Dynamic and quantitative studies of the binding of fibrinogen (Fg) to its receptor, GPIIb-IIIa, on activated platelets, leading to platelet aggregation, are best studied with fluorescently-labelled Fg by flow cytometry. Due to conflicting reports on the functionality of FITC-labelled Fg, we have developed a reproducible and 'mild' labelling of fibrinogen with FITC-celite at pH 7.4-8.5 for direct and dynamic studies of specific Fg binding to activated platelets evaluated for native platelet-rich plasma, for washed platelets, and for activated, fixed platelets. We have demonstrated the equivalence of FITC-labelled and unlabelled Fg for binding to activated GPIIb-IIIa receptors, and in the rate and extent of mediating platelet aggregation. We found that FITC-Fg labelled at pH > or = 9 had reduced to absent specific binding to activated platelets, whether using soluble FITC or FITC-celite. The FITC-labelled Fg must be diluted 3-fold with unlabelled Fg when evaluating maximal Fg binding to activated platelets in order to prevent autoquenching of the FITC-Fg which leads to underestimation of Fg levels. The dissociation constant (KD) of Fg on stable preparations of activated, fixed platelets, determined with FITC-Fg binding to platelets by flow cytometry, was in the range reported for 125I-labelled Fg, 70-255 nm with Bmax = 10000-25000 Fg per platelet (n = 20). The FITC-Fg was used to monitor Fg binding to activated platelets directly by plasma, as well as to evaluate platelet subpopulations which maximally bind Fg according to the concentration of ADP used as activator. It is expected that this 'mildly' labelled FITC-Fg will stimulate further studies of platelet activation directly in native anticoagulated blood/plasma, for both basic and clinical research.
Platelet aggregation, which occurs within seconds of activation, is generally considered to be mediated by fibrinogen binding to glycoprotein IIb-IIIa which becomes expressed as a fibrinogen receptor (FbR) on the activated platelet surface. This receptor expression has, however, only been measured to date at relatively long activation times (greater than 15 min). We have therefore developed a theoretical and experimental approach for determining FbR expression within seconds of platelet activation using flow cytometry. The fluorescently labeled IgM monoclonal antibody FITC-PAC1, was used to report on the GPIIb-IIIa receptor for Fb (FbR). Human citrated platelet-rich plasma (PRP; diluted 1:10) was incubated with adenosine diphosphate (ADP) or phorbol myristate acetate (PMA) for varying times (tau = 0-10 s, out to 60 min), followed by incubation with fluorescein isothiocyanate (FITC)-PAC1 antibody at saturating concentrations. The time course of FITC-PAC1 binding was then measured for these variously preactivated samples (different tau) from the mean platelet-bound fluorescence (Fl), determined for greater than or equal to 5 s of PAC1 addition by dilution quenching and determination of fluorescence intensity histograms with the FACSTAR or FACSCAN (Becton-Dickinson Canada, Mississauga, Ontario) flow cytometers. Both rapid, initial rate of increase in Fl (nu) (related to PAC1 on-rates) and maximal extent of increase (Flmax) were thus determined for different tau values. These measurements yield the rate of formation of FbR (k1), and both the rate (k2) and efficiency (alpha) of binding of PAC1 to FbR as a function of activator type and time of action. We have found that ADP appears to cause rapid, maximal expression of FbR within 1-3 s (k1 greater than 20 min-1), whereas PMA expresses FbR in a slow, biphasic manner (k1 - 0.01 and 0.2 min-1). However, k2 and alpha for maximal PMA activation are about two and three times greater, respectively, than for maximal ADP-activation. Moreover, k2 decreases with post ADP activation time. These differences are discussed in terms of altered FbR organization and accessibility. This kinetic approach can be widely used to analyze the dynamics and organization of molecules on cell surfaces by flow cytometry, including studies of size-dependent subpopulations (see Part II, Frojmovic, M., and T. Wong. 1991. Biophys. J. 59:828-837).
SummaryThe relationship between platelet size (v), platelet number (N0), platelet volume fraction (φ) and platelet aggregation was evaluated in human platelet subpopulations separated on the basis of volume using counterflow centrifugation. The original platelet population and three size-dependent platelet fractions were concentrated and resuspended in autologous citrated platelet-poor plasma at varying N0. Micro-aggregation (PA) and macro-aggregation (TA) were determined respectively by electronic particle counting and light transmission (turbidometry). At similar N0, large platelets were about two-fold more sensitive and more rapidly recruited into both micro (PA) and macro (TA) aggregates in response to ADP than the small platelets (v were respectively 7.3 ± 0.2 and 4.2 ± 0.2 fl, each 16 ± 4% of the total population). At volume fractions favouring the small platelets, however, the above differences persisted for PA, but not for TA. Similar size-dependent differences were observed for two other receptor-mediated platelet activators, namely a stable thromboxane A2 analogue (U46619) and platelet activating factor (PAF), but not for ristocetin-induced agglutination. Increasing platelet size appears to optimize platelet aggregation due to (i) the simple geometric advantage of large-sized platelets associated with any given N0, seen for both PA und TA, and (ii) intrinsic differences in size-dependent subpopulations which favour more efficient platelet membrane surface changes associated with receptor-mediated micro-aggregation (PA), for which a likely model is proposed.
Dynamics of platelet glycoprotein IIb-IIIa receptor expression and fibrinogen binding. I. Quantal activation of platelet subpopulations varies with adenosine diphosphate concentration
We have previously reported that maximal platelet activation with adenosine diphosphate (100 microM ADP) causes rapid expression of all GPIIb-IIIa receptors for fibrinogen (FgR) (< 1-3 s), measured with FITC-labeled PAC1 by flow cytometry. We have extended these studies to examine the effects of ADP concentration on the graded expression and Fg occupancy of GPIIb-IIIa receptors. Human citrated platelet-rich plasma, diluted 10-fold with Walsh-albumin-Mg+2 (2 mM), was treated with ADP (0.1-100 microM). The rates of GPIIb-IIIa receptor expression or Fg binding were measured in unstirred samples by flow cytometry, using FITC-labeled monoclonal antibodies (mAb) PAC1 and 9F9, respectively, from on-rates, using increasing times between mAb and ADP additions. Fibrinogen receptors were all expressed rapidly at low (1 microM) or high (100 microM) ADP (few seconds), whereas Fg occupancy was 50% of maximal by about 2 min. The maximal extent of GPIIb-IIIa receptor expression and Fg occupancy was determined from maximal binding (Flmax) at 30 min incubation with PAC1 or 9F9. On-rates and maximal extents of binding for either PAC1 or 9F9 probes showed identical [ADP]-response profiles ("KD" approximately 1.4 +/- 0.1 microM). However, Flmax studies showed bimodal histograms consisting of "resting" (Po) and maximally "activated" (P*) platelets for both PAC1 and 9F9 binding, with the fraction of "activated" platelets increasing with ADP concentration. The data best fit a model where platelet subpopulations are "quantally" transformed from Po to P*, expressing all GPIIb-IIIa receptors, rapidly filled by Fg, but "triggered" at critical ADP concentrations. Larger, but not the largest, platelets appear to be the most sensitive subpopulation. The implications for clinical studies are discussed, and the relationship to dynamics of aggregation are described in a companion paper.
Platelet aggregation has previously been shown to occur within 1 s of activation with 100 microM adenosine diphosphate (ADP) for both large (L) and small (S) platelet subpopulations, but L platelets were about twofold more sensitive and more rapidly recruited into microaggregates than were S platelets after correcting for differences in platelet surface area. Because platelet aggregation normally requires fibrinogen binding to glycoprotein IIb-IIIa receptors (FbR) expressed on the activated platelet surface, we wished to compare the kinetics and nature of FbR expression induced by ADP for L versus S platelets, and to measure size-dependent differences in FbR expression for platelets maximally activated with phorbol myristate acetate (PMA). We presented the theory and methodology in Part I (Frojmovic, M., T. Wong, and T. van de Ven. 1991. Biophys. J. 59:815-827) for measuring the rate of FbR expression (k1) and both the rate (k2) and efficiency (alpha) of binding of PAC1 to FbR as a function of activation conditions from the initial on-rate of FITC-PAC1 to FbR (V) and the maximal number of FbR expressed: these are measured, respectively, from the initial rate of increase in platelet-bound fluorescence (v) and the maximal increase in mean fluorescence (Flmax). We extended these analyses to L and S platelets, selected by electronic gating of forward scatter profiles (FSC), with corresponding fluorescence (Fl) histograms retrieved analytically. Platelet size (V) and surface area (SA), determined directly for cells separated with a cell sorter, were highly correlated with FSC, allowing v and Flmax values to be expressed per unit area of membrane for L:S comparisons. Surprisingly, ADP activation appeared to express all FbR within 1-3 s of ADP activation for both L and S platelets, whereas k1 was similar for PMA activation. In addition, L platelets maximally expressed two and three times more FbR per unit area than did S platelets when maximally stimulated, respectively, with ADP or PMA. Whereas k2 was independent of platelet size for a given activator, the efficiency of PAC1 binding (alpha), per unit area of membrane, was two times greater for L than for S platelets, for either ADP or PMA activation. Our data suggest that the FbR structure, its microenvironment, or its surface organization may vary with platelet size or activator type. Major reorganization of FbR and/or its environment appears to occur after approximately 5 min of ADP activation equally for both L and S platelets. A model is presented to account for size-dependent differences in FbR expression with implications for regulation of platelet aggregation.
SummaryThe effect of shear rate and fibrinogen concentration on adenosine diphosphate-induced aggregation of suspensions of washed human platelets in Poiseuille flow at 23°C was studied using a previously described double infusion technique and resistive particle counter size analysis (1). Using suspensions of multiple-centrifuged and -washed cells in Tyrodes-albumin [3 × 105 μl−1; (17)] with [fibrinogen] from 0 to 1.2μM, the, rate and extent of aggregation with 0.7 μM ADP in Tyrodes-albumin were measured over a range of mean transit times from 0.2 to 43 s, and at mean tube shear rates, Ḡ, = 41.9, 335 and 1,335 s−1. As measured by the decrease in singlet concentration, aggregation at 1.2 μM fibrinogen increased with increasing Ḡ up to 1,335 s1, in contrast to that previously reported in citratcd plasma, in which aggregation reached a maximum at Ḡ = 335 s−1. Without added fibrinogen, there was no aggregation at Ḡ = 41.9 s1; at Ḡ = 335 s1, there was significant aggregation but with an initial lag time, aggregation increasing further at Ḡ = 1,335 s−1. Without added fibrinogen, aggregation was abolished at all Ḡ upon incubation with the hexapeptide GRGDSP, but was almost unaffected by addition of an F(ab’)2 fragment of an antibody to human fibrinogen. Aggregation in the absence of added fibrinogen was also observed at 37°C. The activation of the multiple-washed platelets was tested using flow cytometry with the fluorescently labelled monoclonal antibodies FITC-PAC1 and FITC-9F9. It was shown that 57% of single cells in unactivated PRT expressed maximal GPIIb-IIIa fibrinogen receptors (MoAb PAC1) and 54% expressed pre-bound fibrinogen (MoAb 9F9), with further increases on ADP activation. However, incubation with GRGDSP and the F(ab’)2 fragment did not inhibit the prebound fibrinogen. Moreover, relatively unactivated cells (8% expressing receptor, 14% prebound fibrinogen), prepared from acidified cPRP by single centrifugation with 50 nM of the stable prostacyclin derivative, ZK 36 374, and resuspension in Tyrodes-albumin at 5 × 104 μl−1, aggregated with 2 and 5 μM ADP at Ḡ = 335 and 1,335 s−1 in the absence of added fibrinogen. We therefore postulate that a protein such as von Willebrand factor, secreted during platelet isolation or in flow at sufficiently high shear rates, may yield the observed shear-rate dependent aggregation without fibrinogen.
SummaryThe relative sensitivities of adenosine diphosphate (ADP)-induced activation, and of prostaglandin-mediated inhibition, were determined for rates of platelet shape change (SC [Vs]), early platelet recruitment measured by electronic platelet counting (PA [PA3]), and turbidometrically-measured aggregation (TA[Va]). Studies were performed in stirred citrated platelet-richplasma from 9 healthy human donors. The [ADP]1/2, ([ADP]giving half maximal rate) was determined for the sequence of activation steps: unactivated platelets → SC → PA → TA. Distinct ADP sensitivities were obtained from log dose-responsestudies, with a relative dose dependency for rates of change in the order of [ADP]1/2 TA > [ADP]1/2 PA > [ADP]1/2 SC of ~4:3:1.Differential inhibition of the above activation scheme was evalu-ated from log dose-response curves for lloprost (ZK 36374), astable carbacyclin analogue of prostacyclin (PGI2), with greaterpotency than PGI2 for the same platelet receptors. IC50 valuescorresponding to lloprost concentrations causing 50% inhibitionof rates of TA (Va), PA (PA3) and SC (Vs) were found in therelative ratios of 1: ~3: ~5, when measured at a common ADPconcentration for all three parameters, or 1: ~2: ~3 when deter-mined at respective [ADP]1/2 values for each parameter. Thus, about 3-5 times more lloprost is required to respectively inhibitthe rates of shape change (Vs) and early platelet recruitment(PA3), than that needed to inhibit the rate of turbidometrically-measured aggregation (Va).
There is broad agreement that platelet aggregation is generally dependent on fibrinogen (Fg) binding to the glycoprotein (GP) IIb-IIIa receptor expressed on the activated platelet surface. We therefore compared rates and extents of aggregation and of fibrinogen receptor expression and specific Fg binding to activated platelets, as a function of ADP concentration. Human citrated platelet-rich plasma (diluted 10-fold) was stirred with adenosine diphosphate (ADP) for 10 s or 2 min to measure rates and extent of aggregation, respectively, determined from the decrease in the total number of particles. The number of fibrinogen receptors and bound Fg were measured from mean fluorescence values obtained with FITC-labeled IgM monoclonal antibody PAC1 and the IgG monoclonal antibody, 9F9, respectively, using flow cytometry as presented in part I (Frojmovic et al., 1994). Because flow cytometric and aggregation measurements were routinely determined at room temperature and 37 degrees C, respectively, we also compared and found temperature-independent initial rates of aggregation. The fraction of platelets with fluorescence values above one critical threshold value, corresponding to maximally "activated" platelets (P*), increased with increasing activator concentration and correlated linearly with the fraction of platelets recruited into aggregates for ADP (r > 0.9). Aggregation was not rate-limited by fibrinogen receptor expression or by Fg binding. It appears that each platelet expresses its maximal Fg receptors at a critical ADP concentration, i.e., occupancy of ADP receptors. This, in turn, leads to rapid Fg occupancy and capture of such "quantally activated" platelets into aggregates.
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