Procalcitonin''s amino-terminal cleavage peptide is a bone-cell mitogen.

The parafollicular-cell (C-cell) hormone calcitonin (CT) can preserve or even augment skeletal mass by inhibiting osteoclast-mediated bone resorption. The possibility of an additional anabolic skeletal influence has also been raised: C cells might, via CT or other secretory products, affect osteoblast-mediated bone formation. The 57-residue amino-terminal procalcitonin cleavage peptide, N-proCT, has recently been identified in human and rat C cells, where it is made and secreted in equimolar amounts with CT. The coelaboration of N-proCT and CT and N-proCT's sequence conservation during evolution prompted us to investigate the potential skeletal bioactivity of N-proCT. We found that synthetic human N-proCT, at nanomolar concentrations, stimulated proliferation of normal and neoplastic human osteoblasts. At maximally effective doses, human N-proCT caused more than a 100% increase above the control rate of DNA synthesis, an effect comparable to the maximal growth effect of insulin, a potent mitogen for osteoblasts. Human N-proCT exerted a similar maximal mitogenic effect in chicken osteoblast cultures but at 1000-fold greater concentrations than in human bone-cell cultures. The bone-cell action of N-proCT was potentiated with insulin with a greater than 200% increase in DNA synthesis at high insulin concentrations. In sharp contrast to these findings for N-proCT, the other bioactive C-cell peptides, CT and somatostatin, showed no mitogenic effects in human or chicken osteoblast cultures. Our results indicate that the action of N-proCT on cultured bone cells is separate from and potentiated by insulin, a known growth factor. Unlike insulin and related growth factors such as insulin-like growth factor I, N-proCT is not mitogenic in skin fibroblast cultures. We propose that N-proCT is a C-cell hormone that promotes bone formation via stimulatory actions on osteoblasts and preosteoblasts.     

IGF-1 or insulin, and the TSH cyclic AMP cascade separately control dog and human thyroid cell growth and DNA synthesis, and complement each other in inducing mitogenesis.

The regular doubling of cell mass, and therefore of cell protein content, is required for repetitive cell divisions. Preliminary observations have shown that in dog thyrocytes insulin induces protein accumulation but not DNA synthesis, while TSH does not increase protein accumulation but triggers DNA synthesis in the presence of insulin. We show here that EGF and phorbol myristate ester complement insulin action in the same way. HGF is the only factor activating both protein accumulation and DNA synthesis. The effects of insulin on protein accumulation and in permitting the TSH effect are reproduced by IGF-1 and are mediated, at least in part by the IGF-1 receptor. The concentration effect curves are similar for both effects. Similar results are obtained in human thyrocytes. They reflect true cell growth, as shown by increases in RNA content and cell size. Carbachol and fetal calf serum also stimulate protein synthesis and accumulation without triggering DNA synthesis, but they are not permissive for the mitogenic effects of TSH or of the general adenylate cyclase activator, forskolin. Moreover the mitogenic effect of TSH greatly decreased in cells deprived of insulin for 2 days although these cells remain hypertrophic. Hypertrophy may therefore be necessary for cell division, but it is not sufficient to permit it. Three different mechanisms can therefore be distinguished in the mitogenic action of TSH: (1) the increase of cell mass (hypertrophy) induced by insulin or IGF-1; (2) the permissive effect of insulin or IGF-1 on the mitogenic effect of TSH which may involve both the increase of cell mass and the induction of specific proteins such as cyclin D3 and (3) the mitogenic effect of the TSH cyclic AMP cascade proper.     

Glucose Intolerance and Insulin Resistance Accompany Immobilization

ABSTRACT. Physical activity is known to increase glucose tolerance and insulin sensitivity. To examine the influence of physical inactivity on insulin sensitivity, we measured oral glucose tolerance (OGTT) and insulin response to glucose in 18 patients immobilized to bed for six weeks after acute spine fracture. The results were compared to those of nine chronically immobilized spinal cord injury patients and to eight healthy mobile controls. During the first week after trauma both glucose and insulin responses in the OGTT were two- to three-fold above normal (p<0.01). The index of insulin resistance (glucose area × insulin area) was seven-fold greater than in healthy controls (p<0.001). After three weeks' immobilization insulin resistance had declined by 30–35% (p<0.05) being then at the level observed in chronically immobilized subjects. After remobilization the insulin resistance was further decreased but remained still 2.3 times higher than in controls. Thus, trauma causes a manifold increase in insulin resistance, which is reduced but not normalized during the subsequent immobilization and remobilization.     

Replacement of insulin receptor tyrosine residues 1162 and 1163 does not alter the mitogenic effect of the hormone

Chinese hamster ovary transfectants that express insulin receptors in which tyrosine residues 1162 and 1163 were replaced by phenylalanine exhibit a total inhibition of the insulin-mediated tyrosine kinase activity toward exogenous substrates [histone, casein, and poly(Glu/Tyr)]; this latter activity is associated with total inhibition of the hypersensitivity reported for insulin in promoting 2-deoxyglucose uptake. We now present evidence that the twin tyrosines also control the insulin-mediated stimulation of glycogen synthesis. Surprisingly, this type of Chinese hamster ovary transfectant is as hypersensitive to insulin for its mitogenic effect as are Chinese hamster ovary cells expressing many intact insulin receptors. Such data suggest that (i) the insulin mitogenic effect routes through a different pathway than insulin uses to activate the transport and metabolism of glucose and (ii) the mitogenic effect of insulin is not controlled by the twin tyrosines. At the molecular level, the solubilized mutated receptor has no insulin-dependent tyrosine kinase activity, whereas this receptor displays measurable insulin-stimulated phosphorylation of its beta subunit in 32P-labeled cells. We therefore propose that the autocatalytic phosphorylating activity of the receptor reports a cryptic tyrosine kinase activity that cannot be visualized by the use of classical exogenous substrates.     

Effect of intensive insulin therapy on insulin sensitivity in the critically ill

CONTEXT: Hyperglycemia and hyperinsulinemia are common in intensive care unit (ICU) patients and relate to illness severity. Intensive insulin therapy (IIT) to maintain normoglycemia reduces morbidity and mortality. Blood glucose control explains this benefit because a high insulin dose is associated with adverse outcome. Mitogenic insulin effects could theoretically explain this link. OBJECTIVE: To investigate further the association between insulin dose and adverse outcome, we studied the effect of IIT on circulating insulin levels, markers of insulin sensitivity, and the metabolic and mitogenic insulin signaling molecules in key tissues. DESIGN: This is a subanalysis of a large randomized, controlled study. SETTING: The study was performed in a university hospital surgical ICU. PATIENTS: A total of 339 critically ill patients, treated in ICU for at least a week, were included in this subanalysis. INTERVENTION: Strict normoglycemia with IIT compared with conventional insulin therapy was performed. RESULTS: Severalfold higher insulin doses than with conventional insulin therapy were required to maintain normoglycemia with IIT. However, serum insulin levels were only transiently higher with IIT, despite the much lower blood glucose levels. IIT normalized the elevated serum C-peptide levels and increased circulating adiponectin levels. The metabolic insulin signal was increased by IIT in muscle, but not in liver. The mitogenic insulin signal in either tissue was not affected by IIT. CONCLUSIONS: Normoglycemia can be maintained in ICU patients without a sustained further elevation of insulinemia. Together with the increased adiponectin levels, this finding suggests that IIT may improve insulin sensitivity. Skeletal muscle, but not liver, revealed an increased metabolic insulin signal. The therapy did not impose mitogenic risk in these tissues.     

Insulin-like growth factor I (IGF-I)-binding protein complex is a better mitogen than free IGF-I

The insulin-like growth factors (IGF)-I and -II are bound to specific carrier proteins in the circulation. For investigation of their physiological role, the acid-stable subunit of the major binding protein (SmBP) was isolated from human plasma Cohn fraction IV. Its effect on the mitogenic activity of IGF-I was studied with baby hamster kidney fibroblasts (BHK-21) and human skin fibroblasts. While free IGF-I had no effect on thymidine incorporation into DNA with BHK-21 cells and only a moderate effect with human fibroblasts under standard conditions, DNA synthesis was significantly enhanced with both cell lines if IGF-I was complexed with SmBP before the experiment. The enhancement was optimal at an approximately equimolar ratio of both peptides. In contrast to experiments in which large concentrations of IGF-I were added at the beginning, repeated addition of small quantities of free IGF-I at hourly intervals clearly stimulated DNA synthesis in BHK-21 cells. Binding studies with radiolabeled SmBP revealed no evidence for direct interaction with either cell line. It is concluded that SmBP acts as a reservoir, releasing continuously low amounts of IGF-I and thereby creating a steady state situation of receptor occupancy, which appears to be a better mitogenic stimulus than temporary large concentrations of IGF-I.     

IGF-1 receptor signalling determines the mitogenic potency of insulin analogues in human smooth muscle cells and fibroblasts

Aims/hypothesis Mitogenic activity of insulin and insulin analogues and the involvement of the IGF-1 receptor (IGF-1R) is still a controversial issue. We compared levels of the proteins IGF-1R and insulin receptor (InsR) in fibroblasts and smooth muscle cells from healthy donors and assessed the downstream signalling and growth-promoting activity of insulin and insulin analogues. Methods DNA synthesis was monitored in human fibroblasts and coronary artery smooth muscle cells. Using small interfering RNAs, the levels of IGF-1 and InsR were reduced by 95 and 75%, respectively. Results Enhanced mitogenic potency of insulin and insulin analogues was observed which correlated with increased levels of IGF-1R and/or IRS-1. A reduction in the IGF-1R level significantly blunted stimulation of Akt phosphorylation by IGF-1, AspB10 and glargine by 72, 58 and 40%, respectively. Akt phosphorylation in response to insulin remained unaffected. Silencing of InsR did not significantly alter Akt phosphorylation in response to IGF-1, AspB10 and glargine. IGF-1R knockdown reduced the stimulation of DNA synthesis in response to IGF-1 and glargine to a level identical to that produced by insulin. Conclusions/interpretation These data show a prominent role of IGF-1R/Akt signalling in mediating the mitogenic effects of insulin analogues. Regular insulin stimulates DNA synthesis by exclusively activating InsR, whereas insulin analogues mainly signal through IGF-1R. It is suggested that inter-individual differences in the levels of proteins of the IGF-1R system may function as a critical determinant of the mitogenic potency of insulin analogues.     

Augmented growth response to IGF-1 via increased IRS-1 in Chinese hamster ovary cells expressing kinase-negative insulin receptors

Aims/hypothesis. Although both increased cell growth and impaired insulin signalling have been associated with diabetes, this association has not been investigated. Insulin-like growth factor-1 (IGF-1), a structural and functional analog of insulin, may play a part in the aberrant insulin receptor-mediated signalling observed in diabetes. Methods. To investigate the consequence of this impaired signalling on cell proliferation and transformation, we transfected Chinese hamster ovary cells with cDNA encoding a kinase-defective insulin receptor. Results. In these mutant cells, the mitogenic and metabolic effects of insulin were reduced compared with control cells (p < 0.05) and this was due to a dominant negative effect. In contrast, these mutant cells showed a higher mitogenic response to IGF-1 than control cells, although IGF-1 receptor expression was similar in both cell lines. There was no statistically significant difference in mitogenic response, however, to platelet-derived growth factor, basic fibroblast growth factor and heparin-binding epidermal growth factor-like growth factor. Variables of the IGF-1 signalling pathway, including tyrosine phosphorylation of insulin receptor substrate-1 and activation of mitogen-activated protein kinase and phosphatidyl inositol 3 kinase, were also augmented in mutant cells. Insulin receptor substrate-1 message and protein abundance were higher in mutant than in control cells. Moreover, mutant cells had a higher mitogenic potential in low-serum-containing medium, suggesting that these cells have a transformed phenotype. Conclusion/interpretation. These findings suggest that an impaired insulin signalling may upregulate insulin receptor substrate-1 and that this, in turn, leads to increased IGF-1 signalling, a phenomenon that is possibly associated with increased cell growth in diabetes. [Diabetologia (1999) 42: 763–772] Received: 27 October 1998 and in final revised form: 30 December 1998     

Insulin and messenger ribonucleic acid expression of insulin receptor isoforms in ovarian follicles from nonhirsute ovulatory women and polycystic ovary syndrome patients

Insulin action is mediated by two insulin receptor (IR) isoforms, differing in mitogenic and metabolic function. IR isoform expression might occur in human granulosa cells and could be altered in polycystic ovary syndrome (PCOS) from hyperinsulinemia. To determine the relationship between granulosa cell IR isoform expression and follicular fluid insulin concentration in individual follicles, 18 normal women and seven PCOS patients receiving gonadotropins for in vitro fertilization were studied. Glucose tolerance testing was performed before pituitary desensitization, and fasting serum insulin was measured at oocyte retrieval. Granulosa cells and fluid aspirated from the first follicle were used to determine IR isoform mRNA expression and insulin concentration, respectively. IR isoform A mRNA expression was greater than that of IR isoform B expression in normal mural granulosa and cumulus cells, without a cell type effect. Intrafollicular insulin levels increased with adiposity and serum insulin levels at oocyte-retrieval but did not predict IR mRNA expression. Total IR mRNA expression, but not intrafollicular insulin levels, was elevated in PCOS patients, whereas intrafollicular insulin levels were increased in women with impaired glucose tolerance. Granulosa cell IR heterogeneity, together with adiposity-dependent intrafollicular insulin availability, introduces a novel mechanism by which insulin may affect granulosa cell function within the follicle.     

Delayed disappearance of human compared to porcine insulin in a patient with the insulin autoimmune syndrome

The insulin autoimmune syndrome is characterised by high titres of autoantibody to insulin, a high circulating concentration of total insulin and later, reactive hypoglycaemia. We have studied a patient with this syndrome whose insulin autoantibody bound exclusively human insulin. This permitted us to investigate the disappearance of bound (human) and unbound (porcine) insulin in the same patient, using i.v. injections of 0.075 U/g of each insulin on separate days. The peak plasma free insulin concentration following porcine insulin was four times greater than that following the same dose of human insulin. The plasma disappearance half-time of porcine insulin following injection was 11 min compared with 32 min following human insulin injection, and the area beneath the disappearance curve of free insulin during the 120 min of sampling was greater for porcine insulin by a factor of 3.15. The nadir in plasma glucose occurred at 45 min following porcine insulin and at 90 min following human insulin injection. The restoration of basal glucose concentration was correspondingly slower following human insulin, but the absolute fall in glucose achieved was no different. There was no evidence of insulin resistance. Insulin autoantibodies can seriously disturb the kinetics and effect of free insulin.     

Insulin-like effects of vanadate in isolated rat adipocytes

Vanadate has been shown to have a number of insulin-like effects in various cells, including isolated rat adipocytes. In the present study we compared the activities of vanadate and insulin in isolated fat cells using a number of different assays of insulin-like activity. Both insulin and vanadate stimulated [2-3H]glucose incorporation into fat cell lipid in a dose-dependent manner, but the maximal effect of vanadate was markedly greater than that of insulin. At 10(-2) M vanadate the effect was 3-4 times as great as the maximal effect of insulin. This effect was dependent on specific glucose transport. Combinations of insulin and vanadate were not more effective than vanadate alone. Vanadate also produced antilipolysis with an effect somewhat greater than that of insulin. Using [U-14C]glucose both vanadate and insulin stimulated 14CO2 production and [14C]glucose incorporation into lipid, and again the effect of vanadate was greater than that of insulin. Vanadate had a greater effect on 14CO2 production than on [14C]glucose incorporation into lipid. When [1-14C]glucose was used vanadate again had a significantly greater effect on 14CO2 production than did insulin, but when [6-14C]glucose was used the effects of vanadate and insulin were equal. These results demonstrate that vanadate has insulin-like effects in isolated fat cells, but it selectively stimulates certain pathways to a greater extent than does insulin. The greater effect of vanadate than insulin appears to be primarily on the pentose phosphate shunt, suggesting that this agent may be useful for examination of this intracellular pathway in fat cells.     

Mitogenic action of insulin: friend, foe or ‘frenemy’?

Either endogenous or exogenous hyperinsulinaemia in the setting of insulin resistance promotes phosphorylation and activation of farnesyltransferase, a ubiquitous enzyme that farnesylates Ras proteins. Increased availability of farnesylated Ras at the plasma membrane enhances mitogenic responsiveness of cells to various growth factors, thus contributing to progression of cancer and atherosclerosis. This effect is specific to insulin, but is not related to the type of insulin used. The stimulatory effect of hyperinsulinaemia on farnesyltransferase in the presence of insulin resistance represents one potential mechanism responsible for mitogenicity and atherogenicity of insulin.     

Inhibition of biological activity of multiplication-stimulating activity by binding to its carrier protein.

Multiplication-stimulating activity (MSA) produced by Buffalo rat liver cells (BRL-3A) in culture is related to the somatomedin family of growth regulatory polypeptides. MSA will stimulate glucose transport and DNA synthesis in normal chicken embryo fibroblasts (CEF) at concentrations of 10-200 ng/ml. MSA found in BRL-3A-conditioned medium, like the somatomedins in serum, does not exist as the free hormone but is bound to a specific high molecular weight carrier protein. In this report we demonstrate that purified MSA carrier protein (MCP) inhibits the biological activity of MSA on CEF as measured by the stimulation of glucose transport and DNA synthesis. In addition, purified MCP competitively inhibits the binding of 125I-labeled MSA to these cells. In control experiments in which insulin was used as the mitogenic agent, MCP had no effect on these biological responses. These results indicate that the inhibitory effect of MCP is the result of specific interaction with MSA and support the hypothesis that cells may be unresponsive to somatomedins bound to their serum carrier proteins.     

The calcium dependence of insulin degradation by rat skeletal muscle

The effect of calcium on insulin degradation by intact or homogenized skeletal muscle, by skeletal muscle cytosol, and by partially purified skeletal muscle insulin-degrading protease activity was examined. After a 15-min lag phase, intact soleus muscles degraded [125I]insulin to trichloroacetic acid-soluble products in a time-dependent fashion. Degradation was accelerated by the addition of calcium (greater than or equal to 1 mM), such that maximal stimulation (2-fold) was obtained with 10 or 25 mM calcium. Calcium stimulated insulin degradation by skeletal muscle homogenate and by cytosol in a nearly identical manner. Furthermore, after inactivation of the purified skeletal muscle, insulin-degrading protease by dialysis against EDTA, this enzyme was reactivated fully (greater than 80%) by a 100 microM concentration of free Ca2+. These observations identify a previously unrecognized but important influence of calcium on cellular insulin handling and provide further evidence for a major role of the calcium-activated enzyme, insulin protease, in cellular insulin degradation.     

Sensitive colorimetric bioassays for insulin-like growth factor (IGF) stimulation of cell proliferation and glucose consumption: use in studies of IGF analogs.

We have established two in vitro bioassay systems for quantification of insulin-like growth factor (IGF) bioactivity. The first assay was used to quantitate mitogenic activity and the second was used to quantitate metabolic activity. Both assays use BALB/c 3T3 fibroblasts grown under serum-free conditions; detection of bioactivity in assays was performed colorimetrically and did not require the use of radioisotopes. The mitogenic bioassay, which requires 48 h for detection, quantitates changes in cell number and provides an index for determining the mitogenic activity of growth factors. Changes in cell number were measured by the enzymatic reduction of exogenously added MTT [3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyl-2H tetrazolium bromide] to MTT-formazan by mitochondrial enzymes, which was directly correlated to cell number. The metabolic bioassay, which requires 22 h for detection, measures glucose consumption by detecting changes from the initial glucose concentration of conditioned medium after addition of various growth factors. When appropriate standards were established for these bioassays, they demonstrated a high level of reproducibility (coefficients of variation were 0.085-0.096 for the mitogenic bioassay and 0.120-0.191 for the metabolic bioassay). Both assays can be performed in 96-well microtiter plates, without the use of radioisotopes, or the limitations of conventional glucose, amino acid, or thymidine incorporation studies. In initial experiments for assay specificity, epidermal growth factor had no measurable effect in either assay. However, IGF-I, IGF-II, and insulin demonstrated effects on both metabolism and mitogenesis. In the case of the mitogenic bioassay, the maximum mitogenic activation by these growth factors was approximately 180% of control, and these factors demonstrated parallel sigmoidal dose-response curves, ranging from 0.02-2 ng/ml for IGF-I and from 2-200 ng/ml for both IGF-II and insulin. In the metabolic bioassay, in contrast to the mitogenic bioassay, insulin showed a dose-response curve whose shape was different from those of IGF-I and IGF-II. IGF-I and IGF-II stimulated glucose consumption in dose-dependent ranges of 0.02-3 ng/ml and 0.4-40 ng/ml, respectively. However, the dose-response effect of insulin was wider, ranging from 0.1-2000 ng/ml. When these assays were used to measure the bioactivity of IGF analogs, a des(1-3)-IGF-I, which has decreased affinity for IGF binding proteins, demonstrated activity equivalent to IGF-I, a [Leu27]IGF-II, which has markedly diminished affinity for the type 1 IGF receptor, exhibited approximately 0.07% of the potency of IGF-I and 1% of the potency of IGF-II.     

A transgene coding for a human insulin analog has a mitogenic effect on murine embryonic beta cells.

We have investigated the mitogenic effect of three mutant forms of human insulin on insulin-producing beta cells of the developing pancreas. We examined transgenic embryonic and adult mice expressing (i) human [AspB10]-proinsulin/insulin ([AspB10]ProIN/IN), produced by replacement of histidine by aspartic acid at position 10 of the B chain and characterized by an increased affinity for the insulin receptor; (ii) human [LeuA3]insulin, produced by the substitution of leucine for valine in position 3 of the A chain, which exhibits decreased receptor binding affinity; and (iii) human [LeuA3, AspB10]insulin "double" mutation. During development, beta cells of AspB10 embryos were twice as abundant and had a 3 times higher rate of proliferation compared with beta cells of littermate controls. The mitogenic effect of [AspB10]ProIN/IN was specific for embryonic beta cells because the rate of proliferation of beta cells of adults and of glucagon (alpha) cells and adrenal chromaffin cells of embryos was similar in AspB10 mice and controls. In contrast to AspB10 embryos, the number of beta cells in the LeuA3 and "double" mutant lines was similar to the number in controls. These findings indicate that the [AspB10]ProIN/IN analog increased the rate of fetal beta-cell proliferation. The mechanism or mechanisms that mediate this mitogenic effect remain to be determined.     

Effect of dietary protein on serum insulin and glucagon levels in hyper- and normocholesterolemic men

This study was designed to test the effect of dietary protein on blood levels of insulin and glucagon. Twelve normocholesterolemic (less than 200 mg/dl) and 11 hypercholesterolemic greater than 240 mg/dl) healthy male subjects, 31-62 years of age, were randomly given 3 liquid test meals 1 week apart. Meals were identical except for the protein source (soybean, casein, or protein free). Blood was drawn at fasting, and 0.5 and 2 h postprandially. Insulin and glucagon levels were measured by radioimmunoassay. Hypercholesterolemic subjects had a higher (P less than 0.05) insulin/glucagon ratio (1.5) than normocholesterolemic subjects (0.7) 2 h post-prandially when fed the casein test meal. There was no significant difference following the soybean test meal. This implies that the post-prandial insulin/glucagon ratio was affected by the amino acid composition of the diet. There was a consistently higher insulin response to all test meals among hyper- versus normocholesterolemic subjects. These results are consistent with our hypothesis that the hypocholesterolemic effects of soybean protein and the hypercholesterolemic effects of casein were mediated by altered levels of insulin and glucagon.     

Somatomedin-C stimulates glycogen synthesis in fetal rat hepatocytes

The effects of somatomedin-C/insulin-like growth factor I (Sm-C) on glycogen metabolism in cultured hepatocytes from 20-day-old rat fetuses have been examined and compared with the effects of insulin. Sm-C (25-375 ng/ml; 3.25-50 nM) stimulated dose-dependent increases in [14C]glucose incorporation into glycogen (14.4-72.9%; P less than 0.001) and total cell glycogen content (10.6-34.3%; P less than 0.01). Maximal stimulation of glycogen synthesis by Sm-C occurred at 2-4 h of incubation. Insulin (10 nM to 10 microM) also stimulated [14C]glucose incorporation but its potency was only 1/20th that of Sm-C. The time course of stimulation of glucose incorporation by insulin was identical to that of Sm-C, the dose-response curves of the two hormones were parallel, and the maximal effects of insulin were not enhanced by simultaneous exposure of cells to Sm-C. These findings suggest that Sm-C and insulin stimulate glycogenesis in fetal liver through similar or identical mechanisms. Since the potency of Sm-C was 20 times greater than that of insulin, the glycogenic action of insulin in fetal liver may be mediated through binding to a hepatic receptor which also binds Sm-C. In addition to having mitogenic effects on fetal tissues, Sm-C may have direct anabolic effects on fetal carbohydrate metabolism.     

Production of insulin-like growth factors and their binding proteins by rabbit articular chondrocytes: relationships with cell multiplication

Articular chondrocytes from 2- to 3-month-old rabbits were cultured in serum-free medium supplemented with fibroblast growth factor. The effects were studied of GH, insulin-like growth factors (IGFs), and insulin on the production of IGF-I, IGF-II, and their binding proteins (BPs) and on cell multiplication. In the control culture medium, IGF-I levels were about one fifth those of IGF-II. Western blot analysis of the BPs revealed a predominant 30K form and 24K and 20K forms which appeared inconsistently and in small quantities. Ten to 100 ng/ml human GH had no mitogenic effect, and even had a slightly inhibitory effect. IGF-I at 10 ng/ml stimulated cell multiplication above the control level by 41% and at 50 ng/ml by 74%, whereas the mean increase obtained with IGF-II (10 and 50 ng/ml) was only 19%. At the same doses, insulin had no effect, but at 5 micrograms/ml it stimulated cell multiplication by a mean of 67%. There was a positive correlation between cell number and release into the medium of both IGF-I (r = 0.86) and IGF-II (r = 0.77). Neither IGF-I nor IGF-II production was affected by GH. Insulin (5 micrograms/ml) increased IGF-I production by a factor of 2.6, but increased IGF-II production by a factor of only 1.4. Under the various conditions of culture with different doses of GH and insulin, cell multiplication, relative to the control value was positively correlated to the IGF-I/IGF-II production ratio (r = 0.77). It would, therefore, seem that IGF-I secreted by the chondrocytes may stimulate their own proliferation. When IGFs or insulin were added to the culture medium, changes in the electrophoretic profiles of the BPs included an increase in the 30K form and an increase in or the appearance of the 24K and 20K forms. Ten and 50 ng/ml IGF-I or IGF-II had effects equal to or greater than those induced by 5 micrograms/ml insulin. These results indicate that the syntheses of BPs and IGFs are coordinated and that IGFs may be implicated in the control of the synthesis of their BPs.     

Catalysis of serine and tyrosine autophosphorylation by the human insulin receptor.

The protein kinase activity of human insulin receptors purified from Sf9 insect cells after infection with a recombinant baculovirus was evaluated. The following experimental observations led to the unexpected conclusion that this receptor protein catalyzes both serine and tyrosine autophosphorylation at significant stoichiometries. (i) Phosphorylation of lectin-purified insulin receptors with [gamma-32P]ATP resulted in rapid receptor tyrosine phosphorylation (7 mol of P per high-affinity binding site) and the delayed onset of insulin-stimulated receptor serine phosphorylation (about 7% of total phosphorylation). The tyrosine kinase inhibitor (hydroxy-2-naphthalenylmethyl)phosphonic acid (HNMPA), which has no effect on protein kinase C or cyclic AMP-dependent protein kinase activities, inhibited both the receptor serine and tyrosine phosphorylation. (ii) Phosphorylation of a synthetic peptide substrate composed of insulin receptor residues 1290-1319 on serines-1305/1306 by partially purified insulin receptors was also inhibited by HNMPA. (iii) Insulin receptors sequentially affinity-purified on immobilized wheat germ agglutinin and immobilized insulin showed no apparent contaminant proteins on silver-stained SDS/polyacrylamide gels yet catalyzed autophosphorylation on receptor serine and tyrosine residues when incubated with [gamma-32P]ATP. These results suggest that the catalytic site of the insulin receptor tyrosine kinase also recognizes receptor serine residues as substrates for the phosphotransfer reaction. Furthermore, insulin-stimulated receptor serine phosphorylation in intact cells may occur in part by an autophosphorylation mechanism subsequent to tyrosine phosphorylation of the insulin receptor.