analogues showed low antagonist activity in chicken pituitary cells, with IC50s varying from 46 to 1490 times ((1.4-44.7) x 10(-7) M) the GnRH EC50 (3 x 10(-9) M) and had a different order of potencies compared with that in the sheep. Furthermore, two analogues did not display antagonist activity at all in the chicken bioassay, but acted as pure agonists, stimulating LH secretion. These findings demonstrate marked differences in pharmacology between the avian and mammalian pituitary GnRH receptors and emphasize that GnRH antagonists, selected for their efficacy in mammals, cannot necessarily be used for physiological studies in non-mammalian vertebrates. The distinctly different pharmacology of the receptors and structural requirements of analogues for agonist/antagonist activity establish a basis for identifying receptor features involved in ligand-induced signal propagation using chimaeras of cloned sheep and chicken receptors.

Identification of N-glycosylation sites in the gonadotropin-releasing hormone receptor: role in receptor expression but not ligand binding.

The asparagine residues of the three N-glycosylation consensus sequences in the mouse gonadotropin-releasing hormone receptor were mutated to determine which residues were glycosylated and the function of glycosylation. Photoaffinity labelled Gln4 and Gln18 receptor mutants exhibited lower apparent molecular weight on SDS polyacrylamide gel electrophoresis, while the Gln102 receptor showed wildtype mobility. This indicates that the receptor is glycosylated at Asn4 and Asn18 but not at Asn102. Binding affinities of all the mutant receptors were normal, indicating that carbohydrate moieties are not involved in ligand binding interactions. However, expression of the Gln4 and Gln18 receptors were substantially decreased, indicating a role for glycosylation in receptor expression or stability. All the glycosylation site mutants were capable of normal signal transduction, as indicated by their ability to stimulate inositol phosphate production.

Spatially and temporally regulated expression of the MADS-box gene AGL2 in wild-type and mutant arabidopsis flowers.

AGL2 is one of several Arabidopsis floral MADS-box genes that were isolated based on sequence similarity to the homeotic gene AGAMOUS. To investigate its possible role in flower development, we have characterized in detail the expression pattern of AGL2 in both wild-type and mutant flowers using RNA in situ hybridization. We find that AGL2 is floral-specific; it is not expressed in the inflorescence meristem. Within the floral meristem, AGL2 is first expressed very early in development, after the floral meristem has emerged from the inflorescence meristem but before any of the organ primordia emerge. The AGL2 transcript is very abundant and uniform throughout the floral meristem and in the primordia of all four floral organs: sepals, petals, stamens and carpels. Thus, AGL2 represents a new class of MADS-box genes which is expressed in all four whorls of the flower. The AGL2 transcript remains abundant in each organ during morphological differentiation, but diminishes as each organ undergoes the final maturation phase of development. AGL2 expression is high in developing ovules and, after fertilization, in developing embryos and seed coats, abating as seeds mature. In the floral organ identity mutants ag-1, ap3-3 and ap2-2, the AGL2 expression pattern is organ- and stage-dependent. These results indicate that AGL2 may play a fundamental role in the development of all floral organs, and of seeds and embryos, and that AGL2 ultimately depends upon the organ identity genes for proper expression.

Glutamate 301 of the mouse gonadotropin-releasing hormone receptor confers specificity for arginine 8 of mammalian gonadotropin-releasing hormone.

The Arg residue at position 8 of mammalian GnRH is necessary for high affinity binding to mammalian GnRH receptors. This requirement has been postulated to derive from an electrostatic interaction of Arg8 with a negatively charged receptor residue. In order to identify such a residue, 8 conserved acidic residues of the mouse GnRH receptor were mutated to isosteric Asn or Gln. Mutant receptors were tested for decreased preference for Arg8-containing ligands by ligand binding and inositol phosphate production. One of the mutants, in which the Glu301 residue was mutated to Gln, exhibited a 56-fold decrease in apparent affinity for mammalian GnRH. The mutant receptor also exhibited decreased affinity for [Lys8]GnRH, but its affinity for [Gln8]GnRH was unchanged compared with the wild type receptor. The apparent affinity of the mutant receptor for the acidic analogue, [Glu8]GnRH, was increased more than 10-fold. The mutant receptor did not, therefore, distinguish mammalian GnRH from analogues with amino acid substitutions at position 8 as effectively as the wild type receptor. This loss of discrimination was specific for the residue at position 8, because the mutant receptor did distinguish mammalian GnRH from analogues with favorable substitutions at positions 5, 6, and 7. These findings show that Glu301 of the GnRH receptor plays a role in receptor recognition of Arg8 in the ligand and are consistent with an electrostatic interaction between these 2 residues.