Enhanced insulin stimulation of sugar transport and DNA synthesis by glucocorticoids in cultured human skin fibroblasts

Glucocorticoids will enhance the growth of cultured human skin fibroblasts in serum-containing medium. In serum-free cultures hydrocortisone (5 X 10(-6) M) will enhance insulin stimulation of sugar transport and DNA synthesis (as measured by thymidine incorporation into trichloroacetic acid-precipitable material). The optimal concentration for the glucocorticoid effect on DNA synthesis was 5 X 10(-8) M for dexamethasone and 5 X 10(-7) M for hydrocortisone. In dexamethasone-treated cells, concentrations of insulin as low as 250 microU/ml (10 ng/ml) were effective in stimulating DNA synthesis. Further, hydrocortisone and dexamethasone (both at 5 X 10(-6) M) exhibited potentiating effects on insulin-stimulated sugar transport. These effects appeared to be mediated via inhibitory actions on the hexose transport system with the preservation of a functional insulin-receptor interaction resulting in insulin stimulation of deoxy-D-glucose transport at physiological insulin concentrations, 250 microU/ml (10 ng/ml). Hydrocortisone also enhanced specific [125I]insulin binding in these cells. The data indicate that the mechanism(s) of glucocorticoid enhancement of two actions of insulin may be different.     

Induction of tyrosine aminotransferase and amino acid transport in rat hepatoma cells by insulin and the insulin-like growth factor,multiplication-stimulating activity: Mediation by insulin and multiplication-stimulating activity receptors

Insulin stimulates a 2-fold increase in the amount of tyrosine aminotransferase and a 5–10-fold increase in the rate of amino acid transport in dexamethasone-treated rat hepatoma cells. In order to determine whether these effects are mediated by insulin receptors or receptors for insulin-like growth factors, we have examined the binding of ¹²⁵I-labeled insulin and ¹²⁵I-labeled multiplication-stimulating activity, a prototype insulin-like growth factor, and compared the biological effects of these polypeptides. Insulin and multiplication-stimulating activity cause an identical increase in transaminase activity and transport velocity; half-maximal biological effects were observed at 35 ng/ml (5.5 nM) insulin and 140 ng/ml multiplication-stimulating activity. The hepatoma cells display typical insulin receptors of appropriate specificity; half-maximal displacement of tracer insulin binding occured at 33 ng/ml unlabeled insulin, but only at 2500 ng/ml unlabeled multiplication-stimulating activity. Specific multiplication-stimulating activity receptors also were demonstrated with which insulin did not interact even at 10 μg/ml. Half-maximal displacement of tracer multiplication-stimulating activity occured at 200 ng/ml unlabeled multiplication-stimulating activity. We conclude that insulin cannot act via the multiplication-stimulating activity receptor and presumably acts via typical insulin receptors. The effects of multiplication-stimulating activity on enzyme induction and amino acid transport are probably mediated primarily via the multiplication-stimulating activity receptor.     

A significant increase of lysophosphatidylinositol 4-phosphate with insulin in isolated rat fat cells

We studied the effects of insulin on the incorporation of 32Pi into phospholipids in rat fat cells. When the cells were treated with insulin, a new radioactive phospholipid was detected on thin layer chromatography. The substance migrated slower than phosphatidylinositol 4,5-bisphosphate and was hardly detectable in the absence of insulin. This effect of insulin was both time- and dose-dependent with half-maximal stimulation at 120 microU/ml. Pretreatment of insulin with anti-insulin antibody or the cells with anti-insulin receptor antibody inhibited the effect of insulin. The product of phosphatidylinositol 4-phosphate hydrolyzed by phospholipase A2 was coincided with the substance on thin layer chromatography. Quinacrine inhibited the formation of the substance in a dose-dependent manner. These results suggested that insulin stimulates the generation of lysophosphatidylinositol 4-phosphate through the insulin-receptor interaction.     

The effect of triiodothyronine on insulin binding and action in rat adipocytes

The effects of a short term (2 hour) incubation of 5 microM triiodothyronine (T3) on 125I-insulin binding and insulin stimulated (14C)-2-deoxy-D-glucose uptake in rat adipocytes was investigated. In the presence of 5 microM T3, (14C)-2-deoxy-D-glucose uptake was significantly decreased by 11 to 24% at insulin concentrations of 5 to 1000 microU/ml. The concentration of insulin eliciting a half maximal response for insulin stimulated (14C)-2-deoxy-D-glucose uptake was 11.5 microU/ml in the control, and 14.3 microU/ml in the T3 treated cells (p less than 0.01). T3 treated adipocytes bound 9 to 22% less 125I-labeled insulin yet the concentration of native insulin necessary to displace 50% of the bound 125I-labeled insulin was the same in the control and T3 treated cells (75 and 70 ng/ml, respectively). These studies indicate that the decreased sensitivity of T3 treated cells to insulin is in accordance with a decreased number of receptors with the same binding characteristics as those of the control cells. The decreased maximal uptake of (14C)-2-deoxy-D-glucose at saturating insulin levels is likely to be independent of receptor number and result from a second, undetermined alteration in the hexose transport system of adipocytes treated with T3.     

Mitogen-potentiating action and binding characteristics of insulin and insulin-like growth factors in Chinese hamster fibroblasts

alpha-Thrombin alone is able to stimulate DNA synthesis reinitiation of G0-arrested Chinese hamster lung fibroblasts (CC139) as well as continued growth of these cells in serum-free medium. Although insulin at high concentrations (1-10 micrograms/ml) is not intrinsically mitogenic for these cells, it potently enhances the growth-promoting action of thrombin. The generation time of CC139 cells in the defined medium, transferrin, alpha-thrombin, insulin, is around 15 h. To determine whether this effect of insulin is mediated via putative receptors for the insulin-like growth factors (IGFs) on these cells, we examined the abilities of two IGFs, Multiplication-Stimulating Activity (MSA) and IGF-I, to potentiate the thrombin-induced reinitiation of DNA synthesis. Both IGFs were found to be as effective as insulin for this biological effect; however, much lower concentrations were required to elicit half-maximal response, 100 ng/ml of MSA and 30 ng/ml of IGF-I. Detailed binding studies using 125I-labelled insulin, MSA, and IGF-I revealed that CC139 cells specifically bind all three polypeptides with IC50 values for the corresponding ligands of 1-2 ng/ml, 80-100 ng/ml, and 30-40 ng/ml, respectively. 125I-MSA binding was insulin-insensitive, whereas insulin did compete with 125I-IGF-I for binding to CC139 cells. These results indicate that CC139 cells possess at least two types of IGF receptors, an insulin-insensitive IGF receptor with high affinity for MSA which apparently mediates its biological effect, and an insulin-sensitive IGF-I receptor. Insulin appears to exert its mitogen-potentiating activity in CC139 fibroblasts by interacting with the IGF-I receptor.     

Reduced mRNA and a nonsense mutation in the insulin-receptor gene produce heritable severe insulin resistance.

Leprechaunism is an autosomal recessive syndrome of severe insulin resistance and is characterized by intrauterine growth restriction, acanthosis nigricans, hirsutism, and loss of glucose homeostasis. Here we report a new female patient of Hispanic and Afro-American descent whose fibroblasts and lymphoblasts had markedly impaired insulin binding (less than 10% of that in controls). Insulin binding to lymphoblasts established from both unrelated parents was partially impaired. Insulin-like growth factor-I (IGF-I) and epidermal growth factor (EGF) binding to the patient's fibroblasts were within the normal range. Insulin stimulation of receptor autophosphorylation and kinase activity was markedly reduced in the patient's fibroblasts. The patient's fibroblasts had both a reduced number of immunoreactive insulin receptor (6% of those in controls) and concomitantly reduced amounts of insulin-receptor mRNA, suggesting that both mutations inherited by the patient reduced insulin-receptor mRNA. Sequencing of the insulin-receptor gene and cDNA indicated that the patient was heterozygous for a paternally derived mutation at bp 1333, converting Arg372 to a STOP codon. This nonsense mutation was observed in the insulin-receptor gene, but not in cDNA, indicating reduced amounts of mRNA for the allele containing this mutation. The coding sequence of the maternally inherited insulin-receptor allele was normal. Both the marked reduction in insulin-receptor mRNA in the compound heterozygous fibroblasts of the proband and the partially reduced insulin binding in maternal cells suggest that the maternally derived mutation is located in an insulin-receptor gene sequence that controls cellular mRNA content.     

Characterization of two high-density lipoprotein binding sites on porcine hepatocyte plasma membranes: contribution of scavenger receptor class B type I (SR-BI) to the low-affinity component

Two HDL(3) high- and low-affinity binding sites are present on the human hepatoma cell line (HepG(2)). Recently, we have suggested that the high-affinity binding sites might modulate the endocytosis of HDL through the low-affinity binding sites [Guendouzi, K. (1998) Biochemistry 37, 14974-14980], highlighting the physiological importance of this family of HDL high-affinity binding sites. The present data demonstrate the presence of HDL(3) high-affinity (K(d) = 0.37 microg/mL, B(max) = 260 ng/mg of protein) and low-affinity (K(d) = 86.2 microg/mL, B(max) = 14 300 ng/mg of protein) binding sites on purified porcine hepatocyte plasma membranes. By contrast, free apoA-I was strictly specific to the high-affinity sites (K(d) = 0.2 microg/mL and B(max) = 72 ng/mg of protein). Competition experiments between (125)I-labeled HDL(3) and either LDL, oxidized LDL, or anti-SR-BI IgG as competitors show that SR-BI is mostly responsible (70% displacement) for the binding of HDL(3) to the low-affinity binding sites. By contrast, the same competition experiments using (125)I-labeled free apoA-I clearly excluded SR-BI as the high-affinity binding receptor. We conclude that the binding of HDL onto hepatocyte plasma membranes involves: (1) two low-affinity binding receptors, one being SR-BI; (2) one family of high-affinity binding sites unrelated to SR-BI.     

Insulin receptors and bioresponses in a human liver cell line (Hep G-2)

A newly developed human hepatoma cell line, designated Hep G-2, expresses high-affinity insulin receptors meeting all the expected criteria for classic insulin receptors. 125I-insulin binding is time-dependent and temperature-dependent and unlabeled insulin competes for the labeled hormone with a half-maximal displacement of 1-3 ng/ml. This indicates a Kd of about 10(-10) M. Since Scatchard analysis of the binding data results in a curvilinear plot and unlabeled insulin accelerates the dissociation of bound hormone, these receptors exhibit the negative cooperative interactions characteristic of insulin receptors in many other cell and tissue types. Proinsulin and des(Ala, Asp)-insulin compete for 125I-insulin binding with 4% and 2%, respectively, of the potency of insulin. Anti-(insulin receptor) antibody competes fully for insulin binding. The two insulin-like growth factors, multiplication-stimulating activity and IGF-I are 2% as potent as insulin against the Hep G-2 insulin receptor. Furthermore, Hep G-2 cells respond to insulin in several bioassays. Glucose uptake, glycogen synthase, uridine incorporation into RNA and acetate incorporation into lipid are all stimulated to varying degrees by physiological concentrations of insulin. In addition, these cells 'down-regulate' their insulin receptor, internalize 125I-insulin and degrade insulin in a manner similar to freshly isolated rodent hepatocytes. This is the first available human liver cell line in permanent culture in which both insulin receptors and biological responses have been carefully examined.     

Insulin-responsive cultured foetal-rat hepatocytes. Their preparation and characterization.

An improved non-perfusion method for the preparation of cultured foetal-rat hepatocytes is described. Digestion of the liver with collagenase and deoxyribonuclease I gave yields of 40 X 10(6) hepatocytes/g of liver. The plating efficiency of hepatocytes in medium with 10 microM-cortisol was 50%. Cell morphology and metabolism were maintained through 3 days of monolayer culture, with minimal contamination by haematopoietic cells or fibroblasts. The cultured cells bound and degraded 125I-insulin in a time- and dose-dependent manner. The estimated ED50 for competitive binding at 37 degrees C was 1.1 nM. Curvilinear Scatchard plots were observed, with estimates of 16 500 high-affinity sites (Kd = 813 pM) and 53 000 low-affinity sites (Kd = 23 nM) per cell. The cultured cells demonstrated a glycogenic response to insulin, with an estimated ED50 of 120 pM. The degree of glycogenic response to insulin varied with time in culture: 500% above basal on day 1, 200% on day 2, and only 150% on day 3. Cultured foetal cells also exhibited a time-dependent uptake of 2-aminoisobutyric acid, which, in contrast with previous reports with adult cells, was not stimulated by the presence of 10 nM-insulin. Cultured foetal hepatocytes may provide an interesting model with which to study the relationship between insulin-receptor binding and insulin action.     

Identification of Glucagon Receptors in Rat Retina

In this study, we characterize the glucagon receptors on rat retinal particulate preparations. The specific binding of 125I-glucagon was saturable and reversible. Apparent equilibrium conditions were established within 30-45 min. Analysis of binding data is compatible with the existence of two classes of binding sites: a high-affinity class with a KD of 7 +/- 0.8 nM and a Bmax of 2.3 +/- 0.2 pmol/mg of protein and a low-affinity class with a KD of 84.4 +/- 2.5 nM and a Bmax of 16.5 +/- 2.3 pmol/mg of protein. The 125I-glucagon binding to retinal particulate preparation was not inhibited by 1 microM concentrations of insulin, atrial natriuretic factor, angiotensin II, somatostatin, and vasoactive intestinal peptide. However, synthetic human pancreatic growth hormone-releasing factor, hGRF-44, inhibited binding, although the concentration required for half-maximal displacement was 10-fold higher than that for native glucagon. Glucagon binding was GTP sensitive. Inclusion of 0.1 mM GTP in the binding assay produced an increase in the concentration of unlabeled glucagon required for half-maximal displacement of 125I-glucagon, from 23 to 220 nM. Glucagon stimulated adenylate cyclase formation in retinal particulate preparations. The concentration of glucagon required for half-maximal activation of retinal adenylate cyclase was 16.2 nM. These results suggest that glucagon may play a role as a neurosignal transmitter in rat retina.     

Structural analysis of normal and mutant insulin receptors in fibroblasts cultured from families with leprechaunism.

Leprechaunism is an inherited disorder characterized by insulin resistance and intrauterine growth restriction. In this study we analyze insulin binding and subunit structure of the insulin receptor in dermal fibroblasts cultured from three unrelated families whose probands (Ark-1, Atl, and Minn) were affected by leprechaunism. Cells cultured from all three probands had markedly reduced insulin binding at equilibrium. Fibroblasts cultured from the parents of Ark-1 and Atl had partial and differing degrees of impairment in insulin binding. The structure of the alpha subunit of insulin receptors was analyzed by cross-linking 125I-insulin to plasma membranes. A major band of 350 kilodaltons (kD) (corresponding to the heterotetrameric insulin receptor alpha 2 beta 2) was observed in control and leprechaun fibroblasts. The relative amount of radioactivity cross-linked to plasma membranes reflected the genetic variations seen in insulin binding to intact cells. In reducing gels, 125I-insulin was cross-linked equally to a 250-kD (alpha-alpha dimer) and a 125-kD (alpha monomer) protein in cells from controls, the parents of Ark-1 and Atl, and probands Atl and Minn. By contrast, cells from the Ark-1 proband had diminished cross-linking of alpha-alpha dimers. The ratio of dimer to monomer in cells from controls was 0.93 +/- 0.06, and that in cells from Ark-1 was 0.31 +/- 0.19 (P less than .01). Beta-subunit structure and function was analyzed by studying insulin-enhanced autophosphorylation. Although maximal stimulation of beta-subunit phosphorylation was reduced to 30% in proband Ark-1 fibroblasts, this reduction was quantitatively related to reduced insulin binding. These results indicate that mutations causing severe insulin resistance and defective insulin binding are transmitted with autosomal recessive patterns of inheritance and that heterogeneity exists for these mutations. The mutation in pedigree Ark-1 most likely produces conformational changes in alpha-subunit interaction.     

Adipocyte insulin receptor. Generation of a cryptic domain of the alpha-subunit during internalization of hormone-receptor complexes.

The dynamics of the internalization of photoaffinity-labelled insulin-receptor complexes was investigated in isolated rat adipocytes by using tryptic proteolysis to probe both the orientation and cellular location of the labelled complexes. In cells that were labelled at 16 degrees C and not prewarmed, 150 micrograms of trypsin/ml rapidly degraded the labelled 125 kDa insulin-receptor subunit into a major proteolytic fragment of 70 kDa and minor amounts of 90- and 50-kDa fragments. With milder trypsin treatment conditions (100 micrograms of trypsin/ml, 15 s at 37 degrees C), the 90 kDa peptide (different from the 90 kDa beta-subunit of the insulin receptor) appeared as a major intermediate proteolytic product, but this species was rapidly and completely converted into the 70- and 50-kDa fragments with continued exposure to trypsin, such that it did not accumulate to appreciable amounts in cells that were not prewarmed before trypsin exposure. By contrast, trypsin treatment of cells prewarmed to 37 degrees C for various times showed that: first, a proportion of the labelled 125 kDa receptors was internalized (became trypsin-insensitive); secondly, the 90 kDa tryptic peptide was formed in large amounts, with proportionate decreases occurring in the amounts of the 70- and 50-kDa tryptic peptides. The increased accumulation of the 90 kDa tryptic peptide from cells preincubated at 37 degrees C, but not at 16 degrees C, indicated that trypsin cleavage sites within the 90 kDa segment of the insulin-receptor alpha-subunit that were exposed at 16 degrees C were made inaccessible by incubation at 37 degrees C, a finding that is consistent with generation of a cryptic domain of the receptor subunit. The tryptic generation of the 90 kDa peptide at 37 degrees C was rapid, becoming half-maximal in 4.4 +/- 0.6 min and maximal in 15-20 min, preceded the intracellular accumulation of labelled receptors (half-maximal in 12.6 +/- 0.7 min and maximal in 30-40 min), was highly correlated with receptor internalization, and was not observed in cultured IM-9 lymphocytes, a cell line in which photolabelled insulin receptors are primarily lost by shedding into the incubation media. These results show that, in adipocytes incubated at 37 degrees C, rapid masking of a previously (at 16 degrees C) accessible domain of the insulin-receptor alpha-subunit occurs and that this dynamic process happens at an early stage in the internalization of insulin-receptor complexes.     

Characterisation of heterologous and homologous low-density lipoprotein binding to apolipoprotein B,E receptors on porcine adrenal cortex membranes: enhanced binding of trypsin-modified human low-density lipoprotein

The characteristics of the binding of homologous and heterologous (human) LDL to membrane preparations from porcine adrenal cortex have been determined. The membranes displayed a single class of high-affinity, saturable binding site for both 125I-labelled porcine and human LDL, which was dependent on divalent cations, in addition to a low-affinity, non-saturable component(s). Porcine LDL displaced both 125I-labelled porcine and 125I-labelled human LDLs from the high-affinity binding site more effectively than human LDL, reflecting the lower Kd, (13.2 micrograms/ml) for porcine than human (Kd 19.2 micrograms/ml) LDL. These values are comparable to those obtained for half-maximal binding of human and bovine LDLs in a bovine adrenocortical membrane system (Kovanen, P.T., Basu, S.K., Goldstein, J.L. and Brown, M.S. (1979) Endocrinology 104, 610-616). Tryptic modification of porcine LDL (T-LDL) diminished its ability to compete with 125I-labelled native LDL for the high-affinity binding site; in contrast, 125I-labelled porcine T-LDL showed an elevated receptor affinity (Kd 9.7 micrograms/ml) and was more efficiently displaced by its unlabelled counterpart than by native porcine LDL. Tryptic treatment of human LDL similarly increased its binding affinity (Kd 8.3 micrograms/ml), although in this case, the unlabelled T-LDL displaced not only 125I-labelled human T-LDL but also 125I-labelled human LDL from the high-affinity site more effectively than native LDL. We conclude that (i) porcine adrenocortical membranes possess binding sites specific for LDL and resembling the apolipoprotein B,E receptors already demonstrated in murine, bovine and human adrenal cortex; (ii) tryptic modification of porcine LDL may remove or destroy segments of apolipoprotein B100 which contribute to receptor recognition sites on the surface of the particle; (iii) trypsinised porcine LDL may interact with the membrane binding site by a mechanism differing from that by which native LDL binds, and (iv) trypsinisation of human LDL may cleave or remove species-specific segments of the B100 protein at or close to the receptor recognition site(s) on the particle, thus decreasing structural differences between porcine and human LDL, and thereby enhancing its binding affinity for the porcine receptor.     

Dependence on pH of substrate binding to a mutant lactose carrier, lacYun, in Escherichia coli. A model for H+/lactose symport.

The potential role of guanine nucleotide regulatory proteins (G-proteins) in acute insulin regulation of glucose transport was investigated by using bacterial toxins which are known to modify these proteins. Cholera-toxin treatment of isolated rat adipocytes had no effect on either 2-deoxyglucose transport or insulin binding. Pertussis-toxin treatment resulted in an inhibition of both insulin binding and glucose transport. Insulin binding was decreased in pertussis-toxin-treated cells by up to 40%, owing to a lowering of the affinity of the receptor for hormone, with no change in hormone internalization. The dose-response curve for insulin stimulation of glucose transport was strongly shifted to the right by pertussis-toxin treatment [EC50 (half-maximally effective insulin concn.) = 0.31 +/- 0.04 ng/ml in control cells; 2.29 +/- 1.0 in treated cells), whereas cholera toxin had only a small effect (EC50 = 0.47 +/- 0.02 ng/ml). Correcting for the change in hormone binding, pertussis toxin was found to decrease the coupling efficiency of occupied receptors (50% of maximal insulin effect with 928 molecules bound/cell in control and 3418 in treated cells). Pertussis-toxin inhibition of insulin sensitivity was slow in onset, requiring 2-3 h for completion. Under conditions where pertussis-toxin inhibition of insulin sensitivity was maximal, a 41,000 Da protein similar to the alpha subunit of Gi (the inhibitory G-protein) was found to be fully ribosylated. These results are consistent with the concept that pertussis-toxin-sensitive G-protein(s) can modify the insulin-receptor/glucose-transport coupling system.     

Purification of an insulin-related factor secreted by a teratoma-derived mesodermal cell line

Insulin-related factor (IRF), a polypeptide secreted by the mouse teratoma-derived cell line (1246-3A), was purified 3210-fold to homogeneity from 1246-3A conditioned medium using a rapid three-step procedure including cation-exchange chromatography, immunoaffinity chromatography using a monoclonal antibody against porcine insulin coupled to an agarose gel support, and reverse phase high performance liquid chromatography. 10 micrograms of IRF was purified from 6 liters of 1246-3A conditioned medium. Pure IRF appeared as a single band with the same mobility as insulin by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. IRF stimulates cell proliferation of insulin-dependent cell line 1246 and competes with 125I-insulin for binding to 1246 cells; half-maximal growth stimulation and binding competition were achieved at an IRF concentration of 6.5 ng/ml (1.3 nM) and 25 ng/ml (4 nM), respectively, comparable with those for bovine insulin. The biochemical, biological, and immunological characteristics of IRF, as well as its amino acid composition, strongly suggest that it is closely related to pancreatic insulin in structure and function.     

Evidence for separate receptors for insulin and insulin-like growth factor-I in choroid plexus of rat brain by quantitative autoradiography

Binding of insulin and insulin-like growth factor-I (IGF-I) to the choroid plexus was quantitatively characterized using autoradiography and computer densitometry. Slide-mounted brain slices were incubated in 0.1 nM [125I]-insulin or [125I]-[Thr59]IGF-I. To determine specificity of the binding sites, the labeled peptides were mixed with unlabeled analogues. Autoradiography was done with LKB Ultrofilm and analyzed with a computer image analysis system and program for densitometry. Results showed that binding was time and temperature dependent and reversible. Binding of the iodinated insulin and IGF-I was inhibited by unlabeled peptides in a dose-dependent manner. The rank order of potency of these peptides in competing for the choroid plexus iodoinsulin binding sites was: chicken insulin greater than porcine insulin greater than desoctapeptide insulin greater than IGF-I. IGF-I was more potent than porcine insulin in competing for the choroid plexus iodolGF-I binding sites. Somatostatin was ineffective. Non-linear regression analysis revealed the presence of high- (Kd 1.3 +/- 0.2 nM) and low-affinity (Kd 36 +/- 1.4 nM) binding sites for insulin and a single high-affinity binding site (Kd 3.1 +/- 0.3 nM) for IGF-I in the choroid plexus. There were approximately 50 times more binding sites (Bmax) for IGF-I than for insulin high-affinity sites, whereas the number of low-affinity sites for insulin was about equal to the number of IGF-I high-affinity sites. The results of these binding studies with iodinated insulin and [Thr59]IGF-I support the conclusion that the rat choroid plexus has separate high-affinity receptors for insulin and IGF-I, and that the IGF-I receptors outnumber the insulin receptors.     

High-affinity binding sites for human Glu-plasminogen unveiled by limited plasmic degradation of human fibrin

The binding of human 125I-Glu-plasminogen to human plasmin-degraded fibrin was studied. Treatment of preformed and polymerized fibrin with 0.01 IU plasmin/ml resulted in an increased binding of 125I-Glu-plasminogen depending upon the length of time of preincubation of fibrin with plasmin. Binding reached a plateau of 30% of total added radioactivity after 60 min. At this time, less than 10% of fibrin had been digested. Polyacrylamide/urea/acetic acid gel electrophoresis revealed that the radioiodinated plasminogen bound to plasmin-degraded fibrin was of the Glu form. Computerized non-linear regression analysis of the binding experiments revealed that limited plasmic degradation of fibrin progressively generates high-affinity binding sites (Kd approximately equal to 0.3 microM) for Glu-plasminogen. At the time of maximal Glu-plasminogen binding approximately 5 high-affinity binding sites per 100 molecules of fibrin had been generated. The low-affinity type of binding sites were also identified. These observations describe a new mechanism which exquisitely modulates the plasmic breakdown of fibrin by a continuous renewal of high-affinity binding sites for Glu-plasminogen on the surface of the fibrin gel during the fibrinolytic process.     

Binding, internalization, and degradation of basic fibroblast growth factor in human microvascular endothelial cells

The binding, internalization, and degradation of basic fibroblast growth factor (bFGF) in human omental microvascular endothelial cells (HOME cells) were investigated. Binding studies of bFGF in human endothelial cells have not yet been reported. Basic FGF bound to HOME cells (KD of 42.0 +/- 3.8 pM and 70,526 +/- 6121 binding sites/cell for the high-affinity sites, KD of 0.933 +/- 0.27 nM and 630,252 +/- 172,459 sites/cell for low-affinity binding sites). The number of low-affinity binding sites was found to be variable. Washing the cells with 2 M phosphate-buffered saline removed completely 125I-bFGF bound to low-affinity binding sites but decreased also the high-affinity binding. The majority of the surface-bound 125I-bFGF was removed by washing the cells with acetic acid buffer at pH 3. At 37 degrees C, 30% of the cell-associated 125I-bFGF became resistant to the acidic wash after 90 min, suggesting that this fraction of bound 125I-bFGF was internalized. At this temperature, degradation of the internalized ligand was followed after 1 h by the appearance of three major bands of 15,000, 10,000, and 8,000 Da and was inhibited by chloroquine. These results demonstrated two classes of binding sites for bFGF in HOME cells; the number of high-affinity binding sites being larger than the number reported for bovine capillary endothelial cells. The intracellular processing of bFGF in HOME cells seems to be different from that of heparin binding growth factor-1 in murine lung capillary endothelial cells and of eye-derived growth factor-1 in Chinese hamster fibroblasts.     

Dual pathways for the intracellular processing of insulin. Relationship between retroendocytosis of intact hormone and the recycling of insulin receptors

Adipocytes process insulin through either of two pathways: a retroendocytotic pathway that culminates in the release of intact insulin, and a degradative pathway that terminates in the intracellular catabolism and release of degraded ligand. Mechanistically, these pathways were found to differ in several ways. First, temporal differences were found in the rate at which intact and degraded products were extruded. After 125I-insulin was preloaded into the cell interior, intact ligand was completely released during the first 10 min (t 1/2 = 2 min), whereas degraded insulin was released at a much slower rate over 1 h (t 1/2 greater than 8 min). Secondly, it was found that chloroquine profoundly inhibited the insulin degradative pathway, resulting in the intracellular accumulation of intact ligand and a reduction in the release of degraded products. In contrast, however, chloroquine was without effect on the retroendocytotic processing of insulin. Based on the known actions of chloroquine, it appears that retroendocytosis of insulin does not involve vesicular acidification or dissociation of the insulin-receptor complex and that insulin is most likely carried to the cell exterior in the same vesicles (either receptor-bound or free) as those mediating recycling receptors. Interestingly, accumulation of undergraded insulin within chloroquine-treated cells did not result in the release of additional intact ligand, suggesting that once insulin enters the degradative compartment it is committed to catabolism and cannot exit the cell through the retroendocytotic pathway. A third difference was revealed by the finding that extracellular unlabeled insulin (100 ng/ml) markedly accelerated the rate at which preloaded 125I-insulin was released from adipocytes (t 1/2 of 3 min versus 7 min in controls cells). Analysis of the composition of the released products revealed that extracellular insulin rapidly augmented (over 10 min) in a dose-dependent manner (5-200 ng/ml) the amount of insulin released intact (from 25 to 38% of preloaded counts; insulin ED50 = 10 ng/ml). Although extracellular insulin had no effect on the early extrusion of degraded insulin, the release of catabolized products was reduced at later times. The interpretation of these results is that the rate or amount of incoming insulin-receptor complexes can effect a sorting process (prior to bifurcation) such that a proportion of insulin is shunted from the slower degradative pathway to the more rapid retroendocytotic pathway.(ABSTRACT TRUNCATED AT 400 WORDS)     

Quantitative studies of the rate of insulin internalization in isolated rat hepatocytes.

We studied internalization of 125I-labelled insulin in isolated rat hepatocytes. Using the acidification technique, we were able to dissociate the ligand from its cell-surface receptors, and thus to separate internalized from surface-bound insulin. Because during the first 5 min of incubation of 125I-labelled insulin with freshly isolated hepatocytes there is no loss of internalized label, the ratio of the amount of internalized ligand to the amount of cell-surface-bound ligand may serve as an index of insulin internalization. Within the first 10 min of insulin's interaction with hepatocytes, the plot of the above ratio as a function of time yields a straight line. The slope of this line is referred to as the endocytic rate constant (Ke) for insulin and denotes the probability with which the insulin-receptor complex is internalized in 1 min. At the insulin concentration of 0.295 ng/ml, the Ke is 0.049 min-1. It is independent of insulin concentration until the latter exceeds 1 ng/ml. At the insulin concentration of 3.2 ng/ml, the Ke accelerates to 0.131 min-1. With the Ke being the probability of insulin-receptor-complex internalization, 4.9% of occupied insulin receptors will be internalized in 1 min at an insulin concentration of 0.295 ng/ml, and 13.1% of occupied insulin receptors will be internalized in 1 min at 3.2 ng/ml. When the insulin concentration decreases from 3.2 to 0.3 ng/ml, the Ke decreases accordingly. The half-time of occupied receptor internalization is 15.4 min at the lower insulin concentration and 5.3 min at the higher insulin concentration.