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© The Rockefeller University Press, 0021-9525/2002/4/173 $5.00
The Journal of Cell Biology, Volume 157, Number 1, April 1, 2002 173-184

PECAM-1 (CD31) regulates a hydrogen peroxide–activated nonselective cation channel in endothelial cells

¹ Division of Pulmonary, Allergy, and Critical Care Medicine
² Institute for Environmental Medicine, Department of Medicine, University of Pennsylvania School of Medicine, Philadelphia, PA 19104
³ Department of Biomedical Sciences, College of Veterinary Medicine, Cornell University, Ithaca, NY 14853

Address correspondence to Christopher D. O'Brien, Dept. of Pulmonary/Critical Care, University of Pennsylvania, 838 BRB II/III, 421 Curie Blvd., Philadelphia, PA 19104. Tel.: (215) 746-6709. Fax: (215) 573-4469. E-mail: christoo{at}mail.med.UPENN.edu

	Abstract

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Hydrogen peroxide (H₂O₂) released by neutrophils is an important mediator of endothelial cell (EC) injury and vascular inflammation via its effect on EC-free Ca²⁺, [Ca²⁺]_i. Although the underlying mechanisms are not well understood, platelet endothelial cell adhesion molecule (PECAM)-1/CD-31 is a critical modulator of neutrophil–EC transmigration. PECAM-1 is also known to regulate EC calcium signals and to undergo selective tyrosine phosphorylation. Here, we report that PECAM-1 molecules transduce EC responses to hydrogen peroxide. In human umbilical vein EC and REN cells (a PECAM-1–negative EC-like cell line) stably transfected with PECAM-1 (RHP), noncytolytic H₂O₂ exposure (100–200 µM H₂O₂) activated a calcium-permeant, nonselective cation current, and a transient rise in [Ca²⁺]_i of similar time course. Neither response was observed in untransfected REN cells, and H₂O₂-evoked cation current was ablated in REN cells transfected with PECAM-1 constructs mutated in the cytoplasmic tyrosine–containing domain. The PECAM-dependent H₂O₂ current was inhibited by dialysis of anti–PECAM-1 cytoplasmic domain antibodies, required Src family tyrosine kinase activity, was independent of inositol trisphosphate receptor activation, and required only an intact PECAM-1 cytoplasmic domain. PECAM-1–dependent H₂O₂ currents and associated [Ca²⁺]_i transients may play a significant role in regulating neutrophil–endothelial interaction, as well as in oxidant-mediated endothelial response and injury.

Key Words: hydrogen peroxide; capacitative current; calcium; tyrosine kinase; ion channels

	Introduction

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Reactive oxygen species (H₂O₂, ^•O₂^-,•OH) are important mediators of endothelial cell (EC)^* injury and likely play a central role in cardiovascular, cerebrovascular, and pulmonary syndromes such as myocardial infarction, ischemic stroke, acute respiratory distress syndrome, and acute organ transplant rejection (Lounsbury et al., 2000). H₂O₂ appears to be particularly important in the context of neutrophil–endothelial interaction in inflammation (Martin, 1984; Lewis et al., 1988; Gasic et al., 1991), during which local H₂O₂ levels may exceed 100–400 µM (Test and Weiss, 1984). H₂O₂ causes cell depolarization (Matoba et al., 2000) and increases cytosolic-free Ca²⁺ concentration ([Ca²⁺]_i) in EC through a range of concentration-dependent [Ca²⁺]_i responses, including Ca²⁺ influx into EC (Bowles et al., 2001) and Ca²⁺ release from intracellular stores (Schilling and Elliott, 1992; Doan et al., 1994; Siflinger-Birnboim et al., 1996; Yolk et al., 1997; Hu et al., 1998). This rise in [Ca²⁺]_i triggers the release of platelet-activating factor (Lewis et al., 1988) and PGI₂ (Harlan and Callahan, 1984), endothelial retraction, adhesion molecule redistribution (Bradley et al., 1995), EC permeability (Siflinger-Birnboim et al., 1996; Carbajal and Schaeffer, 1998), gene transcription (Barchowsky et al., 1995), and apoptosis (Martin, 1984; Suzucki et al., 1997). H₂O₂ can also activate tyrosine kinases and inhibit protein tyrosine phosphatases in ECs (Barchowsky et al., 1995; Carbajal and Schaeffer, 1998). Despite the recognized importance of these EC responses to oxidant exposure, the key regulatory proteins modulating EC calcium responses remain largely unknown.

One potential participant in this regulation is platelet endothelial adhesion molecule (PECAM)-1/CD-31, a 130-kD type 1 membrane glycoprotein belonging to the Ig superfamily of CAMs that plays an important role in the modulation of EC–neutrophil interaction and transmigration in inflammation (Vaporciyan et al., 1993; Nakada et al., 2000) and oxidant injury (Scalia and Lefer, 1998). PECAM-1, which functions as both an adhesion and signaling protein, is highly expressed on ECs where it localizes to cell–cell borders, as well as on leukocytes and platelets (Newman, 1997). Recently, it has been shown that engagement of PECAM-1 elicits prolonged EC calcium transients through a calcium-permeant, plasmalemmel nonselective cation (NSC) channel. Activation of this channel is dependent on Src family kinase activity, but independent of inositol trisphosphate (IP₃)-mediated store release or phosphoinositide turnover (Gurubhagavatula et al., 1998; O'Brien et al., 2001). In addition to a large extracellular domain containing six Ig-like loops, PECAM-1 has a 118–amino acid cytoplasmic domain containing a dual tyrosine SH2 binding motif (Y663/Y686). Under a range of conditions, including phosphatase inhibition (Jackson et al., 1997; Sagawa et al., 1997), Src and Csk overexpression (Lu et al., 1997; Cao et al., 1998), and anti–PECAM-1 antibody engagement (Varon et al., 1998), this motif is selectively tyrosine phosphorylated. Once phosphorylated, PECAM-1 can associate with SH2 domain proteins such as SHP-2, SHP-1, PLC, and PI3-kinase, although the physiologic relevance of these interactions in EC are unknown (Newman, 1999). In light of the evidence that PECAM-1 participates in ionic signaling and may serve as a substrate for phosphotyrosine modification, we hypothesized that PECAM-1 might participate in the regulation of oxidant-mediated calcium signals in ECs.

	Results

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H₂O₂ activates a PECAM-1–dependent, inward-directed current in human umbilical vein EC and PECAM-1–transfected REN cells
In order to test our hypothesis that PECAM-1 may play a role in oxidant-mediated signaling, we performed voltage clamp experiments on human umbilical vein EC (HUVEC), REN cells, and REN cells stably transfected with PECAM-1 (RHP). We have previously utilized REN cells, a mesothelioma cell line that does not express endogenous PECAM-1, as an EC model, and have found that many EC signaling processes may be reconstituted after PECAM-1 expression (Gurubhagavatula et al., 1998; O'Brien et al., 2001). Puffer pipette application of 200 µM H₂O₂ (a dose based on preliminary studies described below) to HUVEC and RHP cells voltage clamped at a holding potential of –60 mV, elicited a large inward current in 93% of HUVEC (n = 15) with a peak amplitude of 648.4 ± 36.6 pA. A similar current (peak amplitude 682.5 ± 41.55 pA) was detected in 89% of RHP (n = 18), whereas no currents were observed in untransfected REN cells exposed to 200 (n = 16) or 400 µM (n = 11) H₂O₂ (Fig. 1). H₂O₂ currents were typically activated 30–90 s after H₂O₂ exposure and were of prolonged time course, features similar to cation currents evoked in HUVEC and RHP cells after PECAM-1 engagement (O'Brien et al., 2001). The response to H₂O₂ was concentration dependent in that RHP cells treated with H₂O₂ at concentrations of 100 µM or lower elicited current less consistently (though those responding manifested similar current kinetics). Cells that responded to 400 or 500 µM H₂O₂ displayed evident cell toxicity over 24 h (unpublished data), consistent with previous reports (Barchowsky et al., 1994). Puffer application of vehicle alone did not elicit a current, further eliminating a potential role for shear stress–gated NSC channels or transient loss of seal in the response (unpublished data).

View larger version (13K): [in this window] [in a new window]   Figure 1. Hydrogen peroxide activates a PECAM-1–dependent inward current in HUVEC and in endothelia-like PECAM-1–transfected REN cells (RHP). HUVEC, RHP, and REN cells were voltage clamped at a holding potential of -60 mV in HBSS with CsCl pipette solution. Cells were puffed with 200 µM H2O2 for 3–5 min. (A) H2O2-treated HUVEC yield a prolonged inward current (B) RHP cells identically treated yield a current with similar kinetics. (C) Untransfected REN cells do not manifest detectable current following 200 or 400 µM H2O2 (unpublished data). Instantaneous voltage ramps from -60 mV up to +50 mV yielded Vrev = 0 in all trials. Experiments using the nystatin perforated patch technique yielded similar results.

View larger version (16K): [in this window] [in a new window]   Figure 2. Intracellular dialysis with anti–PECAM-1 cytoplasmic domain antibodies inhibits the H2O2-activated, PECAM-1–dependent current. Voltage-clamped HUVEC (A) and RHP cells (B) were dialyzed through the patch pipette with CsCl pipette solution containing either (10 µg/ml) polyclonal anti–PECAM-1 cytoplasmic domain antibody (PCD) or a polyclonal anti–HSVTK antibody (TK) negative control. Cells were puffed with 200 µM H2O2 for 3–5 min.

View larger version (44K): [in this window] [in a new window]   Figure 3. The H2O2-activated PECAM-1–dependent current is mediated by a voltage-independent, nonrectifying, NSC channel. RHP cells and HUVEC (unpublished data) voltage clamped at a holding potential of -60 mV in HBSS and CsCl pipette solution were puffed with 200 µM H2O2 for 3–5 min. Reversal potential, voltage gating, and rectification were assessed for both cell types after an instantaneous voltage ramp protocol from -60 mV to +40 mV (A) and a 20-mV/20mS incremental step-gradient protocol (inset) (B). RHP cells demonstrate a Vrev = 0 with a linear I/V relationship derived from instantaneous voltage ramp and step-gradient trials with step-gradient trials manifesting no voltage dependence, consistent with a voltage-independent, NSC channel. Identical results were obtained in similar analyses on HUVEC.

View larger version (34K): [in this window] [in a new window]   Figure 4. The PECAM-1–regulated channel is calcium permeant. RHP cells and HUVEC (unpublished data) were voltage clamped at a holding potential of -60 mV in (A) Hepes-buffered saline solution containing 2 mM CaCl2 or (B) Hepes-buffered solution containing 100 mM Ca+2 as the only permeant cation with CsCl pipette solution. Cells were puffed with 200 µM H2O2 for 3–5 min. Cells in high-calcium solution manifested characteristic current with a right shift in Vrev toward ECa+2.

View larger version (31K): [in this window] [in a new window]   Figure 5. Hydrogen peroxide elicits prolonged intracellular calcium transients in PECAM-1–transfected cells. Fluo-4–loaded RHP and REN cells were treated with 200 µmH2O2 during acquisition of confocal images every 43 ms. (A) After H2O2 exposure, there was a homogenous, prolonged rise in Fluor-4 fluorescence in PECAM-1– expressing cells (images 1–5, above). The fluorescence profile (below, derived from all of the images as described in Materials and methods) indicates a roughly threefold increase in fluorescence, similar in magnitude to that observed when cells were exposed to thrombin (B). (B) Comparison of responses to H2O2 (200 µM) and thrombin (1 U/ml) from confocal images as in A shows a similar magnitude increase in [Ca2+]i, although H2O2 responses are substantially increased in duration. Puff application of buffer was without effect, and thrombin, but not H2O2, increased Ca2+ fluorescence in REN cells (inset).

View larger version (13K): [in this window] [in a new window]   Figure 6. Activation of the PECAM-1–regulated NSC current is IP3 independent. RHP cells and HUVEC (unpublished data) dialyzed with the IP3 receptor inhibitor, heparin sulfate, through the patch pipette (5 mg/ml heparin in CsCl) were voltage clamped at a holding potential of –60mV and puffed with 200 µM H2O2 for 5 min. Currents after dialysis (B) were identical to those of typical PECAM-1–dependent responses (A). Identical results were obtained in RHP and HUVEC puffed with 400 µM H2O2 (unpublished data). In RHP cells analyzed with nonheparin containing pipette solution, thrombin treatment (1.5 U/ml) yielded similar large, prolonged inward currents with a Vrev = 0 and an ohmic I/V relationship. However, in heparin-dialyzed RHP cells (inset) and HUVEC (unpublished data) puffed with thrombin (1.5 U/ml), no current was detected.

The PECAM-1 cytoplasmic domain is necessary and sufficient for current activation
In order to specifically examine the role of the PECAM-1 intracellular domain, REN cells stably transfected with a panel of PECAM-1 mutant constructs were examined in a series of patch clamp studies (Fig. 7). The first construct, PITC, consists of the PECAM-1 extracellular domain fused to the nonhomologous ICAM-1 transmembrane and cytoplasmic domains. This fusion protein does not elicit cation current after antibody engagement (O'Brien et al., 2001), but supports homophilic interaction and localizes to the cell–cell border in confluent monolayers (unpublished data). No currents were observed in voltage-clamped PITC cells puffed with 200 µM H₂O₂ (n = 7), suggesting that the PCD, and possibly the transmembrane domain, are necessary for current activation. A second construct, IL2PCD, was utilized to evaluate the role of the isolated PCD in current regulation. IL2PCD contains the nonhomologous interleuken (IL)-2 receptor (CD25) extracellular and transmembrane domains fused to an intact PECAM-1 cytoplasmic domain that can serve as a substrate for H₂O₂-induced tyrosine phosphorylation (unpublished data). In voltage-clamped IL2PCD cells puffed with 200 or 400 µM H₂O₂, cation currents with kinetics identical to full-length PECAM-1 control cells were observed in 14/15 (93%) cells (Fig. 7). These findings indicate that the PECAM-1 cytoplasmic domain is necessary and sufficient for H₂O₂ current activation.

View larger version (54K): [in this window] [in a new window]   Figure 7. The PECAM-1 cytoplasmic domain is necessary and sufficient for current activation. Schematic representation of wild-type PECAM-1 (expressed endogenously in HUVEC) and mutant PECAM-1 constructs stably transfected into the REN cell line. The extracellular domain containing six Ig-like loops is represented as filled ovals 1–6, the transmembrane domain as a rectangle, and the cytoplasmic domain as a series of boxes representing cytoplasmic exons 9–16. PITC is a chimera containing the intact PECAM-1 extracellular domain fused to the nonhomologous ICAM-1 transmembrane and cytoplasmic domains. IL2PCD is comprised of the intact PECAM-1 cytoplasmic domain fused to the nonhomologous IL2 receptor extracytoplasmic and transmembrane domains. Y663F/Y686F contains dual Y-to-F point mutations in the cytoplasmic Y663/Y686 SH2-interaction motif. Surface PECAM-1 expression relative to HUVEC is shown. Construct ability to mediate H2O2-activated cation signals is indicated.

View larger version (50K): [in this window] [in a new window]   Figure 8. H2O2-activated cation current signals require Src family tyrosine kinase activity. Proportion of voltage-clamped HUVEC (hatched) and RHP cells (spotted) responding to 200 µM H2O2 after 1 h pretreatment with 10 µM genistein or intracellular dialysis with 10 µg/ml Sc-18, an inactivating polyclonal antibody directed against p60 Src tyrosine kinase. Results are compared with nondialysis and anti-HSV TK antibody dialysis controls. Notably, of cells dialyzed with Sc-18, those responding to H2O2 manifested markedly attenuated current amplitude compared with nondialysis and anti-HSV TK controls.

View larger version (47K): [in this window] [in a new window]   Figure 9. The PECAM-1 cytoplasmic Y663/Y686 motif is a substrate for selective H2O2-mediated tyrosine phosphorylation. (A) REN, RHP, Y663F/Y686F, and HUVEC were treated for 10 min with vehicle (lanes 2, 4, 6, 8), 0.5 mM H2O2 (lanes 1, 3, 5, 7) in low serum conditions, or 0.5 mM vanadate (3 h) as a positive control (**). PECAM-1 phosphotyrosine signals were detected by immunoblot with antiphosphotyrosine antibody (mAb 4G10) on anti–PECAM-1 immunoprecipitates (mAb 4G6). (B) REN, RHP, and PITC in low serum conditions were treated with buffer (lanes 10, 14, 17), 200 µM (lanes 11, 15, 18), or 1 mM H2O2 (Lanes 12, 16, 19), for 10 min or 0.5 mM vanadate for 3 h (**). PECAM-1 phosphotyrosine signals were detected with antiphosphotyrosine antibody on anti–PECAM-1 immunoprecipitates. Relative PECAM-1 levels were detected by stripping the membrane and reprobing with mAb 1.3 (anti–PECAM-1) (bottom). PECAM-1 phosphorylation was normalized to PECAM-1 content and compared with baseline phosphorylation (set at 1.0) to yield relative phosphorylation.

	Discussion

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Reactive oxygen species such as hydrogen peroxide are critical mediators of physiologic and pathologic vascular responses after inflammatory, ischemic, and hyperoxic insults. Central to these effects are changes in EC [Ca²⁺]_i, although the molecular interactions underlying H₂O₂ increases in [Ca²⁺]_i are not known. Here we report that physiologically relevant concentrations of H₂O₂ activate Ca²⁺-permeant plasmalemmal cation channels and that this ionic signaling requires PECAM-1 expression. Activation of this current requires the PECAM-1 cytoplasmic Y663/Y686 motif and Src family nonreceptor tyrosine kinase activity, but is independent of IP₃ receptor activation. This is a previously unknown EC function for PECAM-1 that may represent a widespread mechanism linking neutrophil–EC interactions and EC response in the context of oxidant injury and inflammation.

H₂O₂ has been proposed to function as an endothelial signal transduction intermediate at low micromolar concentrations and as a mediator of cell response to pathologic processes at higher concentrations. Although the signaling processes underlying these actions are not well understood, H₂O₂ is known to induce tyrosine phosphorylation through activation of tyrosine kinases and inhibition of protein tyrosine phosphatases (Barchowsky et al., 1995; Carbajal and Schaeffer, 1998), and can activate a range of [Ca²⁺]_i signal responses (Suzucki et al., 1997; Yang et al., 1999; Lounsbury et al., 2000). We observed consistent activation of PECAM-1–dependent cation currents at concentrations of H₂O₂ in excess of 100 µM. At H₂O₂ levels below 100 µM, minimal Ca²⁺ signaling has been reported, whereas sublethal concentrations exceeding 100 µM manifest prolonged, low-amplitude [Ca²⁺]_i transients involving influx of extracellular Ca²⁺ (Bowles et al., 2001). Cytotoxic concentrations exceeding 500 µM result in the activation of phospholipases and release of Ca²⁺ ions from internal calcium stores (Schilling and Elliott, 1992; Natarjan et al., 1993; Barchowsky et al., 1994; Doan et al., 1994; Siflinger-Birnboim et al., 1996; Yolk et al., 1997; Hu et al., 1998; Min et al., 1998). Hydrogen peroxide levels between 200 and 500 µM, although not cytolytic (Shasby et al., 1988), may yield substantial cell toxicity by inducing signal transduction pathways that ultimately lead to apoptosis (Barchowsky et al., 1994; Suhara et al., 1998). Our findings indicate that PECAM-1, a protein highly expressed in ECs, functions as a critical regulator of plasmalemmal ion channels that result in depolarization and Ca²⁺ influx during sublethal hydrogen peroxide exposure. Although PECAM-1 is essential in regulating plasmalemmal cation influx, our results do not exclude other Ca²⁺-mobilizing actions of H₂O₂, particularly at higher H₂O₂ concentrations. We did not observe consistent PECAM-1–dependent cation signaling or tyrosine phosphorylation at H₂O₂ concentrations below 100–200 µM, suggesting that this level of H₂O₂ represents a threshold for PECAM-1–mediated events. Thus, low levels of H₂O₂, such as those endogenously produced as signaling intermediates during ICAM-dependent EC responses to leukocytes (Wang and Doerschuk, 2000), may be PECAM-1 independent. Instead, PECAM-1 appears to function as a calcium-regulating protein at the moderate H₂O₂ levels (100–400 µM) that are generated during EC–neutrophil interaction in the context of inflammation (Test and Weiss, 1984). However, an important caveat in interpreting experiments evaluating H₂O₂ cellular responses is the substantial variability in effective dosage associated with media conditions, particularly serum concentration. For example, it has been reported that H₂O₂ concentration–response relationships may be decreased tenfold relative to serum-free conditions that may support EC morphologic changes after exposure to H₂O₂ levels as low as 20 µM (Bradley et al., 1995).

Although we demonstrate that PECAM-1 is required for H₂O₂ ionic signaling, the identity of the channel and potential linking molecules remain unknown. As the current kinetics, ionic selectivity, and associated [Ca²⁺]_i transients in ECs are indistinguishable when activated by H₂O₂ or PECAM-1 engagement (Gurubhagavatula et al., 1998; O'Brien et al., 2001), it is likely that these phenomena are associated with activation of the same channel(s). Similarly, the failure of PECAM-1 to reconstitute cation signaling in certain cell types suggests that PECAM-1 is not, itself, a channel component (O'Brien et al., 2001). Recently, attention has been directed toward mammalian homologues of the Drosophila transient receptor potential and transient receptor potential–like proteins as possible components in multimeric channels activated by Ca²⁺ store depletion (Xu et al., 1997; Moore et al., 1998; Groschner et al., 1999). As we have previously reported (O'Brien et al., 2001), there is a distinct similarity between PECAM-1–dependent currents and nonspecific cation currents observed in ECs after depletion of Ca²⁺ stores (Vaca and Kunze, 1995; Parekh and Penner, 1997; Kamouchi et al., 1999). Although the H₂O₂-activated current is kinetically similar to store activated currents (Groschner et al., 1999), differences in La³⁺ sensitivity, lack of gating associated with Ca²⁺ depletion, and independence of IP₃ receptor activation (Nilius et al., 1997; Kamouchi et al., 1999) suggest important differences in channel permeability and gating.

Our results are similar to those describing an H₂O₂-activated, store release–independent, plasmalemmal calcium–conducting channel in EC that is gated through an unknown mechanism (Bowles et al., 2001). They are also consistent with reports of a tyrosine kinase–dependent NSC channel activated through engagement of basic FGF (bFGF) or insulin-like growth factor–1 receptors in ECs (Munaron and Pla, 2000). As tyrosine kinase activity is required for both receptor-dependent (bFGF or insulin-like growth factor–1) and independent (H₂O₂ and PECAM-1 ligation) EC Ca⁺² signaling, it is likely that the tyrosine kinase substrate(s) responsible for channel activation are downstream of specific receptors, which are phosphorylated by either mechanism (Fleming et al., 1996). Exposure to phosphatase inhibitors such as vanadate, pervanadate, and H₂O₂ is known to yield selective tyrosine phosphorylation of the PECAM-1 cytoplasmic domain (Sagawa et al., 1997). After tyrosine phosphorylation, PECAM-1 can interact with several SH2 domain–containing proteins, including SHP2, PI3kinase, and PLC- (Newman, 1999), though the physiologic relevance of these interactions in EC is not certain. Similarly, PECAM-1 can function as a reservoir for transcription-regulating proteins such as ß and -catenin in a phosphorylation-dependent manner (Ilan et al., 2000).

Utilizing endothelia-like REN cells stably transfected with wild-type and mutant PECAM-1 constructs, we have begun to conduct a detailed analysis of PECAM-1 structure–function relationships that would be otherwise impossible in ECs. Where possible, we have confirmed these findings in HUVEC. Our data demonstrate that PECAM-1 and likely other participating proteins serve as substrates for H₂O₂-induced tyrosine phosphorylation, that the PECAM-1–regulated current requires Src family nonreceptor tyrosine kinase activity, and that the PECAM-1 cytoplasmic domain (and its incorporated Y663/Y686 phosphotyrosine motif) is necessary and sufficient for H₂O₂-induced current activation (Fig. 10). In confluent cells, full-length PECAM-1, PITC, and Y663F/Y686F localize predominantly to cell–cell borders, whereas IL2PCD is diffusely distributed (Sun et al., 2000). However, the techniques employed in this study do not allow conclusions to be drawn regarding PECAM-1 cell localization requirements for current regulation in confluent monolayers. Similarly, although H₂O₂ activates tyrosine kinases including p60src in ECs (Barchowsky et al., 1995; Carbajal and Schaeffer, 1998), the specific tyrosine kinase(s) mediating H₂O₂-induced PECAM-1 phosphorylation remains an important unresolved question. Interestingly, preliminary data, beyond the scope of this manuscript, suggest that the PECAM-1 transmembrane domain may also play a role in modulating PECAM-1–dependent ionic signals in the absence of an intact cytoplasmic domain (unpublished data). This is consistent with findings that the isolated PECAM-1 transmembrane and cytoplasmic domains function in signal transduction after matrix metalloproteinase–induced extracellular domain cleavage (Ilan et al., 2001). The identification of proteins that have a functional association with PECAM-1 in this response, as well as further delineation of specific tyrosine kinase subtypes underlying H₂O₂-induced PECAM-1 phosphorylation, will be important steps in further defining this unique signaling pathway.

View larger version (35K): [in this window] [in a new window]   Figure 10. Moderate dose H2O2 mediates EC calcium influx through a PECAM-1–regulated NSC channel activated via a tyrosine kinase-dependent, phosphoinositide-independent signaling pathway. After moderate dose hydrogen peroxide (100–400 µM), the PECAM-1 cytoplasmic domain and (most likely) other central downstream components undergo tyrosine phosphorylation, possibly by Src family tyrosine kinases. The tyrosine-phosphorylated PECAM-1 intracellular Y663/Y686 motif then interacts either directly with a plasmalemmal NSC channel or through one or more intermediaries. Alternatively, phosphorylated PECAM-1 may inhibit or sequester a channel suppressor, thus indirectly activating the channel. The PECAM-1–regulated channel is independent of calcium store release or IP3 receptor activation, manifests only partial trivalent cation sensitivity, and is neither [Ca+2]i nor voltage gated, suggesting a calcium signaling pathway distinct from capacitative calcium entry mechanisms. Once activated, this PECAM-1–regulated plasmalemmal channel conducts a prolonged NSC current that mediates the calcium transients observed in ECs and PECAM-1–transfected REN cells following moderate level (100–400 µM) hydrogen peroxide exposure.

	Materials and methods

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Antibodies, reagents, immunoprecipitation, and Western blotting
Antibodies used include the following: mAb 4G6, a murine immunoglobin (IgG) directed against the PECAM-1 extracellular Ig loop six domain (Yan et al., 1995); mAb 1.3, a murine IgG directed against the PECAM-1 extracellular domain, a gift of Dr. Peter Newman (Blood Center of Southeastern Wisconsin, Milwaukee, WI); PCD, a rabbit polyclonal antibody directed against the PECAM-1 cytoplasmic domain; Sc-18 (Santa Cruz Biotechnology), a rabbit polyclonal antibody found to specifically inhibit Src family kinases Src, Yes, Fyn, and Fgr (Marrero et al., 1995); anti-HSVTK, rabbit polyclonal anti-HSVTK antibody (Elshami et al., 1996); anti-IL2 receptor (CD25) mAb 3G10 (Boehringer Mannheim); and 4G10, an anti-phosphotyrosine murine mAb (Upstate Biotechnology). Purified antibodies were obtained by protein G affinity chromatography of hybridoma supernatants or serum. Active binding of antibodies was confirmed by flow cytometry. Reagent grade hydrogen peroxide (Sigma-Aldrich) was diluted in isotonic PBS or media on the day of experiments as indicated. PECAM-1 immunoprecipitation was performed on REN cell lysates incubated with mAb 4G6 or anti-CD25 mAb (Il2PCD) followed by incubation with protein A Sepharose (Amersham Pharmacia Biotech). Lysates were separated on 10% SDS polyacrylamide reducing gels (Invitrogen). Membranes were probed with anti-phosphotyrosine antibody (4G10), counterstained with HRP-conjugated donkey anti–mouse IgG (Cappel), and signals were visualized with ECL (New England Nuclear). Membranes were then stripped per the manufacturer (NEN Life Science Products) and reprobed with mAb 1.3 or PCD and counterstained with donkey anti–mouse or donkey anti–rabbit HRP-conjugated secondary antibody (Cappel). Signals were again detected with ECL. Image capture and densitometry analysis was performed on a Kodak Image Station as per the manufacturer.

Cell lines and mutant PECAM-1 constructs
HUVEC (Clonetics) were cultured in M199 medium (Mediatech, Inc.) supplemented with 15% FBS, 100 µg/ml EC growth factor (Clonetics), 100 ug/ml Heparin (Elkins-Sinn), and 2 mM L-glutamine (GIBCO BRL). Only cells of passage six or less were used. PECAM-1 mutant constructs IL2PCD (Sun et al., 2000), PITC, and Y663F/Y686F, a gift of Dr. P. Newman (Fig. 7) were constructed with the sequence overlap extension technique as previously described (Sun et al., 2000; O'Brien et al., 2001). All full-length and mutant PECAM-1 constructs were subcloned into the pcDNA-neo vector. REN cells, a human mesothelioma cell line previously isolated in our laboratory (Smythe et al., 1994), were grown in RPMI media (Mediatech) supplemented with 10% FBS and 2 mM L-glutamine (R10 media). Stable polyclonal populations of REN cell PECAM-1 transfectants were generated by magnetic bead sorting (Dynal, Inc.) and selected in G418 (0.5 mg/ml) supplemented R10 media as previously described (Gurubhagavatula et al., 1998). Expression was subsequently confirmed by flow cytometry using an EPICS Elite Flow cytometer (Coulter Corporation) as described (O'Brien et al., 2001). All stably transfected cell lines uniformly expressed PECAM-1 at high levels relative to HUVEC (Fig. 7).

Patch clamp recording
Cells were prepared for patch clamp experiments on round 12-mm glass coverslips (Fisher) coated with fibronectin (GIBCO BRL) or 1% gelatin (HUVEC). Treated coverslips were placed in 6-well plates and seeded for 18–24 h with 100,000 cells/well in 3 ml media. Whole-cell currents were recorded utilizing standard whole-cell or perforated patch clamp methods as described previously (O'Brien et al., 2001). Coverslips were transferred to a temperature-controlled chamber maintained at 35°C (Brook Industries), and superfused at 1 ml/min with either HBSS (123 mM NaCl, 2 mM CaCl₂, 1 mM KCl, 25 mM Hepes, and 15 mM glucose, pH 7.4), high-calcium solution (100 mM CaCl₂, 10 mM glucose, 10 mM Hepes, pH 7.4), CsCl solution (130 mM CsCl, 10 mM glucose, 10 mM Hepes, pH 7.4), or Tris-Cl solution (123 mM Tris-HCl, 2 mM CaCl₂, 1 mM KCl, 25 mM Hepes, and 15 mM glucose, pH 7.4) as indicated. Borosilicate glass electrodes (resistance 3–5 Mohm) were filled with internal solution containing 130 mM CsCl, 1.2 mM MgCl₂, 0.075 mM EGTA, 1 mM Mg-ATP, and 10 mM Hepes, except for asymmetric anion experiments in which 130 mM CsAcetate was substituted for CsCl as indicated. For perforated patch experiments, pipettes were dipped 1–2 s in pipette solution then backfilled with pipette solution containing 200 mg/ml nystatin. After seal formation and establishment of whole-cell recording configuration, cells were voltage clamped at –60 mV (Axopatch 200B; Axon Instruments). Records were sampled at 1 kHz and filtered at 100 Hz. Current reversal potentials were measured either by step or ramp (-60 up to +100 mV applied every 30 s) depolarization protocols. Only current traces returning to baseline were considered. Hydrogen peroxide solution was puffed directly onto cells through puffer pipettes (Picospritzer; General Valve). EGTA, heparin, and antibody dialysis experiments were conducted with 10 mM EGTA (Sigma-Aldrich), 5 mg/ml heparin sulfate, or 10 µg/ml of PCD, Sc-18, or anti-thymidine kinase antibody added to the pipette solution. LaCl₃ inhibition experiments were performed with varying concentrations of LaCl₃ (0–100 µM) in HBSS extracellular solution puffed directly onto cells after agonist stimulation with H₂O₂ or thrombin. Cells were equilibrated for 10 min after break-in before initiating experimental protocols (Davis and Sharma, 1997; Wang and Kotlikoff, 1997).

Calcium measurements
Cells were incubated with 10 µM Fluo-4 AM (Molecular Probes) for 10 min at room temperature in a recording chamber mounted on an inverted microscope (TE300; Nikon), and washed with HBSS extracellular solution for 30 min. Fluo-4 fluorescence was recorded using a laser scanning confocal head (Radiance 2000; Bio-Rad Laboratories) attached to an inverted microscope with a plan-apo 60x water immersion objective (1.2 n.a.; Nikon). Cells were excited with 488 nm light from a krypton/argon laser and x-y images (128 x 30 pixels) recorded using Lasersharp software (Bio-Rad Laboratories) at a 44-ms interval. Images were analyzed using LaserPix version 4.2 software (Bio-Rad Laboratories). Fluorescence profiles were obtained by computing the mean fluorescence from a region of the cell (F) for each image and dividing this by the mean fluorescence of the cell prior to stimulation (F_o).

	Footnotes

 
G. Ji and C.D. O'Brien contributed equally to this work.

^* Abbreviations used in this paper: EC, endothelial cell; HSVTK, herpes simplex virus thymidine kinase; HUVEC, human umbilical vein endothelial cell(s); IgG, immunoglobin; IL, interleuken; IP₃, inositol trisphosphate; LaCl_3, lanthanum chloride; NSC, nonselective cation; PCD, PECAM cytoplasmic domain; PECAM, platelet endothelial cell adhesion molecule; SOC, store-operated channel.

	Acknowledgments

 
We thank Dr. Peter Newman for the gift of the PITC and Y663F/Y68F cDNA.

This project was supported by American Heart Association grant #0160343U and National Institutes of Health grants HL49591 and HL04248.

Submitted: 11 October 2001

Revised: 30 January 2002

Accepted: 25 February 2002

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