Aspects of the metabolism of the epidermal growth factor receptor in A431 human epidermoid carcinoma cells.

The biosynthesis and posttranslational metabolism of the epidermal growth factor (EGF) receptor were examined in the A431 human epidermoid carcinoma cell line. Polyclonal antibody against the receptor specifically immunoprecipitated two [35S]methionine-labeled proteins of Mr = 160,000 and 170,000. Pulse chase experiments showed the Mr = 160,000 protein to be a precursor of the Mr = 170,000 protein. Preincubation with tunicamycin resulted in immunoprecipitation of a single band of Mr = 130,000, whereas monensin inhibited maturation to the Mr = 170,000 form. Digestion of the Mr = 160,000 and 170,000 proteins with endoglycosidase H resulted in the appearance of Mr = 130,000 and 165,000 proteins, respectively. Prolonged pulse-chase experiments indicated that the half-life of the receptor is ca. 20 h in the absence of EGF and 5 h in the presence of EGF. Approximately three- to five-fold more phosphate is incorporated into the mature receptor upon addition of EGF, due primarily to increases in levels of phosphotyrosine and phosphoserine. Phosphate was also present on the Mr = 160,000 protein and the Mr = 130,000 protein found in the presence of tunicamycin.     

Cell surface glycoproteins involved in the stimulation of interleukin 1-dependent interleukin 2 production by a subline of EL4 thymoma cells. II. Structure, biosynthesis, and maturation

In the present study, we examined the biosynthesis and the maturation of two distinct membrane glycoproteins detected by two monoclonal antibodies (RL388 and RL119), which were selected on the basis of their ability to stimulate the production of interleukin 2 by a subline of the murine EL4 thymoma. RL388 detected a disulfide-linked heterodimer complex (Mr = 130,000) composed of a glycosylated heavy (Mr = 86,000) and a nonglycosylated light (Mr = 39,000) subunit. The unglycosylated precursor of the heavy chain was a polypeptide of Mr = 57,500, which was converted upon maturation into a Mr = 73,000 core-glycosylated intermediate, and then into the Mr = 86,000 surface-expressed molecule. Partial endo-H digestion of the core-glycosylated form suggested the presence of four N-linked glycan units. The antibody reacted with a protein determinant expressed on the mature form as well as the unglycosylated precursor of the heavy chain. Moreover, both subunits assembled rapidly during biosynthesis, and the glycosylation of the heavy chain was not required for this association. Taken together, these data suggest that the antigen detected by RL388 may be the murine homologue of the human 4F2 antigen. The antigen identified by RL119 was a surface glycoprotein of Mr = 55,000 with three to five N-linked glycan units. The unglycosylated precursor polypeptide was of Mr = 29,000. The fully core-glycosylated form of Mr = 41,000, which was detected after inhibition of glucosidase I with 1-deoxynojirimycin, was converted into a Mr = 39,000 intermediate, and upon further trimming, into a Mr = 36,000 endo-H-sensitive form. The latter could be detected for chase periods of over several hours, thus suggesting a low rate of intracellular processing. The wide cellular distribution of the molecules identified by RL388 and RL119 and their preferential expression on the surface of growing cells suggests that they may be associated with cell activation events.     

The mouse leukocyte adhesion proteins Mac-1 and LFA-1: studies on mRNA translation and protein glycosylation with emphasis on Mac-1

Translation in vitro of mRNA and immunoprecipitation with specific rabbit antisera showed that the unglycosylated precursor polypeptides of the mouse Mac-1 and lymphocyte function associated antigen (LFA-1) alpha subunits are 130,000 Mr and 140,000 Mr, respectively. Furthermore, polysomes purified by using anti-Mac-1 IgG yielded a similar major product of translation in vitro of Mr = 130,000. The Mac-1 and LFA-1 alpha subunit translation products are immunologically noncross-reactive, showing that differences between these related proteins are not due to post-translational processing. Mac-1 and LFA-1 alpha subunits could only be in vitro translated from mRNA from cell lines the surfaces of which express the corresponding Mac-1 and LFA-1 alpha-beta complexes, showing tissue-specific expression is regulated at the mRNA level. The glycosylation of Mac-1 was examined by both translation in vitro in the presence of dog pancreas microsomes and by biosynthesis in vivo and treatment with tunicamycin, endoglycosidase H, and the deglycosylating agent trifluoromethane sulfonic acid. High mannose oligosaccharides are added to the Mac-1 alpha and beta polypeptide backbones of Mr = 130,000 and 72,000, respectively, to yield precursors of Mr = 164,000 and 91,000, respectively. The alpha and beta subunit precursors are then processed with partial conversion of high mannose to complex type carbohydrate to yield the mature subunits of Mr = 170,000 and 95,000, respectively.     

Epidermal growth factor-induced truncation of the epidermal growth factor receptor

NIH-3T3 cells expressing the human epidermal growth factor (EGF) receptor were used in experiments to determine the fate of the EGF receptor in cells continuously exposed to EGF. EGF receptor was immunoprecipitated from cells labeled for 12 h with [35S] methionine in the absence or presence of 10 nM EGF. As expected, a single Mr = 170,000 polypeptide representing the mature EGF receptor was immune-precipitated from control cells. Surprisingly, immune precipitates from EGF-treated cells contained a prominent Mr = 125,000 receptor species, in addition to the Mr = 170,000 mature receptor. The Mr = 125,000 species was shown to be derived from the Mr = 170,000 form by pulse-chase experiments, in which the Mr = 170,000 receptor chased into the Mr = 125,000 form when EGF was included during the chase and by partial proteolysis. Both proteins became extensively phosphorylated on tyrosine residues in immune precipitate kinase assays. Treatment of immune precipitates with endoglycosidase F changed the apparent molecular weight of the Mr = 170,000 receptor to Mr = 130,000 and of the Mr = 125,000 form to Mr = 105,000, indicating that the appearance of the Mr = 125,000 protein was probably due to proteolysis. Antibody against the carboxyl terminus of the mature EGF receptor recognized the Mr = 125,000 protein, whereas antibody against the amino terminus did not. Incubation of cells with leupeptin prior to and during EGF addition inhibited processing to the Mr = 125,000 species. Methylamine and low temperature also inhibited the EGF-induced processing to the Mr = 125,000 form. These data suggest a possible role for proteolysis of the EGF receptor in receptor function.     

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.     

Biosynthesis and glycosylation of the insulin receptor. Evidence for a single polypeptide precursor of the two major subunits

The biosynthesis and carbohydrate processing of the insulin receptor were studied in cultured human lymphocytes by means of metabolic and cell surface labeling, immunoprecipitation with anti-receptor autoantibodies, and analysis on sodium dodecyl sulfate-polyacrylamide gels under reducing conditions. In addition to the two major subunits of Mr = 135,000 and Mr = 95,000, two higher molecular weight bands were detected of Mr = 210,000 and Mr = 190,000. The Mr = 210,000 band and the two major subunits were labeled by [3H]mannose, [3H]glucosamine, [3H]galactose, and [3H]fucose, and were bound by immobilized lentil, wheat germ, and ricin I lectins. On the other hand, the Mr = 190,000 band was labeled only by [3H]mannose and [3H]glucosamine and was bound only by lentil lectin. All four components could be labeled with [35S] methionine; however, in contrast with the other three polypeptides, the Mr = 190,000 band was not labeled by cell surface iodination with lactoperoxidase, suggesting that it is not exposed at the outer surface of the plasma membrane. Pulse-chase studies with [3H]mannose showed that the Mr = 190,000 was the earliest labeled component of the receptor; radioactivity in this band reached a maximum 1 h after the pulse, clearly preceded the appearance of the other components, and had a very brief half-life (t1/2 = 2.5 h). The Mr = 210,000, Mr = 135,000, and Mr = 95,000 bands were next in appearance and reached a maximum 6 h in the chase period. Monensin, an ionophore which interferes with maturation of some proteins, blocked both the disappearance of the Mr = 190,000 protein and the appearance of the Mr = 135,000 and Mr = 95,000 subunits. The mannose incorporated in the Mr = 190,000 component was fully sensitive to treatment with endoglycosidase H while that in the Mr = 210,000 band and the two major subunits was only partially sensitive. Tryptic fingerprints of the 125I-labeled Mr = 210,000 band suggested that this component contains peptides of both the Mr = 135,000 and Mr = 95,000 subunits. In conclusion, the Mr = 190,000 component appears to represent the high mannose precursor form of the insulin receptor that undergoes carbohydrate processing and proteolytic cleavage to generate the two major subunits. In addition, the Mr = 210,000 band is probably the fully glycosylated form of the precursor that escapes cleavage and is expressed in the plasma membrane.     

Biosynthesis of the epidermal growth factor receptor in human epidermoid carcinoma-derived A431 cells

Using human-specific antibody reagents, we have examined the biosynthesis of the epidermal growth factor receptor in human epidermoid carcinoma-derived A431 cells. Four Mr species (Mr = 70,000, 95,000, 135,000, and 145,000) are detected when cells are subjected to a brief pulse of L-[35S]methionine; an Mr = 165,000 species is detected after 45-60 min of exposure of cells to radiolabel. In pulse-chase experiments, the four lower Mr species appear to bear a precursor relation to the Mr = 165,000 protein. The molecule acquires N-linked oligosaccharide cotranslationally, and two of the species (Mr = 95,000 and 145,000) are susceptible to digestion with endo-beta-N-acetylglucosaminidase H. The Mr = 145,000 and Mr = 165,000 proteins, which become labeled with 125I-epidermal growth factor after treatment of intact cells with a bifunctional cross-linking reagent, are phosphorylated at serine and threonine on identical tryptic peptides.     

Characterization of the human transferrin receptor produced in a baculovirus expression system

Recombinant human transferrin receptor has been produced in a baculovirus expression system. Magnetic particles coated with an anti-transferrin receptor monoclonal antibody were used to immunoselect virus-infected Sf9 insect cells expressing the human transferrin receptor on their cell surface. Recombinant virus containing the human transferrin receptor cDNA was then plaque-purified from these cells. Biosynthetic labeling studies of infected cells showed that the human transferrin receptor is one of the major proteins made 2-3 days postinfection. The recombinant receptor made in insect cells is glycosylated and is also posttranslationally modified by the addition of a fatty acid moiety. However, studies with tunicamycin and endoglycosidases H and F showed that the oligosaccharides displayed on the recombinant receptor differ from those found on the naturally occurring receptor in human cells. As a consequence, the human receptor produced in the baculovirus system has an Mr of 82,000 and is smaller in size than the authentic receptor. About 30% of human transferrin receptors made in insect cells do not form intermolecular disulfide bonds, but are recognized by the anti-transferrin receptor antibody, B3/25, and bind specifically to a human transferrin-Sepharose column. Binding studies using 125I-labeled human transferrin showed that insect cells infected with the recombinant virus expressed an average of 5.8 +/- 0.9 X 10(5) transferrin receptors (Kd = 63 +/- 9 nM) on their cell surface. Thus, the human transferrin receptor produced in insect cells is biologically active and appears suitable for structural and functional studies.     

Selective externalization of an ATP-binding protein structurally related to the clathrin-uncoating ATPase/heat shock protein in vesicles containing terminal transferrin receptors during reticulocyte maturation

Transferrin receptors are lost from reticulocytes in vesicles that are released during the final stage of erythrocyte maturation (Pan, B. T., and Johnstone, R. M. (1983) Cell 33, 967-977). Transferrin receptor-containing vesicles have a major protein component present in a 1:1 ratio with the receptor that migrates on sodium dodecyl sulfate gels as two polypeptides of Mr = 71,000 and 72,000. The Mr = 71,000/72,000 doublet is indistinguishable from the clathrin-uncoating ATPase/heat shock protein based on cross-reaction with affinity-purified antibody against the uncoating protein, by comparison of peptide maps of the Mr = 72,000 and 71,000 polypeptides and the uncoating protein, and by selective binding of these polypeptides to ATP-agarose. This finding suggests a possible activity of proteins related to the uncoating/heat shock protein family in the disposal of aged membrane proteins by a pathway independent of lysosomes.     

Glycosylation of the epidermal growth factor receptor in A-431 cells. The contribution of carbohydrate to receptor function

A-431 cells were treated with inhibitors of either N-linked glycosylation (tunicamycin or glucosamine) or of N-linked oligosaccharide processing (swainsonine or monensin) to examine the glycosylation of epidermal growth factor (EGF) receptors and to determine the effect of glycosylation modification on receptor function. The receptor was found to be an Mr = 130,000 polypeptide to which a relatively large amount of carbohydrate is added co-translationally in the form of N-linked oligosaccharides. Processing of these oligosaccharides accounts for the 10,000-dalton difference in electrophoretic migration between the Mr = 160,000 precursor and Mr = 170,000 mature forms of the receptor. No evidence was found for O-linked oligosaccharides on the receptor. Mr = 160,000 receptors resulting from swainsonine or monensin treatment were present on the cell surface and retained full function, as judged by 125I-EGF binding to intact cells and detergent-solubilized extracts and by in vitro phosphorylation in the absence or presence of EGF. On the other hand, when cells were treated with tunicamycin or glucosamine, ligand binding was reduced by more than 50% in either intact cells or solubilized cell extracts. The Mr = 130,000 receptors synthesized in the presence of these inhibitors were not found on the cell surface. In addition, no Mr = 130,000 phosphoprotein was detected in the in vitro phosphorylation of tunicamycin or glucosamine-treated cells. It appears, therefore, that although terminal processing of N-linked oligosaccharides is not necessary for proper translocation or function of the EGF receptor, the addition of N-linked oligosaccharides is required.     

Biosynthesis of mammalian DNA ligase

A monospecific antibody against calf thymus DNA ligase composed of a single polypeptide with Mr = 130,000 cross-reacts with rodent and calf thymus DNA ligases. The antibody precipitates a single Mr = 200,000 polypeptide from detergent lysates of [3H] leucine-labeled mouse Ehrlich tumor cells and calf thymocytes. Pulse-chase experiments show that the Mr = 200,000 polypeptide in Ehrlich tumor cells has a half-life of about 0.5 h. In addition to the Mr = 200,000 polypeptide, a Mr = 130,000 polypeptide is detected in the partially purified enzyme preparations from radiolabeled Ehrlich tumor cells. These results suggest that DNA ligase is synthesized in mammalian cells as a Mr = 200,000 polypeptide and that the Mr = 200,000 polypeptide is degraded to a Mr = 130,000 polypeptide by a limited proteolysis in vitro.     

Glycosylation of the epidermal growth factor receptor and its relationship to membrane transport and ligand binding

Epidermal growth factor (EGF) receptor biosynthesis was examined in an oral squamous cell carcinoma line, NA, which overproduces the receptor to an even greater extent than the widely studied A431 cells. The EGF receptor of NA cells synthesized in the presence of tunicamycin had an apparent molecular weight of 130,000. The nascent protein in untreated cells was cotranslationally glycosylated to Mr 160,000 and further processed to Mr 170,000. The endo-beta-N-acetylglucosaminidase H (Endo H) digestion analysis revealed the presence of high mannose type oligosaccharide on the Mr 170,000 mature receptor. We extended the analysis by correlating the biosynthesis with the acquisition of binding activity. The unglycosylated Mr 130,000 receptor and the Mr 160,000 receptor seen after pulse-labeling had no EGF binding activity, whereas the Mr 160,000 receptor seen after chase-incubation and the Mr 170,000 receptor had binding activity. Thus, not only glycosylation but also some oligosaccharide processing is apparently necessary for the EGF binding. Treatment with processing inhibitors, such as monensin, swainsonine and 1-deoxynojirimycin, affected neither receptor transport to the plasma membrane nor binding activity. Inhibition by 1-deoxynojirimycin is thought to be incomplete since the surface receptor in treated cells had the same molecular weight as that in control cells. An Mr 160,000 receptor without binding activity accumulated in the intracellular fraction in the presence of brefeldin A, an inhibitor of intracellular transport. Thus, the EGF binding activity is thought to be acquired after the brefeldin A-sensitive process but prior to the swainsonine-sensitive mannose removal in NA cells.     

In vitro biosynthesis of the human cell surface receptor for transferrin

The human cell surface receptor for transferrin is a transmembrane phosphoglycoprotein composed of two disulphide linked and apparently identical subunits of Mr 90 000. Using an affinity purified, polyclonal rabbit antibody, we have studied the in vitro biosynthesis of this receptor. The primary translation product, synthesised in a rabbit reticulocyte lysate programmed with human placental RNA, appears to have the same Mr (78 000) as the unglycosylated molecule immunoprecipitated from tunicamycin-treated cells. In the presence of a dog pancreatic microsomal system the cell free system accurately reproduces the glycosylation and the asymmetric transmembrane integration.     

Characterization of antigen recognized by the monoclonal antibody (4F2): different molecular forms on human T and B lymphoblastoid cell lines

The monoclonal antibody 4F2 recognizes a disulfide-linked ricin-binding glycoprotein complex (Mr congruent to 125,000) composed of a sialylated heavy subunit (Mr congruent to 85,000 on T cell lines) and an unsialylated light subunit (Mr congruent to 41,000). The antigen (T85,41) recognized by 4F2 on T cell lines is structurally distinct from the antigen (B93, 41) on B cell lines. The heavy subunits, but not the light subunits, from all T cell lines examined were uniformly smaller in size than the heavy subunits from several B cell lines. This reflects differences in carbohydrate rather than protein represent in B93,41 compared with T85,41, because both heavy subunits have a common unglycosylated form (p65) and a common partially glycosylated precursor form (p68). Among non-T, non-B hematopoietic cell lines, the monocytoid line U-937 expressed an antigen that resembles B93,41, whereas the erythroleukemic line K-562 expressed an antigen more similar to T85,41. 4F2 recognizes a protein determinant on the heavy subunit (with or without N-linked glycosylation) and also the unglycosylated heavy subunit retains the ability to associate with light subunit. The light subunit itself contains no detectable N-linked carbohydrate. Unlike the transferrin receptor, synthesis of the antigen recognized by 4F2 on the promyelocytic cell line HL-60 did not diminish upon dimethylsulfoxide-induced differentiation, and thus is not tightly correlated with cell proliferation.     

Identification of lipoprotein-binding proteins in rat liver Golgi apparatus membranes

The low density lipoprotein (LDL) receptor has been shown to be a plasma membrane glycoprotein responsible for the cellular binding and endocytosis of plasma lipoproteins. Inasmuch as the Golgi apparatus has been shown to participate in glycoprotein processing and in the assembly of plasma lipoproteins by hepatic and intestinal epithelial cells, the present studies were designed to test the hypothesis that lipoprotein receptors are present within Golgi membranes. Utilizing ligand blotting with a variety of iodinated lipoproteins, several lipoprotein-binding proteins were identified in rat liver Golgi membranes at apparent molecular weights (Mr) 200,000, 160,000, 130,000, 120,000, 100,000, 80,000, and 70,000. The 130,000 protein was the most prominent and was identified as the mature LDL receptor by its binding characteristics and an Mr characteristic of the plasma membrane receptor. Enzymatic deglycosylation studies suggested that the 120,000 and 100,000 proteins were LDL receptor precursors lacking sialic acid. Antibody to the LDL receptor recognized all the bands on immunoblots except the 70,000 protein, with the 130,000 protein being the most prominent. Isolation of the Golgi fractions in the presence of protease inhibitors did not eliminate any of the proteins recognized by the antibody but did result in sharper bands on the blots. Additionally, we investigated the hypothesis that conditions that regulate plasma membrane LDL receptors also cause detectable changes in receptors in Golgi membranes. All the binding proteins were increased in Golgi membranes from rats treated with 17-alpha-ethynylestradiol. Colchicine caused an accumulation of 120,000 Mr protein, suggesting blockage of final sialylation in the trans Golgi. When protein synthesis was inhibited by cycloheximide, there was no reduction of mature LDL receptors in Golgi membranes, consistent with recycling of receptors through this organelle.     

Characterization of the cell surface heterodimer VLA-4 and related peptides

A monoclonal antibody (B-5G10) was produced which specifically recognizes the Mr 150,000/130,000 VLA-4 complex on the surface of human cells. Cross-linking studies indicated that the Mr 150,000 alpha 4 subunit of VLA-4 is in noncovalent 1:1 association with the Mr 130,000 VLA beta subunit. In the absence of cross-linking, the VLA-4 alpha 4 beta subunit complex was easily dissociated, especially in Nonidet P-40 detergent, or at elevated pH (above 8.0). Studies of dissociated subunits showed that B-5G10 recognizes an epitope on the Mr 150,000 alpha 4 subunit of VLA-4, whereas the beta subunit is immunologically identical to the Mr 130,000 beta subunit common to all VLA heterodimers. VLA-4 is widely distributed on hematopoietic cells, including thymocytes, peripheral blood lymphocytes, monocytes, activated T cells, T and B lymphoblastoid cell lines, and myeloid cell lines. However, VLA-4 is only weakly expressed on most adherent cell lines tested. Immunoprecipitates of VLA-4 often contain additional proteins of Mr 80,000 and Mr 70,000. These are probably derived from the Mr 150,000 alpha 4 subunit because: 1) they are both recognized by anti-alpha 4 sera, but not anti-beta sera; 2) the sum of their sizes is equal to the size of alpha 4; 3) they are selectively coexpressed with alpha 4 and not other VLA alpha subunits; 4) the Mr 80,000 protein has an identical NH2-terminal sequence to alpha 4; 5) like alpha 4, the Mr 70,000 and 80,000 peptides can variably associate with the VLA beta subunit; and 6) trypsin appears to cleave the Mr 150,000 alpha 4 subunit into products of Mr 70,000 and 80,000.     

Two distinct forms of receptors for atrial natriuretic factor in bovine adrenocortical cells. Purification, ligand binding, and peptide mapping

The atrial natriuretic factor (ANF) receptor of bovine adrenal cortex was solubilized with Triton X-100 and purified by sequential chromatography on ANF-(99-126)-agarose, GTP-agarose, and wheat germ agglutinin-Sepharose. Two subtypes of ANF receptors were isolated, both of which showed specific ANF binding, whereas one of the ANF receptor subtypes also possessed significant cyclase activity. Both of the receptors showed high capacities (Bmax = 5.7-6.8 nmol/mg of protein) and high affinities (Kd = 54-68 pM) for ANF-(99-126). The cyclase-free receptor had high affinity (Ki = 150-220 pM) to C-terminal truncated ANF analogs, whereas the cyclase-containing receptor had a much weaker affinity (Ki = 10(6)-10(7) pM). When treated with dithiothreitol, the purified cyclase-containing and cyclase-free ANF receptors migrated as a single band at Mr 135,000 and 62,000, respectively, in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified cyclase-free receptor is not a product derived from the cyclase-containing receptor because (i) two proteins with Mr of 135,000 and 62,000 were specifically labeled with 4-azidobenzoyl 125I-ANF-(102-126) in nonsolubilized intact membranes; (ii) the truncated ANF analogs (10(4) pM) prevented the photolabeling of the 62,000-dalton protein but not that of the 135,000-dalton protein; and (iii) two-dimensional peptide mapping showed more than 90% difference between the profiles of the two purified ANF receptor subtypes. This study provides first direct evidence for the existence of two distinct ANF receptors which are different not only in their pharmacological properties but also in their primary structure.     

Nerve growth factor receptor from rabbit sympathetic ganglia membranes. Relationship between subforms

The receptor for nerve growth factor (NGF) was purified from Triton X-100 extracts of sympathetic ganglia membranes by affinity chromatography on NGF-Sepharose. Elution of purified receptor was accomplished at pH 5 in the presence of 1 M NaCl. Sodium dodecyl sulfate gel electrophoresis of the purified iodinated receptor showed three major bands at Mr = 126,000, Mr = 105,000, and Mr = 81,000. Affinity labeling of the purified receptor using 125I-NGF and the photoreactive agent N-hydroxysuccinimidyl-p-azidobenzoate resulted in two major cross-linked complexes corresponding to Mr = 135,000 and Mr = 110,000. This labeling pattern is similar to that observed with sympathetic ganglia membranes (Massague, J., Guillette, B. J., Czech, M. P., Morgan, C. J., and Bradshaw, R. A. (1981) J. Biol. Chem. 256, 9419-9424) and indicates that these two forms do not arise from the cross-linking procedure. Reaction of the photoaffinity labeled NGF receptors with increasing amounts of trypsin resulted in a progressive decrease in the high molecular weight complex with a concomitant increase in the low molecular weight form. When the larger complex was isolated by electroelution from a sodium dodecyl sulfate gel and treated with trypsin, a species corresponding to Mr = 100,000 was generated. These observations are best explained by a precursor-product relationship for the two NGF receptor species of sympathetic neurons.     

Characterization of the transferrin receptor in tunicamycin-treated A431 cells

The transferrin receptor undergoes extensive co- and post-translational modifications during its biosynthesis. In this study, the functional and structural properties of the transferrin receptor from tunicamycin-treated A431 cells were examined. Incubation of A431 cells with this inhibitor of asparagine-linked glycosylation results in a shift of the apparent molecular weight of the transferrin receptor from 94,000 to 79,000. The electrophoretic mobility of the receptor from treated cells is that of a monomer under nonreducing conditions, whereas the transferrin receptor in untreated cells has the mobility of a dimer under identical conditions. This result indicates a lack of disulfide bond formation between subunits of the receptor from tunicamycin-treated cells. In solution no dimers can be detected with cross-linking studies. This unglycosylated receptor does not appear to stably bind transferrin as demonstrated by a lack of isolation of this form of the receptor with transferrin-linked Sepharose. It is not transported to the surface of A431 cells.     

Relationship between the affinity and proteolysis of the insulin receptor. Evidence that higher affinity receptors are preferentially degraded

125I-Insulin binding to rat liver plasma membranes initiated two processes that occurred with similar time courses: an increase of receptor affinity for hormone and degradation of the Mr 135,000 alpha subunit of the insulin receptor to a fragment of Mr 120,000. Inhibitors of serine proteinases prevented alpha subunit degradation without affecting the affinity change. This shows that the change of affinity is not produced by receptor proteolysis and that the intact alpha subunit of the insulin receptor can exist as a higher or lower affinity species. Hormone binding was much more rapid than receptor proteolysis and the initial rate of alpha subunit degradation was independent of the concentration of occupied lower affinity receptors. Only persistent hormone binding and the accumulation of higher affinity insulin-receptor complexes led to significant receptor proteolysis. As the incubation time between 125I-insulin and membranes increased, the rate at which hormone dissociated from Mr 135,000 complexes diminished, whereas hormone dissociated from Mr 120,000 complexes slowly after brief or extended incubations. These observations suggest that 125I-insulin binds to membranes to form low affinity complexes that are not substrates for proteolysis. A slow conformational change produces higher affinity hormone-receptor complexes that are selectively degraded. Thus, the conversion between states of affinity may play a role in the regulation of receptor proteolysis and, consequently, insulin action in cells.