Receptors for insulin-like growth factors in the central nervous system: structure and function

Insulin-like growth factors (IGFs) I and II are homologous peptides, which stimulate growth of several vertebrate tissues. Expression of IGF I and IGF II genes and production of IGFs have recently been demonstrated in rat and human brain. In search for the function of IGF I and IGF II in the central nervous system, we have studied IGF receptors in fetal and adult mammalian brain and growth effects of IGFs on primary cultures of fetal rat astrocytes. Two types of IGF receptor are present on adult rat brain cortical plasma membranes, on fetal rat astrocytes and on human glioma cells. Type I IGF receptor is composed of 2 types of subunits: alpha-subunits which bind IGF I and IGF II with high affinity and insulin weakly, and beta-subunits which show tyrosine kinase activity and autophosphorylation stimulated by IGF I and IGF II with almost similar potency. The molecular size of the type I IGF receptor alpha-subunit is larger in cultured fetal rat astrocytes and human glioma cells than in normal adult brain (Mr 130,000 versus 115,000), whereas the beta-subunit has the same electrophoretic mobility (Mr 94,000). The type II IGF receptor is a monomeric protein (Mr 250,000), which binds IGF II 5 times better than IGF I, and does not recognize insulin. The amounts of type II IGF receptor are significantly higher in fetal and malignant cells than in adult brain. Based on these findings we suggest that IGF receptors in brain undergo changes during fetal development and malignant transformation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Insulin-like growth factor (IGF)/somatomedin receptor subtypes: structure, function, and relationships to insulin receptors and IGF carrier proteins

The insulin-like growth factors IGF-I and IGF-II are mitogenic polypeptides with a high degree of chemical homology. Two distinct subtypes of receptors for the IGFs have been identified on the basis of structure and binding specificity. Type I IGF receptors bind IGF-I with equal or greater affinity than IGF-II, and also bind insulin with a low but definite affinity. They are structurally homologous to insulin receptors, containing disulfide-linked a-subunits that bind the peptides and beta-subunits that have intrinsic tyrosine-specific kinase activity. Type II IGF receptors typically bind IGF-II with greater affinity than IGF-I, and do not interact with insulin. They consist of a single polypeptide and lack tyrosine kinase activity. Because of the extensive cross-reactivity of IGF-I and IGF-II with both type I and type II receptors, we believe that potentially either receptor may mediate the biological responses of either peptide. Type I IGF receptors have been shown to mediate the mitogenic effects of the IGFs in some cell types. Whether type II IGF receptors mediate the same or different functions remains to be elucidated.     

Two types of receptor for insulin-like growth factors in mammalian brain.

Two types of receptor for insulin-like growth factors (IGFs) have been identified on adult rat and human brain plasma membranes by competitive binding assay, affinity labelling, receptor phosphorylation and interaction with antibodies to insulin receptors. The type I IGF receptor consists of two species of subunits: alpha-subunits (mol. wt. approximately 115 000), which bind IGF I and IGF II with almost equal affinity and beta-subunits (mol. wt. approximately 94 000), the phosphorylation of which is stimulated by IGFs. The alpha-subunits of type I IGF receptors in brain and other tissues differ significantly (mol. wt. approximately 115 000 versus 130 000), whereas the beta-subunits are identical (mol. wt. approximately 94 000). The type II IGF receptor in brain is a monomer (mol. wt. approximately 250 000) like that in other tissues. Two antibodies to insulin receptors, B2 and B9, interact with type I but not with type II IGF receptors. B2 is more potent than B9 in inhibiting IGF binding and in immunoprecipitating type I IGF receptors, in contrast to their almost equal effects on insulin receptors. This pattern is characteristic for IGF receptors in other cells. The presence of two types of IGF receptor in mammalian brain suggests a physiological role of IGFs in regulation of nerve cell function and growth. Since IGF II, but not IGF I, is present in human brain, we propose that IGF II interacts with both types of IGF receptor to induce its biological actions.     

A novel fetal insulin-like growth factor (IGF) I receptor. Mechanism for increased IGF I- and insulin-stimulated tyrosine kinase activity in fetal muscle

Insulin and insulin-like growth factor (IGF) I receptors from fetal and adult rat skeletal muscle were compared in order to gain insight into the evolving functions of the hormones during development. Basal, insulin-stimulated, and IGF I-stimulated receptor phosphorylation and tyrosine kinase activity are severalfold higher in partially purified receptor preparations from fetal muscle in comparison with equal numbers of receptors from adult muscle. There are distinct insulin and IGF I receptors with Mr 95,000 beta subunits in adult muscle, as evidenced by hormone dose-response curves, immunoprecipitation with specific antibodies, binding to insulin and IGF I affinity columns, and analysis of tryptic phosphopeptides. In addition to these two receptor species, fetal muscle contains a receptor with a Mr 105,000 beta subunit. The fetal receptor is structurally more closely related to the IGF-I receptor than the insulin receptor on the basis of its precipitation with specific antibodies, binding to an IGF I affinity column, and tryptic phosphopeptide map. The fetal receptor does not appear to bind insulin but, unlike the IGF-I receptor, its phosphorylation is stimulated by low physiological concentrations of both insulin and IGF I. This could be explained by the cross-phosphorylation of fetal receptors by activated insulin receptors. Expression of the fetal receptor is highest in the fetus and decreases markedly during the first 2 weeks of postnatal life. The fetal receptor appears to account for the high tyrosine kinase activity of fetal muscle and may be an important mediator of responses to both insulin and IGF I early in development.     

Demonstration and structural comparison of receptors for insulin-like growth factor-I and -II (IGF-I and -II) in brain and blood-brain barrier

Specific receptors for insulin-like growth factors (IGF) I and II on microvessel-free rat brain cell membranes (RBCM) and in the microvessels that constitute the blood-brain barrier (BBB) were identified and characterized by means of affinity cross-linking techniques and specific anti-receptor antibodies. Two different models of BBB were examined: isolated rat brain capillaries and cultured bovine brain microvessel endothelial cells. Cross-linking with 125-I-IGF-I, followed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), revealed an alpha subunit of apparent Mr = 138,000 in both BBB preparations, compared to 120,000 in RBCM. Cross-linking was inhibited by unlabeled IGF and insulin, but not by antibody directed against the IGF-II receptor. When 125-I-IGF-II was cross-linked, followed by SDS-PAGE under reducing conditions, a major band of apparent Mr = 250,000 was identified in RBCM and both BBB preparations. This band, which migrated with an approximately equivalent Mr in both brain and BBB membranes, was inhibited by unlabeled IGF and by antibody specific for the IGF-II receptor. Thus, both rat and bovine brain microvessels possess classical Type I and II IGF receptors. While the alpha subunit of the Type I receptor of brain is smaller than that of the BBB, the Type II receptor of brain and BBB appear to be structurally and immunologically identical.     

Insulin receptors in the mammalian central nervous system: binding characteristics and subunit structure

Insulin receptors in rat and human central nervous system have been identified by binding of 125I-insulin on purified synaptic plasma membranes; affinity labelling of receptors by chemical cross-linking 125I-insulin; or phosphorylation of receptors with [gamma-32P]ATP. Brain insulin receptors showed significant differences in their binding characteristics and subunit structure when compared with receptors in other tissues like adipose and liver cells: absence of negatively cooperative interactions; a distinct binding specificity i.e. porcine proinsulin, coypu insulin and insulin-like growth factor I and II showed 2-5 times higher binding affinity in brain than in other cell types; a smaller molecular size of the brain receptor alpha-subunit than in other tissues (Mr approximately 115,000 instead of 130,000). In contrast, the size (Mr approximately 94,000) and function of the insulin receptor beta-subunit kinase was identical with that described in other cells. We conclude, that insulin receptors in mammalian brain represent a receptor subtype which may mediate growth rather than metabolic activity of insulin.     

Characterization of a novel insulin receptor from stingray liver

The insulin receptor from the liver of stingray, a cartilaginous fish, has characteristics which are in marked contrast to those of the mammalian insulin receptor. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of cross-linked, affinity-labeled stingray insulin receptor shows an apparent molecular mass of 210 kDa for the intact receptor. Reduction with mercaptoethanol resulted in no alteration in the apparent size of the stingray insulin receptor. Gel filtration studies of Triton X-100 solubilized stingray insulin receptor demonstrated an apparent Stokes radius of 7.6 nm. Ultracentrifugation sucrose gradient studies of cross-linked affinity labeled stingray receptor resulted in determination of a sedimentation coefficient of 13 S. Both of these parameters were greater than simultaneously obtained data for the human insulin receptor (7.2 nm and 11 S, respectively). Unlabeled insulin competed with binding of 125I-insulin and 125I-insulin growth factor (IGF) I with a half-maximal concentration of 1 nM for either. Unlabeled IGF I and II also competed, but were 4-5-fold less potent than insulin. It was found that not only did IGF I bind to the 210-kDa material, but both insulin and IGF I stimulated phosphorylation of a 210-kDa material which was immunoprecipitable by a polyclonal insulin receptor antibody. Elution of this material from the gel followed by hydrolysis and thin layer chromatography demonstrated that the 210-kDa material was specifically phosphorylated on tyrosine only. These data suggest that the insulin receptor from stingray liver is a dimer made up of 2 identical subunits of about 210 kDa size which contain both binding regions and insulin-stimulated tyrosine kinase. Specificity studies suggest that the stingray insulin receptor may represent a phylogenetic position prior to the evolutionary divergence of insulin and the insulin-like growth factors.     

Insulin-like growth factor-I is internalized after binding to the type I insulin-like growth factor receptor

Receptor-mediated endocytosis may represent an important mechanism whereby peptide hormones exert their biological effects. The ability of recombinant insulin-like growth factor (IGF)-I to be internalized by cultured cells was evaluated in BRL-3A2 cells, a rat liver-derived cell line which lacks insulin receptors. Since recombinant IGF-I does not bind to the Type II IGF receptor, all specific binding of 125I-IGF-I in BRL-3A2 cells represents binding to the Type I receptor. Exposure of BRL-3A2 cells to IGF-I resulted in a rapid 50% downregulation of Type I IGF receptors. Only one-half of these binding sites were sensitive to treatment with trypsin, a phenomenon which indicates that the peptide and its receptor were internalized after the cells were exposed to IGF-I. In conclusion, these experiments demonstrate that IGF-I can be internalized by cultured cells via the Type I IGF receptor, and suggest that IGF hormone action may be exerted by receptor-mediated endocytosis.     

Madin-Darby canine kidney cells display type I and type II insulin-like growth factor (IGF) receptors

Using affinity cross-linking techniques, we report the presence of type I IGF and type II IGF receptors in Madin-Darby canine kidney cells, a line of cells lacking insulin receptors. The IGF receptors were further characterized by competition binding studies and found to be similar to IGF receptors in other tissue types. In Madin-Darby canine kidney cells, the type I IGF receptor binds IGF-I greater than IGF-II greater than insulin and the type II IGF receptor binds IGF-II and IGF-I with approximately the same affinity, but does not bind insulin.     

Distinct biologically active receptors for insulin, insulin-like growth factor I, and insulin-like growth factor II in cultured skeletal muscle cells

The expression of insulin-like growth factor (IGF) receptors at the cell surface and the changes in IGF responsiveness during differentiation were studied in the L6 skeletal muscle cell line. Throughout the entire developmental sequence, distinct receptors for IGF I and IGF II that differed in structure and peptide specificity could be demonstrated. During differentiation, both 125I-IGF I and 125I-IGF II binding to the L6 cells decreased as a result of a 3-4-fold reduction in receptor number, whereas 125I-insulin binding increased. Under nonreducing conditions, disuccinimidyl suberate cross-linked 125I-IGF I and 125I-IGF II to two receptor complexes with apparent Mr greater than 300,000 (type I) and 220,000 (type II). Under reducing conditions, the apparent molecular weight of the type I receptor changed to Mr 130,000 (distinct from the 120,000 insulin receptor) and the type II receptor changed to 250,000. IGF I and IGF II both stimulated 2-deoxy-D-glucose and alpha-aminoisobutyric acid uptake in the L6 cells with a potency close to that of insulin, apparently through interaction with their own receptors. The stimulatory effects of IGF II correlated with its affinity for the type II but not the type I IGF receptor, as measured by inhibition of affinity labeling, whereas the effects of IGF I correlated with its ability to inhibit labeling of the type I receptor. In spite of the decrease in type I and type II receptor number, stimulation of 2-deoxy-glucose and alpha-aminoisobutyric acid uptake by the two IGFs increased during differentiation.     

Receptors for insulin-like growth factors I and II in developing embryonic mouse limb bud

Insulin-like growth factors (IGF) or somatomedins (SM) have been classically defined as promoting the actions of growth hormone in skeletal growth. IGF is divided into two groups, IGF-I and II, and are presumed to act via IGF type I (higher affinity for IGF-I and II and very low affinity for insulin) and II (higher affinity for IGF-II than I and no affinity for insulin) receptors, respectively. Recently, a switchover role of IGF-II to I during fetal to adult growth has been suggested. We have investigated the possible transitional role of IGF-II to I in a developing mouse embryonic limb bud organ culture model. In this in vitro system, limb bud develops from the blastoma stage to a well-differentiated cartilage tissue. Both IGF type I and II receptors were found to be present in limb buds at all stages of differentiation. Type I receptor decreased with differentiation while Type II receptor increased. The effect of IGF-I on [3H]thymidine and [35S]sulfate uptake by the tissue increased with differentiation while the effect of IGF-II on [3H]thymidine uptake of the undifferentiated tissue was abolished with differentiation of the tissue. The increase of the IGF-I response with decreased type I receptor may reflect an altered receptor sensitivity (occupancy) during differentiation. The decrease of the IGF-II response with increased type II receptor with differentiation may on the other hand suggest that IGF-II in differentiated tissue no longer acts as a classical growth factor. These results tend to support the hypothesis of the switchover role of IGF-I and II during fetal and adult growth, however, confirmation of the precise role of IGF-I and II in biological growth may have to wait until further studies clarifying the significance of the increased IGF type II receptor in differentiated tissue are made.     

Phosphorylation of insulin-like growth factor I receptor by insulin receptor tyrosine kinase in intact cultured skeletal muscle cells

The interaction between insulin and insulin-like growth factor I (IGF I) receptors was examined by determining the ability of each receptor type to phosphorylate tyrosine residues on the other receptor in intact L6 skeletal muscle cells. This was made possible through a sequential immunoprecipitation method with two different antibodies that effectively separated the phosphorylated insulin and IGF I receptors. After incubation of intact L6 cells with various concentrations of insulin or IGF I in the presence of [32P]orthophosphate, insulin receptors were precipitated with one of two human polyclonal anti-insulin receptor antibodies (B2 or B9). Phosphorylated IGF I receptors remained in solution and were subsequently precipitated by anti-phosphotyrosine antibodies. The identities of the insulin and IGF I receptor beta-subunits in the two immunoprecipitates were confirmed by binding affinity, by phosphopeptide mapping after trypsin digestion, and by the distinct patterns of expression of the two receptors during differentiation. Stimulated phosphorylation of the beta-subunit of the insulin receptor correlated with occupancy of the beta-subunit of the insulin receptor by either insulin or IGF I as determined by affinity cross-linking. Similarly, stimulation of phosphorylation of the beta-subunit of the IGF I receptor by IGF I correlated with IGF I receptor occupancy. In contrast, insulin stimulated phosphorylation of the beta-subunit of the IGF I receptor at hormone concentrations that were associated with significant occupancy of the insulin receptor but negligible IGF I receptor occupancy. These findings indicate that the IGF I receptor can be a substrate for the hormone-activated insulin receptor tyrosine kinase activity in intact L6 skeletal muscle cells.     

The type II insulin-like growth factor receptor does not mediate increased DNA synthesis in H-35 hepatoma cells

The immunoglobulin fraction prepared from the serum of a rabbit immunized with purified type II insulin-like growth factor (IGF) receptor from rat placenta was tested for its specificity in inhibiting receptor binding of 125I-IGF II and for its ability to modulate IGF II action on rat hepatoma H-35 cells. The specific binding of 125I-IGF II to plasma membrane preparations from several rat cell types and tissues was inhibited by the anti-IGF II receptor Ig. Affinity cross-linking of 125I-IGF II to the Mr = 250,000 type II IGF receptor structure in rat liver membranes was blocked by the anti-receptor Ig, while no effect on affinity labeling of insulin receptor with 125I-insulin or IGF I receptor with 125I-IGF I or 125I-IGF II was observed. The specific inhibition of ligand binding to the IGF II receptor by anti-receptor Ig was species-specific such that mouse receptor was less potently inhibited and human receptor was unaffected. Rat hepatoma H-35 cells contain insulin and IGF II receptor, but not IGF I receptor, and respond half-maximally to insulin at 10(-10) M and to IGF II at higher concentrations with increased cell proliferation (Massague, J., Blinderman, L.A., and Czech, M.P. (1982) J. Biol. Chem. 257, 13958-13963). Addition of anti-IGF II receptor Ig to intact H-35 cells inhibited the specific binding of 125I-IGF II to the cells by 70-90%, but had no detectable effect on 125I-insulin binding. Significantly, under identical conditions anti-IGF II receptor Ig was without effect on IGF II action on DNA synthesis at both submaximal and maximal concentrations of IGF II. This finding and the higher concentrations of IGF II required for growth promotion in comparison to insulin strongly suggest that the Mr = 250,000 receptor structure for IGF II is not involved in mediating this physiological response. Rather, at least in H-35 cells, the insulin receptor appears to mediate the effects of IGF II on cell growth. Consistent with this interpretation, anti-insulin receptor Ig but not anti-IGF II receptor Ig mimicked the ability of growth factors to stimulate DNA synthesis in H-35 cells. We conclude that the IGF II receptor may not play a role in transmembrane signaling, but rather serves some other physiological function.     

Insulin regulation of insulin-like growth factor action in rat hepatoma cells

We have reported previously that insulin causes a complete but reversible desensitization to insulin action in rat hepatoma HTC cells in tissue culture, and that this insulin resistance is mediated by postbinding mechanisms rather than receptor down-regulation (Heaton, J. H., and Gelehrter, T. D. (1981) J. Biol. Chem. 256, 12257-12262). We report here that insulin causes a similar desensitization to the induction of tyrosine aminotransferase by the insulin-like growth factors IGF-I and IGF-II isolated from human plasma, and by multiplication-stimulating activity, the rat homologue of IGF-II. The results of both competition-binding studies and affinity cross-linking experiments indicate that insulin-like growth factors (IGFs) bind primarily to IGF receptors rather than to insulin receptors. The low concentrations at which these factors induce transaminase is consistent with their acting primarily via IGF receptors. This is confirmed by experiments utilizing anti-insulin receptor antibody which both inhibits 125I-insulin binding and shifts the concentration dependence of insulin induction of tyrosine aminotransferase to the right. This same immunoglobulin does not inhibit 125I-multiplication-stimulating activity binding and only minimally inhibits 125I-IGF-I binding. Anti-insulin receptor antibody also does not significantly shift the concentration dependence for the IGFs, suggesting that IGFs induce transaminase by acting via IGF receptors. Although insulin down regulates insulin receptors, it does not decrease IGF-I or IGF-II binding. We conclude that insulin causes desensitization of HTC cells to IGFs by affecting a postbinding step in IGF action, which may be common to the actions of both insulin and insulin-like growth factors.     

Insulin-like growth factor I (IGF I) receptor autophosphorylation and kinase activity. Effect of a human polyclonal antibody (pIgG)

IGF I receptor is a tyrosine kinase capable of phosphorylating the receptor itself and other substrates. A high degree of homology does exist in tyrosine kinase domain among receptors for several polypeptide growth factor receptors and this enzymic activity has been indicated as a possible mediator of biological action. Nevertheless growth factor receptors possess peculiar specificities both in their functions and tissue distribution. A human polyclonal IgG (pIgG), previously characterized as anti insulin receptor antibody, able to inhibit insulin receptor kinase activity, was used to further investigate subunit homologies and differences in antigenicity and functional regulation between IGF I and insulin receptors, IGF I receptor tyrosine kinase was stimulated by a IGF I analog (aIGF I), produced by DNA recombinant technology, pIgG was able to inhibit IGF I receptor kinase activity, thus revealing antigenic homologies between the kinase domains of insulin and IGF I receptors. However the more pronounced inhibition of IGF I receptor-compared with insulin receptor kinase activity by pIgG suggests the existence of different regulatory mechanisms.     

How distinct are the insulin and insulin-like growth factor I signalling systems?

Insulin and insulin-like growth factor I (IGF-I) are closely related peptides. Insulin is primarily involved in regulating carbohydrate, fat and protein metabolism. IGF-I, however, regulates growth and development of the whole organism as well as differentiated functions in specific tissues. Each of these functions are mediated by specific tyrosine kinase receptors expressed on the cell surface. The insulin and IGF-I receptors, though separate gene products, are very similar. Amino acid similarities range between 40 and 85% in different domains, the highest degree of homology being found in the tyrosine kinase domain. Tertiary structure similarities further explain the interactions of each ligand with the heterologous receptor; thus insulin receptors bind insulin with high affinity and IGF-I with lower affinity, and the opposite is true for the IGF-I receptor. Since each ligand can stimulate both receptors and both receptors seem capable of mediating both metabolic and growth activities, what separates these two distinct physiological roles? The interaction of the ligands with their own specific high affinity receptors is facilitated by the presence of IGF-specific binding proteins (BPs) which, however, do not bind insulin. These BPs, found both in the circulation and in tissues, bind all the circulating IGFs and transport the IGFs to their target tissues, thus ensuring that at physiological concentrations IGF-I will only interact with its own receptor. Furthermore, they modulate IGF effects. Since insulin circulates at much lower concentrations compared with the IGFs, this ensures that insulin will only interact with high-affinity insulin receptors.(ABSTRACT TRUNCATED AT 250 WORDS)     

The inhibition of a membrane-bound enzyme as a model for anaesthetic action and drug toxicity.

Insulin-like growth factor (IGF)-binding sites copurifying with human placental insulin receptors during insulin-affinity chromatography consist of two immunologically distinct populations. One reacts with monoclonal antibody alpha IR-3, but not with antibodies to the insulin receptor, and represents Type I IGF receptors; the other reacts only with antibodies to the insulin receptor and is precipitated with a polyclonal receptor antibody (B-10) after labelling with 125I-multiplication-stimulating activity (MSA, rat IGF-II). The latter is a unique sub-population of atypical insulin receptors which differ from classical insulin receptors by their unusually high affinity for MSA (Ka = 2 x 10(9) M-1 compared with 5 x 10(7) M-1) and relative potencies for insulin, MSA and IGF-I (40:5:1 compared with 150:4:1). They represent 10-20% of the total insulin receptor population and account for 25-50% of the 125I-MSA binding activity in Triton-solubilized placental membranes. Although atypical and classical insulin receptors are distinct, their immunological properties are very similar, as are their binding properties in response to dithiothreitol, storage at -20 degrees C and neuraminidase digestion. We conclude that atypical insulin receptors with moderately high affinity for IGFs co-exist with classical insulin receptors and Type I IGF receptors in human placenta. They provide an explanation for the unusual IGF-II binding properties of human placental membranes and may have a specific role in placental growth and/or function.     

Binding of insulin-like growth Factor ii and multiplication-stimulating activity-stimulated phosphorylation in basolateral membranes from dog kidney

Biologic actions of insulin and insulin-like growth factors (IGFs) are thought to be initiated by binding of peptides to tissues, followed by phosphorylation of specific hormone receptors. Both insulin and IGF bind to renal membranes, suggesting functional roles for these peptides in kidney. The present studies further characterize the interaction of multiplication-stimulating activity (MSA)/IGF II with its renal receptor. Specific binding of 125I-IGF II was measured in basolateral membranes isolated from proximal tubular cells of dog kidney. Binding was half-maximal at 10(-9) M MSA and was not inhibited by human growth hormone, IGF I, insulin, or anti-insulin receptor antibodies. Concentration-dependent MSA-stimulated phosphorylation of a Mr 135,000 protein band was demonstrated in autoradiograms of sodium dodecyl sulfate-polyacrylamide gels from basolateral membrane suspensions. Insulin increased phosphorylation of this band only in the presence of MSA, while a Mr 92,000 band was consistently phosphorylated with insulin alone. The phosphorylated Mr 135,000 band which had been solubilized with detergent from basolateral membranes was immunoprecipitated using serum from a patient with anti-insulin receptor antibodies suggesting that the band is the alpha subunit of the insulin receptor. This was supported by the demonstration of covalent cross-linkage of 125I-insulin to the Mr 135,000 band. We conclude that receptor-mediated MSA-stimulated phosphorylation of isolated basolateral membranes may reflect a process by which biological actions of IGF II are mediated in vivo. Our data suggest that insulin and IGF II may interact by regulating protein phosphorylation.     

CHARACTERISTICS AND REGIONAL DISTRIBUTIONS OF TWO DISTINCT [3H]NALOXONE BINDING SITES IN THE RAT BRAIN

Using [³H]naloxone at a concentration of 4.5 nm , the potent opiate agonist etorphine as well as the potent antagonist diprenorphine displace only about 75% of specific naloxone binding P₂ fractions from rat whole forebrain, without additive effect. Several other opiates and antagonists completely displace specific naloxone binding. This indicates that etorphine and diprenorphine specifically bind to one and the same naloxone binding site (type I) while leaving another naloxone binding site (type II) unaffected. Type I binding sites are much more thermo-labile than type II. [³H]Naloxone binding to type I sites is unaffected by incubation temperature in the range 10 to 25°C. while binding type II sites decreases rapidly with increasing incubation temperature, no specific type II binding being detectable at or above 20°C. The two naloxone receptor types also differ with respect to pH dependence, and affinity for naloxone with types I and II having affinity constants (K_d) of 2 and 16 nm , respectively, at 0°C. The two binding sites have different regional distributions with high relative levels of type II receptors in cerebellum and low relative levels in pons-medulla and striatum. In whole rat brain there are about 4 times as many type II receptors as type I. These results suggest that naloxone and several other opiate agonists and antagonists bind to two distinct receptor types which are probably not agonist/antagonist aspects of the same receptor.     

Tyrosine kinase activity of brain insulin and IGF-1 receptors

Lectin-purified rat brain preparations demonstrate specific [125I]insulin and [125I]-IGF-1 binding. Insulin-stimulable tyrosine kinase activity as measured by exogenous substrate phosphorylation was present in brain and liver lectin purified preparations with the delta kinase activity/B/F of brain approximately 2.5 fold greater than that of liver. Insulin-stimulable tyrosine kinase activity was abolished in liver but decreased by only approximately 50 percent in brain after immuno-depletion with antiserum which recognizes insulin but not IGF-1 receptors. Insulin and IGF-1 dose responses for phosphorylation of the immunodepleted brain preparations suggested that the remaining tyrosine kinase activity was IGF-1 receptor mediated. Thus, functional IGF-1 receptors are present in rat brain, and the doses of insulin typically used to evaluate insulin receptor tyrosine kinase activity will stimulate IGF-1 receptor tyrosine kinase activity as well.