Stimulation of glycosaminoglycan synthesis by somatomedin and insulin in rat chondrocytes via somatomedin receptors

Using cultured normal rat chondrocytes we have investigated 1) the effects of somatomedin and insulin on glycosaminoglycan (GAG) synthesis and 2) somatomedin and insulin binding sites. We confirmed that somatomedin and insulin stimulate GAG synthesis in normal rat chondrocytes. The maximal responses of somatomedin and insulin in GAG synthesis were the same, but the stimulation of GAG synthesis by maximally effective concentrations of insulin plus somatomedin was not cumulative. Cultured rat chondrocytes had binding sites for somatomedin and insulin, and the binding was displaced by both somatomedin and insulin. Somatomedin is much more effective than even large amounts of unlabelled insulin in displacing both somatomedin and insulin binding. Anti-insulin receptor IgG, which inhibits insulin binding to human placental membrane, did not affect GAG synthesis stimulated by insulin nor did it inhibit insulin binding to chondrocytes. Somatomedin used for GAG synthesis and displacement was the partially purified somatomedin A with a biological activity of 80 U/mg. Therefore the possibility that substances other than somatomedin A, which was contaminated in this preparation, affected this result could not be excluded completely. However, these results suggest that somatomedin and insulin act on normal rat chondrocytes through a somatomedin receptor.     

Photoreactive insulin analogues used to characterise the insulin receptor

Three photoreactive insulin analogues (“photoprobes”) have been prepared in which an aryl azide group was substituted at either the A1, B1 or B29 positions of the insulin molecule. When incubated with rat liver plasma membranes and irradiated all three photoprobes covalently labelled specific insulin binding sites within the membrane. SDS-polyacrylamide gel electrophoresis of plasma membranes covalently tagged with either of the three ¹²⁵I-photoprobes resolved one major specifically labelled polypeptide with an apparent molecular weight of 130,000. The labelled polypeptide migrated anomalously in SDS-polyacrylamide gels and a molecular weight of 90,000 for the polypeptide was determined from a ‘Ferguson’ plot using the combined results from gels of different acrylamide concentrations. Column chromatography of detergent solubilised photoprobe-labelled membranes indicated that the labelled polypeptide may be a subunit of a larger protein complex.     

Characterization of the binding of a rat somatomedin to receptors in human placental cell membranes.

The somatomedins presumably initiate their growth promoting effects by first binding to specific cell surface receptors in responsive tissues. The specific and high affinity binding of [¹²⁵I]-rat somatomedin to human placental membranes was saturable and reversible with a dissociation constant of 4.5 × 10^?9 M calculated from Scatchard analysis of competitive binding experiments. Competition for [¹²⁵I]-rat somatomedin binding to placental receptors by other somatomedins and growth factors suggest a close structural relationship between rat somatomedin and the human somatomedin, insulin-like growth factor I.     

Regulation of hepatic growth hormone receptors by insulin.

Induction of diabetes in the rat with streptozotocin caused a decrease in the specific binding of human growth hormone to liver receptors. The decrease was due to a loss of binding sites, with no change in the affinity constant for growth hormone (5.6 × 10⁹M^?1). A highly significant correlation was seen between serum insulin levels and hepatic growth hormone binding. Specific insulin binding to hepatic receptors was increased in diabetes, with a highly significant negative correlation between serum insulin levels and insulin binding. The loss of growth hormone receptors was reversed by treating diabetic rats with insulin. Since hormones which bind to “lactogenic” binding sites in the liver are reported to regulate somatomedin levels, the insulin dependence of human growth hormone receptors might account for the decrease in serum somatomedin in diabetes.     

Interactions of antinicotinic acetylcholine receptor antibodies with rat brain and muscle antigenic determinants

Studies were performed to determine whether antibodies prepared against nicotinic acetylcholine receptors (nAcChoR) from electric tissue are reactive toward nAcChoR-like antigenic determinants in rat brain. Reference experiments involved the use of Torpedo electroplax and rat innervated muscle as tissue controls and an anti-alpha-bungarotoxin antiserum as a probe for curaremimetic neurotoxin binding sites. As evinced by their ability to inhibit immunoprecipitation of Torpedo nAcChoR, brain or muscle membranes specifically interact with polyclonal antisera raised against Electrophorus electroplax nAcChoR. When the extent of polyclonal anti-nAcChoR antibody binding to muscle membranes is measured by protein A binding protocols, receptor-like antigenic determinants and toxin binding sites are found to be present in approximately equal quantities. In contrast, nAcChoR-like antigenic determinants on rat brain membranes are present at concentrations in excess of those of toxin binding sites. The results are consistent with the earlier observation that some antibodies prepared against nAcChoR from peripheral tissues recognize rat brain high-affinity alpha-bungarotoxin binding sites. The results also suggest the existence of nAcChoR-like entities in brain that do not bind toxin with a high affinity.     

Insulin Binding in Four Regions of the Developing Rat Brain

Specific insulin binding has been demonstrated in partially purified membranes prepared from four regions of the developing rat brain. Insulin binding to brain membranes demonstrated kinetics and hormonal specificity that were quite similar to those reported for traditional insulin target tissues (e.g., liver and adipose tissue), and binding was significantly correlated with receptor concentration. Binding in the olfactory bulbs, cerebrum, cerebellum, and hypothalamus all reached highest values at 15 days of postnatal life, with the olfactory bulbs generally showing the greatest binding at all ages studied. A temporal relationship was found between insulin binding to brain membranes in the postnatal rat and plasma membrane protein synthesis, especially in the cerebellum and olfactory bulbs.     

Comparative binding of bovine, human and rat insulin-like growth factors to membrane receptors and to antibodies against human insulin-like growth factor-1.

The immunological properties of human, bovine and rat insulin-like growth factors (IGF) and insulin were compared in competitive binding studies with Tr10 and NPA polyclonal antisera raised in rabbits against human IGF-1. Bovine IGF-1 was 11-19% as effective as human IGF-1 in competing for binding with 125I-labelled human IGF-1, whereas IGF-2 reacted poorly and insulin did not compete. Similar competitive binding curves were obtained with the mouse monoclonal anti-(human IGF-1) antibody 3D1, except that bovine IGF-1 showed a severalfold greater affinity for the monoclonal antibody than for either polyclonal antiserum. Membranes isolated from human placenta, sheep placenta and foetal-human liver were used as sources of cellular receptors. In human placental membranes, most of the binding of IGF-1 tracers could be attributed to a type-1 receptor, because insulin inhibited up to 65% of tracer binding. The other two tissues apparently contain only type-2 receptors, as evidenced by the very low potency of bovine or human IGF-1 in competing for binding with IGF-2 tracers and the absence of any competition by insulin. In competition for binding with labelled bovine or human IGF-1 to human placental membranes, bovine IGF-1 had a similar potency to human IGF-1, whereas bovine IGF-1 was more potent in binding studies with tissues rich in type-2 receptors. Rat IGF-2 was considerably less effective than human IGF-2 in competition for receptors on any of the membrane preparations.     

Effect of zinc on insulin binding to rat adipocytes and hepatic membranes and to human placental membranes and IM-9 lymphocytes

The effect of ionic zinc on the binding of 125I-insulin to a variety of tissues with well-characterized insulin receptors has been assessed. In the isolated rat adipocyte, zinc (250 to 1000 microM) showed dose-dependent stimulation of insulin specific binding, with little change in non-specific binding. This effect was rapid and sustained during a 60 min incubation and was due to a Zn-mediated increase in the number of available binding sites. No changes in binding affinity were apparent. A similar but smaller stimulation of insulin binding was observed at lower Zn concentrations (25-50 microM) in rat liver membranes. In this tissue, higher doses of Zn caused a marked rise in non-specific binding and resulted in the loss of any apparent specific binding of insulin. Similar effects were seen in IM-9 lymphocytes and human placental membranes, although in this latter case the Zn effect on non-specific binding was less marked. These data indicate that ionic zinc exerts a tissue-specific stimulation of insulin binding to its receptors. An intriguing corollary, that requires further study, is that this effect may be related to the known association of insulin with Zn, and thus to an enhancement of insulin action in vivo, at least on the adipocyte.     

Effects of acute and chronic endotoxin treatment on glucagon and insulin receptors on rat liver plasma membranes

The effects of acute and chronic endotoxin treatment on the plasma levels of insulin and glucagon and their binding to rat liver plasma membranes were examined. Both acute and chronic endotoxin administration increased plasma glucagon levels and decreased the glucagon to insulin molar ratio. Acute, but not chronic, endotoxin decreased blood glucose and insulin levels. Glucagon binding was increased in membranes prepared from the acutely treated rats. However, in membranes obtained from rats treated chronically with endotoxin, only insulin binding was increased. The increases in the binding of both insulin and glucagon were the result of increases in receptor sites.     

Ontogeny of somatomedin during development in the mouse. Serum concentrations, molecular forms, binding proteins, and tissue receptors

The purpose of this study was to assess the ontogeny of serum concentrations and molecular forms of somatomedin during fetal and postnatal development and to define the changes in serum binding proteins for somatomedin-C during various stages of development. The finding that fetal, placental, and decidual mouse tissues possess receptors for somatomedin suggests a role for somatomedin in fetal growth and possibly in the maintenance of pregnancy. Serum somatomedin-C was measured using a highly specific, heterologous radioimmunoassay (RIA) and a less specific membrane binding assay (MBA) which is more sensitive to the influence of somatomedins other than somatomedin-C. The assays were validated for mouse serum by showing that serum concentrations were reduced in genetically growth hormone-deficient mice and in hypophysectomized mice and were increased by growth hormone therapy. As in the human, the RIA measures only a portion of the somatomedin-C present in mouse serum. This “covering up” of somatomedin is attributed to the presence of serum binding proteins and is corrected by treatment of serum samples with acid. By both RIA and MBA, serum somatomedin concentrations are low in fetal and newborn mice, begin to rise in the fourth postnatal week, and reach adult values by 7 weeks of age. The chromatographic pattern of adult mouse serum on Sephacryl 200 is similar to that observed with human sera: The immunoreactive material elutes at apparent molecular weights of 140,000 and 30,000–40,000. The elution profile of ¹²⁵I-labeled somatomedin-C bound to components of serum is nearly identical to the pattern of endogenous activity. As with human serum, somatomedin-C in acidified mouse serum elutes at a lower molecular weight, coincident with insulin and purified somatomedin-C. Maternal serum somatomedin declines in the last half of gestation at the time when placental lactogen levels rise. Along with the absolute decline in somatomedin content is the appearance of unsaturated sites on somatomedin binding proteins. These findings are unexpected and unexplained since somatomedin rises late in pregnancy in humans and several lines of evidence suggest that placental lactogen has the capacity to stimulate somatomedin production. We previously have presented evidence that explants of multiple fetal mouse tissues synthesize somatomedin-C. The present study shows that the immunoreactive somatomedin-C in fetal mouse serum shares identical characteristics with those reported previously for media obtained from mouse liver explants. It seems possible that somatomedin's actions are exerted primarily at or near its site of production and that circulatory levels do not reflect the importance of somatomedin-C on fetal growth. While elucidation of the dramatic developmental changes in serum content and molecular forms of somatomedin-C and in somatomedin binding proteins may be essential to clarifying the role of somatomedin on fetal growth, proof that somatomedin stimulates fetal growth will depend in large part on studies of its biological actions on fetal tissues.     

Characterization and Regulation of Insulin Receptors in Rat Brain

An in vitro receptor binding assay, using filtration to separate bound from free [125I]insulin, was developed and used to characterize insulin receptors on membranes isolated from specific areas of rat brain. The kinetic and equilibrium binding properties of central receptors were similar to those of hepatic receptors. The binding profiles in all tissues were complex and were consistent with binding in multiple steps or to multiple sites. Similar binding properties were found among receptors in olfactory tubercle/bulb, cerebral cortex, hippocampus, striatum, hypothalamus, and cerebellum. High affinity [125I]insulin binding sites (KD = 3-11 nM) were distributed evenly between membranes isolated from P1 and P2 fractions of these brain areas, with the exception of the olfactory tubercle in which binding to P2 membranes was four-fold greater (Bmax = 150 fmol/mg protein). One difference between insulin receptors in brain and peripheral target tissues, however, was observed. Following exposure to 0.17 microM insulin for 3 h at 37 degrees C, the number of specific [125I]insulin binding sites on adipocytes decreased by 40%, while the number of binding sites on minces of cerebral cortex/olfactory tubercle remained constant. The results suggest that although the binding characteristics of central and peripheral insulin receptors are similar, these receptors do not appear to be regulated in the same manner.     

Ontogeny of insulin receptors in the rat hemochorial placenta

Binding of 125I-insulin to rat placental membranes was time and protein concentration dependent, reversible, and specific. Unlabeled porcine insulin competed for 125I-insulin binding with an IC50 of 65 nM, while IGF-I was much less potent with an IC50 of 2.12 mM. Specific binding of 125I-insulin decreased during the second half of gestation from Days 11 to 19. Scatchard analysis of the binding data for membranes prepared from Gestation Days 11 and 19 yielded typical curvilinear plots which showed a marked decrease in the number of binding sites in late gestation placenta. Beginning on Day 14, insulin binding was characterized with isolated labyrinth and basal zone portions of the hemochorial placenta. There was no evidence for differences in Kd values or the number of binding sites in these two functionally distinct portions of the rat placenta. Crosslinking of 125I-insulin followed by SDS-PAGE showed a single protein with a molecular weight of 130,000 from placental tissues on Gestation Days 11 and 19 and confirmed a gestational decrease in the number of insulin receptors. In solubilized, lectin-purified preparations from placenta and liver membranes, insulin stimulated the phosphorylation of a Mr 95,000 protein. 32P-incorporation into this 95,000 protein was stimulated fivefold by insulin in Day 11 placenta receptor, whereas no detectable 32P-incorporation was found in Day 19 placenta. Thus, while the alpha- and beta-subunits of insulin receptors in mid and late gestation placenta have molecular weights which are similar to receptors in maternal liver, data indicate the presence of a functional difference in insulin-stimulated kinase activities.     

Identification of the D-glucose-inhibitable cytochalasin B binding site as the glucose transporter in rat diaphragm plasma and microsomal membranes

[3H]Cytochalasin B binding and its competitive inhibition by D-glucose have been used to identify, the glucose transporter in plasma and microsomal membranes prepared from intact rat diaphragm. Scatchard plot analysis of [3H]cytochalasin B binding yields a binding site with a dissociation constant of roughly 110 nM. Since the inhibition constant of cytochalasin B for D-glucose uptake by diaphragm plasma membranes is similar to this value, this site is identified as the glucose transporter. Plasma membranes prepared from diaphragms bind approx. 17 pmol of cytochalasin B/mg of membrane protein to the D-glucose-inhibitable site. If 280 nM (40000 microunits/ml) insulin is present during incubation, cytochalasin B binding is increased roughly 2-fold without alteration in the dissociation constant of this site. In addition, membranes in the microsomal fraction contain 21 pmol of D-glucose-inhibitable cytochalasin B binding sites/mg of membrane protein. In the presence of insulin during incubation the number of these sites in the microsomal fraction is decreased to 9 pmol/mg of membrane protein. These results suggest that rat diaphragm contain glucose transporters with characteristics identical to those observed for the rat adipose cell glucose transporter. In addition, insulin stimulates glucose transport in rat diaphragm through a translocation of functionally identical glucose transporters from an intracellular membrane pool to the plasma membrane without an alteration in the characteristics of these sites.     

Photoaffinity labelling of gonadotropin releasing hormone binding sites in human epithelial ovarian carcinomata

A photoaffinity labelled derivative of [D-Lys6]-GnRH was prepared with a bifunctional photolabile reagent (4-azidobenzoyl)-N-hydroxysuccinimide. In rat pituitary membranes, this analog retained high binding affinity (Ka = 0.12 x 10(9) M-1) consistent with a single class of receptors. The analog was iodinated and used for the identification of GnRH binding sites in human epithelial ovarian carcinomata. By sodium dodecyl sulfate electrophoresis in 10% polyacrylamide gel the presence of two labelled components could be demonstrated: a high molecular weight component of 63,200 and a smaller component of 46,000. Competition experiments with unlabelled ligand suggest that it is the high molecular weight component which specifically binds GnRH.     

Asymmetric distribution of anionic sites on rat liver nuclear membranes.

The labelling characteristics of isolated rat liver cell nuclei was studied using polycationized ferritin as an ultrastructural probe for anionic sites. At low concentrations of the marker the nuclear surface was partly labelled eg. at sites of nuclear annuli. At high probe concentrations the entire cytoplasmic surface of the outer nuclear membrane bound ferritin particles. On the other hand, the cisternal surfaces of nuclear membranes could not be labelled although in parallel experiments Concanavalin A-ferritin bound to the cisternal surface of both nuclear membranes indicating free access of ferritin particles to the perinuclear space. The results indicate that nuclear membranes show a distinct vectorial asymmetry in respect to the presence of anionic surface sites.     

Potential mechanism of insulin action on glucose transport in the isolated rat diaphragm. Apparent translocation of intracellular transport units to the plasma membrane

[3H]Cytochalasin B binding and its competitive inhibition by D-glucose have been used to quantitate the number of functional glucose transport units in plasma and microsomal membranes prepared from intact rat diaphragm. In a series of three experiments, plasma membranes prepared from diaphragms which have not been incubated with insulin bind approximately 16 pmol of cytochalasin B/mg of membrane protein to the D-glucose-inhibitable binding site. If 280 nM (40,000 microunits/ml) insulin is present during the incubation, cytochalasin B binding to the plasma membranes is increased approximately 2-fold without alteration in the dissociation constant of this site. Membranes in the microsomal fraction prepared from diaphragms which have been incubated for 30 min in the absence of insulin contain 21 pmol of D-glucose-inhibitable cytochalasin B binding sites/mg of membrane protein. However, in the presence of insulin during the incubation period, the number of these sites in the microsomal fraction is decreased to 12 pmol/mg of membrane protein. These results suggest that insulin stimulates glucose transport in the isolated rat diaphragm primarily through a translocation of functional glucose transport units from an intracellular membrane pool to the plasma membrane. These results are similar to the results observed in rat adipose cells (Cushman, S. W., and Wardzala, L. J. (1980) J. Biol. Chem. 255, 4758-4762) and suggest that this mechanism of insulin-stimulated glucose transport activity may be general to other cell types.     

Insulin binding sites on rat liver nuclear membranes: biochemical and immunofluorescent studies.

Preliminary investigations (Horvat et al., '75) indicated the nucleus of rat liver as a site for specific binding of insulin. In this report these observations are confirmed. Nuclei from rat liver were isolated in a highly purified state as verified by interference contrast and electron microscopy and by chemical analysis. Extensive scanning of the preparations did not reveal the presence of structures resembling plasma membranes. The nuclear envelope was isolated by a modification of the method of Kay et al. ('72). Electron micrographs showed the presence of nuclear "ghosts" and few other recognizable nuclear elements, but no plasma membranes (60--80 A thick) were detected. The preparation was found to contain specific insulin binding activity. Specificity of the binding sites for insulin was demonstrated in competition studies with other polypeptide hormones and a synthetic insulin analog. Scatchard analysis of the binding data indicates the presence of a single class of high affinity receptors. In contrast to findings with plasma membranes the hormone-receptor complex is very stable and the kinetics of the dissociation of bound [125I]-insulin do not indicate negative cooperativity of the binding sites. Immunofluorescent labeling of intact, unfixed nuclei showed a specific fluorescent halo only around those nuclei that have been preincubated with insulin. All other controls were negative.     

Specific Binding of Insulin to Membranes from Dendrodendritic Synaptosomes of Rat Olfactory Bulb

The external plexiform layer of the olfactory bulb is among the brain regions where insulin receptors are most abundant. In vitro binding of porcine 125I-insulin to membranes of dendrodendritic synaptosomes isolated from adult rat olfactory bulbs was studied to test the hypothesis that dendrodendritic synapses are major insulin-receptive sites in the external plexiform layer of olfactory bulbs. Of the specific insulin binding sites present in a total particulate fraction from the olfactory bulbs, approximately half were recovered in the dendrodendritic synaptosome fraction. The only other subcellular fraction to which substantial insulin binding was observed was the conventional (axodendritic/axosomatic) synaptosome fraction. Analysis of equilibrium binding of insulin to dendrodendritic synaptosomal membranes, at total insulin concentrations of 0.5-1,000 nM, revealed binding site heterogeneity consistent with a two-site model for insulin binding to a high-affinity (KD = 6 nM), low-capacity (Bmax = 110 fmol/mg of protein) site and a low-affinity (KD = 190 nM), high-capacity (Bmax = 570 fmol/mg of protein) site. The results indicate that the intense labeling of the external plexiform layer of the olfactory bulb in autoradiographic studies of insulin binding can be attributed to insulin receptors on dendrodendritic synaptic membranes in this region.     

Identification of the d-glucose-inhibitable cytochalasin B binding site as the glucose transporter in rat diaphragm plasma and microsomal membranes

[³H]Cytochalasin B binding and its competitive inhibition by d-glucose have been used to identify the glucose transporter in plasma and microsomal membranes prepared from intact rat diaphragm. Scatchard plot analysis of [³H]cytochalasin B binding yields a binding site with a dissociation constant of roughly 110 nM. Since the inhibition constant of cytochalasin B for d-glucose uptake by diaphragm plasma membranes is similar to this value, this site is identified as the glucose transporter. Plasma membranes prepared from diaphragms bind approx. 17 pmol of cytochalasin B/mg of membrane protein to the d-glucose-inhibitable site. If 280 nM (40 000 μunits/ml) insulin is present during incubation, cytochalasin B binding is increased roughly 2-fold without alteration in the dissociation constant of this site. In addition, membranes in the microsomal fraction contain 21 pmol of d-glucose-inhibitable cytochalasin B binding sites/mg of membrane protein. In the presence of insulin during incubation the number of these sites in the microsomal fraction is decreased to 9 pmol/mg of membrane protein. These results suggest that rat diaphragm contain glucose transporters with characteristics identical to those observed for the rat adipose cell glucose transporter. In addition, insulin stimulates glucose transport in rat diaphragm through a translocation of functionally identical glucose transporters from an intracellular membrane pool to the plasma membrane without an alteration in the characteristics of these sites.     

Sodium-Sensitive Cocaine Binding to Rat Striatal Membrane: Possible Relationship to Dopamine Uptake Sites

Abstract: In rat striatal membranes, NaCl induced a twofold increase in the maximal number of cocaine binding sites but did not alter the affinity of these sites for cocaine. This effect was concentration-dependent, specific to sodium ions, and occurred in membranes prepared from corpus striatum but not from other brain regions. Lesions with 6-hydroxydopamine but not with kainic acid eliminated the sodium-induced increase in binding and produced a decrease in the B_max of binding measured in the presence of NaCl. The capacity of a series of drugs to interfere with Na⁺–dependent cocaine binding correlated well with their capacity to inhibit [³H]dopamine uptake into rat striatal synaptosomes. The present results suggest that Na⁺–dependent cocaine binding sites are localized presynaptically on dopaminergic nerve terminals in corpus striatum, and may be related to dopamine uptake sites.