Multimeric structure of the membrane erythropoietin receptor of murine erythroleukemia cells (Friend cells). Cross-linking of erythropoietin with the spleen focus-forming virus envelope protein.

In erythroleukemia cells infected with the polycythemia strain of the Friend virus complex, erythropoietin could be cross-linked mainly to a protein of 63 kDa when using disuccinimidyl suberate. In contrast, erythropoietin in other erythroleukemia cells cross-linked to two proteins of 85 and 100 kDa. When native erythropoietin receptor complexes were immunoprecipitated, the 63-kDa erythropoietin-cross-linked protein could be precipitated both by antibodies directed against the intracellular part of the cloned chain of the erythropoietin receptor and by antibodies directed against the envelope proteins of the Friend virus. However, after denaturation of the complexes, the 63-kDa protein was only precipitated by antibodies directed against the envelope proteins of the Friend virus. Enzymatic deglycosylation confirmed that erythropoietin was cross-linked with the envelope protein of the defective virus and bidimensional diagonal gel electrophoresis analyses showed that some of the erythropoietin cross-linked envelope proteins were dimerized by disulfide bonds. Thus, the main erythropoietin-receptor complex in the plasma membrane of these cells consisted of a molecule of the cloned chain of the erythropoietin receptor noncovalently associated with one or two disulfide-bonded molecule(s) of the envelope protein of the defective virus. Moreover, our results also showed that the viral envelope protein associated with the cloned chain of the erythropoietin receptor at a site distinct from the erythropoietin binding site.     

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.     

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.     

Solubilization and hydrodynamic characteristics of the erythropoietin receptor. Evidence for a multimeric complex

In order to study the erythropoietin receptor in its native state, we solubilized erythropoietin-receptor complexes from spleen cell membranes of mice infected with the anemia strain of Friend virus using mild detergents. Among 11 tested detergents, Triton X-100 and Lubrol PX were the most effective. Triton X-100 was therefore selected for this study. The solubilized complexes appeared to be well representative of the total membrane receptor population as indicated by cross-linking experiments and affinity measurements. The hydrodynamic characteristics of the complexes were determined by gel filtration chromatography and ultracentrifugation through sucrose gradients prepared with H2O or D2O. Although erythropoietin-receptor-detergent complexes exhibited some heterogeneity, we determined the following minimal hydrodynamic values: sedimentation coefficient (s20,w): 11.7 +/- 0.8 S, Stokes radius: 7.7 +/- 0.2 nm, partial specific volume: 0.774 +/- 0.017 ml/g, giving a molecular mass of 458 +/- 66 kDa. The contribution of the detergent was estimated to be 28% from the measured partial specific volume, giving an estimated molecular mass of 330 +/- 48 kDa for the erythropoietin-receptor complex. The minimal molecular mass value was significantly greater than those obtained by polyacrylamide gel electrophoresis under denaturing conditions, strongly suggesting that the erythropoietin receptors were present as multimeric complexes. The nature of these complexes is discussed. Beside this major component our results revealed the presence of higher-molecular-mass erythropoietin binding components. We also demonstrated that erythropoietin-receptor complexes could be precipitated with anti-erythropoietin antibodies. This property should greatly improve the purification of erythropoietin receptors.     

In vitro phosphorylation of the erythropoietin receptor and an associated protein, pp130.

The cytoplasmic domain of the cloned erythropoietin (EPO) receptor (EPOR) contains no protein kinase motif, yet addition of EPO to EPO-responsive cells causes an increase in protein-tyrosine phosphorylation. Here we show that addition of EPO or interleukin-3 (IL-3) to an IL-3-dependent cell line expressing the wild-type EPOR causes a small fraction (less than 5%) of total cellular EPOR to shift in gel mobility from 66 to 72 kDa, due at least in part to phosphorylation. Using biotinylated EPO as an affinity reagent, we show that the 72-kDa species is greatly enriched on the cell surface. To demonstrate that a protein kinase activity associates with cell surface EPOR, cells were incubated with biotinylated EPO and then cross-linked with a thiol-cleavable chemical cross-linker. The avidin-agarose-selected complexes were incubated with [gamma-32P]ATP. After in vitro phosphorylation and denaturation without reducing agent, both antiphosphotyrosine and anti-EPOR antibodies immunoprecipitated labeled 72-kDa EPOR and an unidentified 130-kDa phosphoprotein (pp130), indicating that a protein kinase is associated with cell surface EPOR and that a fraction of the EPOR was phosphorylated on tyrosine residues either in the cells or during the cell-free phosphorylation reaction. Under reducing conditions, the 72-kDa phosphorylated EPOR but not pp130 was immunoprecipitated with an anti-EPOR antibody, suggesting that the pp130 is bound to the EPOR by the thiol-cleavable chemical cross-linker. Previously, we showed that deletion of the 42 carboxy-terminal amino acids of the EPOR allows cells to grow in 1/10 the normal EPO concentration, without affecting receptor number or affinity. Two carboxy-terminal truncated EPO receptors that are hyperresponsive to EPO were poorly phosphorylated during the in vitro reaction, suggesting that the carboxy-terminal region of the EPOR contains a site for phosphorylation or a site for interaction with a protein kinase. Our data suggests that phosphorylation or interaction with a protein kinase in the carboxy-terminal region may down-modulate the proliferative action of the EPOR.     

Glycosylation of the murine erythropoietin receptor

Murine erythropoietin-responsive Rauscher Red 5-1.5 cells were used to determine the contribution of glycosylation to the size and function of the erythropoietin receptor. The half life of the receptors was determined to be 4 h. The number of receptors was not significantly decreased in cells treated for 48 h with inhibitors of glycosylation (tunicamycin, glucosamine or swainsonine) and their affinity was slightly enhanced in tunicamycin- or glucosamine-treated cells. Erythropoietin was cross-linked with two proteins of 104 and 86 kDa. Their molecular masses were not significantly reduced in cells treated with the glycosylation inhibitors. When immunoprecipitated cross-linked receptors were digested with endoglycosidases, the molecular masses of both proteins were only slightly modified giving values of 100 and 82 kDa. Thus we can conclude that the proteins cross-linked to erythropoietin are very weakly glycosylated.     

Association of Guide RNA Binding Protein gBP21 with Active RNA Editing Complexes in Trypanosoma brucei

RNA editing in Trypanosoma brucei mitochondria produces mature mRNAs by a series of enzyme-catalyzed reactions that specifically insert or delete uridylates in association with a macromolecular complex. Using a mitochondrial fraction enriched for in vitro RNA editing activity, we produced several monoclonal antibodies that are specific for a 21-kDa guide RNA (gRNA) binding protein initially identified by UV cross-linking. Immunofluorescence studies localize the protein to the mitochondrion, with a preference for the kinetoplast. The antibodies cause a supershift of previously identified gRNA-specific ribonucleoprotein complexes and immunoprecipitate in vitro RNA editing activities that insert and delete uridylates. The immunoprecipitated material also contains gRNA-specific endoribonuclease, terminal uridylyltransferase, and RNA ligase activities as well as gRNA and both edited and unedited mRNA. The immunoprecipitate contains numerous proteins, of which the 21-kDa protein, a 90-kDa protein, and novel 55- and 16-kDa proteins can be UV cross-linked to gRNA. These studies indicate that the 21-kDa protein associates with the ribonucleoprotein complex (or complexes) that catalyze RNA editing.     

Characterization of erythropoietin receptor of murine erythroid cells

Radioiodinated or biologically tritiated recombinant human erythropoietin was used to characterize receptors for this hormone on the surface of Friend erythroleukemic cells (745A and TSA8) and cells from mouse erythropoietic tissues (liver from fetus and spleen from animals made anemic by injection of Friend virus or phenylhydrazine). Specific binding of erythropoietin to these cells was time-dependent and dose-dependent. Binding studies at 37 degrees C showed that dissociation constants of erythropoietin-receptor complexes were in the range of 100-300 pM. The number of receptors on erythroleukemic cells increased after treatment with dimethylsulfoxide. Covalent binding of 125I-erythropoietin to its receptors with a cross-linking reagent, disuccinimidyl suberate or glutaraldehyde, resulted in the formation of two major radiolabeled products that migrated as 120-kDa and 140-kDa species on sodium dodecyl sulfate/polyacrylamide electrophoresis gels under reducing conditions. Under non-reducing conditions, both 120-kDa and 140-kDa species disappeared and two cross-linked products, a minor product with a molecular mass of 250 kDa and a major product of high molecular mass that kept it from migration into the separating gels, appeared. The relationship of the cross-linked products found under non-reducing conditions with those under reducing conditions remains to be clarified.     

Subunit structure of the erythropoietin receptor

Chemical cross-linking of the red blood cell hormone, erythropoietin (Epo), to its receptor on erythroid cells has revealed the presence of two proteins closely associated with Epo, but the relationship between these two proteins is controversial. Using the cross-linking reagents disuccinimidyl suberate and dithiobissuccinimidyl propionate, we show that 125I-Epo can be specifically conjugated in a complex of 224kDa using mouse fetal liver cells, bone marrow cells, and Friend virus-induced splenic erythroblasts as demonstrated by electrophoresis on sodium dodecyl sulfate-polyacrylamide gels under nonreducing conditions. Under reducing conditions, the 224-kDa complex appeared as two Epo conjugates of 136 kDa and 119 kDa, and these bands were also observed to a variable extent in some nonreducing gels. Disulfide linking of the 136-kDa and 119-kDa bands was confirmed by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis run under nonreducing followed by reducing conditions. With increasing time of 125I-Epo binding to Friend virus erythroblasts in the presence of sodium azide to inhibit receptor internalization, the 136-kDa and 119-kDa bands seen under reducing conditions increased markedly in intensity, whereas the 224-kDa band seen under nonreducing conditions declined. These results suggest that the 224-kDa Epo conjugate is inefficiently solubilized under nonreducing conditions following prolonged periods of Epo binding. A single class of saturable, high affinity receptors for Epo on each of the cell types tested is demonstrated. It is concluded that the two disulfide-linked Epo-binding proteins which can be independently cross-linked to Epo form a single ligand binding site.     

Detection of an interaction between the HN and F proteins in Newcastle disease virus-infected cells.

For many paramyxoviruses, including Newcastle disease virus (NDV), syncytium formation requires the expression of both surface glycoproteins (HN and F) in the same cell, and evidence suggests that fusion involves a specific interaction between the HN and F proteins. Because a potential interaction in paramyxovirus-infected cells has never been demonstrated, such as interaction was explored by using coimmunoprecipitation and cross-linking. Both HN and F proteins could be precipitated with heterologous antisera after a 5-min radioactive pulse as well as after a 2-h chase in nonradioactive medium, but at low levels. Chemical cross-linking increased detection of complexes containing HN and F proteins at the cell surface. After cross-linking, intermediate- as well as high-molecular-weight species containing both proteins were precipitated with monospecific antisera. Precipitation of proteins with anti-HN after cross-linking resulted in the detection of complexes which electrophresed in the stacker region of the gel, from 160 to 300 kDa, at 150 kDa, and at 74 kDa. Precipitates obtained with anti-F after cross-linking contained species which migrated in the stacker region of the gel, between 160 and 300 kDa, at 120 kDa, and at 66 kDa. The three to four discrete complexes ranging in size from 160 to 300 kDa contained both HN and F proteins when precipitated with either HN or F antisera. That cross-linking of complexes containing both HN and F proteins was not simply a function of overexpression of viral glycoproteins at the cell surface was addressed by demonstrating cross-linking at early time points postinfection, when levels of viral surface glycoproteins are low. Use of cells infected with an avirulent strain of NDV showed that chemically cross-linked HN and F proteins were precipitated independent of cleavage of F0. Furthermore, under conditions that maximized HN protein binding to its receptor, there was no change in the percentages of HN and F0 proteins precipitated with heterologous antisera, but a decrease in F1 protein precipitated was observed upon attachment. These data argue that the HN and F proteins interact in the rough endoplasmic reticulum. Upon attachment of the HN protein to its receptor, the HN protein undergoes a conformational change which causes a conformational change in the associated F protein, releasing the hydrophobic fusion peptide into the target membrane and initiating fusion.     

Composition and peptide maps of cross-linked human choriogonadotropin-receptor complexes on porcine granulosa cells

Radioiodinated human choriogonadotropin was affinity-cross-linked with a cleavable (nondisulfide) homobifunctional reagent to the hormone receptor on porcine granulosa cells and the solubilized sample was electrophoresed. Cross-linked samples revealed four additional bands of slower electrophoretic mobility in addition to the hormone alpha, beta, and alpha beta dimer bands. The four bands corresponded to masses of 68, 74, 102, and 136 kDa whereas the alpha beta dimer band corresponded to 50 kDa. Formation of the four bands requires the 125I-hormone to bind specifically to the receptor with subsequent cross-linking. Binding can be prevented by excess of native hormone but not by follitropin. A monofunctional analog of the cross-linking reagent failed to produce the four bands. They were also produced by cross-linking Triton X-100-solubilized hormone-receptor complexes. Reagent concentration-dependent cross-linking revealed that their formation was sequential; smaller complexes formed first and then larger ones. When gels of the cross-linked sample were treated with reagents that cleave covalent cross-links and then electrophoresed in a second dimension gel, 18-, 24-, 28-, and 34-kDa components were released, in addition to the alpha and beta subunits of the native hormone. Simultaneous peptide mapping of the cross-linked complexes in the gel matrix with Staphylococcus V8 protease or papain revealed progressive proteolysis to generate terminal fragments of 30 or 27 kDa, respectively. These fragments were unique to and commonly present in the 74-, 102-, and 136-kDa hormone-receptor complexes but were not produced by proteolysis of the cross-linked human choriogonadotropin (hCG) alpha beta dimer or the hCG alpha subunit. Apparently, the radioactively labeled segment(s) of the alpha subunit of 125I-hCG was cross-linked to the 24-kDa component. The results demonstrate the protein nature of the receptor and suggest that 125I-hCG was initially cross-linked to the 24-kDa component to generate the 74-kDa complex, then the 28- and 34-kDa components were sequentially cross-linked to the 24-kDa component in the 74-kDa complex to generate the 102- and 134-kDa complexes.     

Two different cell types have different major receptors for human tumor necrosis factor (TNF alpha)

The receptors for tumor necrosis factor alpha (TNF alpha) were analyzed on myeloid cells (HL60, U937, K562, and freshly isolated blood monocytes) and on cells of epithelial origin (MCF7, HEp2 and HeLa cells), by use of radiolabeled TNF alpha and cross-linking experiments. Both cell types had high but slightly different affinities for TNF alpha. The myeloid cells had major cross-linked products of 98-100 kDa, which were similar in their N-linked glycosylation, whereas the cells of epithelial origin contained a major cross-linked product of 75 kDa, a second product of 95 kDa. The major receptors of both cell types (studied mostly with HL60 and HEp2 cells) are different proteins because (a) their apparent molecular masses were different and no evidence was obtained for cell-specific proteases, which could generate the differently sized receptors from one common receptor molecule; (b) anti-receptor antibodies, which precipitated the 95- and 75-kDa products, did not precipitate the 100-kDa cross-linked complex; (c) the native TNF alpha-receptor complexes had different proteolytic fingerprints; (d) the tryptic fragments differed in their association with the cell membrane vesicles; (e) the receptors differed in their degree of N-linked glycosylation; and (f) O-linked glycosylation was found on the major receptor of HL60 but not of HEp2 cells. In addition, myeloid cells may also contain a small amount of the HEp2-type of TNF alpha receptor. We suggest that at least two different receptors for TNF alpha exist.     

Cross-linking of a monomeric 39/34-kDa dispase fragment of von Willebrand factor (Leu-480/Val-481-Gly-718) to the N-terminal region of the alpha-chain of membrane glycoprotein Ib on intact platelets with bis(sulfosuccinimidyl) suberate

A 39/34-kilodalton (kDa) monomeric dispase fragment of von Willebrand factor (vWF) has been purified by heparin affinity chromatography. Detailed structural analysis of the individual 39- and 34-kDa fragments indicated that they had identical amino acid sequences extending from Leu-480/Val-481 to Gly-718 with an intramolecular disulfide bond between Cys-509 and Cys-695. In addition to the binding site for heparin, the 39/34-kDa fragment also contained binding sites for collagen and for platelet membrane glycoprotein (GP) Ib. Unlike native vWF, the 39/34-kDa fragment bound to GP Ib without the requirement for a modulator but showed increased binding in the presence of botrocetin. The 39/34-kDa vWF fragment was cross-linked to intact human platelets by using the membrane-impermeable, homobifunctional cross-linking reagent bis(sulfosuccinimidyl) suberate. Two distinct cross-linked species of similar molecular weight (220/200 kDa, nonreduced; 190/175 kDa, reduced) were identified by SDS-polyacrylamide gel electrophoresis and autoradiography, consistent with the cross-linking of the 125I-labeled 39/34-kDa vWF fragment to GP Ib. The formation of these cross-linked species was enhanced 1.5-2.5-fold in the presence of the modulator botrocetin. The platelet membrane protein involved in cross-linking was shown unequivocally to be GP Ib since (i) neither cross-linked species was formed with Bernard-Soulier syndrome platelets, which genetically lack the GP Ib-IX complex, (ii) both cross-linked species were specifically immunoprecipitated by anti-GP Ib polyclonal and monoclonal antibodies, and (iii) the formation of the cross-linked species was completely inhibited only by those anti-GP Ib-IX complex monoclonal antibodies that inhibited vWF-GP Ib-IX complex interaction. Proteolysis of cross-linked platelets with endoproteinase Lys-C, which preferentially cleaves off the N-terminal peptide domain on the alpha-chain of GP Ib, indicated that the 39/34-kDa vWF fragment was cross-linked exclusively to this region of the GP Ib-IX complex.     

Association of a lower molecular weight protein to the mu-opioid receptor demonstrated by (125)I-beta-endorphin cross-linking studies

Cross-linking experiments using the (125)I-beta-endorphin revealed the presence of several receptor-related species in cell lines expressing endogenous opioid receptors, including a small molecular mass protein (approximately 22 kDa). Previous reports have suggested that this 22-kDa (125)I-beta-endorphin cross-linked protein could be the degradative product from a higher molecular mass species, i.e., a fragment of the receptor. To determine if this protein is indeed a degraded receptor fragment, (125)I-beta-endorphin was cross-linked to the (His)(6) epitope-tagged mu-opioid receptor (His-mu) stably expressed in the murine neuroblastoma Neuro(2A) cells. Similar to earlier reports with cell lines expressing endogenous receptors, two major bands of 72- and 25-kDa proteins were specifically cross-linked. Initial cross-linking experiments indicated the absolute requirement of the high-affinity (125)I-beta-endorphin binding to the mu-opioid receptor prior to the appearance of the low molecular weight species, suggesting that the 22-kDa protein could be a degraded fragment of the receptor. However, variations in the ratios of these protein bands being cross-linked by several homo- or heterobifunctional cross-linking agents were observed. Although neither the carboxyl terminus mu-opioid receptor-specific antibodies nor the antibodies against the epitope at the amino terminus of the receptor could recognize the 22-kDa protein, this (125)I-beta-endorphin cross-linked species could be coimmunoprecipitated with the receptor antibodies or could be isolated with a nickel resin affinity chromatography. The direct physical association of the 22-kDa protein with the receptor was demonstrated also by the observation that the 22-kDa protein could not bind to the nickel resin alone, but that its binding to the nickel resin was restored in the presence of the His-mu. Taken together, these results suggest that the 22-kDa protein cross-linked by (125)I-beta-endorphin is not a degradative product, but a protein located within the proximity of the mu-opioid receptor, and that it is tightly associated with the receptor.     

Characterization of multiple forms of the Ah receptor: recognition of a dioxin-responsive enhancer involves heteromer formation.

We have employed a combination of gel retardation, protein-DNA cross-linking, and protein-protein cross-linking techniques to further examine the 2,3,7,8-tetrachlorodibenzo-p- dioxin-(TCDD-) dependent changes in the Ah receptor that result in a DNA-binding conformation. Gel retardation analysis of DNA-Sepharose chromatographic fractions of rat hepatic cytosol indicated that TCDD-dependent and sequence-specific DNA binding coeluted with a 200-kDa form of the Ah receptor (peak 2) previously characterized as being multimeric and having high affinity for calf thymus DNA. The TCDD-bound, 100-kDa form of the receptor (peak 1) bound weakly to the DNA recognition motif. These results indicated that the DNA-binding form of the Ah receptor is a multimer. SDS-polyacrylamide gel electrophoresis of peak 2 cross-linked to a bromodeoxyuridine-substituted DNA recognition motif indicated that this form of the receptor present in rat hepatic cytosol is composed of at least two DNA-binding proteins of approximately 100 and 110 kDa. Using the chemical cross-linking agent dimethyl pimelimidate, we further established that the 100-kDa form of the receptor (peak 1) associates with a different protein to generate the receptor form (peak 2) that binds to the dioxin-responsive enhancer. Photoaffinity-labeling studies indicated that only the 100-kDa protein (peak 1), and not the 110-kDa protein, binds ligand. Together, these observations imply that the DNA-binding form of the Ah receptor exists as a heteromer.     

Interleukin-6 signal transducer gp130 mediates oncostatin M signaling.

Oncostatin M (OM) is a multifunctional cytokine that is structurally and functionally related to interleukin 6 (IL-6) and leukemia inhibitory factor (LIF). The specific receptor for OM has been demonstrated (by chemical cross-linking) to be a 150-kDa protein in a number of cell lines. The IL-6 signal transducer, gp130, is also an affinity converter for the LIF receptor. It does not bind to either IL-6 or LIF, but associates with the alpha subunits of the receptors and transduces the signals. We examined the possible involvement of gp130 in OM binding and signaling. We demonstrate that: (a) anti-gp130 monoclonal antibodies (mAbs) block the inhibitory effect of OM on A375 cell growth, (b) the binding and cross-linking of 125I-OM to H2981 cells are completely abolished by anti-gp130 mAbs, (c) the cross-linked OM-receptor complex is immunoprecipitated by anti-gp130 mAbs, and (d) COS-7 cells transfected with the full-length cDNA encoding gp130 exhibit increased OM binding and cross-linking, which are also blocked by anti-gp130 mAbs. Therefore, we conclude that the 150-kDa OM binding protein previously characterized in a variety of cell lines is gp130. OM is the natural ligand for gp130 and gp130 mediates the biological responses of OM.     

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.     

The 260-kDa transforming growth factor (TGF)-beta binding protein in rat glomeruli is a complex comprised of 170- and 85-kDa TGF-beta binding proteins.

In a previous study (MacKay, K., Robbins, A. R., Bruce, M. D., and Danielpour, D. (1990) J. Biol. Chem. 265, 9351-9356) we showed that rat glomeruli contain transforming growth factor (TGF)-beta 1 binding proteins with apparent molecular masses of 260, 170, and 85 kDa (Gl-260, Gl-170, Gl-85) as determined by electrophoresis under nonreducing conditions. We demonstrate here that Gl-260 is a complex of 170- and 85-kDa TGF-beta binding proteins. Under denaturing conditions the integrity of Gl-260 is maintained through the cross-linking of one monomer of the disulfide-linked TGF-beta 1 homodimer to Gl-85 and of the other monomer to the 100-kDa subunit of Gl-170. In addition, some Gl-260 complexes are maintained by direct cross-linking of Gl-85 to the 100-kDa subunit of Gl-170. One-dimensional peptide maps of Gl-85 and the 100-kDa subunit of Gl-170 indicate that they have distinctly different ligand binding domains. In contrast, peptide maps of Gl-85 and the type II receptor of normal rat kidney fibroblasts are similar. The biological responses of isolated glomeruli to TGF-beta appear to parallel those of cultured glomerular cells which are without detectable Gl-170 and Gl-260 binding proteins.