The human thyrotropin receptor activates G-proteins Gs and Gq/11

Dual coupling and down regulation of human FSH receptor in CHO cells

The FSH receptor is a member of the family of G protein-coupled receptors that activate adenylyl cyclase. The binding of agonist to cell surface receptors leads to a reduction in the intensity of the response to continuous stimulation, a process that is usually referred to as desensitization. Although the exact mechanism is not fully understood, the molecular cloning of the FSH receptor has made it possible to study desensitization in transfected cell lines. In this experiment FSH-induced desensitization was studied using Chinese hamster ovary cells expressing a functional human FSH receptor (CHO-FSHR cells). Stimulation of the CHO-FSHR cells with 10 ng/ml human FSH resulted in a decreased sensitivity to a second FSH stimulation. This decrease in FSH-induced cAMP production was observed within 2 h, and exposure of cells to FSH for 20 h led to a 70-80 % inhibition of cAMP formation. Moreover, the desensitization effect observed in CHO cells was mimicked by forskolin and, therefore, was mediated by cAMP. Incubation of cells with 125I-FSH showed an efficient internalization of the ligand in the CHO-FSHR cells. The CHO-FSHR cells rapidly internalized approximately 30% of the receptor-associated 125I-FSH by 2 h and 50% by 4 h. The responsiveness of individual CHO-FSHR cells to FSH was studied and administration of human FSH (30 ng/ml) induced a rapid rise in cytosolic calcium, reaching a peak at 6 sec. The data that human FSH can increase intracellular calcium in cells transfected with the FSH receptor cDNA reveal the possibility for the human FSH receptor to couple to both adenylyl cyclase and phospholipase C cascades.

Functional and structural complexity of signal transduction via G-protein-coupled receptors

A prerequisite for the maintenance of homeostasis in a living organism is fine-tuned communication between different cells. The majority of extracellular signaling molecules, such as hormones and neurotransmitters, interact with a three-protein transmembrane signaling system consisting of a receptor, a G protein, and an effector. These single components interact sequentially and reversibly. Considering that hundreds of G-protein-coupled receptors interact with a limited repertoire of G proteins, the question of coupling specificity is worth considering. G-protein-mediated signal transduction is a complex signaling network with diverging and converging transduction steps at each coupling interface. The recent realization that classical signaling pathways are intimately intertwined with growth-factor-signaling cascades adds another level of complexity. Elaborate studies have significantly enhanced our knowledge of the functional anatomy of G-protein-coupled receptors, and the concept has emerged that receptor function can be modulated with high specificity by coexpressed receptor fragments. These results may have significant clinical impact in the future.

Pituitary adenylate cyclase-activating polypeptides, PACAP-38 and PACAP-27, regulation of sympathetic neuron catecholamine, and neuropeptide Y expression through activation of type I PACAP/VIP receptor isoforms

The current studies have implicated a prominent role for PACAP peptides in modulating the physiological function of cells derived from the sympathoadrenal lineage. Compared to VIP, both PACAP-27 and PACAP-38 demonstrated potent, efficacious, and sustained stimulatory effects on sympathetic neuronal NPY and catecholamine production. The differential effects of PACAP peptides on SCG NPY and catecholamine content and secretion coincided with previous studies that activated directly the sympathetic intracellular cyclic AMP-protein kinase A signaling pathway. These effects appear to be mediated primarily by PACAP1 receptor splice variants coupled to both adenylyl cyclase and phospholipase C in SCG neurons. The actions of PACAP peptides in the SCG shared many parallels with adrenal medullary chromaffin cells, suggesting diverse roles for the PACAP peptidergic system in sympathoadrenal cell development and function. Rather than solutions, these results pose additional questions for the future. What are the endogenous sources of PACAP that regulate sympathetic and adrenal function? Do PACAP peptides, like VIP, have dual roles and also act as sympathetic postganglionic neuromodulators? Are VIP/PACAP receptors expressed during SCG development? What regulates sympathetic PACAP1 receptor isoform expression and how are they differentially coupled to neuronal intracellular signaling cascades? What defines the tissue-specific responses to PACAP-27 and PACAP-38? While many of these questions are not easily approached, future studies of these issues will certainly illuminate the function of PACAP and PACAP receptors in the nervous and endocrine systems.

Tyrosine phosphorylation of GSalpha and inhibition of bradykinin-induced activation of the cyclic AMP pathway in A431 cells by epidermal growth factor receptor

An increasing amount of experimental data suggest that cross-talk exists between pathways involving tyrosine kinases and heterotrimeric G proteins. In a previous study, we demonstrated that bradykinin (BK) increases the intracellular accumulation of cAMP in the human epidermoid carcinoma cell line A431 by stimulating adenylate cyclase activity via a stimulatory G protein (Gsalpha) (Liebmann, C., Graness, A., Ludwig, B., Adomeit, A., Boehmer, A., Boehmer, F.-D., Nürnberg, B., and Wetzker, R. (1996) Biochem. J. 313, 109-118). Here, we present several lines of evidence indicating the ability of epidermal growth factor (EGF) to suppress BK-induced activation of the cAMP pathway in A431 cells via tyrosine phosphorylation of Gsalpha. Gsalpha was specifically immunoprecipitated from A431 cells using the anti-alphas antiserum AS 348. Tyrosine phosphorylation of Gsalpha was detectable in EGF-pretreated cells with monoclonal anti-phosphotyrosine antibodies. Additionally, A431 cells were labeled with [32P]orthophosphate in vivo and treated with EGF, and the resolved immunoprecipitates were subjected to amino acid analysis. The results clearly indicate that EGF induces tyrosine phosphorylation of Gsalpha in A431 cells. Treatment of A431 cells with EGF decreased BK-induced cAMP accumulation in intact cells as well as the stimulation of adenylate cyclase by BK, NaF, and guanyl nucleotides, but not by forskolin. Also, EGF treatment abolished both the BK- and isoprenaline-induced stimulation of guanosine 5'-O-(3-[35S]thiotriphosphate) binding to Gsalpha. In contrast, the BK-evoked, Gq-mediated stimulation of inositol phosphate formation in A431 cells was not affected by EGF pretreatment. Thus, EGF-induced tyrosine phosphorylation of Gsalpha is accompanied by a loss of its susceptibility to G protein-coupled receptors and its ability to stimulate adenylate cyclase via guanyl nucleotide exchange. We propose that Gsalpha may represent a key regulatory protein in the cross-talk between the signal transduction pathways of BK and EGF in A431 cells.

The luteinizing hormone/chorionic gonadotropin receptor has distinct transmembrane conductors for cAMP and inositol phosphate signals

The luteinizing hormone/chorionic gonadotropin receptor is a member of the seven-transmembrane receptor family. It is coupled, presumably via Gs and Gq, to two signal pathways involving adenylyl cyclase/cAMP and phospholipase C/inositol phosphate (IP). Little is known about the events prior to G-protein coupling: for example, whether these signals are generated from a single or multiple independent origins and mechanisms, when and where they diverge, and how they are transduced. We report novel observations that the cAMP signal and the IP signal originate and diverge upstream of G-protein coupling. The generation of these two signals independently involves Lys583 in exoloop 3 of the rat receptor. For this study, Lys583 of the receptor was substituted with a panel of amino acids, and mutant receptors were assayed for hormone binding and induction of cAMP, inositol monophosphate, inositol bisphosphate, and inositol trisphosphate. No substitutions for Lys583 were permissible for cAMP induction, despite successful surface expression and hormone binding. In contrast, several substitutions were permissible for IP induction. Our results suggest two distinct transmembrane signal conductors for cAMP and inositol phosphate signals and imply particular models of receptor activation not previously suggested.

Cloning and characterization of the signal transduction of four splice variants of the human pituitary adenylate cyclase activating polypeptide receptor. Evidence for dual coupling to adenylate cyclase and phospholipase C

Alternative splicing of two exons of the rat pituitary adenylate cyclase activating polypeptide (PACAP) receptor gene generates four major splice variants that are differentially expressed in specific tissues and variably coupled to intracellular second messengers. To evaluate the potential implications of these findings in human physiology, the human PACAP receptor gene was cloned. Alternative splicing about two exons of the gene allowed for four major splice variants that were subsequently identified on cDNA cloning. Each of the four splice variant cDNAs (null, SV-1, SV-2, and SV-3) was stably expressed in NIH/3T3 cells at similar receptor densities. For each splice variant, PACAP (both PACAP-38 and PACAP-27) had similar affinity and potency for stimulating either adenylate cyclase or phospholipase C. However, each receptor splice variant differed in their ligand-stimulated maximal response (efficacy) for total inositol phosphate accumulation with the SV-2 showing the greatest efficacy, followed by the null, SV-1, and SV-3 splice variants. Therefore, unlike the rat, PACAP binds and stimulates signal transduction with nearly equal affinity and potency for each of the receptor splice variants although with varying efficacy for the stimulation of phospholipase C. These results suggest a novel and potentially important mechanism for a single hormone to not only couple to dual signal transduction cascades but also elicit tissue-specific differential activation of phospholipase C in humans.

Involvement of Gs and Gi proteins in dual coupling of the luteinizing hormone receptor to adenylyl cyclase and phospholipase C

Binding of lutropin/choriogonadotropin to its cognate receptor results in the activation of adenylyl cyclase and phospholipase C. The mechanism underlying the generation of this bifurcating signal is presently not known. To analyze the coupling mechanism of the LH receptor, activated G proteins were labeled with [alpha-32P]GTP azidoanilide and identified by selective immunoprecipitation. In membranes of bovine corpora lutea and of L cells stably expressing the murine LH receptor (LHR cells), human chorionic gonadotropin (hCG) led to incorporation of the label into alphas and alphai2. Stimulation of LHR cells or of L cells expressing the M5 muscarinic receptor (LM5 cells) with the respective agonist resulted in activation of phospholipase C in both cell lines. However, alphaq and alpha11 were only labeled upon stimulation of the M5 muscarinic receptor. Agonist-induced Ca2+ mobilization and inositol phosphate accumulation were partially sensitive to pertussis toxin, and the expression of the betagamma-stimulable phospholipase C isoforms beta2 and beta3 could be demonstrated in LHR cells. Overexpression of phospholipase C-beta2 led to increased hCG-stimulated inositol phosphate accumulation, and expression of a beta-ARK1 C-terminal polypeptide effectively suppressed hCG-mediated phosphatidylinositol hydrolysis. Thus, the LH receptor couples to both Gs and Gi, and betagamma-subunits released from either G protein contribute to the stimulation of phospholipase C-beta isoforms.

Clinical implications of genetic defects in G proteins. The molecular basis of McCune-Albright syndrome and Albright hereditary osteodystrophy

Inactivating and activating mutations in the gene encoding G alpha s (GNAS1) are known to be the basis for 2 well-described contrasting clinical disorders, Albright hereditary osteodystrophy (AHO) and McCune-Albright syndrome (MAS). AHO is an autosomal dominant disorder due to germline mutations in GNAS1 that decrease expression or function of G alpha s protein. Loss of G alpha s function leads to tissue resistance to multiple hormones whose receptors couple to G alpha s. By contrast, MAS results from postzygotic somatic mutations in GNAS1 that lead to enhanced function of G alpha s protein. Acquisition of the activating mutation early in life leads to a more generalized distribution of the mosaicism and is associated with the classic clinical triad of polyostotic fibrous dysplasia, endocrine hyperfunction, and café au lait skin lesions described in MAS. Acquisition of a similar activating mutation in GNAS1 later in life presumably accounts for the restricted distribution of the gsp oncogene, and is associated with the development of isolated lesions (for example, fibrous dysplasia, pituitary or thyroid tumors) without other manifestations of MAS. Tissues that are affected by loss of G alpha s function in AHO are also affected by gain of G alpha s function in MAS, thus identifying specific tissues in which the second messenger cAMP plays a dominant role in cell growth, proliferation, or function. Further investigations of the functions of G alpha s and other members of the GTPase binding protein family will provide more insight into the pathogenesis and clinical manifestations of human disease.

Gene usage and regulation of Gsα gene expression in thyroid cells

The TSH receptor is a G-protein-coupled seven transmembrane segment receptor. The interaction between TSH and its receptor mediates signal transduction by activating adenylyl cyclase through Gsα. There are four forms of Gsα (two short [45 kDa] and two large [52 kDa]), arising from alternative splicing of exon 3 of the Gsα gene. Gsα-1 and -2 contain exon 3, whereas exon 3 is spliced out in Gsα-3 and -4. The inclusion of a serine residue at the 3' splice junction of exon 3 distinguishes Gsα-2 and -4 from Gsα-1 and -3. The expression of different Gsα forms appears to be tissue-specific. In this study, we have examined the Gsα splice variants in 26 human thyroid tumor specimens and rat thyroid tissues as well as a rat FRTL-5 cell line. Furthermore, we have studied the regulation of the Gsα gene expression by TSH and cAMP in FRTL-5 cells. We found that Gsα-1 and -4 mRNA were present in both human and rat thyroid cells, although Gsα-4 was more abundant in human thyroid cells as compared to rat thyroid and FRTL-5 cells. The Gsα mRNA can be easily amplified by RT-PCR regardless of tumor type and stage, suggesting that Gsα gene expression in thyroid tumors may not be markedly affected by dedifferentiation of thyroid cells.Both TSH and 8-bromo-cAMP, a cAMP analog, can stimulate the Gsα gene expression in FRTL-5 cells with maximal effect by 6 h and 1 h, respectively. The addition of cycloheximide to the culture of FRTL-5 cells abolished the effect of bTSH, but not that of 8-bromo-cAMP, on the expression of the Gsα gene. Cellular cAMP measurements showed that bTSH-stimulated cAMP production was significantly reduced to the basal level after addition of cycloheximide. These results suggest that regulation of the Gsα gene expression by TSH is mediated by a cAMP-dependent process and requires new protein synthesis.

Specific activation of the thyrotropin receptor by trypsin

The identification of 16 different activating mutations in the TSH receptor, found in patients suffering from toxic autonomous adenomas or congenital hyperthyroidism, leads to the concept that this receptor is in a constrained conformation in its wild-type form. We used mild trypsin treatment of CHO-K1 cells or COS-7 cells, stably or transiently transfected with the human TSH receptor, respectively, and measured its consequences on the TSH receptor coupled cascades, i.e. cyclic AMP and inositol-phosphates accumulation. A 2-min, 0.01% trypsin treatment increased stably cyclic AMP but not inositol-phosphates formation. This was not observed after chymotrypsin, thrombin and endoproteinase glu C treatment. The TSH action on cyclic AMP was decreased by only 25%. The effect was also observed in cells expressing the dog TSH receptor. It was not observed in MSH receptor, LH receptor expressing or mock transfected cells (vector alone). It is therefore specific for the TSH receptor, for its action on the Gs/adenylate cyclase cascade, and for the proteolytic cleavage caused by trypsin. Using monoclonal (A. Johnstone and P. Shepherd, personal communication) and polyclonal antibodies directed against the extracellular domain of the TSH receptor, it was shown that treatment by trypsin removes or destroys a VFFEEQ epitope (residues 354-359) from the receptor. The effect mimics the action of TSH as it activates Gs alpha and enhances the action of forskolin. It is not reversible in 1 h. The results support the concept that activation of the receptor (by hormone, autoantibodies, mutations or mild proteolysis) might involve the relief of a built-in negative constrain. They suggest that the C-terminal portion of the large extracellular domain plays a role in the maintenance of this constrain.

Different single receptor domains determine the distinct G protein coupling profiles of members of the vasopressin receptor family

The vasopressin receptor family is unique among all classes of peptide receptors in that its individual members couple to different subsets of G proteins. The V1a vasopressin receptor, for example, is preferentially linked to G proteins of the Gq/11 class (biochemical response: stimulation of phosphatidylinositol hydrolysis), whereas the V2 vasopressin receptor is selectively coupled to Gs (biochemical response: stimulation of adenylyl cyclase). To elucidate the structural basis underlying this functional heterogeneity, we have systematically exchanged different intracellular domains between the V1a and V2 receptors. Transient expression of the resulting hybrid receptors in COS-7 cells showed that all mutant receptors containing V1a receptor sequence in the second intracellular loop were able to activate the phosphatidylinositol pathway with high efficiency. On the other hand, only those hybrid receptors containing V2 receptor sequence in the third intracellular loop were capable of efficiently stimulating cAMP production. These findings suggest that the differential G protein coupling profiles of individual members of a structurally closely related receptor subfamily can be determined by different single intracellular receptor domains.

Differential effects of NaCl concentration on the constitutive activity of the thyrotropin and the luteinizing hormone/chorionic gonadotropin receptors

The TSH receptor (TSHR) and the LH/CG receptor (LHR) are members of the family of G protein-coupled receptors. Recently, point mutations conferring constitutive activity to the TSHR and LHR have been observed as a cause of toxic adenoma and familial/sporadic male pseudo-precocious puberty, respectively. When evaluated by transfection in COS-7 cells the wild-type (wt) TSHR displays definite constitutive activity towards Gs-dependent adenylylcyclase stimulation, while available evidence shows that the LHR does not. In order to compare the constitutive activity of both receptors, we performed functional studies in COS-7 cells using different assay conditions. Human TSHR and LHR cDNAs subcloned in the expression vector pSVL were transiently expressed in COS-7 cells and cAMP production was determined following incubation in a medium containing physiological concentration of NaCl [isotonic (NaCl)] or in the same medium without NaCl [hypotonic (NaCl-)] or where NaCl was replaced by an isoosmolar concentration of sucrose [isotonic (sucrose)]. Cells transfected with the TSHR showed higher basal cAMP levels over cells transfected with pSVL in all conditions tested. The effect was stronger when cells were incubated in isotonic (sucrose) buffer. Cells expressing LHR exhibited a minimal increase of cAMP levels over cells transfected with pSVL in isotonic (NaCl) buffer; however, a marked increase in basal cAMP levels was observed when cells were assayed in hypotonic (NaCl-) or isotonic (sucrose) buffers. Varying the pH or incubation temperature was without effect on the results obtained with both receptors. Our data show that despite extensive sequence similarity, the LH and TSH receptors differ markedly in their basal activity. The differential sensitivity of both receptors to low NaCl concentrations, suggests that the unliganded TSH receptor is less constrained than its LH homolog and may be more susceptible to activation by a wide spectrum of mutations.

The TSH receptor and thyroid diseases

Recent advances in the understanding of the molecular biology of the TSH receptor have had a considerable impact on several aspects of thyroidology. The identification and functional characterization of mutations in the TSH receptor gene which constitutively activate the TSH receptor in the absence of its ligand provide an explanation for the molecular mechanism which is most likely responsible for the majority of the hyperfunctioning thyroid adenomas. Moreover, these constitutively activating mutations also cause a new form of familial hyperthyroidism: non-autoimmune autosomal dominant hyperthyroidism and also sporadic cases of congenital non-autoimmune hyperthyroidism. TSH receptor mutations which cause a reduced sensitivity to TSH have been identified as the cause of non-autoimmune congenital hypothyroidism. TSH receptor mRNA variants have been found in thyroid associated ophthalmopathy. If protein expression for these variants can be demonstrated, this finding could advance our understanding of thyroid associated ophthalmopathy. The ability to produce large quantities of TSH receptor protein in bacteria has led to the generation of more sophisticated assays for TSH receptor antibodies and enabled the generation of an animal model for thyroid autoimmunity.

Phosphoinositide-specific phospholipase C and mitogenic signaling

The importance of PLC activation in cell proliferation is evident from the fact that the hydrolysis of PtdIns(4,5)P2 is one of the early events that follow the interaction of many growth factors and mitogens with their respective receptors. However, the importance of PLC activation is not restricted to proliferation; it is one of the most common transmembrane signaling events elicited by receptors that regulate many other cellular processes, including differentiation, metabolism, secretion, contraction, and sensory perception. It is also clear that cell proliferation signaling does not always require PLC, as indicated by the fact that growth factors such as insulin and CSF-1 do not appear to elicit the hydrolysis of PtdIns(4,5)P2, even though the intracellular domains of their receptors carry a PTK domain and the receptors show topologies very similar to those of the PLC-activating growth factors PDGF, EGF, and FGF. The growth factor-dependent activation of PLC is initiated by the formation of a complex between the receptor PTK and PLC-gamma; the formation of this complex is mediated by a specific interaction between a tyrosine phosphate residue on the intracellular domain of PTK and the SH2 domain of PLC-gamma. The receptor PTK subsequently phosphorylates PLC-gamma, of which two distinct isozymes, PLC-gamma 1 and PLC-gamma 2, have been identified. Proliferation of T cells and B cells in response to the aggregation of their respective cell surface receptors is also accompanied by the activation of PLC-gamma isozymes at an early stage. Unlike growth factor receptors, the T cell and B cell receptors lack intrinsic PTK activity but associate with several non-receptor PTKs of the Src and Syk families. Although the specific kinases are not known, one or more of these enzymes phosphorylate and activate PLC-gamma 1 and PLC-gamma 2. Transduction of growth signals by G protein-coupled receptors such as those for thrombin or bombesin also requires PtdIns(4,5)P2 hydrolysis, which, in this instance, is mediated by PLC-beta isozymes. The PLC-beta subfamily consists of four distinct members: PLC-beta 1, PLC-beta 2, PLC-beta 3, and PLC-beta 4. Agonist interaction with specific G protein-coupled receptors causes the dissociation of Gq proteins into G alpha and G beta gamma subunits and the exchange of GDP bound to G alpha for GTP. The resulting GTP-bound G alpha subunit then activates PLC-beta isoforms by binding to the carboxyl-terminal region of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of deletion and truncation mutants of the rat glucagon receptor. Seven transmembrane segments are necessary for receptor transport to the plasma membrane and glucagon binding

Glucagon receptor mutants were characterized with the aim of elucidating minimal structural requirements for proper biosynthesis, ligand binding, and adenylyl cyclase coupling. One N-terminal deletion mutant and five truncation mutants with progressively shorter C termini were expressed in transiently transfected monkey kidney (COS-1) cells. Each truncation mutant was designed so that the truncated C-terminal tail would remain on the cytoplasmic surface of the receptor. In order to characterize the cellular location of the expressed receptor mutants, a highly specific, high affinity antipeptide antibody was prepared against the extracellular, N-terminal tail of the receptor. Immunoblot analysis and immunofluorescence microscopy showed that the presence of all seven putative transmembrane segments, but not not an intact N-terminal tail, was required for cell surface expression of the receptor. Membranes from cells expressing receptor mutants lacking a large portion of the N-terminal tail or any of the seven putative transmembrane segments failed to bind glucagon. Membranes from cells expressing the C-terminal tail truncation mutants, which retained all seven transmembrane segments, bound glucagon with affinities similar to that of the native receptor and activated cellular adenylyl cyclase in response to glucagon. These results indicate that all seven helices are necessary for the proper folding and processing of the glucagon receptor. Glycosylation is not required for the receptor to reach the cell surface, and it may not be required for ligand binding. However, the N-terminal extracellular portion of the receptor is required for ligand binding. Most of the distal C-terminal tail is not necessary for ligand binding, and the absence of the tail may increase slightly the receptor binding affinity for glucagon. The C-terminal tail is also not necessary for adenylyl cyclase coupling and therefore does not play a direct role in G protein (GS) activation by the glucagon receptor.

Selective coupling of prostaglandin E receptor EP3D to Gi and Gs through interaction of alpha-carboxylic acid of agonist and arginine residue of seventh transmembrane domain

Prostaglandin (PG) E receptor EP3D is coupled to both Gi and Gs. To examine the roles of the interaction of alpha-carboxylic acid of PGE2 and its putative binding site, the arginine residue in the seventh transmembrane domain of EP3D, in receptor-G protein coupling, we have mutated the arginine residue to the noncharged glutamine. PGE2 with a negatively charged alpha-carboxylic acid and sulprostone, an EP3 agonist with a noncharged modified alpha-carboxylic acid, inhibited the forskolin-stimulated adenylate cyclase activity via Gi activation in the EP3D receptor in the same concentration-dependent manner. In contrast, the adenylate cyclase stimulation via Gs activation by sulprostone was much lower than that by PGE2. On the other hand, both PGE2 and sulprostone showed potent Gi activity but failed to show Gs activity in the mutant receptor. EP3D receptor showed a high affinity binding for PGE2 in the form coupled to either Gi or Gs. Although the mutant receptor showed high affinity binding when coupled to Gi, it lost high affinity binding in the condition of Gs coupling. Furthermore, sulprostone bound to the Gi-coupled EP3D receptor with higher affinity than the Gs-coupled receptor. Among various EP3 agonists, alpha-carboxylic acid-unmodified agonists showed both Gi and Gs activities, but the modified agonists showed only Gi activity. These findings suggest that the interaction between the alpha-carboxylic acid of PGE2 and the arginine residue of the receptor regulates the selectivity of the G protein coupling.

Coupling of human D-1 dopamine receptors to different guanine nucleotide binding proteins. Evidence that D-1 dopamine receptors can couple to both Gs and G(o)

Coupling between D-1 dopamine receptors and G proteins in cell lines expressing human D-1 receptors and different G proteins was examined. Pertussis toxin (PTX) treatment of rat pituitary GH4C1 cells significantly reduced, but did not abolish, agonist high affinity binding sites of the D-1 dopamine receptor; in SK-N-MC neuroblastoma cells, PTX failed to have any effect on D-1 high affinity sites. Cholera toxin (CTX) treatment of GH4C1 cells reduced but did not abolish the high affinity sites of D-1 receptors, while in SK-N-MC cells, treatment with CTX abolished all the high affinity sites. Western blot analyses with specific antisera indicated that Gs alpha, Gi1 alpha, Gi3 alpha, and Gq alpha were expressed in both cell lines, while Gi2 alpha and G(o) alpha were expressed in GH4C1 but not SK-N-MC cells. Antisera NEI-805 (anti-Gs alpha) and 9072 (anti-G(o) alpha) immunoprecipitated 24 +/- 4.3 and 34.4 +/- 6.9%, respectively, of G protein-associated D-1 dopamine receptors. Antisera 3646 (anti-Gi1 alpha), 1521 (anti-Gi2 alpha), 1518 (anti-Gi3 alpha), and 0941 (anti-Gq alpha) failed to coimmunoprecipitate appreciable levels of soluble receptors. These data indicate that D-1 dopamine receptors are coupled to both Gs alpha and G(o) alpha but not to Gq alpha.

Stimulation of mitogen-activated protein kinase by thyrotropin in primary cultured human thyroid follicles

In the thyroid, thyrotropin (TSH) stimulates both growth and function, and stimulates the production of cAMP which reproduces most of the effects of TSH. Here, we report evidence that TSH stimulates the mitogen-activated protein (MAP) kinase cascade through a cAMP-independent pathway, in human thyroid. TSH stimulated MAP kinase activity (4-9-fold the basal level) measured in the cytosolic fractions of primary cultured thyroid follicles. Maximal activity was reached after 20 min and remained sustained for 1-3 h, TSH being as potent as EGF; EC50 was 1.5 nM TSH. Only a single isoform of MAP kinase (p42) was detected in the follicles. p42 was phosphorylated on tyrosine residues and showed a reduced electrophoretic mobility in follicles stimulated by TSH. All these effects on MAP kinase were decreased by preincubation of the follicles with human anti-TSH receptor antibodies. The stimulation of MAP kinase by TSH was neither blocked by pertussis toxin nor reproduced by forskolin, cholera toxin, or 8-bromo-cAMP. In conclusion, in human thyroid cells, in contrast with previous observations on dog thyroid cells, TSH stimulates strongly MAP kinase through a pertussis toxin-insensitive and cAMP-independent pathway.

Constitutive activation of cyclic AMP but not phosphatidylinositol signaling caused by four mutations in the 6th transmembrane helix of the human thyrotropin receptor

Four different somatic mutations (F631C, T632I, D633E, and D633Y) in the putative 6th transmembrane helix of the human thyrotropin receptor (TSHR) were recently described in hyperfunctioning thyroid adenomas [Porcellini et al. (1994) J. Clin. Endocrinol. Metab. 79, 657-661]. We transiently expressed these mutant receptors in Cos-7 cells and measured [125I]TSH binding, basal and TSH-stimulated cAMP production, and phosphatidylinositol hydrolysis. The concentration of receptors expressed at the cell surface was lower for the mutants than for the wild type (WT) TSHR. Compared to the WT, all four mutant receptors caused a marked increase in basal cAMP levels, but did not increase basal production of inositol phosphates. This suggests that autonomous thyroid function and adenoma formation may be related to constitutive activation of the cAMP pathway alone. A cluster of conserved residues at the base of the 6th transmembrane helix of the TSHR and other glycoprotein hormone receptors appears important for maintaining an inactive receptor conformation.