Biosynthesis of the insulin receptor in rat adipose cells. Intracellular processing of the Mr-190 000 pro-receptor.

We investigated the biosynthesis of the insulin receptor in primary cultures of isolated rat adipose cells. Cells were pulse-chase-labelled with [3H]mannose, and at intervals samples were homogenized. Three subcellular membrane fractions were prepared by differential centrifugation: high-density microsomal (endoplasmic-reticulum-enriched), low-density microsomal (Golgi-enriched), and plasma membranes. After detergent solubilization, the insulin receptors were immunoprecipitated with anti-receptor antibodies and analysed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and autoradiography. After a 30 min pulse-label [3H]mannose first appeared in a band of Mr 190 000. More than 80% of the Mr-190 000 component was recovered in the microsomal fractions. Its intensity reached a maximum at 1 h in the high-density microsomal fraction and at 2 h in the low-density microsomal fraction, and thereafter declined rapidly (t 1/2 approx. 3 h) in both fractions. In the plasma-membrane fraction, the radioactivity in the major receptor subunits, of Mr 135 000 (alpha) and 95 000 (beta), rose steadily during the chase and reached a maximum at 6 h. The Mr-190 000 precursor could also be detected in the high-density microsomal fraction by affinity cross-linking to 125I-insulin. In the presence of monensin, a cationic ionophore that interferes with intracellular transport within the Golgi complex, the processing of the Mr-190 000 precursor into the alpha and beta subunits was completely inhibited. Our results suggest that the Mr-190 000 pro-receptor originates in the endoplasmic reticulum and is subsequently transferred to the Golgi complex. Maturation of the pro-receptor does not seem to be necessary for the expression of the insulin-binding site. Processing of the precursor into the mature receptor subunits appears to occur during the transfer of the pro-receptor from the Golgi complex to the plasma membrane.     

Internalization of insulin and its receptor in the isolated rat adipose cell. Time-course and insulin concentration dependency

The time-course and insulin concentration dependency of internalization of insulin and its receptor have been examined in isolated rat adipose cells at 37 degrees C. The internalization of insulin was assessed by examining the subcellular distribution of cell-associated [125I]insulin among plasma membrane, and high-density (endoplasmic reticulum-enriched) and low-density (Golgi-enriched) microsomal membrane fractions prepared by differential ultracentrifugation. The distribution of receptors was measured by the steady-state exchange binding of fresh [125I]insulin to these same membrane fractions. At 37 degrees C, insulin binding to intact cells is accompanied initially by the rapid appearance of intact insulin in the plasma membrane fraction, and subsequently, by its rapid appearance in both the high-density and low-density microsomal membrane fractions. An apparent steady-state distribution of insulin per mg of membrane protein among these subcellular fractions is achieved within 30 min in a ratio of 1:1.54:0.80, respectively. Concomitantly, insulin binding to intact cells is associated with the rapid disappearance of approx. 30% of the insulin receptors initially present in the plasma membrane fraction and appearance of 20-30% of those lost in the low-density microsomal membrane fraction. However, the number of receptors in the high-density microsomal membrane fraction does not change. This redistribution of receptors also appears to reach a steady-state within 30 min. Both processes are insulin concentration-dependent, correlating with receptor occupancy in the intact cell, and are partially inhibited at 16 degrees C. While the steady-state subcellular distributions of insulin and its receptor do not correlate with that of acid phosphatase, chloroquine markedly increases the levels of insulin associated with all three membrane fractions in apparent proportion to the distribution of this lysosomal marker enzyme activity, without more than marginally potentiating insulin's effects on the distribution of receptors. These results demonstrate that insulin, initially bound to the plasma membrane of the isolated rat adipose cell, is rapidly translocated by a receptor-mediated process into at least two intracellular compartments associated with the cell's high- and low-density microsomes. Furthermore, insulin simultaneously induces the translocation of its own receptor from the plasma membrane into the latter compartment. These translocations appear to represent the internalization and partial dissociation of the insulin-receptor complex through insulin-induced receptor cycling.     

Internalization of insulin and its receptor in the isolated rat adipose cell: Time-course and insulin concentration dependency

The time-course and insulin concentration dependency of internalization of insulin and its receptor have been examined in isolated rat adipose cells at 37°C. The internalization of insulin was assessed by examining the subcellular distribution of cell-associated [¹²⁵I]insulin among plasma membrane, and high-density (endoplasmic reticulum-enriched) and low-density (Golgi-enriched) microsomal membrane fractions prepared by differential ultracentrifugation. The distribution of receptors was measured by the steady-state exchange binding of fresh [¹²⁵I]insulin to these same membrane fractions. At 37°C, insulin binding to intact cells is accompanied initially by the rapid appearance of intact insulin in the plasma membrane fraction, and subsequently, by its rapid appearance in both the high-density and low-density microsomal membrane fractions. An apparent steady-state distribution of insulin per mg of membrane protein among these subcellular fractions is achieved within 30 min in a ratio of 1:1.54:0.80, respectively. Concomitantly, insulin binding to intact cells is associated with the rapid disappearance of approx. 30% of the insulin receptors initially present in the plasma membrane fraction and appearance of 20–30% of those lost in the low-density microsomal membrane fraction. However, the number of receptors in the high-density microsomal membrane fraction does not change. This redistribution of receptors also appears to reach a steady-state within 30 min. Both processes are insulin concentration-dependent, correlating with receptor occupancy in the intact cell, and are partially inhibited at 16°C. While the steady-state subcellular distributions of insulin and its receptor do not correlate with that of acid phosphatase, chloroquine markedly increases the levels of insulin associated with all three membrane fractions in apparent proportion to the distribution of this lysosomal marker enzyme activity, without more than marginally potentiating insulin's effects on the distribution of receptors. These results demonstrate that insulin, initially bound to the plasma membrane of the isolated rat adipose cell, is rapidly translocated by a receptor-mediated process into at least two intracellular compartments associated with the cell's high- and low-density microsomes. Furthermore, insulin simultaneously induces the translocation of its own receptor from the plasma membrane into the latter compartment. These translocations appear to represent the internalization and partial dissociation of the insulin-receptor complex through insulin-induced receptor cycling.     

Subcellular distribution of GTP-binding proteins, Go and Gi2, in rat cerebral cortex

The localization of GTP-binding protein (G-protein) subunits, Go alpha, Gi2 alpha and beta, in subcellular fractions of rat cerebral cortex was determined by means of immunoassays specific for the respective subunits. High concentrations of all three subunits were observed in both crude mitochondrial and microsomal fractions. Muscarinic cholinergic receptors were also densely localized in these fractions. Then the crude mitochondrial and microsomal fractions were subfractionated by sucrose density gradient centrifugation. Each fraction obtained was evaluated morphologically by electron microscopy and biochemically by determination of membrane markers. The crude mitochondrial fraction was subfractionated into myelin, synaptic plasma membrane, and mitochondrial fractions. All the G-protein subunits examined and muscarinic receptors were exclusively localized in the synaptic plasma membrane fraction. Among the submicrosomal fractions, the heavy smooth-surfaced microsomal fraction showed the highest concentrations of all G-protein subunits and receptors, while the rough-surfaced microsomal fraction contained low amounts of them. The heavy smooth-surfaced microsomal fraction also contained high specific activity of (Na(+)-K+)-ATPase, a marker of the plasma membrane. These results indicated that the Go alpha, Gi2 alpha and beta subunits are mainly localized in the plasma membrane in the brain.     

Divergent metabolism of human chorionic gonadotropin subunits within rat ovarian lysosomes

Pseudopregnant rats were injected with either native human chorionic gonadotropin or with (125I)-human chorionic gonadotropin and their ovarian homogenates fractionated on Percoll density gradients. The levels of alpha and beta subunits within subcellular fractions were measured using radioimmunoassays specific for each subunit. Radioactivity measurements of fractions obtained from rats injected with (125I)-human chorionic gonadotropin were used as a separate index of alpha subunit distribution. The alpha subunit was primarily restricted to a combined plasma membrane/prelysosomal vesicle fraction. Immunoreactive beta subunit was present at high concentrations within both this plasma membrane/prelysosomal vesicle fraction and within lysosomes. The striking difference in alpha and beta subcellular distribution may arise from differential sensitivities to lysosomal enzymes.     

Myristyl and palmityl acylation of the insulin receptor

The presence of covalently bound fatty acids in the insulin receptor has been explored in cultured human (IM-9) lymphocytes. Both alpha (Mr = 135,000) and beta (Mr = 95,000) subunits of the receptor incorporate [3H]myristic and [3H]palmitic acids in a covalent form. The effects of alkali and hydroxylamine on the labeled subunits indicate the existence of two different kinds of fatty acid linkage to the protein with chemical stabilities compatible with amide and ester bonds. The alpha subunit contains only amide-linked fatty acid while the beta subunit has both amide- and ester-linked fatty acids. Analysis by high performance liquid chromatography after acid hydrolysis of the [3H]myristate- and [3H]palmitate-labeled subunits demonstrates the fatty acid nature of the label. Furthermore, both [3H]myristic and [3H]palmitic acids are found attached to the receptor subunits regardless of which fatty acid was used for labeling. The incorporation of fatty acids into the insulin receptor is dependent on protein synthesis and is also detectable in the Mr = 190,000 proreceptor form. Fatty acylation is a newly identified post-translational modification of the insulin receptor which may have an important role in its interaction with the membrane and/or its biological function.     

Development regulation of the subcellular distribution and glycosylation of GLUT1 and GLUT4 glucose transporters during myogenesis of L6 muscle cells.

L6 myoblasts spontaneously undergo differentiation and cell fusion into myotubes. These cells express both GLUT1 and GLUT4 glucose transporters, but their expression varies during myogenesis. We now report that the subcellular distribution and the protein processing by glycosylation of both glucose transporter isoforms also change during myogenesis. Crude plasma membrane and light microsome fractions were isolated from either myoblasts or myotubes and characterized by the presence of two functional proteins, the Na+/K(+)-ATPase and the dihydropyridine receptor (DHPR). Immunoreactive alpha 1 subunit of the Na+/K(+)-ATPase was faint in the crude plasma membrane fraction from myoblasts, but abundant in both membrane fractions from myotubes. In contrast, the alpha 1 subunit of the DHPR, which is expressed only in differentiated muscle, was detected in crude plasma membrane from myotubes but not from myoblasts. Therefore, crude plasma membrane fractions from myoblasts and myotubes contain cell surface markers, and the composition of these membranes appears to be developmentally regulated during myogenesis. GLUT1 protein was more abundant in the crude plasma membrane relative to the light microsome fraction prepared from either myoblasts or myotubes. The molecular size in sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the GLUT1 transporters in myotubes was smaller than that in myoblasts (Mr 47,000 and 53,000, respectively). GLUT4 protein (Mr 48,000) was barely detectable in the crude plasma membrane fraction and was almost absent in the light microsome fraction prepared from myoblasts. However, GLUT4 protein was abundant in myotubes and was predominantly located in the light microsome fraction. Treatment with endoglycosidase F reduced the molecular size of the transporters in all fractions to Mr 46,000 for GLUT1 and Mr 47,000 for GLUT4 proteins. In myotubes, acute insulin treatment increased the crude plasma membrane content of GLUT1 marginally and of GLUT4 markedly, with a concomitant decrease in the light microsomal fraction. These results indicate that: (a) the subcellular distribution of glucose transporters is regulated during myogenesis, GLUT4 being preferentially sorted to intracellular membranes; (b) both GLUT1 and GLUT4 transporters are processed by N-linked glycosylation to form the mature transporters in the course of myogenesis; and (c) insulin causes modest recruitment of GLUT1 transporters and marked recruitment of GLUT4 transporters, from light microsomes to plasma membranes in L6 myotubes.     

Monoclonal antibody DH12 reacts with a cell surface and a precursor form of the beta subunit of the human fibronectin receptor

Monoclonal and polyclonal antibodies were raised against a placenta plasma membrane protein preparation, which was obtained by fractionation on Blue B dye matrix and by HPLC-anionexchange, and which was shown to contain fibronectin receptors. Immunochemical and functional evidence showed that monoclonal antibody DH12 recognized the beta subunit of the human fibronectin receptor on fibroblasts. This monoclonal antibody reacted with two proteins in Western blots and in double immune precipitations of whole cell preparations. Only the higher Mr protein became labeled by surface iodination of intact fibroblasts. The lower Mr protein is thought to be an intracellular precursor of the beta subunit of the fibronectin receptor.     

Lactoperoxidase-catalyzed iodination of the receptor for immunoglobulin E at the cytoplasmic side of the plasma membrane

The structural organization of the high affinity receptor for immunoglobulin E has been investigated in plasma membrane vesicles from rat basophilic leukemia cells using lactoperoxidase-catalyzed 125I-iodination to label exposed polypeptide regions. Intact vesicles are predominantly right-side-out in orientation, and lactoperoxidase iodination of these vesicles results in labeling of the alpha subunit of receptor but not the beta and gamma subunits. Lysis of these vesicles to expose the cytoplasmic face of the membrane by two different methods permits labeling of the beta and gamma subunits with no increase in labeling of alpha. The results indicate that both the beta and gamma subunits of the receptor have segments exposed at the cytoplasmic side of the plasma membrane. These studies have also revealed a previously unidentified IgE binding component in the membrane vesicles; its 125I-labeling characteristics and some other properties are described.     

The saxitoxin receptor of the sodium channel from rat brain. Evidence for two nonidentical beta subunits

The saxitoxin receptor of the sodium channel purified from rat bran contains three types of subunits: alpha with Mr approximately 270,000, beta 1 with Mr approximately 39,000, and beta 2 with Mr approximately 37,000. These are the only polypeptides which quantitatively co-migrate with the purified saxitoxin receptor during velocity sedimentation through sucrose gradients. beta 1 and beta 2 are often poorly resolved by gel electrophoresis in sodium dodecyl sulfate (SDS), but analysis of the effect of beta-mercaptoethanol on the migration is covalently attached to the alpha subunit by disulfide bonds while the beta 1 subunit is not. The alpha and beta subunits of the sodium channel were covalently labeled in situ in synaptosomes using a photoreactive derivative of scorpion toxin. Treatment of SDS-solubilized synaptosomes with beta-mercaptoethanol decreases the apparent molecular weight of the alpha subunit band without change in the amount of 125I-labeled scorpion toxin associated with either the alpha or beta subunit bands. These results indicate that the alpha and beta 1 subunits are labeled by scorpion toxin whereas beta 1 is not and that the beta 2 subunit is covalently attached to alpha by disulfide bonds in situ as well as in purified preparations.     

Topology of the hog intrinsic factor receptor in the intestine

The intrinsic factor receptor was isolated from Triton X-100 extract of hog ileal mucosa using affinity chromatography on intrinsic factor bound to cobalamin-Sepharose. We verified that the receptor contains two subunits, alpha and beta. The purified receptor located in the detergent micelle was radioiodinated. The alpha subunit was labeled and dissociated from the receptor. When the receptor was immobilized on intrinsic factor cobalamin-Sepharose, the part of the receptor which binds intrinsic factor evidently faces the gel and the rest faces outward. When such gel-bound pure receptor was iodinated, the beta subunit was labeled. Iodination of the micellar cobalamin-intrinsic factor receptor complex also caused labeling of the beta subunit. This was interpreted as being due to a conformational change in the receptor affected by the binding of the substrate cobalamin-intrinsic factor, exposing groups accessible to iodination. The beta subunit was found to be hydrophobic, but the alpha subunit was soluble in phosphate buffer without detergent. The receptor was liberated from intestinal mucosa by papain treatment. The enzyme seems to solubilize an intrinsic factor-binding part of the receptor, apparently a part of the alpha subunit. The liberated papain-alpha was purified by affinity chromatography. In gel filtration, it seemed to occur in dimeric form, but its true Mr = 45,000, according to findings in sodium dodecyl sulfate-electrophoresis. In the light of the findings, the topology of the receptor is suggested to be as follows: the alpha subunit binding intrinsic factor faces out and the hydrophobic beta subunit faces in.     

src kinase catalyzes the phosphorylation and activation of the insulin receptor kinase

When a partially purified insulin receptor preparation immobilized on insulin-agarose is incubated with [gamma-32P]ATP, Mn2+, and Mg2+ ions, the receptor beta subunit becomes 32P-labeled. The 32P-labeling of the insulin receptor beta subunit is increased by 2-3-fold when src kinase is included in the phosphorylation reaction. In addition, the presence of src kinase results in the phosphorylation of a Mr = 125,000 species. The Mr = 93,000 receptor beta subunit and the Mr = 125,000 32P-labeled bands are absent when an insulin receptor-deficient sample, prepared by the inclusion of excess free insulin to inhibit the adsorption of the receptor to the insulin-agarose, is phosphorylated in the presence of the src kinase. These results indicate that the insulin receptor alpha and beta subunits are phosphorylated by the src kinase. The src kinase-catalyzed phosphorylation of the insulin receptor is not due to the activation of receptor autophosphorylation because a N-ethylmaleimide-treated receptor preparation devoid of receptor kinase activity is also phosphorylated by the src kinase. Conversely, the insulin receptor kinase does not catalyze phosphorylation of the active or N-ethylmaleimide-inactivated src kinase. Subsequent to src kinase-mediated tyrosine phosphorylation, the insulin receptor, either immobilized on insulin-agarose or in detergent extracts, exhibits a 2-fold increase in associated kinase activity using histone as substrate. src kinase mediates phosphorylation of predominantly tyrosine residues on both alpha and beta subunits of the insulin receptor. Tryptic peptide mapping of the 32P-labeled receptor alpha and beta subunits by high pressure liquid chromatography reveals that the src kinase-mediated phosphorylation sites on both receptor subunits exhibit elution profiles identical with those phosphorylated by the receptor kinase. Furthermore, the HPLC elution profile of the receptor auto- or src kinase-catalyzed phosphorylation sites on the receptor alpha subunit are also identical with that on the receptor beta subunit. These results indicate that: the src kinase catalyzes tyrosine phosphorylation of the insulin receptor alpha and beta subunits; and src kinase-catalyzed phosphorylation of insulin receptor can mimic the action of autophosphorylation to activate the insulin receptor kinase in vitro, although whether this occurs in intact cells remains to be determined.     

Insulin induces translocation of the alpha 2 and beta 1 subunits of the Na+/K(+)-ATPase from intracellular compartments to the plasma membrane in mammalian skeletal muscle.

Unlike glucose transport, where translocation of the insulin-responsive glucose transporter (GLUT4) from an intracellular compartment to the plasma membrane is the principal mechanism underlying insulin stimulation, no consensus exists presently for the mechanism by which insulin activates the Na+/K(+)-ATPase. We have investigated (i) the subunit isoforms expressed and (ii) the effect of insulin on the subcellular distribution of the alpha beta isoforms of the Na+/K(+)-ATPase in plasma membranes (PM) and internal membranes (IM) from rat skeletal muscle. Western blot analysis, using isoform-specific antibodies to the various subunits of the Na+/K(+)-ATPase, revealed that skeletal muscle PM contains the alpha 1 and alpha 2 catalytic subunits and the beta 1 and beta 2 subunits of the Na+ pump. Skeletal muscle IM were enriched in alpha 2, beta 1, and beta 2; alpha 1 was barely detectable in this fraction. After insulin treatment, alpha 2 content in the PM increased, with a parallel decrease in its abundance in the IM pool; insulin did not have any effect on alpha 1 isoform amount or subcellular distribution. The beta 1 subunit, but not beta 2, was also elevated in the PM after insulin treatment, but this increase originated from a sucrose gradient fraction different from that of the alpha 2 subunit. Our findings suggest that insulin induces an isoform-specific translocation of Na+ pump subunits from different intracellular sources to the PM and that the hormone-responsive enzyme in rat skeletal muscle is an alpha 2:beta 1 dimer.     

Insulin receptor kinase following internalization in isolated rat adipocytes

We have studied how insulin-mediated internalization of insulin receptors and insulin activation of the insulin receptor kinase might be inter-related. Isolated rat adipocytes were exposed to 0, 6, or 500 ng/ml insulin for 40 min at 37 degrees C. Subsequently, plasma membrane, low-density microsomal membrane and high-density microsomal membrane subcellular fractions were prepared. Measurement of insulin binding to insulin receptors isolated from the membrane fractions revealed that exposure of cells to insulin resulted in a loss of binding activity (13% at 6 ng/ml, 27% at 500 ng/ml insulin) from the plasma membranes which was completely accounted for by the appearance of receptors in the low-density and high-density microsomal membrane fractions, indicating that insulin had induced translocation of insulin receptors from the surface to the cell interior. Measurement of kinase activity of the isolated receptors revealed that exposure of intact cells to 500 ng/ml insulin resulted in as much as a 35-fold increase in the intrinsic kinase activity of receptors from subcellular fractions. The kinase activity per receptor was equal in all fractions at 3-4 min but by 20 min the activity of the internalized receptors fell approximately 40% to a steady state; plasma membrane receptors, on the other hand, remained fully active over time. This indicates that newly internalized receptors retain their kinase activity but undergo subsequent deactivation. Following exposure of cells to 6 ng/ml insulin, the degree of activation of the insulin receptor kinase was lower in the plasma membrane fraction (24% of the insulin effect at 500 ng/ml) than in the low-density and high-density microsomal membrane fractions (54 and 77%, respectively, of the insulin effect at 500 ng/ml). These results suggest that receptors with an activated kinase are preferentially internalized. We conclude that exposure of adipocytes to insulin causes endocytosis of insulin receptors and activation of insulin receptor kinase, newly internalized receptors are fully active tyrosine kinases but are deactivated as they traverse the intracellular organelles represented by low-density and high-density microsomal membranes, and insulin receptor occupancy, possibly by stimulating phosphorylation and activating the insulin receptor kinase, is important for targeting insulin receptors for internalization.     

Golgi-enriched membrane fractions from rat brain and liver contain long-chain polyisoprenyl pyrophosphate phosphatase activity.

The subcellular distribution of polyisoprenyl pyrophosphate phosphatase activity has been examined in rat brain by assaying the release of 32Pi from [beta-32P]dolichyl pyrophosphate (Dol-P-P) as described previously (Scher,M.G. and Waechter, C.J. (1984) J. Biol. Chem., 259, 14580-14585). The highest specific activities of Dol-P-P phosphatase in rat brain were found in the Golgi-enriched light microsomal, synaptic plasma membrane and heavy microsomal fractions. A comparative analysis of the distribution of galactosyltransferase and dolichol kinase reveals that Dol-P-P phosphatase activity co-fractionates with galactosyltransferase activity, and that the high level found in the Golgi-enriched fraction is not due to cross-contamination with heavy microsomes. When beta-labelled C95 Dol-P-P and the C95 allylic polyisoprenyl pyrophosphate (Poly-P-P) were compared as substrates for the Golgi-enriched light microsomal and heavy microsomal fractions, similar Km values were calculated for the two pyrophosphorylated substrates for each membrane fraction. Based on these kinetic analyses, the enzyme(s) catalysing this reaction do not distinguish between substrates containing saturated or allylic alpha-isoprene units. When Dol-P-P phosphatase activity was assessed in submicrosomal fractions obtained from rat liver by two separate procedures, the highest specific activity was also detected in the Golgi-enriched fraction. While the specific activities for Dol-P-P phosphatase and sialyltransferase were in the relative order of Golgi greater than smooth endoplasmic reticulum (ER) greater than rough ER, the relative order of dolichol kinase was rough ER greater than smooth ER greater than Golgi.(ABSTRACT TRUNCATED AT 250 WORDS)     

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

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

Characterization of an insulin receptor mutant lacking the subunit processing site

An insulin receptor mutant was constructed utilizing site-directed mutagenesis to delete the Arg-Lys-Arg-Arg basic amino acid cleavage site (positions 720-723) from the cDNA encoding the human insulin proreceptor. This mutant was transfected into Chinese hamster ovary cells. Immunoprecipitation of metabolically labeled cells revealed a 205-kDa proreceptor which bound to wheat germ agglutinin. Processed 130-kDa alpha and 95-kDa beta subunits were also observed and contained approximately 20% as much protein as the proreceptor on a molar basis. Trypsin digestion of intact metabolically labeled cells decreased the proreceptor band by 80%. Pulse-chase studies revealed a half-life of 28 h for the proreceptor. When cells were photolabeled with 125I-B2(2-nitro-4-azidophenylacetyl)-des-PheB1 (NAPA)-insulin, the proreceptor incorporated 10% as much label as the 130-kDa alpha subunit in spite of a 5-fold molar excess. Incubation of NAPA-labeled cells at 37 degrees C for 20 min resulted in 60% of the labeled subunits, but little labeled proreceptor, becoming resistant to trypsin degradation. Immunoprecipitation of NAPA-insulin-stimulated cells with anti-phosphotyrosine antibodies revealed that 62% of the processed labeled receptors, but very little proreceptor, contained phosphotyrosine. Thus, this mutant receptor is synthesized, glycosylated, and expressed on the cell surface as uncleaved proreceptor, although some processing to alpha and beta subunits still occurs. It exhibits a markedly decreased affinity for insulin, and when insulin is bound to, demonstrates defective internalization, down-regulation, and autophosphorylation. These data suggest that cleavage of the mutant proreceptor into subunits is required not only for the development of high affinity binding sites, but also for normal transduction of the signal which activates the beta subunit tyrosine kinase.     

Subunit structure and dynamics of the insulin receptor

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