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Department of Pharmacology, College of Medicine, University of Illinois at Chicago, Chicago, IL 60612

Address correspondence to Xiaoping Du, Department of Pharmacology, College of Medicine, University of Illinois at Chicago, 835 South Wolcott Ave., Chicago, IL 60612. Tel.: (312) 355-0237. Fax: (312) 996-1225. E-mail: xdu{at}uic.edu

	Abstract

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Bidirectional signaling of integrin _IIbß₃ requires the ß₃ cytoplasmic domain. To determine the sequence in the ß₃ cytoplasmic domain that is critical to integrin signaling, cell lines were established that coexpress the platelet receptor for von Willebrand factor (vWF), glycoprotein Ib-IX, integrin _IIb, and mutants of ß₃ with truncations at sites COOH terminal to T⁷⁴¹, Y⁷⁴⁷, F⁷⁵⁴, and Y⁷⁵⁹. Truncation at Y⁷⁵⁹ did not affect integrin activation, as indicated by vWF-induced fibrinogen binding, but affected cell spreading and stable adhesion. Thus, the COOH-terminal RGT sequence of ß₃ is important for outside-in signaling but not inside-out signaling. In contrast, truncation at F⁷⁵⁴, Y⁷⁴⁷, or T⁷⁴¹ completely abolished integrin activation. A point mutation replacing Y⁷⁵⁹ with alanine also abolished integrin activation. Thus, the T⁷⁵⁵NITY⁷⁵⁹ sequence of ß₃, containing an NXXY motif, is critical to inside-out signaling, whereas the intact COOH terminus is important for outside-in signaling. In addition, we found that the calcium-dependent protease calpain preferentially cleaves at Y⁷⁵⁹ in a population of ß₃ during platelet aggregation and adhesion, suggesting that calpain may selectively regulate integrin outside-in signaling.

Key Words: integrin; platelet; calpain; signaling; platelet activation

^* Abbreviation used in this paper: vWf, von Willebrand factor.

	Introduction

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The prototype integrin, _IIbß₃, plays critical roles in platelet adhesion and aggregation. Normally, _IIbß₃ on circulating platelets is present in a "resting" form, with a low affinity for its ligands such as soluble fibrinogen and von Willebrand factor (vWF).^* Upon vascular injury, exposure of platelets to soluble agonists, such as thrombin and ADP, or extracellular matrix adhesive proteins, such as collagen and vWF, induces "inside-out" signals activating the ligand-binding function of _IIbß₃ (Ginsberg et al., 1992; Shattil et al., 1998; Parise, 1999). Ligand binding to _IIbß₃ not only forms adhesive bonds between platelets and adhesive ligands, but also transmits "outside-in" signals to induce a series of cellular responses, such as protein phosphorylation (Ferrell and Martin, 1989; Golden et al., 1990; Lipfert et al., 1992; Clark et al., 1994; Law et al., 1996; Lerea et al., 1999), elevation of intracellular Ca²⁺ (Pelletier et al., 1992), and cytoskeleton reorganization (Phillips et al., 1980), leading to cell spreading, stabilization of cell adhesion, and secondary wave of platelet aggregation (Shattil et al., 1998; Parise, 1999).

Inside-out and outside-in signaling of integrins have been suggested to involve the interaction between the cytoplasmic domains of integrins and intracellular signaling molecules. Interactions between the membrane-proximal regions of the integrin _IIb and ß₃ cytoplasmic domains are important in maintaining a resting conformation of the integrin, and inside-out signaling is associated with disruption of this interaction (Hughes et al., 1996; Vinogradova et al., 2002). The cytoplasmic domain of _IIbß₃ interacts with several intracellular proteins, including cytoskeletal proteins such as talin (Calderwood et al., 1999; Knezevic et al., 1996) and myosin (Phillips et al., 2001), calcium-binding protein CIB (Naik et al., 1997), phosphotyrosine-binding proteins SHC and GRB2 (Law et al., 1996), protein kinases such as integrin-linked protein kinase (Hannigan et al., 1996), and ß3 endonexin (Shattil et al., 1995). Binding of talin (Calderwood et al., 1999, 2002) and ß₃ endonexin (Kashiwagi et al., 1997) to ß₃ has been implicated in promoting integrin activation. Binding of phosphotyrosine-binding proteins and focal adhesion kinase has been suggested to play roles in outside-in signaling (Law et al., 1996). Also, the ß₃ cytoplasmic domain can be chemically modified during platelet activation. For example, T⁷⁵³ (Lerea et al., 1999), Y⁷⁴⁷, and Y⁷⁵⁹ (Law et al., 1996) are phosphorylated by protein kinases, and the COOH-terminal region of ß₃ is cleaved by calpain at the COOH-terminal side of Y⁷⁴¹, T⁷⁴⁷, F⁷⁵⁴, and Y⁷⁵⁹ (Du et al., 1995). Phosphorylation at both Y⁷⁴⁷ and Y⁷⁵⁹ is critical to outside-in signaling of the integrin (Law et al., 1999). The roles of calpain cleavage of the ß₃ cytoplasmic domain in bidirectional signaling of the integrin, however, are not clear.

The requirement for specific sequences in the ß₃ cytoplasmic domain in outside-in integrin signaling has been indicated by mutagenesis studies in transfected CHO cell models (Chen et al., 1994; Hughes et al., 1995; Ylanne et al., 1995; Patil et al., 1999) and transgenic mouse models (Law et al., 1999). Deletions or mutations that disrupted the two NXXY motifs in the cytoplasmic domain of the integrin abolished outside-in signal-dependent integrin functions such as stable cell adhesion and cell spreading (Ylanne et al., 1993, 1995; Chen et al., 1994; Patil et al., 1999). In a transgenic mouse model, mutations replacing both Y⁷⁴⁷ and Y⁷⁵⁹ in the NXXY motifs with phenylalanine to disrupt tyrosine phosphorylation inhibited outside-in signaling but had no significant effect on inside-out signaling (Law et al., 1999). The requirement for the cytoplasmic domain of ß₃ in inside-out signaling has been indicated by defective integrin activation in variant Glanzmann's thrombasthenia patients whose ß₃ cytoplasmic domain either has a point mutation replacing S⁷⁵² with proline (Chen et al., 1992, 1994) or has a truncation mutation at R⁷²⁴ (Wang et al., 1997). However, mapping of functional sites important to inside-out signaling has been hampered by the lack of a suitable inside-out signaling model in cultured cells deficient in endogenous wild-type ß₃, as recombinant integrin _IIbß₃ expressed in CHO cells is not activated by platelet agonists such as thrombin and ADP (O'Toole et al., 1990). Although constitutively active integrin mutants have been useful in characterizing the affinity regulation by integrin cytoplasmic domains (O'Toole et al., 1991, 1994; Hughes et al., 1995), these mutants obviously bypass the normal on–off switch mechanism of inside-out signaling. We and others have recently shown that integrin can be activated in a reconstituted CHO cell model via the GPIb-IX pathway (Gu et al., 1999; Zaffran et al., 2000; Li et al., 2001). In this model, and as shown here, binding of vWF to GPIb-IX induces inside-out signaling and results in activation of the fibrinogen-binding function of _IIbß₃, which replicates the GPIb-IX–induced inside-out signaling mechanism in platelets. To understand the structural requirement of the ß₃ cytoplasmic domain in integrin inside-out signaling and the role of calpain cleavage in regulating integrin signaling, we have expressed different truncation mutants of ß₃ in this reconstituted integrin activation model. We show that removal of the NITY sequence abolished inside-out signaling, whereas truncation of RGT sequence COOH terminal to the NITY motif reduced outside-in signaling without affecting inside-out signaling. Furthermore, a point mutation changing Y⁷⁵⁹ to alanine abolished inside-out signaling and reduced outside-in signaling. Thus, the NITY sequence is essential for both inside-out and outside-in signaling of _IIbß₃, and the RGT sequence is important for outside-in signaling. Furthermore, localized calpain cleavage of ß₃ during platelet activation mainly occurs at a site COOH terminal to Y⁷⁵⁹, suggesting that calpain cleavage may selectively regulate outside-in signaling.

	Results

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CHO cell lines coexpressing mutants of the human integrin _IIbß₃ and GPIb-IX
To study the roles of the COOH-terminal region of ß₃ in integrin signaling, we have generated four truncation mutants of the ß₃ subunit with truncations at sites COOH terminal to T⁷⁴¹, Y⁷⁴⁷, F⁷⁵⁴, and Y⁷⁵⁹. Truncations at these sites also coincide with previously identified calpain cleavage sites in ß₃ (Du et al., 1995; Fig. 1 A). These mutants were cotransfected with the integrin _IIb subunit into a CHO cell line that expresses recombinant human GPIb-IX complex (1b9). Complex formation between these ß₃ mutants and _IIb was verified by flow cytometry using an _IIbß₃ complex–specific monoclonal antibody, D57. Stable cell lines expressing both GPIb-IX and integrin mutants (1b9/741, 1b9/747, 1b9/754, and 1b9/759) were obtained by cell sorting with antibodies specific for integrin _IIbß₃ and GPIb-IX. Expression of correct mutants at each of the four sites was verified by immunoblotting with antibodies that specifically recognize each of these sites only when the site is truncated (Du et al., 1995; Fig. 1 B). In addition, a cell line coexpressing GPIb-IX and a mutant _IIbß₃ bearing alanine substitution of Y⁷⁵⁹ in ß₃ was also established (1b9/Y759A). Expression levels of GPIb-IX and integrin _IIbß₃ on the above mutant cell lines were comparable with a cell line expressing GPIb-IX and wild-type integrin _IIbß₃ (123 cells) at the time of experiments (Fig. 1 C).

View larger version (84K): [in this window] [in a new window]   Figure 1. Truncation mutants of IIbß3 coexpressed with GPIb-IX in CHO cells. (A) Schematics showing truncation mutants of ß3 that mimic calpain cleavage at four previously identified sites. A Y759A point mutation is also depicted. (B) The mutants described in A were cotransfected with IIb in a CHO cell line already expressing GPIb-IX, and stable cell lines were established. Expression of correct truncation mutants in each of the cell lines was verified by immunoblotting cell lysates with antibodies specifically recognizing calpain-cleaved forms of ß3 (Ab 741, Ab 747, Ab 754, and Ab 759) and with an antibody recognizing the COOH terminus of ß3 (Ab 762). A cell line expressing wild-type IIbß3 and GPIb-IX (123) was also immunoblotted with these antibodies as a control. (C) Levels of surface expression of wild type or mutants of IIbß3 were examined by flow cytometry with an antibody recognizing IIbß3 complex (D57) (dotted lines), and levels of GPIb-IX expression were examined with an antibody against GPIb, SZ2 (shaded lines). Nonspecific mouse IgG was used as a negative control (solid lines). Please note that levels of expression of each of these mutants were comparable with 123 cells. Expression of GPIb-IX and integrin was also comparable with a cell line expressing GPIb-IX alone (1b9) and a cell line expressing IIbß3 alone (2b3a), respectively.

Reconstituted CHO cell model of integrin _IIbß₃ activation

View larger version (15K): [in this window] [in a new window]   Figure 2. vWF-induced activation of fibrinogen binding to cell lines coexpressing GPIb-IX and IIbß3 reflects specific activation of integrin IIbß3. (A) CHO cells (CHO), CHO cells coexpressing GPIb-IX and integrin IIbß3 (123), and CHO cells coexpressing GPIb-IX and ß3 in the absence of IIb (1b9/ß3) were incubated with control mouse IgG, IIbß3-specific antibodies, 2G12 and D57, and an antibody recognizing integrin vß3, anti-VNR1. The reactivity of these antibodies was detected by flow cytometry. (B) 123 cells were preincubated with 100 µg/ml of control mouse IgG, 2G12, or anti-VNR1 (previously shown to inhibit ligand-binding functions of IIbß3 or vß3, respectively) for 10 min at 22°C, and then Oregon green–labeled fibrinogen (30 µg/ml) was added and activated with vWF in the presence of ristocetin. Nonspecific binding was estimated by adding the integrin inhibitor RGDS. Quantitative results from three experiments (means ± SD) are expressed as fibrinogen binding index (total bound fibrinogen/nonspecifically bound fibrinogen in the presence of RGDS). Statistical differences between samples were analyzed using the RRISM software and the Repeated Measures ANOVA method.

View larger version (22K): [in this window] [in a new window]   Figure 3. vWF-induced fibrinogen binding to wild type or various mutants of IIbß3. (A) Cells (123, 1b9/741, 1b9/747, 1b9/754, 1b9/759, and 1b9/Y759A) suspended in modified Tyrode's buffer were incubated at 22°C for 30 min with Oregon green–labeled fibrinogen (30 µg/ml) and 1 mg/ml of ristocetin with (right) or without (left) adding 25 µg/ml of vWF, and then were analyzed for fluorescence intensity by flow cytometry (solid lines). Nonspecific binding of fibrinogen was estimated by adding 1 mM RGDS (shaded lines). (B) Quantitative results from three experiments (means ± SD) are expressed as fibrinogen binding index (total bound fluorescence intensity/nonspecifically bound fluorescence intensity).

Fibrinogen-binding function of the integrin _IIbß₃ mutants

View larger version (19K): [in this window] [in a new window]   Figure 4. Fibrinogen binding to mutants of IIbß3 pretreated with RGDS peptide. Cells coexpressing GPIb-IX and wild-type IIbß3 (123) or integrin mutants were preincubated with or without 1 mM of RGDS peptide for 10 min and then fixed with paraformaldehyde (1% in PBS) for 30 min at 22°C. As a negative control, cells expressing GPIb-IX alone (1b9) were identically treated. The cells were washed, resuspended in modified Tyrode's buffer at a concentration of 5 x 105/ml, and then incubated with Oregon green–labeled fibrinogen for 30 min. Fibrinogen binding was detected by flow cytometry. Nonspecific binding was estimated by adding RGDS peptide to the assay. Specific fibrinogen binding was determined by subtracting the geometric means of fluorescence intensity of the nonspecific binding from that of total binding. Shown in the figure are the data (mean ± SD) from three experiments.

View larger version (61K): [in this window] [in a new window]   Figure 5. Effects of mutations on integrin-dependent stable cell adhesion and spreading on vWF or fibrinogen (Fg) under static conditions. The indicated cell lines in modified Tyrode's buffer (106/ml) were allowed to incubate in fibrinogen- or vWF-coated microtiter wells at 37°C for 1 h. The wells were washed three times, and the cells remaining adherent were quantitated using an acid phosphatase assay, as described under the Materials and methods (A), and photographed to document cell spreading (B). The means and standard deviations of triplicate samples are shown in A.

View larger version (28K): [in this window] [in a new window]   Figure 6. Effects of mutations on GPIb-IX–induced, integrin-dependent cell adhesion to vWF under flow conditions. Cells coexpressing GPIb-IX with wild type and different mutants of IIbß3 as well as control cells expressing GPIb-IX alone or IIbß3 alone (5 x 106/ml in modified Tyrode's buffer containing 5% BSA) were perfused though the capillary tubes precoated with vWF at indicated shear rates for 2 min, followed by a further 10-min perfusion with Tyrode's buffer at the same shear rate to wash out transient adherent cells. Cell interaction with immobilized vWF under flow conditions was observed under an inverted microscope and recorded on videotapes. The number of stable adherent cells on vWF was counted on images obtained at 10 randomly selected positions in each vWF-coated capillary tube. The difference between the control 123 cells with each of the other cell lines was analyzed by t test and shown to be highly significant (P < 0.01), unless otherwise indicated.

Differential cleavage at different sites of the ß₃ cytoplasmic domain by calpain in platelets
We have shown previously that calpain may cleave the cytoplasmic domain of ß₃ at sites COOH terminal to T⁷⁴¹, Y⁷⁴⁷, F⁷⁵⁴, and Y⁷⁵⁹, which generates ß₃ fragments identical to the above-described truncation mutants of ß₃ (741, 747, 754, and 759). As we showed above that truncations at these different sites result in different functional effects on integrin signaling, our results also indicate that cleavage of the ß₃ cytoplasmic domain at these different sites has the potential to differentially regulate outside-in and inside-out signaling of integrin _IIbß₃. To determine if calpain differentially cleaves the ß₃ integrin at different sites during platelet activation, washed platelets were treated with or without thrombin (0.1 U/ml) and then immunoblotted for calpain cleavage by the cleavage-specific antibodies (Du et al., 1995). We found that anti-759 antibody, which only recognizes ß₃ molecules with cleavage at Y⁷⁵⁹, reacted with 0.8% of the integrin _IIbß₃ molecules in washed "resting" platelets (Fig. 7). This reaction was unlikely to result from cross-reaction of this antibody with the intact ß₃ subunit, because we showed that the antibody did not react with the intact ß₃ subunit but reacted with the 759 mutant expressed in CHO cells (Fig. 2). Thus a very small percentage of the ß₃ molecules in resting platelets has been cleaved at the Y⁷⁵⁹ site. Stimulation of platelets with thrombin caused a time-dependent and significant increase in the cleavage at Y⁷⁵⁹. In contrast to the 759 site, calpain cleavage at T⁷⁵⁴ or Y⁷⁴⁷ (Fig. 7) occurred to a much lesser degree and only after a much longer exposure to thrombin. Calpain cleavage at the 741 site was not detectable in thrombin-stimulated platelets (unpublished data) but was detected in platelets treated with calcium ionophore A23187 (Du et al., 1995). Thus, in thrombin-activated platelets, calpain preferentially cleaves ß₃ at Y⁷⁵⁹. As we showed above that cleavage at Y⁷⁵⁹ selectively reduced integrin outside-in signaling without affecting inside-out signaling, this result indicates that calpain cleavage has the potential to selectively regulate outside-in signaling during platelet activation.

View larger version (33K): [in this window] [in a new window]   Figure 7. Progressive cleavage at different sites of the ß3 cytoplasmic domain by calpain. Washed human platelets (109/ml) were directly solubilized in SDS-PAGE sample buffer containing EDTA and E64 (Control), or treated with thrombin (0.1 U/ml) for increasing lengths of time at 37°C before being solubilized. Platelet lysates were then immunoblotted with Ab759, Ab754, Ab747, and Ab741 to detect calpain cleavages at Y759, F754, T747, and Y741 sites, with Ab762 to detect uncleaved ß3 and Mab 15 to detect total ß3 levels. Quantification of antibody reactions was performed by scanning the immunoblots and analyzing using NIH Image as described under the Materials and methods. Percentages of the molecules cleaved (or uncleaved) at a particular site are shown in B.

View larger version (64K): [in this window] [in a new window]   Figure 8. Localization of calpain-cleaved ß3 in spreading platelets. Platelets in Tyrode's buffer (1 x 108/ml) were incubated in the chamber slides precoated with 20 µg/ml fibrinogen for 2 h at 37°C. After three washes, the adherent platelets were fixed with 4% paraformaldehyde and permeabilized. The slides were incubated subsequently with Mab15, specific for integrin ß3 extracellular domain (green), and with one of the cleavage site–specific antibodies (Ab759 and Ab754) or an antibody against the COOH terminus of ß3 (Ab762) (red), and then with Alexa Fluor 488–conjugated anti–mouse IgG antibody and Alexa Fluor 546–conjugated anti–rabbit IgG antibodies. The slides were scanned under a confocal microscope (63x lens). Images of the green and red fluorescence overlay are shown in the left column. Green fluorescence (Mab15) from the same images is shown in the middle column. Red fluorescence (cleavage site–specific antibodies) from the same images is shown in the right column.

	Discussion

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We conclude that the NITY sequence of the ß₃ cytoplasmic domain is critical to the inside-out signaling function of _IIbß₃. This conclusion is supported by the finding that deletion of the RGT sequence COOH terminal to the NITY motif did not affect vWF-induced integrin activation, but deletion of the TNITY sequence completely abolished integrin activation. The importance of the NITY sequence in inside-out signaling is further supported by the data that the Y759A point mutation inhibited vWF-induced integrin activation. Also, we show that inhibition of vWF-induced fibrinogen binding is not caused by loss of the fibrinogen-binding function per se, as RGDS-induced fibrinogen binding to either 1b9/754 or 1b9/Y759A mutant cells was not different from the wild-type integrin. Furthermore, our data indicate that the NITY sequence and the COOH-terminal RGT sequence are both important for outside-in signaling of _IIbß₃ and integrin-dependent stable cell adhesion and spreading. This is consistent with previous work showing that this region of the ß₃ cytoplasmic domain is important in cell spreading and focal adhesion formation (Ylanne et al., 1993, 1995). Thus, the NITY motif is important for both inside-out and outside-in signaling of the integrin _IIbß₃.

The NITY motif contains a tyrosine residue that becomes phosphorylated during platelet aggregation (Law et al., 1996). The phosphorylated NXXY motifs have been shown to interact with several intracellular molecules, including myosin and phosphotyrosine-binding proteins such as GRB2 and SHC (Cowan et al., 2000), which are implicated in integrin outside-in signaling. It has been shown that mutation of both tyrosine residues to phenolalanines selectively abolished outside-in signaling in transgenic mouse platelets (Law et al., 1999), suggesting that phosphorylation of one or both of these tyrosine residues is important for outside-in signaling but not for integrin activation (inside-out signaling). Thus, although we conclude that the NITY sequence is essential for inside-out signaling, phosphorylation at Y⁷⁵⁹ is unlikely to be involved in this process. In this regard, a functional difference between Y759F and Y759A mutations has been shown previously (Schaffner-Reckinger et al., 1998). Y759A, but not Y759F, inhibited integrin-dependent cell adhesion. Furthermore, tyrosine phosphorylation occurs only after platelet aggregation, suggesting that inside-out signaling does not involve tyrosine phosphorylation in the NXXY motifs (Law et al., 1996, 1999).

It is interesting to note that although the NITY sequence is important for both inside-out and outside-in signaling, there is a significant difference in the structural requirement between inside-out signaling (integrin activation) and outside-in signaling. Cleavage of the COOH-terminal three residues did not affect inside-out signaling but significantly inhibited outside-in signaling–dependent integrin function, such as cell spreading and stable cell adhesion. On the other hand, disruption of the NITY sequence by Y759A mutation abolished vWF-induced integrin activation (as indicated by soluble fibrinogen binding) and partially (although significantly) inhibited cell spreading and stable cell adhesion on fibrinogen. In addition, previous work suggests that outside-in signaling, but not inside-out signaling, requires phosphorylation at tyrosine residues (Law et al., 1999). The difference in the structural requirements between inside-out and outside-in signals suggests that inside-out and outside-in signals may be mediated by different molecules (or mechanisms) that interact with the COOH-terminal region of ß₃ during platelet adhesion and aggregation. This also suggests that inside-out and outside-in signals can be differentially regulated.

The family of the calcium-dependent intracellular proteases, calpain, plays important roles in cytoskeletal reorganization, cell migration, platelet aggregation, and clot retraction (Fox et al., 1983; Huttenlocher et al., 1997; Croce et al., 1999; Bialkowska et al., 2000; Azam et al., 2001). We have shown previously that the ß₃ cytoplasmic domain is cleaved by either calpain I or calpain II at sites flanking two NXXY motifs in human platelets (Du et al., 1995; Pfaff et al., 1999). Calpain cleavage of the ß₃ cytoplasmic domain also occurs during endothelial cell apoptosis (Meredith et al., 1998). The physiological roles of calpain cleavage of ß₃ have been unclear. Calpain I knockout in mouse inhibited platelet aggregation but did not affect ß₃ cleavage. This suggests that cleavage of the ß₃ subunit is not involved in promoting platelet aggregation (Azam et al., 2001). Here we show that one of the functional consequences of calpain cleavage of ß₃ is to negatively regulate the signaling functions of integrin _IIbß₃. Furthermore, we show that cleavage by calpain at different sites of ß₃ may result in different regulatory effects. Cleavage at Y⁷⁵⁹ has no significant effect on inside-out signaling but significantly reduces the integrin functions associated with outside-in signaling. In contrast, cleavage at F⁷⁵⁴ or further NH₂-terminal sites abolishes both inside-out and outside-in signaling. Nevertheless, cleavage at these sites occurs much later during platelet activation (Figs. 7 and 8), suggesting that such cleavages are not important for the early phase of integrin activation. On the other hand, we found that calpain cleavage of integrin ß₃ subunit in intact platelets mainly occurs at the most COOH-terminal Y⁷⁵⁹ site during platelet activation and adhesion (Figs. 7 and 8). Furthermore, cleavage of ß₃ does not appear to occur to the integrin molecules at the leading edge of spreading platelets but occurs to more centrally localized integrin molecules. Thus, it is likely that cleavage at Y⁷⁵⁹ serves to selectively down-regulate outside-in signaling in the integrin–cytoskeletal signaling complexes that have been formed during the earlier stage of platelet spreading, thereby facilitating the dynamic reorganization of the integrin–cytoskeleton signaling complex during platelet spreading.

	Materials and methods

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Reagents and cell lines
Human vWF was purified as described previously (Booth et al., 1984). Human -thrombin was purchased from Enzyme Research Laboratories. RGDS peptide was from Bachem, and ristocetin was from Sigma-Aldrich. Monoclonal antibodies against integrin _vß₃ (anti-VNR1) (O'Toole et al., 1990), against integrin ß₃ (Mab15) (Frelinger et al., 1990), and against the integrin _IIbß₃ complex (D57 and 2G12) (Frojmovic et al., 1991) were provided by M. Ginsberg (The Scripps Research Institute, La Jolla, CA) and V. Woods (University of California, San Diego, CA). Monoclonal antibodies against GPIb (SZ2) (Ruan et al., 1987) were a gift from C. Ruan (Jiangsu Institute of Hematology, Suzhou, China). Calpain cleavage site–specific antibodies were generated by immunizing rabbits with pentapeptides (AKWDT for Ab741, NNPLY for Ab747, ATSTF for Ab754, TNITY for Ab759, and TYRGT for Ab762) as described previously (Du et al., 1995). Oregon green 488–conjugated human fibrinogen, Alexa Fluor 488–conjugated goat anti–mouse IgG, and Alexa Fluor 546–conjugated goat anti–rabbit IgG were from Molecular Probes. Integrin _IIb and ß₃ cDNA clones in pCDM8 vector were provided by M. Ginsberg, and a mutant ß₃ cDNA clone bearing the Y⁷⁵⁹A substitution was a gift from J. Ylänne (University of Helsinki, Helsinki, Finland). Cell lines expressing GPIb-IX complex (1b9), integrin _IIbß₃ (2b3a), or both GPIb-IX and _IIbß₃ (123) were described previously (Gu et al., 1999).

Construction of truncation mutants of ß₃ subunit
Truncation mutagenesis was performed using PCR to introduce stop codons into integrin ß₃ cDNA at sites corresponding to the carboxy side of amino acid residues 741, 747, 754, or 759, respectively. The forward primer has the sequence of AGAGCTTAAGGACAC at an AflII site of ß₃ cDNA. The reverse primers contain an XhoI digestion site, a stop codon, and the 18-nucleotide ß₃ sequences at the intended COOH terminus of each mutant. The PCR products were digested with restriction enzymes AspI and XhoI and ligated into a ß₃ cDNA construct in a modified cDM8 vector containing only the 3'-end XhoI site that was digested with the same restriction enzymes. All mutant constructs were verified by DNA sequencing.

Expression of mutant ß₃ cDNA constructs in CHO cells
CHO cells expressing GPIb-IX (1b9) were maintained in DEAE medium supplemented with 10% FBS, glutamine, and nonessential amino acid. Transfection was performed using LipofectAMINE 2000 (Life Technologies). Each mutant ß₃ cDNA was cotransfected together with wild-type _IIb and pcDNA3.1/Hyg plasmid at a ratio of 5:5:1. Stable cell lines expressing mutant ß₃ were selected in 0.2 mg/ml of hygromycin (Invitrogen). Expression of integrin _IIbß₃ was monitored by flow cytometry using D57. Expression of GPIb-IX was detected using SZ2. Cells expressing both GPIb-IX and integrin _IIbß₃ were selected by cell sorting. All cell lines were sorted using the expression levels of 123 cells as a gate until similar levels of expression were achieved. To verify correct expression of calpain cleavage–mimicking mutants, cells were also solubilized and electrophoresed on 7% polyacrylamide gels and then immunoblotted with various cleavage-specific antibodies followed by detection using the ECL kit from Amersham.

Fibrinogen binding to transfected CHO cells activated by vWF
Activation of _IIbß₃ induced by ristocetin and vWF was examined by flow cytometric analysis of Oregon green 488–conjugated fibrinogen binding to _IIbß₃, as previously described (Gu et al., 1999; Li et al., 2001). In brief, transfected CHO cells were resuspended to 5 x 10⁵/ml in modified Tyrode's solution (2.5 mM Hepes, 150 mM NaCl, 2.5 mM KCl, 12 mM NaHCO₃, 5.5 mM D-glucose, 1 mM CaCl₂, 1 mM MgCl₂, 0.1% BSA, pH 7.4), incubated with Oregon green 488–conjugated fibrinogen (30 µg/ml) and ristocetin (1 mg/ml) in the presence or absence of purified human vWF (25 µg/ml) at 22°C for 30 min, and analyzed by flow cytometry. Nonspecific binding of fibrinogen was estimated by measuring fibrinogen binding in the presence of an integrin inhibitor, RGDS (1 mM).

Fibrinogen binding induced by RGDS peptide
RGDS pretreatment–induced fibrinogen binding was assayed according to a previously described method (Du et al., 1991). Cells in modified Tyrode's solution were incubated with 1 mM RGDS peptide at 22°C for 10 min. Paraformaldehyde–PBS was then added (to a final concentration of 1%), and the mixture was incubated at 22°C for 1 h. After adding 250 mM NH₄Cl, the fixed cells were washed, resuspended in modified Tyrode's solution, and incubated with Oregon green 488–conjugated fibrinogen (30 µg/ml) for 30 min before flow cytometric analyses.

Cell adhesion under static conditions
Microtiter wells were coated with 10 µg/ml human vWF or fibrinogen in 0.1 M NaHCO₃, pH 8.3, at 4°C overnight and then blocked with 5% BSA–PBS at 22°C for 2 h. Cell suspension (10⁶/ml in modified Tyrode's buffer with 1% BSA) was added to ligand-coated microtiter wells and incubated for 60 min at 37°C in a CO₂ incubator. After three washes, cell spreading was examined under an inverted microscope (20x objective lens). In quantitative assays, 50 µl of 0.3% p-nitrophenyl phosphate in 1% Triton X-100, 50 mM sodium acetate, pH 5.0, was added to microtiter wells and incubated at 37°C for 1 h. The reaction was stopped by adding 50 µl of 1 M NaOH. Results were determined by reading the OD at a 405-nm wavelength.

Cell adhesion under flow
Purified human vWF (100 µg/ml with 0.1 mM NaHCO₃, pH 8.3) was added into a glass capillary tube (0.59 mm ID, 75 mm in length; Harvard Apparatus Inc.) and then incubated overnight in a humid environment at 4°C (Englund et al., 2001). The capillary tubes were rinsed with PBS and then blocked with 5% BSA in PBS. CHO cells expressing human platelet receptors (5 x 10⁶/ml in modified Tyrode's buffer containing 5% BSA) were perfused with a syringe pump (Harvard Apparatus Inc.) through the capillary tube at various shear rates for 2 min followed by perfusion for 10 min with cell-free buffer at the same shear rates. Shear rate was calculated as described by Slack and Turitto (1994). Cell interaction with immobilized vWF was observed in real time under an inverted microscope and recorded on videotapes. The number of stable adherent cells on immobilized vWF was counted on images obtained in 10 randomly selected fields in the vWF-coated tubes. The statistical difference between 123 cells and each one of the mutant cell lines was determined using the t test.

Calpain cleavage of integrin ß₃ subunit in human platelets
Preparation of washed human platelets has been described previously (Li et al., 2003). Platelet aggregation was induced in a Chronolog lumi-aggregometer by adding 0.1 U/ml thrombin with constant stirring at 1,000 rpm for various lengths of time. The reaction was stopped by adding an equal volume of 2x SDS-PAGE sample buffer containing 1 mM EDTA, 1 mM PMSF, and 0.1 mM E64. Samples were then analyzed by SDS-PAGE on a 7% gel and immunoblotted with cleavage-specific antibodies (Du et al., 1995). The densities of reactive bands were scanned and then quantitated using NIH Image. Lysates prepared from 123, 1b9/747, 1b9/754, and 1b9/579 CHO cell lines were used as internal calibration standards for each of the cleavage-specific antibodies. The ratio of cleaved ß₃ molecules was calculated as the ratio between the optical density of the reaction of an antibody with platelet lysates and the reaction of the same antibody with the corresponding standard CHO cell lysates multiplied by the ratio between the ß₃ levels in the standard CHO cell lysates and the ß₃ level in platelet lysates (as determined by immunoblotting with Mab15 directed against the extracellular domain of ß₃).

Immunofluorescence analysis of calpain-cleaved ß₃ in spreading platelets
Platelets in modified Tyrode's buffer (1 x 10⁸/ml) were allowed to adhere to the Lab-Tek chamber slides (Nunc) precoated with 20 µg/ml of fibrinogen at 37°C for 2 h as previously described (Bodnar et al., 1999). The chamber slides were rinsed three times. Adherent platelets were fixed with 1% paraformaldehyde and permeabilized with 0.1 M Tris, 10 mM EGTA, 0.15 M NaCl, 5 mM MgCl₂, 1 mM PMSF, 0.1 mM E64, 0.1% Triton X-100, 1% BSA, pH 7.5. The samples were incubated first with Mab15 and one of the cleavage-specific antibodies and then with Alexa Fluor 488–conjugated goat anti–mouse IgG and Alexa Fluor 546–conjugated goat anti–rabbit IgG. The slides were then scanned under a Carl Zeiss MicroImaging, Inc. LSM510 confocal microscope (63x objective lens).

	Acknowledgments

 
This work was supported in part by a Grant-in-Aid (0050306N) from the American Heart Association and by grants from the National Institutes of Health/National Heart, Lung, and Blood Institute (HL62350, HL68819, and HL41793). A part of the work by X. Du was done during the tenure of the Established Investigatorship of the American Heart Association.

Submitted: 18 March 2003

Revised: 6 June 2003

Accepted: 10 June 2003

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