Regulation of the interleukin 2 receptor complex tyrosine kinase activity in vitro.

Interleukin 2 (IL-2) has been shown to stimulate tyrosine phosphorylation of a number of proteins requiring only the p75 beta chain of the IL-2 receptor. Unlike the receptors for epidermal growth factor, insulin, and other growth factors, the p55-alpha and p75-beta chains of the IL-2 receptor have no tyrosine protein kinase domain suggesting that the IL-2 receptor complex activates protein kinases by a unique mechanism. The activation of tyrosine kinases by IL-2 in situ was studied and using a novel methodology has shown tyrosine kinase activity associated with the purified IL-2R complex in vitro. IL-2 stimulated the in situ tyrosine phosphorylation of 97 kDa and 58 kDa proteins which bound to poly(Glu,Tyr)4:1, a substrate for tyrosine protein kinases, suggesting these proteins had characteristics found in almost all tyrosine kinases. IL-2 was found to stimulate tyrosine protein kinase activity in receptor extracts partially purified from human T lymphocytes and the YT cell line. Biotinylated IL-2 was used to precipitate the high-affinity-receptor complex and phosphoproteins associated with it. The data indicated that the 97-kDa and 58-kDa phosphotyrosyl proteins were tightly associated with the IL-2 receptor complex. These proteins were phosphorylated on tyrosine residues by IL-2 stimulation of intact cells and ligand treatment of in vitro receptor extracts. Furthermore, the 97-kDa and 58-kDa proteins were found in streptavidin-agarose/biotinylated IL-2 purified receptor preparations and showed high affinity for tyrosine kinase substrate support matrixes. The experiments suggest that these two proteins are potential candidates for tyrosine kinases involved in the IL-2R complex signal transduction process.     

Recombinant interleukin-2 analogs. Dynamic probes for receptor structure.

Interleukin-2 (IL-2) and its receptor complex have become one of the most studied members of a growing family of protein hormones characterized by structural similarities in both ligands and their receptors. Structure-function studies of IL-2 have been complicated by the multimeric nature of its receptor. Two receptor subunits (55- and 75-kDa type I cell surface proteins) can participate to form the high affinity binding site. Although the IL-2 is apparently unique in some respects, similar subunit cooperativity has now been shown to be a common feature for other members of this receptor family. The availability of cell lines expressing the individual IL-2 receptor subunits has allowed detailed analysis of subunit binding characteristics. Results regarding the relationship of molecular recognition at each subunit to the mechanism of ligand binding at the high affinity site, however, have led to different interpretations. In this study we have employed previously prepared C-terminal IL-2 mutant proteins to examine receptor binding at all three classes using a variety of equilibrium and kinetic techniques. These results indicate that the high affinity IL-2 receptor complex includes the p55/p75 heterodimer prior to IL-2 binding and that both receptor subunits participate simultaneously in ligand capture.     

Putative gamma-subunit of the IL-2 receptor is detected in low, intermediate, and high affinity IL-2 receptor-bearing cells

Three forms of the IL-2R have been reported: low, intermediate, and high affinity. Each form correlates with the expression of two different chains: p55 (alpha-subunit) and p75 (beta-subunit). We report here a putative new subunit of the IL-2R, termed p95-110 or gamma-subunit. This new subunit has a molecular mass of 95 to 110 kDa and is expressed in low, intermediate, and high affinity IL-2R-bearing cells. We propose that p95-110 is the partner of p75 in the formation of intermediate affinity IL-2R, inasmuch as neither p75 nor p95-110 alone can bind IL-2.     

Interleukin 2-induced tyrosine phosphorylation. Interleukin 2 receptor beta is tyrosine phosphorylated

Interaction of interleukin 2 (IL2) with its high affinity membrane receptor complex (IL2R) is sufficient to induce proliferation of T lymphocytes. However, the biochemical mechanisms by which IL2 induces this process remain unresolved. The IL2R complex consists of at least two distinct polypeptides that bind IL2, a 75-kDa intermediate affinity subunit (IL2R beta) and a 55-kDa low affinity subunit (IL2R alpha). As indicated by Western blotting with anti-phosphotyrosine-specific antibodies and confirmed by phosphoamino acid analysis, we now demonstrate that interaction of the T cell growth factor interleukin 2 (IL2) with its high affinity receptor on IL2-sensitive human peripheral blood lymphoblasts induces tyrosine phosphorylation of proteins of 92, 80, 78, 70-75, and 57 kDa. IL2 induced tyrosine phosphorylation in YT 2C2 cells which express only the 75-kDa intermediate affinity IL2 binding molecule (IL2R beta) but not in cells which either express only the 55-kDa low affinity IL2 receptor molecule (IL2R alpha) or no IL2-binding sites. Therefore, IL2R beta, in the absence of IL2R alpha, appears sufficient to transduce the transmembrane signal leading to tyrosine phosphorylation. Two different antibodies reactive with phosphotyrosine specifically immunoprecipitated IL2R beta cross-linked to radiolabeled IL2. These findings suggest that IL2R beta is a substrate for the tyrosine kinase which is activated by IL2 binding to its receptor. Thus, like several other growth factor receptors, activation of the IL2R results in an increase in tyrosine phosphorylation with the receptor itself serving as one substrate.     

Binding of interleukin 2 to its 75-kDa intermediate affinity receptor is sufficient to activate Na+/H+ exchange

High affinity interleukin 2 (IL-2) binding sites are composed of two IL-2-binding molecules: one of 55 kDa, commonly called TaC, and another of 75 kDa. In the absence of the other IL-2-binding molecule, the 55-kDa molecule binds IL-2 with a relatively low affinity and the 75 kDa molecule binds IL-2 with an intermediate affinity. One of the earliest events following interaction of IL-2 with its receptor on the surface of cells is an increase in intracellular pH due to activation of the Na+/H+ antiport. In contrast to IL-2-induced proliferation of human IL-2-sensitive T cells, interaction of IL-2 with a low affinity binding site was sufficient to activate the Na+/H+ antiport. By determining the effect of IL-2 on cytosolic pH in cells that express one of the two IL-2-binding molecules in the absence of the other IL-2-binding molecule, we have demonstrated that interaction of IL-2 with the 75 kDa IL-2-binding molecule is sufficient to activate the Na+/H+ antiport and thus induce cytosolic alkalinization. This indicates that the 75-kDa IL-2-binding molecule, in the absence of the 55-kDa IL-2-binding molecule, forms a functional receptor that can transduce an activation signal across the cell membrane.     

Direct identification of the murine IL-2 receptor p55-p75 heterodimer in the absence of IL-2

The proteins cross-linked to the IL-2R p55 subunit were biochemically compared in distinct cell populations that varied in their capacity to express high affinity IL-2R. We directly cross-linked p75 to p55 in the absence of IL-2 for the cell populations that bear only high affinity IL-2R. Furthermore, although no endogenous IL-2 production was detected, p75 was readily cross-linked to p55 for EL4J-3.4, a p55 transfectant of EL4 that bears high affinity IL-2R. These results strongly suggest that high affinity IL-2R exist as a preformed heterodimer of p55 and p75 which do not require IL-2 for their association. Furthermore, cross-linking of three other proteins of apparent Mr of 100,000, 135,000, and 180,000 to p55 was also seen, raising the possibility of a more complex subunit composition for the IL-2R.     

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.     

Cell surface molecules that bind fibronectin's matrix assembly domain

The assembly of fibronectin into disulfide cross-linked extracellular matrices requires the interaction of mesenchymal cells with two distinct sites on fibronectin, the Arg-Gly-Asp cell adhesive site and an amino-terminal site contained within the first five type I homologous repeats (Quade, B. J., and McDonald, J. A. (1988) J. Biol. Chem. 263, 19602-19609). Proteolytically derived 29-kDa fragments of fibronectin (29kDa) containing these repeats bind to monolayers of cultured fibroblasts and inhibit fibronectin matrix assembly. The cell surface molecules interacting with fibronectin's 29-kDa matrix assembly domain have resisted purification using conventional methods such as affinity chromatography. Accordingly, in order to identify molecules which bind this fragment, 125I-labeled 29kDa was allowed to bind to fibroblast monolayers and chemically cross-linked to the cell surface with bis(sulfosuccinimidyl) suberate. Extraction of the cross-linked cell layer yielded radiolabeled complexes of 56, 150, and 280 kDa. Formation of these cross-linked complexes was specifically inhibited by the addition of excess unlabeled 29kDa but was unaffected by the presence of fibronectin fragments containing other type I repeats outside of the 29kDa matrix assembly domain. The cross-linked complexes were insoluble in nondenaturing detergents but soluble when denatured and reduced, suggesting that 29kDa may be cross-linked to components of the pericellular matrix. Immunoprecipitation of cross-linked cell extracts with a polyclonal antibody to fibronectin that does not recognize the amino terminus demonstrate that the 280-kDa band contains 29kDa cross-linked to fibronectin present on the cell surface. Formation of the 150-kDa complex was inhibited by EDTA, suggesting that divalent cations are required for its formation. Although the molecular mass and divalent cation requirement suggest that the 150-kDa complex may be related to an integrin, this complex was not immunoprecipitated by polyclonal antibodies generated to the alpha 5 beta 1 integrin fibronectin receptor.     

Phosphorylation of a cytosolic 65-kDa protein induced by interleukin 1 in glucocorticoid pretreated normal human peripheral blood mononuclear leukocytes

The authors have previously observed that glucocorticoids dramatically increase the number of interleukin 1 (IL-1) receptors on normal human peripheral blood mononuclear cells (PBMC) (from approximately 100 to 2000 receptors/cell) without significant change in the binding affinity (Kd = approximately 2.6 x 10(-10) M). We, therefore, used such a receptor-enriched glucocorticoid-pretreated PBMC to investigate whether IL-1 induces/increases the phosphorylation of any cell-associated proteins, including possible autophosphorylation of IL-1 receptors. Extraction of 125I-labeled IL-1 alpha cross-linked to IL-1 receptor on steroid-treated PBMC yielded two bands estimated to be 60 and 70 kDa in molecular mass. No molecules were significantly cross-linked with 125I-labeled IL-1 alpha on untreated PBMC. Carrier-free recombinant human IL-1 alpha induced phosphorylation of an acidic 65-kDa protein (pp65) at serine residues within 5 min more effectively in glucocorticoid-treated PBMC than in untreated PBMC. Fractionation of extracts of IL-1-stimulated prednisolone-pretreated PBMC by ultracentrifugation showed that pp65 is located in the cytosol, suggesting that pp65 is not the IL-1 receptor itself. Protein kinase inhibitors, HA1004 and W-7, but not H-7, significantly inhibited the induction of the phosphorylation of 65-kDa protein by IL-1. These data indicate that the glucocorticoid-induced IL-1 receptor is functional and either contains or is closely associated with a serine kinase that is distinct from protein kinase C.     

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.     

Purification of a 130-kDa T cell glycoprotein that binds human interleukin 4 with high affinity

The interleukin 4 (IL-4) receptor was purified from the gibbon T cell line MLA 144. These cells were found to express high numbers of human IL-4-binding proteins (5000-6000 sites/cell) with an affinity constant (Kd) similar to that measured in human cell lines (Kd = 40-70 pM). Affinity cross-linking of 125I-IL-4 to human cell lines and MLA 144 cells demonstrated the labeling of three proteins of approximately 130, 75, and 65 kDa. Human IL-4-binding sites were solubilized from MLA 144 cells using Triton X-100 and then purified by carboxymethyl chromatography, which removed 50% of the protein without loss of IL-4-binding activity. Then sequential affinity purification over wheat germ agglutinin and a single IL-4 Affi-Gel 10 column resulted in a final 8000-fold purification of the IL-4 receptor. When analyzed on a silver-stained sodium dodecyl sulfate-polyacrylamide gel, the purified receptor migrated as a single molecular species of 130 +/- 5 kDa. Identification of the 130-kDa protein as the IL-4 receptor was demonstrated by cross-linking experiments and specific binding of 125I-IL-4 to nitrocellulose membranes after electrophoretic transfer of the purified receptor on sodium dodecyl sulfate-polyacrylamide gel.     

Identification of the second subunit of the murine interleukin-5 receptor: interleukin-3 receptor-like protein, AIC2B is a component of the high affinity interleukin-5 receptor.

Murine interleukin-5 (IL-5) binds to its receptor with high and low affinity. It has been shown that the high affinity IL-5 receptor (IL-5-R) is composed of at least two membrane protein subunits and is responsible for IL-5-mediated signal transduction. One subunit of the high affinity IL-5-R is a 60 kDa membrane protein (p60 IL-5-R) whose cDNA was isolated using the anti-IL-5-R monoclonal antibody (mAb), H7. This subunit alone binds IL-5 with low affinity. The second subunit does not bind IL-5 by itself, and is expressed not only on IL-5-dependent cell lines but also on an IL-3-dependent cell line, FDC-P1. Expression of the p60 IL-5-R cDNA in FDC-P1 cells, which do not bind IL-5, reconstituted the high affinity IL-5-R. We have characterized the second subunit of the IL-5-R by using another anti-IL-5-R mAb, R52.120, and the anti-IL-3-R mAb, anti-Aic-2. The anti-Aic-2 mAb down-regulated binding of IL-5 to an IL-5-dependent cell line, Y16. Both R52.120 and anti-Aic-2 mAbs recognized membrane proteins of 130-140 kDa expressed on FDC-P1 and Y16 cells. The R52.120 mAb recognized both murine IL-3-R (AIC2A) and its homologue (AIC2B) expressed on L cells transfected with suitable cDNAs. The high affinity IL-5-R was reconstituted on an L cell transfectant co-expressing AIC2B and p60 IL-5-R, whereas only the low affinity IL-5-R was detected on a transfectant co-expressing AIC2A and p60 IL-5-R.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular cloning of the guinea-pig IL-5 receptor alpha and beta subunits and reconstitution of a high affinity receptor

The functional IL-5 receptor is a heteromeric complex consisting of an alpha and beta subunit. The cloning, sequencing and expression of guinea-pig IL-5Ralpha and beta subunits is described. The guinea-pig IL-5Ralpha subunit cDNA encodes a protein of M(r)47 kDa, which is 72 and 66% homologous to the human and murine orthologs, respectively. Three guinea-pig IL-5Rbeta subunit cDNA clones were isolated, which differ in the N-terminus and are 56-64% homologous to the human and murine IL-5Rbeta subunits. Expressing human IL-5Ralphabeta and guinea-pig IL-5Ralphabeta(1)in the baculovirus-insect cell system resulted in recombinant receptors which bound hIL-5 with high affinity (K(d)=0.19 and 0.11 nM, respectively). Expressing just gpIL-5Ralpha was not sufficient to demonstrate binding. This contrasts with the human receptor, where hIL-5Ralpha alone can bind hIL-5 with high affinity. gpIL-5Ralphabeta(1)bound both hIL-5 and mIL-5 with comparable affinity (K(i)=0.10 and 0.06 nM), similar to that seen with hIL-5Ralphabeta. Thus, both the heteromeric hIL-5R and gpIL-5Ralphabeta(1)can bind multiple IL-5 orthologs with high affinity whereas the murine IL-5R is selective for the murine ligand.     

Identification of heparan sulfate proteoglycan as a high affinity receptor for acidic fibroblast growth factor (aFGF) in a parathyroid cell line.

We have characterized two high affinity acidic fibroblast growth factor (aFGF) receptors in a rat parathyroid cell line (PT-r). Affinity labeling with 125I-aFGF showed that these two receptors, apparent molecular masses, 150 and 130 kDa, respectively, display higher affinity for aFGF than for bFGF. The 150-kDa receptor bears a heparan sulfate chain(s), demonstrated by a decrease in size of 15-20 kDa with heparitinase digestion after affinity labeling. Heparitinase digestion before affinity labeling markedly reduced the intensity of the 150 kDa species. Scatchard analysis showed two different high affinity binding sites (Kd of 3.9 pM with 180 sites/cell and Kd of 110 pM with 5800 sites/cell). The higher affinity site was completely eliminated by digestion with heparitinase before adding labeled aFGF; the lower affinity site was unaffected. In ion exchange chromatography after metabolic labeling of the cells with [3H]glucosamine and affinity labeling with 125I-aFGF, the larger receptor-ligand complex, 165 kDa, eluted with approximately 0.5 M NaCl, typical eluting conditions for heparan sulfate proteoglycans. Both of the receptor-ligand complexes were smaller on sodium dodecyl sulfate-polyacrylamide gel electrophoresis than two major heparan sulfate proteoglycans, HSPG I and II, which we characterized in this cell line previously (Yanagishita, M., Brandi, M. L., and Sakaguchi, K. (1989) J. Biol. Chem. 264, 15714-15720). Both receptors have similar N-linked oligosaccharide and sialic acid contents, shown by analysis of affinity-labeled receptors upon digestion with glycopeptidase F and with neuraminidase. All together, these results suggest that PT-r cells bear two distinct high affinity receptors for aFGF, a 150-kDa receptor which is a heparan sulfate proteoglycan and another that is a glycoprotein. The heparan sulfate glycosaminoglycan moiety of the 150- kDa receptor is critical for high affinity binding of aFGF. These findings contrast with current concepts derived from other systems, suggesting that heparan sulfate glycosaminoglycans/proteoglycans function as a reservoir source for FGF or as a group of low affinity binding sites.     

Species specificity of human and murine tumor necrosis factor. A comparative study of tumor necrosis factor receptors

Recombinant murine and human tumor necrosis factor (mTNF and hTNF, respectively) were radioiodinated to high specific activity using a solid-phase lactoperoxidase method. A single class of high affinity receptors for 125I-TNF was identified on TNF-sensitive murine L cells and human HeLa S2 cells. Competitive radioligand binding assays were used to study the species specificity of TNF preparations. Unlabeled hTNF competed 30-fold less effectively than mTNF for binding to L cell receptors, whereas mTNF competed to approximately the same extent as hTNF for binding to HeLa cell receptors. A similar species specificity was observed in cytotoxicity assays; hTNF was more cytotoxic for HeLa cells than mTNF. Conversely, mTNF was more growth inhibitory and cytotoxic for L cells than hTNF. mTNF. and hTNF.receptor complexes were compared by gel filtration chromatography and polyacrylamide gel electrophoresis before and after cross-linking with bis[2-(succinimidooxycarbonyloxy)ethyl]sulfone (BSOCOES). These complexes eluted in gel filtration at a position corresponding to a globular protein of 350,000 Mr. Gel autoradiographs of the fractions containing cross-linked complexes showed bands of 95,000 and 75,000 Mr as well as small amounts of higher Mr bands. mTNF and hTNF treated with BSOCOES formed cross-linked dimers and trimers. Therefore, we were unable to determine whether the 95,000 and 75,000 Mr bands represented two distinct subunits of receptors or one subunit to which either a dimer or a monomer of TNF was cross-linked. These results demonstrate species specificity in the TNF-receptor interaction. In addition, the affinity labeling studies in two species give an identical pattern for the TNF X receptor complexes, suggesting that the receptors have similar subunit composition.     

Murine interleukin-2 receptor subunits differentially detected with anti-interleukin-2 monoclonal antibodies

Cross-linking of radioiodinated interleukin-2 to murine CTLL-2 cells enabled detection of 70 kDa, 85 kDa and 105 kDa complexes of IL-2 and its binding proteins under the high-affinity binding condition. A series of anti-interleukin-2 monoclonal antibodies (L15, L20, L23, L34, and L61) were tested for their activity to immunoprecipitate these cross-linked complexes. L61, which had strong neutralizing activity, precipitated only the 70 kDa complex. L15, L20, and L34, which also had neutralizing activity, precipitated not only the 70 kDa complex but also the 85 kDa complex. L23, which had practically no neutralizing activity, precipitated the 105 kDa complex as well as the 85 kDa complex. These results suggest that there are at least three distinct receptor binding sites for each receptor subunit on the interleukin-2 molecule, which are discernible by these monoclonal antibodies and that the 105 kDa complex may play a significant role in the formation of the high-affinity receptor complex and the signal transduction.     

Possible association between IL-2 receptors and class I HLA molecules on T cells

In the process of evaluating murine hybridomas for an antibody to the beta-subunit of the IL-2R (p70) we identified an antibody that immunoprecipitated a 55- to 57-kDa complex from cross-linked lysates. We demonstrate that this complex is composed of IL-2 (15.5 kDa) cross-linked to the H chain of HLA class I (40 to 42 kDa), suggesting a molecular interaction between HLA class I molecules and IL-2R. Although the exact role of this association remains to be determined, the specific cross-linking of IL-2 to HLA class I Ag is intriguing in view of published claims for a role of HLA class I in OKT3-induced lymphocyte proliferation and in NK cell lytic activity.     

Affinity Purification of Angiotensin Type 2 Receptors from N1E-115 cells: Evidence for Agonist-Induced Formation of Multimeric Complexes

Abstract: The murine neuroblastoma N1E-115 cell line possesses type 1 and type 2 angiotensin II (Angll) receptor subtypes. In vitro differentiation of these cells substantially increases the density of the AT₂-receptor subtype, whereas the density of the AT₁ receptors remains unchanged. In the present study, we report that the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]- 1-propanesulfonate (CHAPS) selectively solubilized AT₂receptors from N1E-115 cell membranes and that these receptors could be purified further to near homogeneity by affinity chromatography. More specifically, the presence of an agonist (Angll) during affinity purification of AT₂ receptors resulted in the elution of high (110-kDa) and low (66-kDa) molecular mass proteins as determined by gel electrophoresis under nonreducing conditions. In contrast, when the nonselective antagonist Sar¹, lle⁸-Angll was used during purification, only the lower 66-kDa protein was observed. Affinity purification in the presence of the peptide and nonpeptide AT₂-receptor antagonists CGP42112A and PD123319 also resulted in elution of the same 66-kDa protein, but unlike that in the presence of Sar¹, lle⁸-Angll, some of the high molecular weight site was observed as well. On the other hand, Losartan, an AT₁-receptor antagonist, was completely ineffective in eluting any Angll receptors from the affinity column, further confirming their AT₂ identity. After agonist elution, the 110-kDa band dissociated into two low molecular mass bands of 66 kDa and 54 kDa when sodium dodecyl sulfate-gel electrophoresis was run under reducing conditions. The 110-kDa and 66-kDa proteins, but not smaller, affinity-purified proteins, specifically bound ¹²⁵l-Angll as determined by covalent cross-linking of ¹²⁵l-Angll to the receptors with the homobifunctional cross-linker disuccinimidyl suberate, or by size exclusion chromatography on a TSK 3000 SW column. Lastly, immunoblot analysis of affinity- purified material with antibodies selective for AT₂ receptors revealed major immunoreactive proteins of 110 kDa and 66 kDa in the presence of an agonist, whereas the same 66-kDa protein, as well as a smaller (54-kDa) immunoreactive protein, was detected under reducing conditions. Collectively, these data suggest that CHAPS-solubilized AT₂ receptors from N1E-115 cells may consist of a binding protein of approximately 66 kDa, which in the presence of an agonist readily associates with other smaller proteins to form larger multimeric complexes.     

Solubilization of the functional C5a receptor from human polymorphonuclear leukocytes

The C5a receptor has been extracted in an active state from the membranes of human polymorphonuclear leukocytes with the detergents digitonin and beta-dodecyl maltoside. The solubilized receptor exhibits a single class of high affinity binding sites with a Kd = 90 pM, a value similar to that found with intact membranes. Physical studies with the soluble receptor demonstrate that it exists in two forms which differ in molecular mass. Gel filtration experiments with receptor to which C5a has been bound give an apparent molecular mass for the complex of 150-200 kDa. When the experiments were repeated with nonliganded receptor, most of the C5a binding activity eluted with an apparent mass of 150-200 kDa. However, the peak had a pronounced trailing shoulder indicating that, in the nonliganded state, a portion of the receptor population exists in a smaller form, which may be converted to the larger form on binding C5a. The molecular mass of the smaller form, estimated to be 30-70 kDa, is consistent with that of the binding subunit of the receptor. These data imply that the larger form, and therefore the bulk of the solubilized receptor, is oligomeric, a conclusion which is supported by cross-linking studies. When C5a was cross-linked to the soluble receptor two specific complexes with molecular masses of 52 and 95 kDa were formed. The former is the covalent adduct of C5a and the binding subunit of the receptor and the latter appears to be a complex between the 52-kDa species and an additional polypeptide.