The synthetic RGDS peptide inhibits the binding of fibrinogen lacking intact alpha chain carboxyterminal sequences to human blood platelets

The alpha chain 572-574 Arg-Gly-Asp sequence of fibrinogen appears to play only a minor role in platelet aggregation based on the ability of fibrinogen preparations lacking alpha chain carboxyterminal segments to support platelet aggregation, but synthetic Arg-Gly-Asp-Ser (RGDS) peptides are capable of inhibiting platelet aggregation and fibrinogen binding. The present study thus examined the ability of RGDS peptides to inhibit platelet interactions with a plasmic degradation product of fibrinogen (8D-50) that resembles an intermediate fragment X. Gel- filtered, human blood platelets suspended in 0.01 mol/L HEPES-buffered modified Tyrode's solution, pH 7.5, were stimulated with 20 mumol/L adenosine diphosphate and the binding of 125I-labeled 8D-50 or intact fibrinogen (0.01 to 0.6 mg/mL) assessed in the presence of 0 to 117 mumol/L RGDS. The data revealed that RGDS decreased the apparent affinity of 8D-50 and intact fibrinogen for platelets but did not affect the maximum number of binding sites. RGDS thus appears to be a competitive inhibitor not only of intact fibrinogen (Ki = 12 +/- 2 mumol/L) but also of 8D-50 (Ki = 15 +/- 3 mumol/L) (mean +/- SD, n = 3).     

The C-terminal sequences of the gamma 57.5 chain of human fibrinogen constitute a plasmin sensitive epitope that is exposed in crosslinked fibrin

The gamma chain of human plasma fibrinogen is heterogeneous with three forms differing in length at the C-terminus. Alternative RNA splicing produces two gamma chain mRNAs encoding gamma 50 and gamma 57.5 polypeptides, while fibrinogen gamma 55 is produced by post- translational modification of the gamma 57.5 chain. The composition of purified variant gamma chain fibrinogens, which comprise 10% to 13% total plasma fibrinogen, is predominantly heterodimeric (A alpha, B beta, gamma 50/gamma 55 or A alpha, B beta, gamma 50/gamma 57.5), whereas the composition of purified fibrinogen with the major form of the gamma chain is homodimeric (A alpha, B beta, gamma 50/gamma 50). These gamma chain variations interrupt sequences that mediate platelet- fibrinogen interactions. Therefore, the structure and function of gamma 57.5 C-terminal sequences were investigated using synthetic peptides and a specific monoclonal antibody (MoAb), L2B. The L2B epitope was localized and included gamma 57.5 chain residues 409-412 (Arg-Pro-Glu- His), as determined by differential enzyme-linked immunosorbent assay (ELISA) reactivity with a His-412 deleted synthetic peptide and by Western blot analysis of plasmin cleaved fibrinogen gamma 57.5. L2B had no effect on adenosine diphosphate (ADP)-induced platelet aggregation supported by either fibrinogen gamma 50 or gamma 57.5. High concentrations (0.5 to 1 mmol/L) of synthetic peptide gamma 57.5 405- 416 only weakly inhibited ADP-induced platelet aggregation supported by either fibrinogen gamma 50 or gamma 57.5. Binding of fibrinogen gamma 50 (IC50 = 780 mumol/L) or gamma 57.5 (IC50 = 650 mumol/L) to ADP- stimulated platelets was weakly inhibited, and MoAb L2B failed to inhibit fibrinogen gamma 57.5 binding. Peptide gamma 57.5 408-416 failed to dissociate platelet-bound fibrinogens. These data indicate that the gamma 408-416 sequence of fibrinogen gamma 55 or gamma 57.5 alone is unlikely to bind to the platelet fibrinogen receptor, glycoprotein llb-llla (GPllb-llla), in support of platelet aggregation under physiologic conditions. The sequence recognized by L2B does not resemble known GPllb-llla binding site peptide sequences [Arg-Gly-Asp- Ser (RGDS) or gamma 50 400-411] as determined by competitive inhibition ELISA comparing these binding site synthetic peptides with gamma 57.5 408-416. This epitope is available for binding MoAb L2B in gamma 55 or gamma 57.5 chain dimers and binds to all gamma 57.5 408-416 epitopes equally in non-crosslinked and factor Xllla crosslinked fibrin clots.(ABSTRACT TRUNCATED AT 400 WORDS)     

Expression of complement components and inhibitors on platelet microparticles

Platelet microparticles (PMP) are released from activated platelets and play an important role in hemostasis, thrombosis and inflammation. Since platelets were recently found to demonstrate an intrinsic capacity for activating both classical and alternative pathways of the complement system, the present study extended these observations to PMP. PMP were generated by treating platelets with 10 microM A23187 (37 degrees C, 5 min). PMP were identified by flow cytometry, based on size, Annexin V binding, and expression of P-selectin and GPIIb (CD41). PMP expressed gC1qR/p33, a multifunctional cellular protein that was recently described to activate the classical complement cascade. PMP also expressed the classical pathway and contact system regulator, C1 inhibitor (C1-INH), as well as CD55 and CD59. Despite C1-INH expression, PMP supported classical pathway C4 activation in the presence of purified C1 and C4. Moreover, statistically significant deposition of C3b and C5b-9 was detected on PMP exposed to plasma, concurrently with expression of CD55 and CD59. These data provide the first evidence for the ability of PMP to support in situ complement activation. Complement activation contributes to a variety of vascular and inflammatory disease states including atherosclerosis and ischemia/reperfusion injury.     

Anagrelide metabolite induces thrombocytopenia in mice by inhibiting megakaryocyte maturation without inducing platelet aggregation

OBJECTIVE: The mechanism for anagrelide's potent platelet lowering activity in human subjects is not well defined. Studies related to anagrelide function have been hampered by its lack of activity in nonhuman primates and water insolubility. In an effort to define the mechanism whereby anagrelide exerts its therapeutic effect, we identified a water-soluble metabolite (anagrelide.met). The availability of anagrelide.met allowed, for the first time, parallel in vitro and in vivo animal studies centered on the mechanisms by which anagrelide lowers platelet levels. MATERIALS AND METHODS: The effects of anagrelide.met on proliferation and maturation of mega-karyocytes (MKs) as well as platelet production were studied both in vitro and in vivo. RESULTS: Anagrelide.met is capable of blocking in vitro MK migration by 20% to 40%. At 100 ng/mL, anagrelide.met selectively blocked in vitro MK maturation, resulting in a 50% decrease in the total number of CD41a(+) MKs, corresponding with a 30% decrease in MK ploidy by day 10 and a 60% decrease by day 20. Daily intraperitoneal injections of anagrelide.met 100 microg into BALB/c mice was sufficient to significantly decrease platelet counts within 24 to 48 hours, stabilizing to 40 to 50% of normal levels by day 5. This was associated with a 45% decrease in the number of developing MKs and an increase in thrombopoietin levels. Anagrelide.met did not alter WBC counts, hematocrit, or bleeding time, or lead to any apparent signs of toxicity. Furthermore, unlike the parent anagrelide compound, anagrelide.met did not inhibit ADP-induced platelet aggregation even at high concentrations (10 microg/mL). CONCLUSIONS: We describe a cross-species reactive anagrelide metabolite that selectively inhibits MK maturation and migration, lowering platelet levels without influencing platelet aggregation.     

Von Willebrand factor assay proficiency testing. The North American Specialized Coagulation Laboratory Association experience

We evaluated the accuracy and precision of von Willebrand disease (vWD) testing performed by up to 50 North American Specialty Coagulation Laboratories from 2004 through 2009, using proficiency samples from healthy subjects (n = 7) and patients with type 1 vWD (n = 7) or type 2 vWD (n = 3). We analyzed 2,212 submitted results. Precision was highest for von Willebrand factor (vWF) antigen assays (coefficient of variation, 14%), which were performed predominantly by latex immunoassays, and lowest for ristocetin cofactor assays (coefficient of variation, 28%), which were increasingly replaced by collagen binding and immunofunctional methods during the 6-year evaluation period. Overall interpretation error rates ranged from 3% for normal samples, 28% for type 1 vWD, and 60% for type 2 vWD. Type 2 vWD samples were correctly identified by all laboratories using collagen binding/antigen ratios but by only one third of laboratories using ristocetin cofactor/antigen or immunofunctional/antigen ratios. In 2009, only 27% (12/45) of laboratories performed vWF multimer analysis, with error rates ranging from 7% to 22%.     

The receptor for the globular "heads" of C1q, gC1q-R, binds to fibrinogen/fibrin and impairs its polymerization

The 33-kDa cellular C1q binding protein, designated gC1q-R was previously shown to bind a number of plasma proteins involved in the coagulation and kinin systems. This study demonstrates the interaction between recombinant gC1q-R and fibrinogen. Using enzyme-linked immunosorbent assays, biotinylated gC1q-R was found to bind to microplate-immobilized fibrinogen in a manner which was specific and inhibited by excess soluble fibrinogen or polyclonal antibodies directed against either gC1q-R or fibrinogen. Moreover, gC1q-R inhibited fibrin polymerization in a dose-dependent manner. Reptilase induced fibrin clot formation was completely inhibited by gC1q-R at a 2:1 molar ratio (gC1q-R:fibrinogen), and repolymerization of thrombin induced fibrin monomers was similarly abrogated. At equivalent molar concentrations, gC1q-R appeared to be a more potent inhibitor of fibrin polymerization than fibrinogen, a well-known inhibitor. Moreover, in the presence of both gC1q-R and soluble fibrinogen, the effect of each inhibitor on fibrin polymerization was additive. When plasmin derived fibrinogen degradation products, including the C-terminal D domain (D-100) or the N-terminal E domain, were immobilized on microtiter plates, gC1q-R bound to fibrinogen fragment D-100, but not to fragment E. Further digestion of fibrinogen fragment D-100 by plasmin to fragment D-60 resulted in loss of gC1q-R binding. Thus, gC1q-R binds to the D domain of fibrinogen/fibrin, and the carboxyterminal segment of at least the fibrinogen/fibrin gamma chain appears important for this interaction. These observations may suggest a potential role for gC1q-R in modulating fibrin formation particularly at local sites of immune injury or inflammation.     

Development of proteomic signatures of platelet activation using surface-enhanced laser desorption/ionization technology in a clinical setting

The objective of this study was to develop proteomic profiles that would distinguish between resting and activated platelets in a clinical setting using surface-enhanced laser desorption/ionization (SELDI) time of flight (TOF) technology. A data set of 50 donors was analyzed. Distinct spectral patterns emerged in the low-molecular-weight range (2-10 kDa) for resting platelets and platelets aggregated with adenosine diphosphate (ADP) or thrombin receptor activation peptide SFLLRN (TRAP) and in platelets exposed to shear stress. Platelets from patients treated with ADP receptor antagonists did not show the expected change in proteomic profile following aggregation with ADP. These data provide the first demonstration that proteomic signatures of platelets can be developed using SELDI-TOF in a clinical laboratory setting.     

Effect of epinephrine on fibrinogen receptor exposure by aspirin-treated platelets and platelets from concentrates in response to ADP and thrombin

Synergistic effects between agonists on platelet aggregation have long been appreciated. Recently epinephrine was reported to induce maximal aggregation of aspirin-treated platelets when combined with ADP or thrombin, and to increase fibrinogen binding of non-aspirin treated platelets stimulated with low doses of ADP. The present study extends these observations to correlate fibrinogen binding in response to various combinations of ADP, epinephrine, and thrombin with platelet aggregation and 14C-serotonin release using aspirin-treated platelets as well as platelets from stored concentrates. When fresh platelets were stimulated with epinephrine (5 microM) together with either ADP (10 microM) or thrombin (150 mU/ml), fibrinogen binding increased by 180% compared to binding observed in response to ADP or thrombin alone. This was accompanied by enhanced platelet aggregation, but no increase in 14C-serotonin release. While both ADP and epinephrine potentiated the aggregation and fibrinogen binding of stored platelets in response to high doses of thrombin (150 mU/ml), maximal aggregation was achieved only with thrombin (150 mU/ml) and epinephrine (5 microM) in combination. The data thus suggest that 1) epinephrine induces maximal aggregation of aspirin-treated platelets stimulated with thrombin or ADP by significantly enhancing fibrinogen receptor exposure independently of the cyclooxygenase-mediated release reaction; 2) epinephrine stimulates platelets by a mechanism different from that of thrombin or ADP; and 3) as demonstrated by others, the ability of platelets from stored concentrates to aggregate and to bind fibrinogen in response to ADP can be enhanced by epinephrine, and, in addition, these platelets can aggregate and bind fibrinogen maximally when stimulated with combinations of epinephrine and thrombin.     

gC1q-R/p33: structure-function predictions from the crystal structure

Human gC1q-R (p33) is a multicompartmental cellular protein expressed on various types of cells and tissues. Although originally isolated as a receptor for C1q by virtue of its specificity for the globular heads of that molecule, a large body of evidence has now been accumulated which shows that in addition to C1q, gC1q-R can serve as a receptor for diverse ligands including proteins of the intrinsic coagulation/bradykinin forming cascade, as well as antigens of cellular, bacterial, and viral origin. Furthermore, since gC1q-R has been shown to regulate the functions of protein kinase C (PKC), it is postulated that gC1q-R-induced signaling cascade may involve activation of PKC. These data collectively therefore suggest that gC1q-R plays an important role in blood coagulation, inflammation, and infection. However, although significant progress has been made in unraveling the molecular, biochemical, and structural features of this molecule, and data in support of its biological relevance is accumulating, it is still unclear as to how the molecule is anchored on the membrane since its sequence is devoid of a classical transmembrane domain or a glycosylphosphatidylinositol (GPI) anchor. Furthermore, while recombinant gC1q-R can bind to cell surfaces suggesting that it may bind directly to the phospholipid bilayer, our recent experiments show that, at least in vitro, gC1q-R does not bind to unilamellar vesicle preparations of either phosphatidylcholine (PC) or phosphatidylserine: phosphatidylcholine. This work was therefore undertaken to analyze the three-dimensional structure of gC1q-R in order to identify unique structural features that may serve not only to anchor the protein but also to explain its affinity for such a diversity of plasma as well as microbial and viral ligands.     

Receptor for the globular heads of C1q (gC1q-R, p33, hyaluronan-binding protein) is preferentially expressed by adenocarcinoma cells

Combinatorial Ig libraries with phage display allow in vitro generation of human Ig fragments without the need to maintain hybridomas in ongoing cell culture or to select circulating Ig from human serum. Identifying tumor-associated antigens on the surface of intact tumor cells, as opposed to purified proteins, presents a challenge due to the difficulty of preserving complex 3-D epitopic sites on the cell surface, the variable expression of antigens on different malignant cell types and the stereotactic interference of closely associated proteins on the intact membrane surface limiting accessibility to antigenic sites. A combinatorial Ig library of 10(10) clones was generated from the cDNA of PBMCs derived from patients with breast adenocarcinoma. Following subtractive panning, the library was enriched for Ig (Fab fragment) binding to intact adenocarcinoma cells and the resultant Fabs were screened against a cDNA expression library, itself generated from breast cancer cells. Using this approach, we isolated clones from the cDNA library expressing gC1q-R, a glycoprotein comprising the major structure of C1, the first component of the complement system. gC1q-R is a 33 kDa glycoprotein expressed not only on the cell surface but also intracellularly, with motifs that target it to mitochondria and complete homology with HABP and human HeLa cell protein p32, which is copurified with pre-mRNA SF2. Sequencing of the gene encoding tumor-associated gC1q-R did not reveal any consistent tumor-specific mutations. However, histochemical staining with anti-gC1q-R MAb demonstrated marked differential expression of gC1q-R in thyroid, colon, pancreatic, gastric, esophageal and lung adenocarcinomas compared to their nonmalignant histologic counterparts. In contrast, differential expression was not seen in endometrial, renal and prostate carcinomas. Despite high expression in breast carcinoma, gC1q-R was also expressed in nonmalignant breast tissue. Although the precise relation of gC1q-R to carcinogenesis remains unclear, our finding of tumor overexpression and the known multivalent binding of gC1q-R to not only C1q itself but also a variety of circulating plasma proteins as well as its involvement in cell-to-cell interactions suggest that gC1q-R may have a role in tumor metastases and potentially serve in molecule-specific targeting of malignant cells.