Purification and characterization of the human brain insulin receptor

The insulin receptor from human brain cortex was purified by a combination monoclonal antibody affinity column and a wheat germ agglutinin column. This purified receptor preparation exhibited major protein bands of apparent Mr = 135,000 and 95,000, molecular weights comparable to those for the alpha and beta subunits of the purified human placental and rat liver receptors. A minor protein band of apparent Mr = 120,000 was also observed in the brain receptor preparation. Crosslinking of 125I-insulin to all three receptor preparations was found to preferentially label a protein of apparent Mr = 135,000. In contrast, cross-linking of 125I-labeled insulin-like growth factor I to the brain preparation preferentially labeled the protein of apparent Mr = 120,000. The purified brain insulin receptor was found to be identical with the placental insulin receptor in the amount of neuraminidase-sensitive sialic acid and reaction with three monoclonal antibodies to the beta subunit of the placental receptor. In contrast, a monoclonal antibody to the insulin binding site recognized the placental receptor approximately 300 times better than the brain receptor. These results indicate that the brain insulin receptor differs from the receptor in other tissues and suggests that this difference is not simply due to the amount of sialic acid on the receptor.     

Deglycosylation and proteolysis of photolabeled D2 dopamine receptors of the porcine anterior pituitary

Dopamine D2 receptor binding subunits of the porcine anterior pituitary were visualized by autoradiography following photoaffinity labeling with [125I]N-azidophenethylspiperone and sodium dodecyl-sulfate polyacrylamide gel electrophoresis. The ligand binding subunit comprising the pituitary D2 dopamine receptor migrated as two distinct bands of apparent Mr approximately equal to 150,000 and 118,000, substantially higher than neuronal D2 receptor subunits from porcine or canine brain. The glycoprotein nature of pituitary D2 receptor binding subunits was investigated by the use of exo- and endo-glycosidase treatments and peptide mapping experiments. Photoaffinity labeled polypeptides of the anterior pituitary were susceptible to both neuraminidase and alpha-mannosidase digestion as indexed by their increased electrophoretic mobility on sodium dodecyl-sulfate polyacrylamide gels, and suggests the presence of both complex type and terminal mannose carbohydrate residues. Moreover, the additive effects of sequential treatment with these enzymes suggests that both types of carbohydrate chains are present on each receptor peptide. N-linked deglycosylation of pituitary D2 photolabeled receptors with glycopeptidase-F produced a further increase in the mobility of the labeled protein to apparent Mr approximately equal to 44,000, similar to that of deglycosylated D2 binding subunits of porcine and canine brain. Peptide mapping experiments following limited proteolysis with Staphylococcus aureus V8 proteinase and papain demonstrated that deglycosylated D2 dopamine receptors (Mr = 44,000), in different tissues and species, were homologous. Taken together, these data suggest that despite the differences in the overall molecular weight and tissue specific glycosylation pattern of pituitary D2 dopamine receptors, the primary structure of mammalian D2 receptors appears to be conserved.     

Comparative studies on human placental insulin and basic somatomedin receptors

The disuccinimidy! suberate, affinity-labeling procedure, and proteolytic mapping techniques have been employed to characterize further the human placental receptors for insulin and basic somatomedin. Electrophoretic analysis of the basic somatomedin receptor, selectively crosslinked to ¹²⁵I basic somatomedin in the presence of excess native insulin revealed, under reducing conditions, major labeled constituents of 270-280 and 125-140 kd, substantiating our previous work employing a photoaffinity labeling reagent. Affinity labeling also demonstrated the presence of less intensely labeled components with apparent molecular weights of 40 and 45 kd but failed to reveal a distinct 90- to 100-kd species observed in parallel experiments with insulin. In the absence of β-mercaptoethanol, all components specifically labeled with ¹²⁵I basic somatomedin migrated in the 300- to 400-kd range. In comparison, selective affinity labeling of the insulin receptor in the presence of excess native basic somatomedin revealed components, upon electrophoresis under reducing conditions, with apparent molecular weights of 270-280, 125-140, 90-100, and 40 kd. The major insulin-labeled component (125-140 kd) comigrated with the major constituent (125-140 kd) selectively labeled with basic somatomedin. When digestion was performed prior to solubilization, chymotryptic and tryptic proteolysis of the membrane-localized selectively labeled insulin, and basic somatomedin receptors yielded quite similar gel electrophoretic maps. However, when digestion was done subsequent to solubilization, chymotryptic and tryptic proteolysis of selectively labeled insulin and basic somatomedin receptors solubilized in SDS yielded similar but not identical gel electrophoretic maps. We conclude that the receptors for basic somatomedin and insulin are highly homologous structures with respect to their disulfide crosslinked composition, and with respect to the size of the major components detected by selective affinity-labeling procedures. Nevertheless, the detection of electrophoretically distinct labeled receptor components upon analysis of specifically labeled intact or proteolytically digested receptors points to subtle differences between the polypeptide compositions of the two receptors.     

The brain corticotropin-releasing factor (CRF) receptor is of lower apparent molecular weight than the CRF receptor in anterior pituitary. Evidence from chemical cross-linking studies

The ligand binding subunits of the corticotropin-releasing factor (CRF) receptors in brain and anterior pituitary of a number of species have been identified by chemical affinity cross-linking using the homobifunctional cross-linking agent disuccinimidyl suberate and 125I-Tyr0-oCRF (ovine CRF). In homogenates of rat, monkey, and human cerebral cortex, 125I-Tyr0-oCRF was covalently incorporated into a protein of Mr = 58,000. Under identical conditions in the anterior pituitary of rat, monkey, cow, and pig, 125I-Tyr0-oCRF was incorporated into a protein of apparent Mr = 75,000. The specificity of the labeling was typical of the CRF binding site since both the cerebral cortex- and pituitary-labeled proteins exhibited the appropriate pharmacological rank order profile characteristic of the CRF receptor (Nle21,Tyr32-oCRF approximately equal to rat/human CRF approximately equal to ovine CRF approximately equal to alpha-helical CRF(6-41) greater than alpha-helical oCRF(9-41) greater than or equal to oCRF(7-41) greater than rat/human CRF(1-20) approximately equal to vasoactive intestinal peptide). In addition to the major labeled proteins, 125I-Tyr0-oCRF was incorporated into higher molecular weight peptides which may represent precursors and into lower molecular weight components which may represent fragments of the major labeled proteins or altered forms of the CRF binding subunit. In summary, these data indicate a heterogeneity between brain and pituitary CRF receptors with the ligand binding subunit of the brain CRF receptor residing on a Mr = 58,000 protein, while in the anterior pituitary, the identical binding subunit resides on a protein of apparent Mr = 75,000.     

Structural and Functional Characteristics of Insulin Receptors in Rat Neuroblastoma Cells

Insulin receptors were detected in a variety of rat neuroblastoma and glioma cell lines. The binding of 125I-insulin to B103 neuroblastoma cells had characteristics typical of insulin receptors in other tissues, including high affinity for insulin, low affinity for insulin-like growth factor I (IGF-I), and curvilinear Scatchard plots. Using photoaffinity labeling procedures and sodium dodecyl sulfate (SDS) gel electrophoresis to analyze the subunit structure of insulin receptors in B103 cells, the predominantly labeled protein had an apparent molecular weight of 125K and the mobility of this protein was shifted after removal of sialic acid residues. On the basis of size and susceptibility to neuraminidase, the insulin binding subunit in neuroblastoma cells was identical to the alpha-subunit of insulin receptors in adipocytes and different from the 115K subunit found in brain. The presence of an "adipocyte" form of the insulin receptor in clonal cells derived from brain is probably a consequence of transformation and results from more extensive oligosaccharide processing of the 115K receptor expressed in normal brain cells. The fully glycosylated receptors in neuroblastoma cells were capable of exerting functions typical of insulin receptors in adipocytes such as internalization of insulin and stimulation of glucose transport.     

Evidence for a subtype of insulin-like growth factor I receptor in brain

We examined the structure of receptors for insulin-like growth factor I (IGF-I), insulin, and epidermal growth factor (EGF) in human brain and human placenta using affinity cross-linking procedures and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In human brain, proteins specifically cross-linked to 125I-IGF-I, 125I-insulin, and 125I-EGF had apparent molecular weights of 120,000, 115,000 and 170,000, respectively. In human placenta, proteins cross-linked to 125I-IGF-I and 125I-insulin were 10 kDa larger than the corresponding subunits in brain. The receptor labeled by 125I-EGF in placenta was indistinguishable from the EGF receptor in brain. The size discrepancy of IGF-I receptors in brain and placenta was no longer apparent after removing the carbohydrate moieties of the proteins with endo-beta-N-acetylglucosaminidase F (EndoF). Furthermore, the brain IGF-I receptor was not cleaved by neuraminidase, whereas, the placental IGF-I receptor had increased mobility on SDS gels following neuraminidase treatment. The results indicate that receptors for IGF-I and insulin in human brain are structurally distinct from the corresponding receptors in human placenta, the structural heterogeneity of the receptors involves differences in N-linked glycosylation, particularly the terminal processing steps, and EGF receptors are present in human brain and human placenta but are structurally similar in these tissues. We conclude that there is a selective modification in the glycosylation of receptors for IGF-I and insulin in brain.     

The effect of reducing agents on the structure of mammalian beta-adrenergic receptors

Under reducing conditions (5% beta-mercaptoethanol) the mammalian beta-adrenergic receptor binding site from both beta 1 (porcine heart membranes) and beta 2 receptors (hamster lung and rat erythrocyte membranes) appears to reside on peptides of Mr 62,000-65,000 as determined by photoaffinity labeling with p-azido-m-[125I]iodobenzylcarazolol and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When similar experiments are performed in these same systems under a variety of non-reducing conditions, there are minimal changes in the apparent molecular weight of both the beta 1- and beta 2-adrenergic receptor binding subunits and no specifically labeled higher molecular weight proteins are observed suggesting that there are no disulfide linked subunits in mammalian beta-adrenergic receptors.     

Use of the heterobifunctional cross-linker m-maleimidobenzoyl N-hydroxysuccinimide ester to affinity label cholecystokinin binding proteins on rat pancreatic plasma membranes

The binding of 125I-cholecystokinin-33 (125I-CCK-33) to its receptors on rat pancreatic membranes was decreased by modification of membrane protein sulfhydryl groups. Sulfhydryl modifying reagents also caused an accelerated release of bound 125I-CCK-33 from its receptor. Because of the presence of an essential sulfhydryl group(s) in CCK receptor binding we studied the application of the heterobifunctional (SH,NH2) cross-linker, m-maleimidobenzoyl N-hydroxysuccinimide ester (MBS), to affinity label 125I-CCK-33 binding proteins on rat pancreatic plasma membranes. Analysis of the cross-linked products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography revealed that this heterobifunctional cross-linker affinity labeled a major Mr = 80,000-95,000 protein previously identified as part of the CCK receptor on the basis of affinity labeling using homobifunctional and heterobifunctional photoreactive cross-linkers. Additional proteins of Mr greater than 200,000, and Mr = 130,000-140,000 were affinity labeled using MBS. The efficiency of the cross-linking reaction between 125I-CCK-33 and its membrane binding proteins with MBS was significantly greater than that obtained with NH2-directed homobifunctional reagents such as disuccinimidyl suberate. The efficiency of cross-linking could be dramatically improved by reduction of membrane proteins with low-molecular weight thiols prior to binding and cross-linking. The differential labeling patterns of the CCK binding proteins obtained with chemical cross-linkers of similar length but different chemical reactivity underscores the need for caution in predicting native receptor structure from affinity labeling data alone. Using the same pancreatic plasma membrane preparation and 125I-insulin, the Mr = 125,000 alpha-subunit of the insulin receptor was affinity labeled using MBS as cross-linker, demonstrating its utility in identifying other peptide hormone receptors.     

The subunit structure of the insulin receptor and molecular interactions with major histocompatibility complex antigens

Insulin receptors were labeled with 125I-photoreactive insulin (specifically labeling alpha-subunits) and by insulin-stimulated autophosphorylation (specifically labeling beta-subunits). The results show that the insulin receptor exists under different free and disulfide-linked combinations of alpha and beta subunits. Moreover, the insulin receptor is closely associated to class I antigens of the major histocompatibility complex to form a high molecular weight multi-molecular membrane complex.     

Affinity labeling of multiplication stimulating activity receptors in membranes from rat and human tissues

Plasma membranes from rat adipocytes and liver and from human placenta have been labeled by covalent cross-linking to membrane-bound 125I-labeled multiplication stimulating activity (125I-MSA) with three different bishydroxysuccinimide esters: disuccinimidyl suberate, disuccinimidyl succinate, and ethyleneglycolyl bis(succinimidyl succinate). Dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiographic analysis of the 125I-MSA-labeled material in the presence of dithiothreitol reveals one single-labeled protein migrating with an apparent Mr = 255,000 regardless of the kind and concentration of cross-linker used. Electrophoresis in the absence of reductant indicates that the affinity-labeled species is not disulfide-linked to any other protein in the native plasma membrane, but contains internal disulfide bonds that compact its structure. The labeling of the Mr = 255,000 species increases with increasing concentrations of 125I-MSA between 0.3 and 3 nM. Labeling is abolished in a competitive manner by nonradioactive MSA but not by similar concentrations of insulin, proinsulin, or epidermal growth factor in all three tissues examined. The unique labeling of this Mr = 225,000 membrane component and its selective inhibition by MSA suggest that this protein is a plasma membrane receptor for MSA.     

Preparation of enriched plasma membranes from bovine gallbladder muscularis for characterization of cholecystokinin receptors

A method for the preparation of enriched plasma membranes from bovine gallbladder muscularis was developed, validated, and applied to the characterization of receptors for the gastrointestinal hormone cholecystokinin (CCK) on this target. Binding of radioiodinated CCK ligands to this preparation was rapid, reversible, temperature-dependent, saturable, and specific. Only structurally related peptides inhibited CCK binding, and good correlation existed between relative potencies for binding inhibition and for stimulating gallbladder contraction. Computer analysis of CCK-binding data using a nonlinear model-fitting program best fit a model with a single class of sites, with Kd 756 pm and binding capacity 4.5 +/- 1.3 pmol/mg of protein. This degree of enrichment for plasma membranes was adequate for the initial biochemical characterization of this CCK receptor. Affinity labeling using 125I-Bolton Hunter-CCK-33 and m-maleimidobenzoyl-N-hydroxysuccinimide ester identified proteins with Mr = 70,000-85,000, Mr = 120,000-125,000, and Mr = 200,000. Labeling was inhibited in a concentration-dependent manner, with an IC50 of 1 nM CCK-8, and the electrophoretic mobility of these bands was not different under reducing and nonreducing conditions. The major labeled band of Mr = 70,000-85,000 has a lower apparent Mr than that of the analogous band in pancreas labeled with similar methods, supporting the molecular heterogeneity of CCK receptors on these two target tissues.     

Characterization and photoaffinity labeling of a calcitonin gene-related peptide receptor solubilized from human cerebellum.

Calcitonin gene-related peptide (CGRP) receptors were solubilized from human (h) cerebellum with use of the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid (CHAPS). Scatchard analysis of equilibrium binding data indicated that the soluble extract contained a single class of CGRP binding sites with apparent dissociation constants of 50 pM for the intact 125I-hCGRP-I(1-37) and 160 pM for the antagonist 125I-hCGRP-I(8-37). Unlabeled hCGRP-I and -II and hCGRP-I(8-37) displaced 125I-hCGRP-I from solubilized CGRP receptors with similar potencies (ID50 = 70-150 pM). Human CGRP-I(15-37), -(21-37), and -(28-37) were less potent (ID50 greater than or equal to 70 nM), suggesting that amino acid residues 8-14 may be important for maintaining high binding affinity. A novel photoreactive analogue of hCGRP-I, 125I-[C gamma-(4-azidoanilino)Asp3] hCGRP-I, was prepared by carbodiimide coupling of 4-azidoaniline to 125I-hCGRP-I. Photoaffinity labeling of soluble CGRP receptors with the photoreactive analogue and analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography revealed three specifically labeled binding proteins with apparent molecular weights (Mr) of 60,000, 54,000, and 17,000. Cross-linking of 125I-hCGRP-I and -II and 125I-hCGRP-I(8-37) to soluble CGRP binding sites using disuccinimidyl suberate revealed three specifically labeled binding proteins with the same Mr. The C-terminal fragment 125I-hCGRP-I(8-37), unlike the intact peptide, was, furthermore, cross-linked specifically to a 95,000 Mr protein. The CGRP receptor is N-glycosylated. Treatment with endoglycosidase F/N-glycosidase F converted the 60,000 and 54,000 to 46,000 and 41,000 Mr components.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of the human placental receptor for basic somatomedin

We have determined optimal conditions for the solubilization of the basic somatomedin (SM) receptor from human placental membranes and for the measurement of the binding of basic SM to the solubilized receptor. Further, we have developed conditions under which the basic SM receptor, in the presence of equivalent amounts of insulin receptor, can be selectively and specifically affinity-labeled with 125I-labeled basic SM, using the cross-linking reagent disuccinimidyl suberate (DSS). Our results with these developed methods indicate that the properties of the soluble basic SM receptor (pH optimum for ligand binding, pH 7 to 9; adsorption to lectin-agarose derivatives; sedimentation coefficient in detergent-sucrose solutions, 11S) closely parallel data previously reported for the insulin receptor. Based on the sedimentation coefficient and the previously estimated Stokes radius of the soluble receptor (7.2 nm), a molecular weight of 402 000 can be calculated for the detergent-receptor complex. Electrophoretic analysis of the basic SM receptor, selectively cross-linked to 125I-labeled basic SM with DSS in the presence of excess unlabeled insulin revealed, under reducing conditions, a major labeled constituent of 140 kdaltons, substantiating our previous work employing a photoaffinity labeling reagent. DSS cross-linking also demonstrated the presence of less intensely labeled components with apparent molecular weights of 54 000, 43 000 and 35 000 but failed to reveal a distinct 90- to 100-kdalton species visualized in parallel experiments with insulin. The 53-kdalton species was not detected in similar experiments with insulin. A specifically labeled basic SM receptor component of 300 kdaltons was also observed under reducing conditions; in the absence of beta-mercaptoethanol, all labeled components migrated in the 300-kdalton range. In comparison, selective DSS labeling of the insulin receptor in the presence of excess basic SM revealed components which, upon electrophoresis under reducing conditions, exhibited apparent molecular weights of 300 000, 140 000, 90 000--100 000, 43 000 and 35 000. The major insulin-labeled component (140 000) comigrated with the major constituent (140 000) selectively labeled with basic SM. Chymotryptic digestion of the receptors selectively DSS labeled with either 125I-labeled insulin or 125I-labeled basic SM yielded quite similar, but distinctive, gel electrophoretic maps. We conclude that the receptors for basic SM and insulin are highly homologous structures, particularly with respect to their glycoprotein nature, their hydrodynamic properties, their disulphide cross-linked composition, and with respect to the size of the major constituent detected by selective affinity labeling. Nonetheless, the detection of electrophoretically distinct labeled receptor substituents upon analysis of specifically labeled material, both before and after chymotryptic cleavage, points to subtle differences between the polypeptide compositions of the two receptors.     

Photoaffinity labeling of dopamine D1 receptors

A high-affinity radioiodinated D1 receptor photoaffinity probe, (+/-)-7-[125I]iodo-8-hydroxy-3-methyl-1-(4-azidophenyl)-2,3,4,5-tetra hyd ro- 1H-3-benzazepine ([125I]IMAB), has been synthesized and characterized. In the absence of light, [125I]IMAB bound in a saturable and reversible manner to sites in canine brain striatal membranes with high affinity (KD approximately equal to 220 pM). The binding of [125I]IMAB was stereoselectively and competitively inhibited by dopaminergic agonists and antagonists with an appropriate pharmacological specificity for D1 receptors. The ligand binding subunit of the dopamine D1 receptor was visualized by autoradiography following photoaffinity labeling with [125I]IMAB and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Upon photolysis, [125I]IMAB incorporated into a protein of apparent agents in a stereoselective manner with a potency order typical of dopamine D1 receptors. In addition, smaller subunits of apparent Mr 62,000 and 51,000 were also specifically labeled by [125I]IMAB in these species. Photoaffinity labeling in the absence or presence of multiple protease inhibitors did not alter the migration pattern of [125I]IMAB-labeled subunits upon denaturing electrophoresis in both the absence or presence of urea or thiol reducing/oxidizing reagents. [125I]IMAB should prove to be a useful tool for the subsequent molecular characterization of the D1 receptor from various sources and under differing pathophysiological states.     

Characterization of a neuronal subtype of insulin-like growth factor I receptor

Primary neuronal cultures from fetal rat brain were utilized to investigate the possible role of insulin-like growth factor I (IGF-I) in neuronal growth and differentiation. 125I-IGF-I binding to intact cultured neurons was specific and saturable with an apparent Kd of 7.0 +/- 1.2 nM and a Bmax of 1.8 +/- 0.3 pmol/mg protein. Binding of 125I-IGF-I to neurons was inhibited by IGF-I, followed by IGF-II and insulin. 7 S nerve growth factor, but not beta-nerve growth factor, also inhibited 125I-IGF-I binding. A similar binding site was detected on brain membranes. Affinity cross-linking of 125I-IGF-I to intact cultured neurons revealed, under reducing conditions, a major binding moiety with an Mr of 115,000 and a minor component at Mr 260,000. The former represents a neuronal type of the IGF-I receptor alpha subunit, whereas the latter probably represents an alpha dimer. The Mr = 115,000 binding component for 125I-IGF-I was also present in membranes prepared from postnatal whole brain. In contrast, the binding moiety in cultured glial cells was of Mr = 135,000, which was identical to the IGF-I receptor alpha subunit of placenta. Thus mature brain, despite its cellular heterogeneity, expresses a structural subtype of IGF-I receptor which appears to be unique to differentiated neurons. Moreover, glial and neuronal cultures secreted a polypeptide which specifically bound IGF-I; the apparent Mr of this binding protein was determined by affinity cross-linking to be approximately 35,000. The presence of neuronal IGF-I receptors and binding proteins suggested that IGF-I may exert neurotrophic effects on developing neurons. This possibility was supported by the observation that IGF-I markedly stimulated neuronal RNA synthesis.     

Unique Features of the Insulin Receptor in Rat Brain

We examined the structure of the affinity-labeled insulin receptors in rat brain, rat liver, and human IM-9 lymphocytes using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In gels run under reducing conditions, the alpha-subunit of the insulin receptor in brain had an apparent Mr of 127,000 distinctly lower than that seen in both rat liver and human lymphocytes (apparent Mr = 136,000). Exposure to neuraminidase increased the electrophoretic mobility of the liver receptor, but had no effect on the insulin receptor in brain. The carbohydrate moieties of the insulin receptors in rat brain and liver were further examined by chromatography on wheat-germ agglutinin agarose. The receptors in both tissues adsorbed to the wheat-germ agglutinin; elution with 0.3 M N-acetyl glucosamine resulted in slightly better recovery of the brain than of the liver receptor. Exposure to neuraminidase virtually abolished the interaction of the liver receptor with the lectin, whereas adsorption of the brain receptor was unaffected by neuraminidase. These results indicate that the insulin receptor in brain is distinguished from those in peripheral tissues by structural alterations, including changes in the carbohydrate moiety of the receptor. Such alterations contrast sharply with the previously observed similarities in insulin binding properties between insulin receptors in brain and other tissues. The implications of such structural alterations for the program of insulin action expressed by the receptors in brain remain to be explored.     

Characterization of vasoactive intestinal peptide (VIP) receptors in mammalian lung

125I-VIP bound specifically to sites on human, rat, guinea pig, and rabbit lung membranes with a dissociation constant (KD) of 60-200 pM and binding site maxima of 200-800 fmol/mg of protein. The presence of a second lower affinity site was detected but not investigated further. High affinity 125I-VIP binding was reversible and displaced by structurally related peptides with an order of potency: VIP greater than rGRF greater than PHI greater than hGRF greater than secretin = Ac Tyr1 D Phe2 GRF. 125I-VIP has been covalently incorporated into lung membranes using disuccinimidyl suberate. Sodium dodecyl sulfate-polyacrilamide gel electrophoresis of labeled human, rat, and rabbit lung membranes revealed major 125I-VIP-receptor complexes of: Mr = 65,000, 56,000, and 64,000 daltons, respectively. Guinea pig lung membranes exhibited two 125I-VIP-receptor complexes of Mr = 66,000 and 60,000 daltons. This labeling pattern probably reflects the presence of differentially glycosylated forms of the same receptor since treatment with neuroaminidase resulted in a single homogeneous band (Mr = 57,000 daltons). Soluble covalently labeled VIP receptors from guinea pig and human lung bound to and were specifically eluted from agarose-linked wheat germ agglutinin columns. Our studies indicate that mammalian lung VIP receptors are glycoproteins containing terminal sialic acid residues.     

Use of photoaffinity probes containing poly(ethylene glycol) spacers for topographical mapping of the cholecystokinin receptor complex

To further define the structure of the pancreatic cholecystokinin (CCK) receptor and the topographical distance relationships between its subunits, we developed a series of monofunctional photoaffinity probes in which a fixed receptor-binding domain was separated from a photolabile nitrophenylacetamido group by defined lengths of a flexible spacer. The well-characterized CCK receptor radioligand 125I-D-Tyr-Gly-[(Nle28,31)CCK-26-33] provided the receptor-binding component of the probes, while the polymer poly(ethylene glycol) (2, 4, 7, and 10 monomer units long) was used as the spacer. The patterns of affinity labeling of rat pancreatic plasma membranes were examined as a function of spacer length. This ranged from 7.3 to 16.2 A, as calculated by root-mean-square end-to-end distances and validated experimentally by time-resolved fluorescence resonance energy transfer measurements. All probes in the series specifically labeled the Mr = 85,000-95,000 glycoprotein with Mr = 42,000 core, which has been proposed to contain the hormone recognition site. In addition, when the spacer length reached 16.2 A, membrane proteins of Mr = 80,000 and Mr = 40,000 were specifically labeled. The product of endo-beta-N-acetylglucosaminidase F digestion of the Mr = 80,000 protein was Mr = 65,000, similar to a protein previously identified in affinity labeling experiments using a CCK-33-based probe. These observations are consistent with the Mr = 85,000-95,000 pancreatic protein representing the hormone-binding subunit of the CCK receptor, while proteins of Mr = 80,000 and Mr = 40,000 may represent noncovalently associated subunits sited within 16.2 A of the binding domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Insulin binds to and promotes the phosphorylation of a Mr 210 000 component of its receptor in detergent extracts of rat liver microsomes

Insulin in the presence of Mn2+ and [gamma 32P]ATP promoted the phosphorylation of two proteins of Mr 95 000 and Mr 210 000 in detergent extracts of rat liver microsomes. The Mr 210 000 protein was identified as a component od the insulin receptor by immunoprecipitation. It also bound [125I]insulin specifically, was phosphorylated largely on a tyrosine residue and could not be cleaved to smaller subunits under extreme reducing conditions. The Mr 210 000 protein appears to be a component of a sub-population of liver membrane insulin receptors in which insulin-binding and insulin-stimulated tyrosine kinase phosphorylation site(s) reside in a single polypeptide chain.     

Identification of the glucagon receptor by covalent labeling with a radiolabeled photoreactive glucagon analogue

The photoreactive 125I-labeled glucagon-NAPS [125I-labeled 2-[2-nitro-4-azidophenyl)sulfenyl]-Trp25-glucagon] was used to label the glucagon receptor sites in rat liver plasma membranes. The proteins labeled were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis with or without reduction with dithiothreitol. The photoaffinity peptide specifically labeled a number of bands with apparent molecular weights greater than 200000 and probably at least two protein bands in the molecular weight range 52000-70000. The relative amounts of radioactivity associated with these bands and their relative mobilities differed in samples from reduced and unreduced membranes. Their relative mobilities also differed with percent acrylamide cross-linking, suggesting a glycoprotein nature and the presence of intramolecular disulfide bonds. A nonspecifically labeled band with an apparent molecular weight of 27000-28000 also displayed a similar behavior. Photolabeling in the presence of 0.1 mM guanosine 5'-triphosphate (GTP) decreased the amount of radiolabeling of these bands, suggesting their involvement in the glucagon stimulation of adenylate cyclase. The photolabeled receptor in the membranes, solubilized with Lubrol-PX and fractionated on an Ultrogel AcA22 column, eluted with an apparent molecular weight of 200000-250000. Addition of GTP to the solubilized glucagon receptor of nonirradiated membranes caused complete dissociation of the complex. Gel electrophoresis of the partially purified radiolabeled receptor identified the same protein components observed in photolabeled membranes. These results indicate that the glucagon receptor is an oligomer probably composed of at least two different subunits that are linked together or greatly stabilized by disulfide bonds. They also show that 125I-labeled glucagon-NAPS can be used effectively to covalently label the putative glucagon receptor and thus aid in its further characterization.