Stimulus-aggregation coupling in platelets activated with PAF-acether

Contrary to most agonists, platelet-activating factor (PAF-acether) induces a more pronounced aggregation at 22 degrees C than at 37 degrees C. A possible explanation was sought in the mechanism that couples the PAF-acether-receptor complex with exposure and occupation of fibrinogen binding sites. Comparison of studies performed at 37 degrees C with those at 22 degrees C revealed: a faster binding of [3H]PAF-acether to its receptors; more accumulation of 32P-labelled phosphatidylinositol 4-monophosphate and a slower but more abundant formation of phosphatidic acid that lasted for 5 min; a 1.4-fold increase in phosphorylation of the Mr 47,000 protein and a 2-fold increase in phosphorylation of the myosin light chain. In contrast, less secretion occurred and less [32P]phosphatidylinositol accumulated at 22 degrees C than at 37 degrees C, and also the increase in cytosolic Ca2+ content and the formation of thromboxane B2 were considerably lower. No differences were found in [32P]phosphatidylinositol 4,5-bisphosphate formation and arachidonate metabolism. Fibrinogen binding studies revealed two types of binding at both temperatures, a high-affinity and a low-affinity binding. There were 6-fold more low-affinity binding sites at 22 degrees C than at 37 degrees C, whereas high-affinity binding did not change. These data suggest that the better aggregation found at 22 degrees C is the result of exposure of an increased number of fibrinogen binding sites. The increased protein phosphorylation and phosphatidic acid accumulation and the faster binding of PAF-acether to its receptors which accompany the better aggregation responses at 22 degrees C suggest that these processes are involved in the regulation of exposure of fibrinogen binding sites.     

Binding kinetics of PAF-acether (1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine) to intact human platelets.

The binding of [3H]PAF-acether (1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine) to intact human gel-filtered platelets was measured at 22 degrees C. Specific binding reached saturation within 15 min at high doses of [3H]PAF-acether (0.5-0.9 nM), whereas about 90 min were required when low doses (0.02-0.5 nM) were used. Above 1 nM, [3H]PAF-acether non-specific binding increased progressively, which together with the demonstration of a 3H-labelled metabolite suggested uptake and metabolism of [3H]PAF-acether. Equilibrium analysis revealed one class of specific receptors with a Ka of 18.86 +/- 4.82 X 10(9) M-1 and 242 +/- 64 binding sites per platelet. Non-equilibrium binding revealed a similar Ka (16.87 X 10(9) M-1). Specific binding became irreversible after prolonged incubation, a process that was enhanced at increasing concentrations of [3H]PAF-acether. Platelets made desensitized to PAF-acether by prior incubation with unlabelled PAF-acether failed to bind a second dose of PAF-acether (3H-labelled), suggesting that desensitization resulted from loss of available binding sites. Under the conditions of the binding studies, PAF-acether induced exposure of the fibrinogen receptor, aggregation (in a stirred suspension) and alterations in (poly)-phosphatidylinositides. These results suggest that PAF-acether initiates platelet responses via receptor-mediated processes.     

Cycle of the vasoactive intestinal peptide and its binding site in a human adenocarcinoma cell line (HT 29)

The disappearance of vasoactive-intestinal-peptide (VIP) binding sites at the cell surface of a cultured target cell, originating from a human colonic adenocarcinoma (HT 29 cell line), was studied, after preexposition of the cell to the peptide, as a function of time, VIP concentration and temperature. Maximum effect (60-80% loss of binding capacity) was obtained after a 5-10 min exposure of the cells at 37 degrees C with a VIP concentration of 100 nM. The t1/2 of maximum disappearance was less than 2 min and the concentration of native VIP giving half-maximum decrease in 125I-VIP binding was 6 nM. The affinity of remaining binding sites for VIP was not affected compared to that of control cells (Kd = 0.3 nM). Disappearance of VIP binding sites was specific since, with the same conditions of preincubation, the specific binding of 125I-labeled epidermal growth factor to HT 29 cells was not modified. The phenomenon was reversible and 90% of binding capacity could be restored in less than 60 min by incubating cells in VIP-free medium. Correlatively we showed, by two independent experimental procedures, that 125I-VIP, initially bound to HT 29 cells, was maximally internalized after 10 min of incubation at 37 degrees C. All the data strongly suggest that: internalization of VIP is receptor-mediated; upon exposure to native VIP, VIP receptors are down-regulated or at least sequestered within HT 29 cells.     

Platelet-activating factor (PAF-acether) induces high- and low-affinity binding of fibrinogen to human platelets via independent mechanisms.

When human platelets are incubated with 500 nM-PAF-acether (platelet-activating factor. 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine) under equilibrium conditions (60 min, 22 degrees C, non-stirred suspensions), two classes of fibrinogen binding sites are exposed: one class with a high affinity [Kd (7.2 +/- 2.1) X 10(-8) M, 2367 +/- 485 sites/platelet, n = 9] and one class with a low affinity [Kd (5.9 +/- 2.4) X 10(-7) M, 26972 +/- 8267 sites/platelet]. Preincubation with inhibitors of cyclo-oxygenase (acetylsalicylic acid, indomethacin) or thromboxane synthetase (UK 38.485) completely abolishes high-affinity binding, leaving low-affinity binding unchanged. In contrast, ADP scavengers (phosphocreatine/creatine kinase or phosphoenol pyruvate/pyruvate kinase) completely prevent low-affinity binding, leaving high-affinity binding unaltered. Initial binding studies (2-10 min incubation) confirm these findings with a major part of the binding being sensitive to ADP scavengers, a minor part sensitive to indomethacin and complete blockade with both inhibitors. Increasing the temperature to 37 degrees C decreases the number of low affinity-binding sites 6-fold without changing high-affinity binding. Aggregation, measured as the rate of single platelet disappearance, then depends on high-affinity binding at 10 nM-fibrinogen or less, whereas at 100 nM-fibrinogen or more low-affinity binding becomes predominant. These findings point at considerable platelet activation during binding experiments. However, arachidonate metabolism [( 3H]arachidonate mobilization and thromboxane synthesis) and secretion [( 14C]serotonin and beta-thromboglobulin) are about 10% or less of the amounts found under optimal conditions (5 units of thrombin/ml 37 degrees C, stirring). We conclude that PAF-acether induces little platelet activation under binding conditions. The amounts of thromboxane A2 and secreted ADP, however, are sufficient for initiating high- and low-affinity fibrinogen binding via mutually independent mechanisms.     

High molecular weight kininogen inhibits fibrinogen binding to cytoadhesins of neutrophils and platelets

Fibrinogen inhibited 125I-high molecular weight kininogen (HMWK) binding and displaced bound 125I-HMWK from neutrophils. Studies were performed to determine whether fibrinogen could bind to human neutrophils and to describe the HMWK-fibrinogen interaction on cellular surfaces. At 4 degrees C, the binding of 125I-fibrinogen to neutrophils reached a plateau by 30 min and did not decrease. At 23 and 37 degrees C, the amount of 125I-fibrinogen bound peaked by 4 min and then decreased over time because of proteolysis of fibrinogen by human neutrophil elastase (HNE). Zn++ (50 microM) was required for binding of 125I-fibrinogen to neutrophils at 4 degrees C and the addition of Ca++ (2 mM) increased the binding twofold. Excess unlabeled fibrinogen or HMWK completely inhibited binding of 125I-fibrinogen. Fibronectin degradation products (FNDP) partially inhibited binding, but prekallikrein and factor XII did not. The binding of 125I-fibrinogen at 4 degrees C was reversible with a 50-fold molar excess of fibrinogen or HMWK. Binding of 125I-fibrinogen, at a concentration range of 5-200 micrograms/ml of added radioligand, was saturable with an apparent Kd of 0.17 microM and 140,000 sites/cell. The binding of 125I-fibrinogen to neutrophils was not inhibited by the peptide RGDS derived from the alpha chain of fibrinogen or by the mAb 10E5 to the platelet glycoprotein IIb/IIIa heterodimer. Fibrinogen binding was inhibited by a gamma-chain peptide CYGHHLGGAKQAGDV and by mAb OKM1 but was not inhibited by OKM10, an mAb to a different domain of the adhesion glycoprotein Mac-1 (complement receptor type 3 [CR3]). HMWK binding to neutrophils was not inhibited by OKM1. These observations were consistent with a further finding that fibrinogen is a noncompetitive inhibitor of 125I-HMWK binding to neutrophils. Fibrinogen binding to ADP-stimulated platelets was increased twofold by Zn++ (50 microM) and was inhibited by HMWK. These studies indicate that fibrinogen specifically binds to the C3R receptor on the neutrophil surface through the carboxy terminal of the gamma-chain and that HMWK interferes with the binding of fibrinogen to integrins on both neutrophils and activated platelets.     

The tetrapeptide analogue of the cell attachment site of fibronectin inhibits platelet aggregation and fibrinogen binding to activated platelets

Fibrinogen binding to receptors on activated platelets is a prerequisite for platelet aggregation. However, the regions of fibrinogen interacting with these receptors have not been completely characterized. Fibronectin also binds to platelet fibrinogen receptors. Moreover, the amino acid sequence Arg-Gly-Asp-Ser, corresponding to the cell attachment site of fibronectin, is located near the carboxyl-terminal region of the alpha-chain of fibrinogen. We have examined the ability of this tetrapeptide to inhibit platelet aggregation and fibrinogen binding to activated platelets. Arg-Gly-Asp-Ser, but not the peptide Arg-Gly-Tyr-Ser-Leu-Gly, inhibited platelet aggregation stimulated by ADP, collagen, and gamma-thrombin without inhibiting platelet shape change or secretion. At a concentration of 60-80 microM, Arg-Gly-Asp-Ser inhibited the aggregation of ADP-stimulated gel-filtered platelets approximately equal to 50%. Arg-Gly-Asp-Ser, but not Arg-Gly-Tyr-Ser-Leu-Gly, also inhibited fibrinogen binding to ADP-stimulated platelets. This inhibition was competitive with a Ki of approximately equal to 25 microM but was incomplete even at higher tetrapeptide concentrations, indicating that Arg-Gly-Asp-Ser is a partial competitive inhibitor of fibrinogen binding. These data suggest that a region near the carboxyl-terminus of the alpha-chain of fibrinogen interacts with the fibrinogen receptor on activated platelets. The data also support the concept that the sequence Arg-Gly-Asp-Ser has been conserved for use in a variety of cellular adhesive processes.     

Lysine binding to activated human platelets and its similarity to fibrinogen binding

Platelet surface glycoproteins IIb-IIIa are considered to function as the binding site for fibrinogen. Fibrinogen binding is essential for platelet aggregation and several amines have been shown to inhibit this binding. The present study compares the binding properties of 125I-fibrinogen and [3H]lysine with platelets activated by the Ca2+ ionophore A23187. Many lines of similarities in the binding properties are apparent; however, several differences were also found. The similarities are listed below and the differences are pointed out in parentheses. Marked enhancement by platelet activation; deficiency of binding by thrombasthenic platelets lacking the glycoproteins IIb-IIIa; saturability (fibrinogen binding approaches saturation at more than 12 microM, within 10 min; lysine binding at more than 100 mM within 1 min); Ca2+-dependence (at 1 mM Ca2+ lysine binding is minute and fibrinogen binding is half-saturated); reversibility; the binding achieved within 10 min is exchangeable; dissociation depends upon time and external ligand concentration; inhibition by the oligoamines His-Lys and Lys4; inhibition by serum from a thrombasthenic patient who developed anti-glycoproteins IIb-IIIa antibodies; specificity; alanine neither binds to activated platelets nor inhibits fibrinogen binding; it thus appears that the lysine which associates with activated platelets is mostly bound onto the surface of the cells rather than being incorporated. Moreover, the major site of lysine binding seems to be the complexed glycoproteins IIb-IIIa.     

Biochemical and biological properties of the binding of human fibrinogen to M protein in group A streptococci.

Fibrinogen is known to bind to group A streptococci and precipitate with extracts containing streptococcal M protein. We have previously shown that the binding of fibrinogen to M-positive streptococci prevents opsonization by complement and protects that organism from phagocytosis in nonimmune blood. In the present study, we used 3H-labeled fibrinogen, a highly purified peptide fragment of type 24 M protein (pep M24), and anti-pep M sera to show that fibrinogen binds to M-positive streptococci with high affinity (dissociation constants, 1 to 5 nM); occupation of the high-affinity binding sites suffices to protect the organism from phagocytosis; proteolytic treatments that remove M protein from streptococcal cells abolish binding; binding is competitively inhibited by anti-pep M sera; pep M24 precipitates fibrinogen; and binding to type 24 cells is inhibited by pep M24. We conclude that M protein is the cell surface structure principally responsible for binding fibrinogen on the surface of M-positive streptococci and that this binding contributes to the known antiopsonic property of M proteins.     

Fibrinogen binding to human platelet plasma membranes. Identification of two steps requiring divalent cations

Fibrinogen binding to platelet plasma membranes, which is a prerequisite for platelet aggregation, was determined by incubating 125I-labeled fibrinogen with isolated membranes and measuring the amount of radioactivity sedimenting with the membranes through 15% sucrose. Fibrinogen binding was optimal at 10(-3) M Ca2+. Scatchard analyses of the fibrinogen binding showed that the membrane capacity for fibrinogen was 1.6 X 10(-12) mol/mg of membrane protein, with a dissociation constant (Kd) = 1.2 X 10(-8) M. When Ca2+ levels were manipulated by the addition of varying amounts of EGTA at a fixed Mg2+ concentration of 3 X 10(-3) M, specific binding of fibrinogen to platelet membranes occurred only at Ca2+ concentrations greater than or equal to 10(-6) M. Membranes isolated from platelets of an individual with Glanzmann's thrombasthenia bound only 12% as much fibrinogen as control platelets. The data in the present study suggest that there are two divalent cation binding sites that must be occupied for fibrinogen to bind: one site is specific for calcium and is saturated at 10(-6) M Ca2+; the other site is less specific and is saturated at a 10(-3) M concentration of either Ca2+ or Mg2+. Fibrinogen binding to intact platelets and, consequently, platelet aggregation only required 10(-3) M extracellular divalent cation and was not specific for Ca2+. These data indicate that the cytoplasm is a potential source for the requirement of 10(-6) M Ca2+, and that changes in the intracellular concentration of Ca2+ may cause the expression of fibrinogen receptors during ADP-induced platelet activation.     

Lysine binding to activated human platelets and its similarity to fibrinogen binding

Platelet surface glycoproteins IIb-IIIa are considered to function as the binding site for fibrinogen. Fibrinogen binding is essential for platelet aggregation and several amines have been shown to inhibit this binding. The present study compares the binding properties of ¹²⁵I-fibrinogen and [³H]lysine with platelets activated by the Ca²⁺ ionophore A23187. Many lines of similarities in the binding properties are apparent; however, several differences were also found. The similarities are listed below and the differences are pointed out in parentheses. (a) Marked enhancement by platelet activation; (b) deficiency of binding by thrombasthenic platelets lacking the glycoproteins IIb-IIIa; (c) saturability (fibrinogen binding approaches saturation at more than 12 μM, within 10 min; lysine binding at more than 100 mM within 1 min); (d) Ca²⁺-dependence (at 1 mM Ca²⁺ lysine binding is minute and fibrinogen binding is half-saturated); (e) reversibility; the binding achieved within 10 min is exchangeable; dissociation depends upon time and external ligand concentration; (f) inhibition by the oligoamines His-Lys and Lys₄; (g) inhibition by serum from a thrombasthenic patient who developed anti-glycoproteins IIb-IIIa antibodies; (h) specificity; alanine neither binds to activated platelets nor inhibits fibrinogen binding; it thus appears that the lysine which associates with activated platelets is mostly bound onto the surface of the cells rather than being incorporated; Moreover, the major site of lysine binding seems to be the complexed glycoproteins IIb-IIIa.     

Binding of fibrinogen molecules to pig platelets and their membranes

Following addition of ADP, 125I-labelled fibrinogen binds specifically to pig platelets. This binding is completely inhibited by the unlabelled fibrinogen. Quantitative analysis indicates the presence of 12,400-25,000 molecules of fibrinogen which can be bound with an association constant of 5 . 10(8) M-1 to platelets. Fibrinogen receptors were found to be active in the isolated platelet membranes as well. Quantitative analysis of the saturable binding of fibrinogen to the platelet membranes showed that these receptors react with the same affinity with fibrinogen molecules. In contrast to the intact platelets, the platelet membranes can specifically bind fibrinogen in the absence of ADP. We conclude that a specific receptor for fibrinogen is exposed on the surface as a result of cell damage which is the first step of the platelet membrane isolation.     

Evidence that changes in platelet cyclic AMP levels regulate the fibrinogen receptor on human platelets

Fibrinogen binds to human platelets after specific receptor sites are exposed by thrombin, ADP, epinephrine, and other stimuli. Since prostaglandin I2 (PGI2), a potent activator of platelet adenylate cyclase, prevents mobilization of the fibrinogen receptor by aggregating agents, we investigated the relationship between platelet cAMP levels and fibrinogen receptor status in thrombin-stimulated human platelets. A dose-dependent rise in platelet cAMP in response to two adenylate cyclase agonists, PGI2 and forskolin, correlated with progressive inhibition of fibrinogen binding. Moreover, the receptor inhibition produced by either agonist was sustained up to 2 h and was associated with a persistent increase in cAMP levels. The phosphodiesterase inhibitor, 1-methyl-3-isobutylxanthine, in the presence of a subthreshold concentration of PGI2 also raised cAMP and inhibited fibrinogen binding. In contrast, the effects of PGI2 on both cAMP and fibrinogen binding were markedly attenuated by 9-(tetrahydro-2-furyl) adenine, an adenylate cyclase inhibitor. These results indicate that the inhibition of fibrinogen binding by PgI2 is linked to its effect on cAMP levels and suggest that elevation of platelet cAMP levels from any cause prevents exposure of the fibrinogen receptor.     

Expression of primary polymerization sites in the D domain of human fibrinogen depends on intact conformation

Fragments D1 and DD, plasmic degradation products of human fibrinogen and cross-linked fibrin, respectively, originate from the COOH-terminal domain of the parent molecule. Since a specific binding site for fibrin resides in the COOH-terminal region of the gamma chain, the primary structure of the two fragments was compared and their affinity for fibrin monomer measured. Fragments D1 and DD contained the same segments of the three fibrinogen chains, corresponding to the sequences alpha 105-206, beta 134-461, and gamma 63-411. Fragment DD had a double set of the same chain remnants. Fragments D1 and DD inhibited polymerization of fibrin monomer in a dose-dependent manner; 50% inhibition occurred at a molar ratio of fragment to monomer of 1:1 and 0.5:1, respectively. To prevent fibrin monomer polymerization and render it suitable for binding studies in the liquid phase, fibrinogen was decorated with Fab fragments isolated from rabbit antibodies to human fragment D1. Fibrinogen molecules decorated with 6 molecules of this Fab fragment did not clot after incubation with thrombin, and the decorated fibrin monomer could be used to measure binding of fragments D1 and DD in a homogeneous liquid phase. The data analyzed according to the Scatchard equation and a double-reciprocal plot gave a dissociation constant of 12 nM for fragment D1 and 38 nM for fragment DD. There were two binding sites/fibrin monomer molecule for each fragment. After denaturation in 5 M guanidine HCl, the inhibitory function on fibrin polymerization was irreversibly destroyed. Denatured fragments also lost binding affinity for immobilized fibrin monomer. The preservation of the native tertiary structure in both fragments was essential for the expression of polymerization sites in the structural D domain.     

Association of 125I-nerve growth factor with PC12 pheochromocytoma cells. Evidence for internalization via high-affinity receptors only and for long-term regulation by nerve growth factor of both high- and low-affinity receptors

Association of 125I-nerve growth factor (NGF) with PC12 pheochromocytoma cells was studied. Surface-bound and internalized NGF were distinguished by differential release of the former at low pH, high salt. Binding to the surface was rapid; at 0.2 nM (5 ng/ml) 125I-NGF, this was near-maximal within 5 min. Internalization, in contrast, did not start until about 2 min after NGF exposure and, thereafter, proceeded linearly for at least 1/2-1 h. By the latter time, approximately 75% of total bound NGF was within rather than on the surface of the cells. Binding versus concentration experiments indicated two distinct classes of surface binding sites. For both naive cells and cells treated with NGF for at least a week (primed cells), about 7% of the receptors had an apparent binding constant of about 0.3 nM; the remaining sites half-saturated at approximately 4 nM NGF. The number of each type of site was 3--4-fold higher/mg of protein in primed cells. For both naive and primed cultures, internalization appeared to be mediated by a single class of uptake sites which half-saturated at about 0.3 nM. The maximal rate of uptake by primed cells (200 fmol/h/mg protein) was about twice that for naive cells. Light and electron microscopic autoradiography indicated that the density of binding was substantially higher in primed cultures and that this increase took place over a time course of days to weeks. These findings suggest that NGF brings about long-term increases in its own high- and low-affinity surface receptors, but is internalized only via the high-affinity sites.     

Binding and degradation of 125I-labeled insulin by a clonal line of rat pituitary tumor cells

Receptor sites for insulin on GH3 cells were characterized. Uptake of 125I-labeled insulin by the cells was dependent upon time and temperature, with apparent steady-states reached by 120, 20 and 10 min at 4, 23 and 37 degrees C, respectively. The binding sites were sensitive to trypsin, suggesting that the receptors contain protein. Insulin competed with 125I-labeled insulin for binding sites, with half-maximal competition observed at 5 nM insulin. Neither adrenocorticotropic hormone nor growth hormone competed for 125I-labeled insulin binding sites. 125I-labeled insulin binding was reversible, and saturable with respect to hormone concentration. 125I-labeled insulin was degraded at both 4 and 37 degrees C by GH3 cells, but not by medium conditioned by these cells. After a 5 min incubation at 37 degrees C, products of 125I-labeled insulin degradation could be recovered from the cells but were not detected extracellularly. Extending the time of incubation resulted in the recovery of fragments of 125I-labeled insulin from both cells and the medium. Native insulin inhibited most of the degradation of 125I-labeled insulin suggesting that degradation resulted, in part, from a saturable process. At steady-state, degradation products of 125I-labeled insulin, as well as intact hormone, were recovered from GH3 cells. After 30 min incubation at 37 degrees C, 80% of the cell-bound radioactivity was not extractable from GH3, cells with acetic acid.     

Binding of cholecystokinin to high affinity receptors on isolated rat pancreatic acini

The binding of cholecystokinin (CCK) to its receptors on isolated rat pancreatic acini was investigated employing high specific activity, radioiodinated CCK (125I-BH-CCK), prepared by the conjugation of 125I-Bolton-Hunter reagent (125I-BH) to CCK. Binding was specific, time-dependent, reversible, and linearly related to the acinar protein concentration. After incubation for 30 min at 37 degrees C, the 125I-BH-CCK both in the incubation medium and bound to acini remained intact, as judged by gel filtration and trichloroacetic acid precipitation studies. Scatchard analysis was compatible with two classes of binding sites on acini: a very high affinity site (Kd, 64 pM) and a lower affinity site (Kd, 21 nM). 125I-BH-CCK binding to acini was competitively inhibited by CCK and four of its analogues in proportion to their biological potencies but not by unrelated hormones. Stimulation of amylase secretion by CCK and inhibition of 125I-BH-CCK binding by the same analogues carried out under identical conditions revealed a correlation (r = 0.99) between binding potency and amylase secretion. Stimulation of amylase secretion by CCK closely paralleled the occupancy of the high affinity CCK binding sites. It is concluded that the high affinity CCK binding sites most likely are the receptors mediating the stimulation of amylase secretion by CCK.     

Gonadotropin receptor complexes and free receptors in porcine Leydig cell cultures during recovery from hCG stimulation

Free and occupied gonadotropin receptors were studied in vitro in porcine Leydig cells culture maintained in chemically defined medium. Free receptors were evaluated by the binding capacity for 125I-hCG. hCG bound molecules (or hCG receptor complexes) were evaluated using immunocytochemical visualization on fixed cells. Exposure to hCG for 16 hours (.5 to 50 ng/ml) induced the disappearance of free receptors. After removal of the hormone, the return to control levels was observed at 48 and 72 hours. Visualization of hCG bound at the cell surface indicates that, following continuous exposure to gonadotropins for 48 hours, hCG molecules are still present on the cell. Following short-time exposure (1 h) to hCG and 48 hrs washing the number of stained cells is very close to the initial value suggesting that the occupied sites (at 48 hours) represent the initial hormone receptor complexes. These results indicate that, during prolonged incubation, hCG binding is not reversible, that the half-life of some of the complexes at the cell surface is very long and that the receptors recovery is slow and is probably the result of a de novo synthesis.     

The expression of high molecular weight kininogen on human umbilical vein endothelial cells

High molecular weight kininogen (HMWK) functions as a cofactor for activation of plasma serine zymogens and as an inhibitor of tissue cysteine proteases. Cell surfaces to which HMWK binds may provide sites for regulation of these systems. Localization of these HMWK-dependent processes at sites of vascular injury may depend on its binding to specific receptors on endothelial cells. In culture, passaged human umbilical vein endothelial cells (HUVEC) bind anti-HMWK antibody to the cell surface and contain 171 +/- 75 ng of HMWK/10(8) cells. [35S]Methionine-labeled HUVEC in culture synthesize a 120-kDa protein immunoisolated using an anti-kininogen antibody, and a 3500-nucleotide message for human HMWK was detected by Northern blot in RNA extracted from HUVEC. HUVEC also express unoccupied binding sites for HMWK on their surface. 125I-HMWK specifically binds to HUVEC in a reaction requiring Zn2+. 125I-HMWK binding to HUVEC is saturable at 4 degrees C but not at 23 degrees C. 125I-HMWK binds to HUVEC with equal affinity as unlabeled HMWK. Kallikrein, factor XII, fibrinogen, fibronectin, and thrombin do not inhibit 125I-HMWK binding to HUVEC. 125I-HMWK-HUVEC binding remains fully reversible at 60 min following the addition of a 50-fold molar excess HMWK. HUVEC express 9.3 +/- 2.0 X 10(5) (mean +/- S.E.) HMWK binding sites/cell (Kd = 52 +/- 13 nM). Both added and cell-bound 125I-HMWK migrate at 120 kDa on sodium dodecyl sulfate gel electrophoresis, suggesting that the protein remains uncleaved upon binding to the HUVEC surface. These studies indicate that HUVEC synthesize HMWK and the HUVEC surface has a site for its expression. By synthesizing and localizing HMWK to the cell surface, endothelial cells may contribute to the activation of plasma's contact serine zymogens and regulation of tissue cysteine proteases.     

Characterization of gonadotropin-releasing hormone (GnRH) binding sites in the pituitary and testis of the frog, Rana esculenta

Frog, Rana esculenta, pituitary and testis gonadotropin-releasing hormone (GnRH) receptors were characterized by using 125I-chicken IIGnRH (cIIGnRH) as radiolabeled ligand. At 4 C equilibrium binding of 125I-cIIGnRH to pituitary homogenates was achieved after 90 min of incubation; binding of 125I-cIIGnRH to testis membrane fractions reached its maximum at 60 min of incubation. Binding of the radioligand was a function of tissue concentration, with a positive correlation over the range 0.5-2 tissue equivalents per tube. One pituitary and one testis per tube were used as standard experimental condition. Incubation of the pituitary homogenate with increasing concentrations of 125I-cIIGnRH indicated saturable binding at radioligand concentrations of 1 nM and above while for the testis membrane preparation saturation was achieved using 5 nM 125I-cIIGnRH. The binding of 125I-cIIGnRH was found to be reversible after addition of the cold analog and the displacement curves could be resolved into one linear component for both tissues. Scatchard analysis suggested the presence of one class of binding sites for both pituitary and testis (Pituitary: Kd = 1.25 +/- 0.14 nM and Bmax = 8.55 +/- 2.72 fmol/mg protein; testis: Kd = 2.23 +/- 0.89 nM and Bmax = 26.48 +/- 7.39 fmol/mg protein). Buserelin displaced the labeled 125I-cIIGnRH with a lower IC50 as compared with cIIGnRH cold standard, while Arg-vasopressin (AVP) was completely ineffective, confirming the specificity of binding.     

Insulin-like growth factor-binding protein-3 binds fibrinogen and fibrin.

Following tissue injury, a fibrin network formed at the wound site serves as a scaffold supporting the early migration of stromal cells needed for wound healing. Growth factors such as insulin-like growth factor-I (IGF-I) concentrate in wounds to stimulate stromal cell function and proliferation. The ability of IGF-binding proteins (IGFBPs) such as IGFBP-3 to reduce the rate of IGF-I clearance from wounds suggests that IGFBP-3 might bind directly to fibrinogen/fibrin. Studies presented here show that IGFBP-3 does indeed bind to fibrinogen and fibrin immobilized on immunocapture plates, with K(d) values = 0.67 and 0.70 nM, respectively, and competitive binding studies suggest that the IGFBP-3 heparin binding domain may participate in this binding. IGF-I does not compete for IGFBP-3 binding; instead, IGF-I binds immobilized IGFBP-3.fibrinogen and IGFBP-3.fibrin complexes with affinity similar to that of IGF-I for the type I IGF receptor. In the presence of plasminogen, most IGFBP-3 binds directly to fibrinogen, although 35-40% of the IGFBP-3 binds to fibrinogen-bound plasminogen. IGFBP-3 also binds specifically to native fibrin clots, and addition of exogenous IGFBP-3 increases IGF-I binding. These studies suggest that IGF-I can concentrate at wound sites by binding to fibrin-immobilized IGFBP-3, and that the lower IGF affinity of fibrin-bound IGFBP-3 allows IGF-I release to type I IGF receptors of stromal cells migrating into the fibrin clot.