Insulin-like growth factor II acts as an autocrine growth and motility factor in human rhabdomyosarcoma tumors

Rhabdomyosarcoma is the most common soft tissue sarcoma of childhood and appears to arise from developing striated muscle-forming cells. Since insulin-like growth factor II (IGF-II) is involved in normal muscle growth and maturation and elevated IGF-II mRNA levels have previously been reported in rhabdomyosarcomas, we have been studying the possible role of IGF-II in the unregulated growth and invasive potential of these embryonal tumors. In this study, we demonstrate that 13 of 14 rhabdomyosarcoma tumors express high levels of IGF-II mRNA relative to normal adult muscle and also express mRNA for the type I IGF receptors on their cell surface, the receptor thought to mediate the effects of IGF-II on muscle cells. We have established several rhabdomyosarcoma cell lines in mitogen-free media and demonstrate that these cells express type I IGF receptors on their cell surface and secrete IGF-II into the media. Exogenous IGF-II is able to stimulate cellular motility in these cell lines as assayed in a modified Boyden chamber. Finally, alpha IR-3, a type I receptor antagonist, inhibits the growth of these cell lines in serum-free media but does not inhibit IGF-II-induced motility of these cells. These data suggest that endogenously produced IGF-II functions as an autocrine growth and motility factor in many rhabdomyosarcoma tumors. The mitogenic actions of IGF-II are mediated through a domain of the type I IGF receptor that is blocked by alpha IR-3. IGF-II-induced motility may be mediated through an alternative signaling pathway.     

The type I insulin-like growth factor receptor is a motility receptor in human melanoma cells

Insulin-like growth factors I and II (IGF-I and II) and insulin are chemotactic agents for the human melanoma cell line A2058. As shown in this report, the motility receptor mediating this response is the heterodimeric type I IGF receptor. These three factors are able to compete with 125I-labeled IGF-I for binding to the cell surface with IC50 values equal to approximately 2 (IGF-I), approximately 150 (IGF-II), and approximately 300 nM (insulin). Cross-linking of 125I-IGF-I to the cell surface with disuccinimidyl suberate followed by analysis with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography reveals a 130-kDa protein (reduced) consistent with the alpha component of a type I receptor and a 38-kDa protein which does not bind insulin, and thus could be another IGF-I cell surface binding protein. The anti-IGF-I receptor monoclonal antibody (alpha IR-3) also competes with labeled IGF-I in binding experiments. In contrast, a control monoclonal antibody, matched to alpha IR-3 with respect to IgG subclass, has no significant effect on IGF-I binding. While alpha IR-3 inhibits the motility induced by IGF-I, IGF-II, and insulin, pertussis toxin (0.01-1.0 micrograms/ml) has no significant effect on the motility induced by the insulin-like growth factors or insulin on this cell line. Therefore, the type I IGF receptor appears to mediate a highly potent pertussis toxin-insensitive motility response to IGF-I, IGF-II, and insulin. In contrast, motility induced by the autocrine motility factor, a cytokine produced by the A2058 cells, is not affected by alpha IR-3 but is extremely sensitive to pertussis toxin. When mixtures of autocrine motility factor and IGF-I are employed to induce chemotaxis, the resulting motility is greater than that induced by either agent alone. These data indicate that motility in this melanoma cell line can be initiated through multiple receptors that stimulate the cells by separate transduction pathways. This capability to respond to multiple stimuli could enhance the metastatic potential.     

Heterogeneity of insulin-like growth factor-I affinity for the insulin-like growth factor-II receptor: comparison of natural, synthetic and recombinant DNA-derived insulin-like growth factor-I

Although insulin-like growth factors (IGF) I and II bind with high affinity to structurally discrete receptors, they bind with a lesser affinity to each other's receptor. We have evaluated the affinity of five different IGF-I preparations (three natural IGF-I preparations, one synthetic preparation, and one recombinant DNA-derived) for the IGF-II receptor in rat placental membranes, 18-54,SF cells and BRL-3A cells. In all tissues tested, the natural IGF-I preparations demonstrated an affinity for the IGF-II receptor which was 10-20% that of IGF-II. However, the recombinant and synthetic IGF-I preparations exhibited substantially lower affinities than natural IGF-I for this receptor, with only 10-25% reduction in (125-I)iodo IGF-II binding at peptide concentrations up to 400 ng/ml. Radioimmunoassay of the natural IGF-I preparations with an antibody directed against the unique C-peptide region of IGF-II demonstrated that contamination of IGF-I preparations with immunoreactive IGF-II could not exceed 5%. These results demonstrate that IGF-I purified from human plasma has a different affinity for the IGF-II receptor than does synthetic or recombinant IGF-I. Furthermore, these data are consistent with the hypothesis that IGF-I, itself, may be heterogeneous, and that subforms may vary in their affinities for the IGF receptors. Alternatively, IGF-I preparations which have been considered to be pure may be contaminated with small amounts of IGF-II, resulting in overestimation of the affinity of IGF-I for the type II IGF receptor.     

Expression and characterization of a functional human insulin-like growth factor I receptor

Stable transfectants of Chinese hamster ovary (CHO) cells were developed that expressed the protein encoded by a human insulin-like growth factor I (IGF-I) receptor cDNA. The transfected cells expressed approximately 25,000 high affinity receptors for IGF-I (apparent Kd of 1.5 X 10(-9) M), whereas the parental CHO cells expressed only 5,000 receptors per cell (apparent Kd of 1.3 X 10(-9) M). A monoclonal antibody specific for the human IGF-I receptor inhibited IGF-I binding to the expressed receptor and immunoprecipitated polypeptides of apparent Mr values approximately 135,000 and 95,000 from metabolically labeled lysates of the transfected cells but not control cells. The expressed receptor was also capable of binding IGF-II with high affinity (Kd approximately 3 nM) and weakly recognized insulin (with about 1% the potency of IGF-I). The human IGF-I receptor expressed in these cells was capable of IGF-I-stimulated autophosphorylation and phosphorylation of endogenous substrates in the intact cell. This receptor also mediated IGF-I-stimulated glucose uptake, glycogen synthesis, and DNA synthesis. The extent of these responses was comparable to the stimulation by insulin of the same biological responses in CHO cells expressing the human insulin receptor. These results indicate that the isolated cDNA encodes a functional IGF-I receptor and that there are no inherent differences in the abilities of the insulin and IGF-I receptors to mediate rapid and long term biological responses when expressed in the same cell type. The high affinity of this receptor for IGF-II also suggests that it may be important in mediating biological responses to IGF-II as well as IGF-I.     

Functional and immunological distinction between insulin-like growth factor I receptor subtypes in KB cells.

Subtypes of insulin-growth factor I (IGF-I) receptors, including hybrid receptors containing insulin receptor alpha beta dimers associated with IGF-I receptor alpha beta dimers, have been described in a number of systems. The molecular basis of the multiple subtypes and their functional significance is not understood. Ligand-dependent phosphorylation of insulin and IGF-I receptors and immunoprecipitation with antipeptide and monoclonal antibodies have been used to characterize the subpopulations of these receptors in the human KB cell line. IGF-I receptors exhibit beta subunits of 95 and 102 kDa in these cells. IGF-I receptors containing 102-kDa beta subunits are immunoprecipitated by the IGF-I receptor-specific antibody alpha-IR3. Antibody alpha-IR3 does not appear to recognize a hybrid receptor in these cells. However, an antipeptide antibody against the carboxyl-terminal domain of the insulin receptor (AbP5) immunoprecipitates a population of receptors phosphorylated in response to IGF-I (1 nM) which contains both 95- and 102-kDa beta subunits. These receptors must be hybrid complexes because AbP5 does not recognize the 102-kDa beta subunit directly. The inability of antibody alpha-IR3 to recognize these complexes suggests that their IGF-I receptor alpha subunits must differ from typical IGF-I receptor alpha subunits either in primary sequence or conformation. Therefore, KB cells may contain more than one type of IGF-I receptor alpha subunit. Hybrid IGF-I receptors can also be distinguished from homotypic IGF-I receptors by their responsiveness to IGF-II. Stimulation of autophosphorylation in hybrid IGF-I receptors by IGF-I is 3-4-fold greater than that seen in response to IGF-II. In contrast, IGF-I and IGF-II are nearly equipotent in stimulating autophosphorylation in the alpha-IR3-reactive receptor population. This suggests the existence of functionally distinct receptor subtypes which may differ in their ability to mediate the biological effects of IGF-II.     

Insulin-like growth factor II binding to the type I somatomedin receptor. Evidence for two high affinity binding sites

We have previously shown that the antireceptor antibody alpha IR-3 inhibits binding of 125I-somatomedin-C/insulin-like growth factor I (Sm-C/IGF-I) to the 130-kDa alpha subunit of the type I receptor in human placental membranes, but does not block 125I-insulin-like growth factor II (IGF-II) binding to a similar 130-kDa complex in these membranes. To determine whether the 130-kDa 125I-IGF-II binding complex represents a homologous receptor or whether 125I-IGF-II binds to the type I receptor at a site that is not blocked by alpha IR-3, type I receptors were purified by affinity chromatography on Sepharose linked alpha IR-3. The purified receptors bound both 125I-Sm-C/IGF-I and 125I-IGF-II avidly (KD = 2.0 X 10(-10) M and 3.0 X 10(-10) M, respectively). The maximal inhibition of 125I-Sm-C/IGF-I binding by the antibody, however, was 62% while only 15% of 125I-IGF-II binding was inhibited by alpha IR-3. In the presence of 500 nM alpha IR-3, Sm-C/IGF-I bound with lower affinity (KD = 6.5 X 10(-10) M) than IGF-II (KD = 4.5 X 10(-10) M) and IGF-II was the more potent inhibitor of 125I-Sm-C/IGF-I binding. These findings suggest that the type I receptor contains two different binding sites. The site designated IA has highest affinity for Sm-C/IGF-I and is blocked by alpha IR-3. Site IB has higher affinity for IGF-II than for Sm-C/IGF-I and is not blocked by alpha IR-3.     

The receptor for insulin-like growth factor II mediates an insulin-like response.

Insulin-like growth factor II (IGF-II) shares sequence homology and predicted three-dimensional structure with insulin and IGF-I. IGF-II can bind, therefore, to a limited extent with the receptors for these two other hormones, as well as to a distinct receptor for IGF-II. Previous studies have been unable to attribute a particular response of IGF-II through its own receptor. In the present studies, the IGF-II receptor is shown to mediate the stimulation of glycogen synthesis in human hepatoma cells since: (i) IGF-II is found to be capable of stimulating a response at concentrations in which it would primarily interact with its own receptor; (ii) the response to IGF-II was not blocked by monoclonal antibodies which inhibit the responses of cells through the insulin and IGF-I receptors; and (iii) polyclonal antibodies to the IGF-II receptor were found to mimic the ability of IGF-II to stimulate glycogen synthesis. These results indicate that the IGF-II receptor mediates a particular biological response--stimulation of glycogen synthesis in hepatoma cells. Furthermore, a monovalent Fab fragment of the polyclonal antibody to the IGF-II receptor was also shown to stimulate glycogen synthesis in these cells. These data indicate that clustering of the IGF-II receptor is not required to stimulate a biological response.     

Insulin-like growth factor II binding and action in human fetal fibroblasts

To investigate the role of insulin-like growth factor II (IGF-II) in human prenatal growth, IGF-II binding and biological action were studied in four lines of fetal and three lines of postnatal human fibroblasts. Specific binding of IGF-II was similar in both groups: 15.7% and 14.9% for fetal and postnatal fibroblasts, respectively. This was 5-10 times the amount of IGF-I binding found in these cells. IGF-I and IGF-II caused dose-dependent increases in [14C]aminoisobutyric acid (AIB) uptake. IGF-II was sevenfold less potent than IGF-I in stimulating this metabolic response in both fetal and postnatal fibroblasts. The maximal effect of IGF-II in stimulating [14C]AIB uptake approach that of IGF-I. Similar results were obtained when IGF-I and IGF-II stimulation of [3H]thymidine incorporation was compared in fetal and postnatal fibroblasts. Incubation in the presence of alpha IR-3, a monoclonal antibody to the type I IGF receptor, inhibited the ability of both IGF-I and IGF-II to stimulate [14C]AIB uptake and [3H]thymidine incorporation in fetal and postnatal cells. A monoclonal antibody to the insulin receptor did not affect IGF action. These data indicate that IGF-II is a potent metabolic and mitogenic stimulus for human fetal fibroblasts. However, despite the presence of abundant type II IGF receptors on both fetal and postnatal human fibroblasts, IGF-II stimulation of amino acid transport and DNA synthesis appears to be mediated through the type I rather than through its own type II IGF receptor.     

Monoclonal antibody alpha IR-3 inhibits the ability of insulin-like growth factor II to stimulate a signal from the type I receptor without inhibiting its binding

We have previously shown that the protein encoded by a human insulin-like growth factor I (IGF-I) receptor cDNA binds both IGF-I and II with high affinity. In the present studies, we show that a monoclonal antibody to the IGF-I receptor, alpha IR-3, inhibits the binding of IGF-I but not IGF-II to the expressed receptor in intact cells and after solubilization. Surprisingly, this monoclonal antibody inhibits the ability of both IGF-I and II to stimulate thymidine synthesis in cells with the expressed receptor. Moreover, this antibody inhibits the ability of both IGF-I and II to stimulate the kinase activity of the IGF-I receptor in intact cells. These results indicate that alpha IR-3 binds to the IGF-I receptor in such a way that it does not inhibit the binding of IGF-II but does inhibit the subsequent ability of the receptor to be activated to transmit a signal.     

Insulin-like growth factors, insulin, and epidermal growth factor cause rapid cytoskeletal reorganization in KB cells. Clarification of the roles of type I insulin-like growth factor receptors and insulin receptors

Insulin-like growth factor (IGF) I (greater than or equal to 10(-10)M, insulin-like growth factor II (greater than or equal to 10(-9) M), insulin (greater than or equal to 10(-9) M, and epidermal growth factor (EGF, greater than or equal to 10(-11) M) caused rapid membrane ruffling in KB cells. The morphological change was observed within 1 min after the addition of these growth factors and was accompanied by microfilament reorganization, but not by microtubule reorganization. IGF-I, IGF-II, and insulin induced morphologically very similar or identical membrane ruffles with the order of potency IGF-I greater than IGF-II greater than insulin, whereas EGF-induced membrane ruffles were morphologically different. KB cells possessed EGF receptors, type I IGF receptors, and insulin receptors, but few or no type II IGF receptors. Monoclonal antibody against type I IGF receptors, which completely inhibited the binding of 125I-IGF-I to the cells but did not inhibit the binding of 125I-insulin, caused marked inhibition of IGF-I (10(-8) M)-stimulated membrane ruffling. IGF-II (10(-8) M)-stimulated membrane ruffling was partially inhibited in the presence of this antibody, but insulin (10(-7) M)-stimulated membrane ruffling was only slightly inhibited. In contrast, monoclonal antibody against insulin receptors blocked insulin (10(-7) M) stimulation, but not IGF-I (10(-8) M) stimulation, of membrane ruffling. Thus, this study provides evidence that IGF-I and insulin act mostly through their own (homologous) receptors and that IGF-II acts by cross-reacting with both type I IGF and insulin (heterologous) receptors in causing rapid alterations in cytoskeletal structure.     

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.     

Characterization of the receptor for insulin-like growth factor II in bone cells

We have previously shown that insulin-like growth factor II (IGF-II) is produced by bone cells and that IGF-II stimulates cell proliferation and collagen synthesis in bone cells. We now extend these in vitro findings by demonstrating specific IGF-II binding to bone cells derived from newborn mouse calvaria and embryonic chick calvaria. The kinetics of [125I] IGF-II binding in embryonic chick calvaria cells showed time and temperature dependence. Scatchard analysis of [125I]IGF-II binding to chick calvaria cells showed an apparent Kd of 1.4 x 10(-10) M, with a calculated receptor site concentration of 40,000/cell. The specificity characteristics showed that IGF-II was significantly more potent than IGF-I or insulin in displacing IGF-II tracer. Competition for binding of [125I]IGF-II by unlabeled IGF-II showed a dose-dependent displacement between 0.5 and 25 ng/ml. Fifty percent displacement of [125I]IGF-II binding to chick and mouse calvarial cells was achieved at 1-2 ng/ml; 90% of specific binding of [125I]IGF-II was displaceable in the presence of 125 ng/ml of unlabeled IGF-II. IGF-I showed less than 5% cross reactivity for displacement of [125I]IGF-II binding to chick and mouse bone cells. Type II receptor inhibitory antibodies, R-II-PAB1 inhibited the binding of [125I]IGF-II to mouse bone cells and H-35 rat hepatoma cells (which contain type II but not type I receptors) in a dose-dependent manner. R-II-PAB1 also inhibited basal cell proliferation as well as IGF-II-, IGF-I-, and fibroblast growth factor (FGF)-induced cell proliferation in mouse bone cells. In chick calvaria bone cells and TE89 human osteosarcoma cells, R-II-PABI inhibited neither binding of [125I]IGF-II nor IGF-II-induced cell proliferation. These results together with our findings that IGF-II increased chick bone cell proliferation in the presence of maximal doses of IGF-I suggest that at least part of the mitogenic action of IGF-II is mediated through type II rather than type I receptors in bone cells.     

Type I insulin-like growth factor receptors in human ovarian stroma

Hyperandrogenism observed in a variety of hyperinsulinemic states is thought to be due to an effect of insulin mediated through the type I insulin-like growth factor (IGF) receptors. These receptors, however, have not yet been demonstrated in normal human ovarian cells capable of androgen production. We now report the presence of type I IGF receptors in membrane preparations of human ovarian stroma. The ovarian stromal tissue was obtained from women undergoing indicated oophorectomy. Stromal plasma membranes were prepared. Specific 125I-IGF-I binding was 6.6 +/- 0.2%/100 micrograms protein. The affinity constant estimated by Scatchard analysis was 4.6 X 10(-9) M. 50% inhibition of 125I-IGF-1 binding was observed at 5 ng/ml of IGF-1. Specificity of the 125I-IGF-I-binding sites was confirmed by analogue specificity studies and in experiments utilizing monoclonal antibody to the IGF-I receptor, alpha-IR-3. IGF-II and insulin competed with 125I-IGF-I for the binding sites, but with an affinity significantly lower than that of IGF-I: 50% inhibition was observed at approximately 60 ng/ml of IGF-II or insulin. alpha-IR-3, a monoclonal antibody with high specificity for the type I IGF receptor, effectively inhibited 125I-IGF-I binding in a dose-dependent manner, confirming that the 125I-IGF-I binding was indeed to the type I IGF receptor. We conclude that type I IGF receptors are present in human ovarian stroma. These receptors may mediate effects of insulin on the ovary in hyperinsulinemic insulin-resistant states.     

Differential activation of insulin receptor substrates 1 and 2 by insulin-like growth factor-activated insulin receptors

The insulin-like growth factors (insulin-like growth factor I [IGF-I] and IGF-II) exert important effects on growth, development, and differentiation through the IGF-I receptor (IGF-IR) transmembrane tyrosine kinase. The insulin receptor (IR) is structurally related to the IGF-IR, and at high concentrations, the IGFs can also activate the IR, in spite of their generally low affinity for the latter. Two mechanisms that facilitate cross talk between the IGF ligands and the IR at physiological concentrations have been described. The first of these is the existence of an alternatively spliced IR variant that exhibits high affinity for IGF-II as well as for insulin. A second phenomenon is the ability of hybrid receptors comprised of IGF-IR and IR hemireceptors to bind IGFs, but not insulin. To date, however, direct activation of an IR holoreceptor by IGF-I at physiological levels has not been demonstrated. We have now found that IGF-I can function through both splice variants of the IR, in spite of low affinity, to specifically activate IRS-2 to levels similar to those seen with equivalent concentrations of insulin or IGF-II. The specific activation of IRS-2 by IGF-I through the IR does not result in activation of the extracellular signal-regulated kinase pathway but does induce delayed low-level activation of the phosphatidylinositol 3-kinase pathway and biological effects such as enhanced cell viability and protection from apoptosis. These findings suggest that IGF-I can function directly through the IR and that the observed effects of IGF-I on insulin sensitivity may be the result of direct facilitation of insulin action by IGF-I costimulation of the IR in insulin target tissues.     

Progestins induce down-regulation of insulin-like growth factor-I (IGF-I) receptors in human breast cancer cells: potential autocrine role of IGF-II.

Insulin-like growth factor-I (IGF-I) receptors are present in breast cancer cells and may play a role in breast cancer cell growth. We have studied the effect of progestins on IGF-I receptors in T47D human breast cancer cells. T47D cells constitutively express high levels of progesterone receptors and are a model for studying the regulation of cellular functions by progestins. Treatment of T47D cells with either progesterone or the synthetic progestin promegestone (R5020) decreased IGF-I receptor content by approximately 50%, as measured by Scatchard analysis and receptor biosynthesis studies. In contrast to progestins, estradiol, dexamethasone, and dihydrotestosterone did not influence IGF-I receptor content. No effect of R5020 was seen after 12 h of incubation, a near-maximal effect was seen after 24 h, and greatest effects were seen after 72 h. R5020 decreased IGF-I receptor mRNA abundance, indicating that progestins acted at the level of gene expression. However, progestins also increased the secretion of IGF-II, a ligand for the IGF-I receptor. In contrast to IGF-II, T47D cells did not express IGF-I. The addition of exogenous IGF-II to T47D cells down-regulated both IGF-I receptor binding and IGF-I receptor mRNA abundance. This study indicates, therefore, that progestins regulate IGF-I receptors in breast cancer cells and suggests that this regulation occurs via an autocrine pathway involving enhanced IGF-II secretion.     

Expression and function of insulin-like growth factor receptors on anti-CD3-activated human T lymphocytes.

The pattern of expression of receptors for insulin-like growth factors (IGF-I and IGF-II) and insulin was studied on monocyte-depleted human peripheral blood T cells activated via anti-CD3. Binding assays demonstrated the sequential appearance of receptors for IGF-I, IGF-II, and insulin on activated T cells. IGF-IR appeared early, their expression reaching maximum levels at or before the peak of cellular proliferation. IGF-IIR expression generally followed that of the IGF-IR and was more transient, with increases and decreases in expression paralleling the rise and decline of cellular proliferation. Insulin receptor expression remained low throughout the activation time course. The identity of the IGFR on anti-CD3-activated T cells was confirmed in affinity cross-linking experiments. These data demonstrated a 135,000 Mr peptide that specifically binds radiolabeled IGF-I and corresponds to the alpha subunit of the type I IGF-IR, and a 260,000 Mr peptide that specifically binds radiolabeled IGF-II and corresponds to the type II IGFR. We have additionally found that IGF-I and IGF-II (in nanomolar concentrations) produce as much as a threefold enhancement of T cell proliferation early in the activation process, correlating with the early appearance of IGF-IR. The effect of both IGF appeared to be mediated through the type I receptor, since an antibody (alpha IR3), which blocks binding to the alpha subunit of this receptor, inhibited enhancement by up to 83%. Furthermore, we have found expression of IGF-IR on T cells after activation to be associated with both CD4+ and CD8+ T cell subpopulations. These observations provide a foundation for investigating the contribution of IGF in regulating T cell proliferation, differentiation, and effector function.     

Insulin-like growth factor-mediated phosphorylation and protooncogene induction in Madin-Darby canine kidney cells.

We have characterized the role of tyrosine phosphorylation in protooncogene induction mediated by insulin-like growth factors I and II (IGF-I and IGF-II) in the Madin-Darby canine kidney (MDCK) cell line. These cells possess few, if any, insulin receptors, thus allowing determination of the effects of these growth factors in the absence of any secondary signal mediated through the insulin receptor. We found that IGF-I produced a specific stimulation of tyrosine kinase activity of the 97-kDa beta-subunit of the IGF-I receptor, resulting in autophosphorylation of the receptor and an increase in kinase activity toward a synthetic peptide substrate. This was associated with a gradual decrease in the level of phosphorylation of pp120, the major constitutive phosphotyrosine-containing protein of MDCK cells, and an increase in the ratio of serine to tyrosine phosphorylation. This was followed by a rapid, but transient, induction of c-fos gene expression, with no change in the levels of c-myc mRNA. Cycloheximide treatment resulted in a superinduction of both c-fos and c-myc and prevented any further stimulation by IGF-I. IGF-II did not stimulate tyrosine phosphorylation of its own receptor, but was 25% as active as IGF-I in stimulating phosphorylation of the IGF-I receptor. Despite this, IGF-II did not significantly enhance the expression of either nuclear protooncogene. Insulin also produced a delayed stimulation of IGF-I receptor phosphorylation, but was unable to stimulate biological effects in these cells. Under these conditions neither of the IGFs nor insulin produced any significant stimulation of thymidine incorporation into DNA. These data indicate that the IGF-I receptor can be activated upon binding of IGF-I, and to a lesser extent IGF-II, in intact cells to mediate cellular events. The nature of the signal generated by the IGF-I receptor appears to vary depending on the ligand that occupies it.     

Insulin-like growth factors stimulate chemotaxis in human melanoma cells

Insulin and insulin-like growth factors stimulate motility in the highly metastatic human melanoma cell line, A2058. Insulin-like growth factor-I (IGF-I) is the most potent with a maximal response at a concentration of 10 nM compared to the activities of insulin and insulin-like growth factor-II (IGF-II) which peak at 300-400 nM. Using checkerboard analysis, the responses to IGF-I and insulin are predominantly chemotactic, although insulin had a significant chemokinetic component. Pertussis toxin does not inhibit the response to any of these polypeptides. However, in previous studies, it was shown that the motile response to autocrine motility factor from these same A2058 cells was markedly inhibited by pertussis toxin. 125I-labelled IGF-I binds saturably and specifically to the A2058 cells. Scatchard analysis indicates a high binding affinity (Kd approximately 3 x 10(-10) M) and an estimated 5000 receptors/cell. These studies indicate that in addition to their mitogenic properties, certain growth factors may profoundly enhance metastasis of tumor cells by their ability to induce motility.     

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.