Evidence that the thyroid-stimulating hormone (TSH) receptor transmembrane domain influences kinetics of TSH binding to the receptor ectodomain

Thyroid-stimulating hormone (TSH)-induced reduction in ligand binding affinity (negative cooperativity) requires TSH receptor (TSHR) homodimerization, the latter involving primarily the transmembrane domain (TMD) but with the extracellular domain (ECD) also contributing to this association. To test the role of the TMD in negative cooperativity, we studied the TSHR ECD tethered to the cell surface by a glycosylphosphatidylinositol (GPI) anchor that multimerizes despite the absence of the TMD. Using the infinite ligand dilution approach, we confirmed that TSH increased the rate of dissociation (k(off)) of prebound (125)I-TSH from CHO cells expressing the TSH holoreceptor. Such negative cooperativity did not occur with TSHR ECD-GPI-expressing cells. However, even in the absence of added TSH, (125)I-TSH dissociated much more rapidly from the TSHR ECD-GPI than from the TSH holoreceptor. This phenomenon, suggesting a lower TSH affinity for the former, was surprising because both the TSHR ECD and TSH holoreceptor contain the entire TSH-binding site, and the TSH binding affinities for both receptor forms should, theoretically, be identical. In ligand competition studies, we observed that the TSH binding affinity for the TSHR ECD-GPI was significantly lower than that for the TSH holoreceptor. Further evidence for a difference in ligand binding kinetics for the TSH holoreceptor and TSHR ECD-GPI was obtained upon comparison of the TSH K(d) values for these two receptor forms at 4 °C versus room temperature. Our data provide the first evidence that the wild-type TSHR TMD influences ligand binding affinity for the ECD, possibly by altering the conformation of the closely associated hinge region that contributes to the TSH-binding site.     

Intersubunit disulfides of the follitropin receptor

The electrophoretic mobility of radioiodinated follitropin (FSH) alpha and beta subunits as well as the alpha beta dimer changed markedly depending on the concentration of reducing agents such as dithiothreitol. The changes were more dramatic in the beta subunit than in the alpha subunit. 125I-FSH, complexed to the receptor on porcine granulosa cells or in Triton X-100 extracts, was cross-linked with a cleavable (nondisulfide) homobifunctional reagent, solubilized in sodium dodecyl sulfate without reducing agents, and electrophoresed. The cross-linked sample revealed three bands of high molecular mass, in addition to the hormone subunit and dimer bands. The band of lightest mass, 110 kDa, was the major band and the other two of 76 and 62 kDa were barely noticeable. Upon reduction with dithiothreitol, the 110-kDa band decreased while the 76- and 62-kDa bands increased, indicating the existence of disulfides between components of the 110-kDa complex. Formation of the disulfide-linked complexes requires 125I-FSH, specifically bound to the hormone receptor and cross-linking, and can be prevented with an excess of native FSH but not human choriogonadotropin. Complex formation was independent of blocking free sulfhydryl groups with N-ethylmaleimide. When the cross-linked complexes were reduced in the gel matrix and analyzed on fresh gels, the 76- and 62-kDa complexes were generated from the 110-kDa band, indicating the loss of two components. The lost components were estimated to be at 14 and 34 kDa. The rate of formation and cleavage of the cross-linked complexes indicated a sequential and incremental addition of 22-, 14-, and 34-kDa components to the FSH alpha beta dimer. The results of reduction of the cross-linked complexes demonstrate the existence of disulfide linkage between the three components.     

The two proteins of the erythropoietin receptor are structurally similar

The structure of the erythropoietin receptor has been identified in this laboratory as two proteins of 100 and 85 kDa by cross-linking 125I-erythropoietin (125I-EP) to the surface of erythroid cells purified from the spleens of mice infected with the anemia strain of Friend virus. This study investigates the relatedness of these two proteins and the possibility that these proteins are subunits of the functional receptor for EP. Other workers have claimed that the 100- and 85-kDa proteins are bridged by disulfide bonds. This most likely is an artifact due to the insolubility of the cross-linked membrane. Proteolytic digestion by the method of Cleveland (Cleveland, D. W., Fischer, S. G., Kirschner, M. W., and Laemmli, U. K. (1977) J. Biol. Chem. 252, 1102-1106) resulted in identical fragments from the 100- and 85-kDa proteins, which strongly suggests that the primary amino acid sequence of these two proteins is similar if not identical. Increasing the number of protease inhibitors during the preparation of membranes and the binding and cross-linking steps increased the ratio of 100-kDa protein labeled compared to the 85-kDa protein. Together these results suggest that the 85-kDa protein is derived by proteolytic cleavage of the 100-kDa receptor for EP. It is not clear whether the 100-kDa protein can bind EP in the absence of the 85-kDa protein.     

Subunit structure and dynamics of the insulin receptor

A model for the minimum subunit composition and stiochiometry of the physiologically relevant insulin receptor has been deduced based on results obtained by affinity labeling of this receptor in a variety of cell types and species. We propose that the receptor is a symmetrical disulfide-linked heterotetramer composed of two alpha (apparent Mr = 125,000) and two beta (apparent Mr = 90,000) glycoprotein subunits in the configuration (beta-S-S-alpha)-S-S-(alpha-S-S-beta). The disulfide or disulfides linking the two (alpha-S-S-beta) halves (class I disulfides) exhibit greater sensitivity to reduction by exogenous reductants than those linking the alpha and beta subunits (class II disulfides). When the class I disulfides are reduced by addition of diothiothreitol to intact cells, the receptor retains its ability to bind insulin and to effect a biological response. The beta subunit contains a site at about the center of its amino acid sequence that is extremely sensitive to proteolytic cleavage by elastaselike proteases, yielding a beta 1 fragment (Mr = 45,000) that remains disulfide linked to the receptor complex and a free beta 2 fragment. Binding of insulin to the receptor complex appears to result in the formation or stabilization of a new receptor conformation as evidenced by an altered susceptibility of the alpha subunit to exogenous trypsin. A receptor structure with high affinity for insulinlike growth factor (IGF) I and low affinity for insulin in fibroblast and placental membranes has also been affinity labeled. It exhibits the same structural features found for the insulin receptor, including two classes of disulfide bridges and beta subunits highly sensitive to proteolytic cleavage. These recent observations identifying the presence of distinct insulin and IGF-I receptors that share similar complex structures suggest that these hormones may also share common mechanisms of transmembrane signaling.     

Protease resistance of the beta subunit of the hamster fibronectin receptor. Evidence for differential cleavage of membrane-bound and soluble receptor

The structural stability of the hamster fibronectin receptor has been studied using limited proteolytic digestion and anti-(fibronectin receptor) monoclonal antibodies of known specificity. Treatment of the solubilized intact receptor or of the dissociated alpha and beta chains with any one of several proteases generated large protease-resistant fragments (92-110 kDa). Western blot analysis of tryptic digests using subunit-specific monoclonal antibodies revealed the large trypsin-generated fragment to be of beta-subunit origin. No products from the alpha subunit were detected. The protease-resistant fragment is lost upon exposure to reducing conditions; thus, the highly disulfide-bonded region of the beta subunit is important in the maintenance of the tertiary structure of the entire subunit. In contrast to solubilized fibronectin receptor, membrane-bound receptor is much more stable to proteolysis, and tryptic cleavage results in two large immunoreactive fragments of approximately 100 kDa and 95 kDa. This suggests a difference in the conformation and/or oligomeric organization of the membrane-bound receptor as compared with the solubilized heterodimeric receptor.     

Tryptic activation of the insulin receptor. Proteolytic truncation of the alpha-subunit releases the beta-subunit from inhibitory control

Trypsin exerts insulin-like effects in intact cells and on partially purified preparations of insulin receptors. To elucidate the mechanism of these insulinomimetic effects, we compared the structures of insulin- and trypsin-activated receptor species with their functions, including insulin binding, autophosphorylation, and tyrosine kinase activity. In vitro treatment of wheat germ agglutinin-purified receptor preparations with trypsin resulted in proteolysis of both alpha- and beta-subunits. The activated form of the receptor had an apparent molecular mass of 110 kDa under nonreducing conditions, compared to the 400-kDa intact receptor, and was separated following reduction into an 85-kDa beta-subunit related fragment and a 25-kDa alpha-subunit related fragment. Treatment of whole cells with trypsin prior to isolation of the insulin receptor resulted in proteolytic modification of the alpha-subunit only. In this case, the total molecular mass of the activated species was 116 kDa, comprised of an intact 92-kDa beta-subunit and again a 25-kDa alpha-subunit related fragment. Values of Km for peptide substrate phosphorylation and Ki for inhibition of receptor autophosphorylation, and sites of autophosphorylation within the beta-subunits were similar for receptors activated either by insulin or trypsin. Insulin had no additional effect on the rate of autophosphorylation of the truncated receptor, and no binding of insulin by the truncated receptor was detected either by direct assay or cross-linking with bifunctional reagents. Based on the deduced amino acid sequence of the insulin receptor and the structural studies presented here we concluded that this activated form of the receptor resulted from tryptic cleavage at the dibasic site Arg576-Arg577. This was accompanied by loss of the insulin binding site and separation of alpha-beta heterodimers. As truncation of the alpha-subunit results in beta-subunit activation, it appears that the beta-subunit is a constitutively activated kinase and that the function of the alpha-subunit in the intact receptor is to inhibit the beta-subunit.     

Subunit composition of the untransformed glucocorticoid receptor in the cytosol and in the cell.

We have used bifunctional reagents to examine the subunit composition of the non-DNA-binding form of the rat and human glucocorticoid receptor. Treatment of intact cells and cell extracts with a reversible cross-linker, followed by electrophoretic analysis of immunoadsorbed receptor revealed that three proteins of apparent approximate molecular masses, 90, 53 and 14 kDa are associated with the receptor. The first of these was identified immunochemically as a 90-kDa heat-shock protein (hsp90). The complex isolated from HeLa cells contained 2.2 mol hsp90/mol steroid-binding subunit. Cross-linking of the receptor complex in the cytosol completely prevented salt-induced dissociation of the subunits. The cross-linked receptor was electrophoretically resolved into two oligomeric complexes of apparent molecular mass 288 kDa and 347 kDa, reflecting the association of the 53-kDa protein with a fraction of the receptor. Since no higher oligomeric complexes could be generated by cross-linking cell extracts under different conditions, we conclude that most of the untransformed cytosolic receptor is devoid of additional components.     

Monoclonal antibodies to distinctive epitopes on the alpha and beta subunits of the fibronectin receptor

Monoclonal antibodies (MAbs) have been developed that can recognize epitopes that are unique to either the alpha or beta subunit of the fibronectin receptor (FnR). MAbs 11B4 and 7A8 immunoblot the alpha subunit of FnR either in purified form from Chinese hamster ovary (CHO) cells or in nonionic detergent extracts of cells of human and rodent origin electrophoresed under reducing or nonreducing conditions. The MAbs seem to be more reactive to the subunit when it has been electrophoresed under reducing conditions, suggesting that the epitope may be partially masked by the conformation conferred by disulfide bonding. A second set of MAbs, 7E2 and 7F9, is directed to an epitope on the beta subunit that is conformationally dependent upon disulfide bonding, as reduction of the subunit leads to loss of reactivity with both MAbs. Further, 7E2/7F9 immunoblots of nonionic detergent extracts of CHO cells, run under nonreducing conditions, reveal the presence of a third band (90-kDa), immunologically related to the beta subunit, which is not surface-labeled with 125I in intact cells and which does not copurify with the alpha and beta subunits isolated by immunoaffinity purification of FnR using the MAb PB1. The 90-kDa component is not found associated with a plasma membrane fraction prepared by crude cell fractionation, but is abundant in a low-speed pellet containing nuclei and intracellular membranes. This finding suggests that the 90-kDa component is a precursor to the beta subunit. Finally, the epitope of 7E2/7F9 is unique to CHO cells, as cross-reactivity to other cell types cannot be demonstrated by either immunoblotting or immunoprecipitation.     

A conserved region in alpha-macroglobulins participates in binding to the mammalian alpha-macroglobulin receptor

Efforts to characterize the receptor recognition domain of alpha-macroglobulins have primarily focused on human alpha 2-macroglobulin (alpha 2M). In the present work, the structure and function of the alpha-macroglobulin receptor recognition site were investigated by amino acid sequence analysis, plasma clearance, and cell binding studies using several nonhuman alpha-macroglobulins: bovine alpha 2M, rat alpha 1-macroglobulin (alpha 1M), rat alpha 1-inhibitor 3 (alpha 1I3), and proteolytic fragments derived from these proteins. Each alpha-macroglobulin bound to the murine peritoneal macrophage alpha-macroglobulin receptor with comparable affinity (Kd approximately 1 nM). A carboxyl-terminal 20-kDa fragment was isolated from each of these proteins, and this fragment bound to alpha-macroglobulin receptors with Kd values ranging from 10 to 125 nM. The amino acid identity between the homologous carboxyl-terminal 20-kDa fragments of human and bovine alpha 2M was approximately 90%, while the overall sequence homology between all carboxyl-terminal fragments studied was 75%. The interchain disulfide bond present in the human alpha 2M carboxyl-terminal 20-kDa fragment was conserved in bovine alpha 2M and rat alpha 1I3, but not in rat alpha 1M. The clearance of each intact alpha-macroglobulin-proteinase complex was significantly retarded following treatment with cis-dichlorodiammineplatinum(II) (cis-DDP). cis-DDP treatment, however, did not affect receptor recognition of purified carboxyl-terminal 20-kDa fragments of these alpha-macroglobulins. A carboxyl-terminal 40-kDa subunit, which can be isolated from rat alpha 1M, bound to the murine alpha-macroglobulin receptor with a Kd of 5 nM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein components of the nonactivated glucocorticoid receptor.

The nonactivated glucocorticoid receptor (Mr approximately 350,000) of WEHI-7 mouse lymphoma cells was investigated with respect to the stoichiometry of protein subunits. Cross-linking patterns obtained by affinity labeling and denaturing gel electrophoresis revealed a heterotetramer consisting of one receptor polypeptide in association with two 90- and one approximately 50-kDa subunits. The receptor stabilized by molybdate, disulfide bond formation, or chemical cross-linking was purified roughly 6000-fold by immunoaffinity chromatography and analyzed by gel electrophoresis and immunoblotting. The 90-kDa component was consistently detected in a 2:1 ratio with respect to the receptor polypeptide and was identified as the 90-kDa heat shock protein, hsp90. A 70-kDa heat shock protein was found in both stabilized and nonstabilized receptors and bound to the immunomatrix independent of receptor. The additional receptor subunit was unequivocally identified as the 59-kDa protein previously described (Tai, P.-K. K., Maeda, Y., Nakao, K., Wakim, N. G., Duhring, J. L., and Faber, L. E. (1986) Biochemistry 25, 5269-5275). This component was found only in complexes cross-linked via amino groups. It was removed from the molybdate-stabilized receptor under our purification conditions, thus leaving behind a trimer composed of the receptor polypeptide and two molecules of hsp90. In the absence of hormone, the receptor had the same subunit composition as in its presence.     

Phosphorylation of the 48-kDa subunit of the glycine receptor by protein kinase C.

The postsynaptic glycine receptor purified from rat spinal cord is rapidly and specifically phosphorylated by protein kinase C. The target for phosphorylation is the strychnine-binding subunit of the receptor (molecular mass of approximately 48 kDa), which is phosphorylated on serine residues to a final stoichiometry of approximately 0.8 mol of phosphate/mol of subunit. The 48-kDa phosphoprotein was analyzed by proteolytic cleavage and peptide mapping in order to localize the site of phosphorylation within the receptor molecule. Examination of the 32P-labeled receptor fragments generated by digestion with N-chlorosuccinimide, cyanogen bromide, and endoproteinase lysine C and of the deduced amino acid sequence of the 48-kDa protein (Grenningloh, G., Rienitz, A., Schmitt, B., Methfessel, C., Zensen, M., Beyreuther, K., Gundelfinger, E. D., and Betz, H. (1987) Nature 328, 215-220) indicates that the phosphorylation site is located in a region corresponding to the major intracellular loop of the predicted structure of the glycine receptor subunit and suggests serine 391 as the phosphorylated residue. In fact, a synthetic peptide corresponding to residues 384-392 of the 48-kDa subunit was specifically phosphorylated by protein kinase C. Moreover, tryptic digests of this phosphopeptide and of the phosphorylated 48-kDa subunit of the glycine receptor migrated to the same position in two-dimensional peptide mapping. Furthermore, antibodies elicited against peptide 384-392 were shown to inhibit the protein kinase C-dependent phosphorylation of the 48-kDa polypeptide. Interestingly, the relative position of the phosphorylated domain is similar to those known or proposed to be phosphorylated in other ligand-gated ion channel receptor subunits, thus suggesting further the existence of a homologous regulatory region in these receptor proteins.     

Photoaffinity labeling of the erythropoietin receptor and its identification in a ligand-free form.

Pure human recombinant erythropoietin (EP) was acylated through a primary amino residue with a cross-linking reagent, N-[[3-[[4-[(p-azido-m-[125I]iodophenyl)azo]benzoyl]amino] propanoyl]oxy]-succinimide (Denny-Jaffe reagent), which is photoreactive and cleavable at the azo residue. The resulting conjugated hormone (DJ-EP) was purified from unmodified EP by reverse-phase high-pressure liquid chromatography and maintained its capacity to bind to receptors for EP on erythroid progenitor cells. The receptor for EP was previously identified as two related proteins of 100 and 85 kDa molecular mass by chemical cross-linking to 125I-EP. Recently, D'Andrea and co-workers [(1989) Cell 57, 277-285] cloned a cDNA that codes for a protein of 55-66 kDa, which is thought to be the EP receptor. In this report, cross-linking to the receptor through the monofunctional DJ-EP labeled the same 140- and 125-kDa molecular mass bands (100- and 85-kDa proteins) cross-linked with 125I-EP and disuccinimidyl suberate. Furthermore, cleavage of the azo bond of the DJ-EP receptor complex by sodium dithionite (80 degrees C, 5 min) demonstrated that proteins of 105 and 90 kDa were labeled in ligand-free form by DJ-EP. This result demonstrates that artifactual cross-linking of multiple proteins or other artifacts of cross-linking do not explain the difference in molecular mass of the EP receptor identified by cross-linking and the receptor identified by expression cloning.     

Insight into thyrotropin receptor cleavage by engineering the single polypeptide chain luteinizing hormone receptor into a cleaving, two subunit receptor.

To gain insight into the thyrotropin hormone (TSH) receptor (TSHR) cleavage, we sought to convert the noncleaving luteinizing hormone (LH) receptor (LHR) into a cleaved, two-subunit molecule. For this purpose, we generated a series of LHR mutants and chimeric LH-TSH receptors. Cleavage of mature, ligand binding receptors on the cell surface was determined by covalent 125I-labeled hCG crosslinking to intact, stably transfected mammalian cells. We first targeted a cluster of three N-linked glycans in the LHR (N295, N303, N317) in a region corresponding to the primary TSHR cleavage site, which has only one N-linked glycan. Elimination by mutagenesis of the most strategic N-linked glycan (LHR-N317Q) generated only a trace amount of LHR cleavage. Removal of the other N-linked glycans had no additive effect. A much greater degree of cleavage ( approximately 50%) was evident in a chimeric LH-TSHR in which the juxtamembrane segment of the LHR (domain E; amino acids 317-367) was replaced with the corresponding domain of the TSHR (residues 363-418). Similarly cleaving LHR were created using a much smaller component within this region, namely LHR-NET317-319 replaced with TSHR-GQE367-369, or by substitution of the same three amino-acid residues with AAA (LHR-NET317-319AAA). In summary, our data alter current concepts regarding TSHR cleavage by suggesting limited (not absent) amino-acid specificity in a region important for TSHR cleavage (GQE367-369). The data also support the concept of a separate and distinct downstream cleavage site 2 in the TSHR.     

The subunit structure of the follitropin (FSH) receptor. Photoaffinity labeling of the membrane-bound receptor follitropin complex in situ

Human follicle-stimulating hormone (hFSH) was acylated with N-hydroxysuccinimidyl-4-azidobenzoate (HSAB) and radioiodinated (55 microCi/micrograms) for use as a photoaffinity probe to investigate the subunit structure of the FSH receptor in calf testis. After incubation with the photoaffinity probe and photolysis with UV light, the cross-linked hormone-receptor complex was solubilized from the membrane and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence and absence of the reducing agent dithiothreitol. Autoradiography of the polyacrylamide gels revealed two major bands, 64 kDa and 84 kDa. These were equivalent in molecular mass to those observed in a previous study (Branca, A. A., Sluss, P. M., Smith, A. A., and Reichert, L. E., Jr. (1985) J. Biol. Chem. 260, 9988-9993) in which performed hormone-receptor complexes were solubilized with detergent prior to formation of covalent cross-linkages through the use of homobifunctional cross-linking reagents. Reduction with dithiothreitol resulted in the loss of radioactivity from the 84-kDa band with a concomitant increase in the intensity of the 64-kDa band. Since dithiothreitol increases the dissociation of intact radioiodinated azidobenzoyl-FSH into subunits, it is suggested that the conversion of the 84-kDa band to the 64-kDa band by dithiothreitol is due to the loss of non-cross-linked hFSH subunit from the 84-kDa band and that the two bands observed after photoaffinity labeling arise from covalent bond formation between hFSH and a receptor subunit having a relative molecular weight (Mr) of 48,000. In addition to the predominant photolabeling of the receptor to yield the 64-kDa and 84-kDa bands, several other, less intense bands (54 kDa, 76 kDa, 97 kDa, and 116 kDa) were also consistently observed on autoradiographs. The appearance of all bands, however, was inhibited by the inclusion of unlabeled hFSH in the initial binding incubation mixtures. The results of this study indicate that the calf testis FSH receptor has a multimeric structure containing at least one 48-kDa subunit and suggest the presence of other nonidentical receptor subunit proteins.     

Structure and ligand specificity of the Drosophila melanogaster insulin receptor.

The insulin-binding and protein tyrosine kinase subunits of the Drosophila melanogaster insulin receptor homolog have been identified and characterized by using antipeptide antibodies elicited to the deduced amino acid sequence of the alpha and beta subunits of the human insulin receptor. In D. melanogaster embryos and cell lines, the insulin receptor contains insulin-binding alpha subunits of 110 or 120 kilodaltons (kDa), a 95-kDa beta subunit that is phosphorylated on tyrosine in response to insulin in intact cells and in vitro, and a 170-kDa protein that may be an incompletely processed receptor. All of the components are synthesized from a proreceptor, joined by disulfide bonds, and exposed on the cell surface. The beta subunit is recognized by an antipeptide antibody elicited to amino acids 1142 to 1162 of the human insulin proreceptor, and the alpha subunit is recognized by an antipeptide antibody elicited to amino acids 702 to 723 of the human proreceptor. Of the polypeptide ligands tested, only insulin reacts with the D. melanogaster receptor. Insulinlike growth factors type I and II, epidermal growth factor, and the silkworm insulinlike prothoracicotropic hormone are unable to stimulate autophosphorylation. Thus despite the evolutionary divergence of vertebrates and invertebrates, the essential features of the structure and intrinsic functions of the insulin receptor have been remarkably conserved.     

Affinity labeling of the sialoglycopeptide antimitogen receptor

An 18-kDa 125I-sialoglycopeptide growth inhibitor was covalently cross-linked to its binding site on intact cultured Swiss 3T3 cells by three bifunctional cross-linkers with short (dimethyl adipimate), medium (disuccinimidyl suberate), and long (bis(2-succinimidooxycarbonyloxyethyl)sulfone) chain lengths. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography demonstrated a band of Mr approximately 168,000 regardless of which cross-linker was used. The labeling of this band was specific in that it was prevented by excess unlabeled inhibitor and the apparent molecular weight of the cross-linked receptor-ligand complex was unchanged by treatment with reducing agent. The efficiency of the cross-linking was increased by increasing pH, and the extent of covalent cross-linking was dependent on the concentration of the bifunctional reagent. Octyl glucoside and sodium dodecyl sulfate were effective in solubilizing the receptor while Triton X-100 did not extract the receptor from the plasma membrane. These observations suggest that the 168-kDa binding species represents the 125I-sialoglycopeptide cross-linked to a specific plasma membrane receptor and that the receptor does not appear to contain interchain disulfide bonds.     

The role of the carboxyl-terminal 6 amino acid extension of human TSH beta subunit

The nucleotide sequence of human thyroid stimulating hormone (hTSH) gene can encode a protein of 138 amino acids. However, the mature polypeptide is lacking 6 amino acids of the carboxyl-terminus (C-terminus), suggesting posttranslational cleavage of these residues. To analyze a possible function of these 6 amino acids, we expressed two hTSH beta cDNAs with or without the 6 codons for C-terminal extension, together with alpha subunit cDNA in CHO cells, and determined the amino acid sequence of C-terminus of hTSH beta. hTSH beta propeptides without C-terminal extension were glycosylated, associated with alpha subunit and secreted, as normal propeptides were, and its heterodimer with alpha subunit showed normal TSH bioactivity in FRTL-5 bioassay. These data indicate that the 6 amino acid C-terminal extension is not necessary for the hTSH maturation in the process of the biosynthesis and for its bioactivity.     

Biogenesis, transit, and functional properties of the insulin proreceptor and modified insulin receptors in 3T3-L1 adipocytes. Use of monensin to probe proreceptor cleavage and generate altered receptor subunits

The biogenesis, intracellular transport, and functional properties of the insulin proreceptor and modified insulin receptors were studied in hormone-responsive 3T3-L1 adipocytes. After control cells were labeled with [35S]Met for 7 min, the principal polypeptide that was precipitated by anti-insulin receptor antibodies had a molecular weight (Mr) of 180 000. This initial precursor was rapidly converted (t1/2 = 35 min) to a 200-kilodalton (kDa) polypeptide, designated the insulin proreceptor, by the apparent posttranslational addition of N-linked, high mannose core oligosaccharide units. Mature alpha (Mr 130 000) and beta (Mr 90 000) subunits were derived from sequences within the proreceptor by proteolytic cleavage and late processing steps, and these subunits appeared on the cell surface 2-3 h after synthesis of the 180-kDa precursor. The cation ionophore monensin was used in combination with metabolic labeling, affinity cross-linking, and external proteolysis to probe aspects of proreceptor function, transit, and the development of insulin sensitivity at the target cell surface. At 5 micrograms/mL, monensin potently inhibited the proteolytic cleavage step, and the 200-kDa polypeptide accumulated. Lower concentrations of the ionophore selectively blocked late processing steps in 3T3-L1 adipocytes so that apparently smaller alpha' (Mr 120 000) and beta' (Mr 85 000) subunits were produced. Proreceptor and alpha' and beta' subunits were translocated to the cell surface, indicating that the signal for intracellular transit occurs in the 200-kDa polypeptide and is independent of the posttranslational proteolysis and late processing steps. The alpha' subunit bound insulin both at the surface of intact cells and after solubilization with Triton X-100; the beta' subunit was phosphorylated in an insulin-stimulated manner. The detergent-solubilized 200-kDa proreceptor also exhibited both functional properties. However, the proreceptor that was transported to and exposed on the cell surface was incapable of binding insulin in intact adipocytes. Thus, late processing is not essential for the expression of functions associated with mature alpha and beta subunits. In contrast, it appears that the proteolytic generation of subunits is required for the correct orientation of the hormone binding site in the plasma membrane bilayer and the development of insulin responsiveness in 3T3-L1 adipocytes.     

Structure and membrane topology of the high-affinity receptor for human IFN-gamma: requirements for binding IFN-gamma. One single 90-kilodalton IFN-gamma receptor can lead to multiple cross-linked products and isolated proteins

We analyzed the high affinity receptor for IFN-gamma of Raji cells and human placenta by combining Scatchard analysis, cross-linking experiments, and receptor purification. Only one high affinity binding site was found, Kd 2.1 X 10(-10). The receptor is a 90-kDa glycoprotein. However, multiple cross-linked products of 110 kDa to about 250 kDa could be generated and proteins of 90, 70, and 50 kDa could be obtained upon purification. These proteins all contained the same 90-kDa receptor, or part of it. We suggest that extensive cross-linking and/or proteolysis may explain many of the conflicting results published thus far. The extracellular domain of the 90-kDa receptor protein was highly resistant to digestion with trypsin or proteinase K. Trypsin digestion neither affected the number of binding sites per cell, nor the Kd for IFN-gamma. A cluster of sites for different proteases was found in the intracellular domain. The 50-kDa fragment created by trypsin digestion had the same characteristics as the isolated 50-kDa receptor fragment. It contained the IFN-gamma binding site and the receptor's extracellular and amino-terminal domain. N-linked glycosylation contributed about 15 kDa to its molecular mass, of which 4 kDa were attributable to sialic acid residues. O-Linked glycosylation was not detected. The number of binding sites per cell and the Kd for IFN-gamma were not affected by the presence or absence of N-linked glycosylation. The receptor contained at least one critical disulfide bridge and the reduced receptor could be reactivated in vitro.     

Tetrameric structure of the nonactivated glucocorticoid receptor in cell extracts and intact cells

Mouse lymphoma cells contain a nonactivated glucocorticoid receptor of Mr approximately 330,000 which is heteromeric in nature and is unable to bind to DNA. Following affinity labeling of the steroid-binding subunit and subsequent cross-linking with dimethyl suberimidate at various times either in cell extracts or in intact cells, a series of labeled bands was detected in SDS gels. From the molecular masses of completely and partially cross-linked complexes we conclude that the large nonactivated receptor is a tetramer composed of two 90 kDa subunits, one 50 kDa polypeptide and one steroid-binding subunit.