Human Neutrophil Elastase Proteolytically Activates the Platelet Integrin αIIbβ3 through Cleavage of the Carboxyl Terminus of the αIIb Subunit Heavy Chain

Si‐Tahar, Mustapha; Pidard, Dominique; Balloy, Viviane; Moniatte, Marc; Kieffer, Nelly; Dorsselaer, Alain Van; Chignard, Michel

doi:10.1074/jbc.272.17.11636

Cited by 71 publications

(61 citation statements)

References 60 publications

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“…Prevention of this endoproteolytic cleavage by mutagenesis abrogated ␣6␤1 activation by phorbol myristate acetate (31). Neutrophil elastase cleaves ␣IIb between Val 837 and Asp 838 , close to the endoproteolytic cleavage site in the calf-2 domain (32). Although the elastase does not, by itself, induce platelet aggregation, it greatly potentiates ␣IIb␤3 activation by cathepsin G and Mn 2ϩ (17,33).…”

Section: Discussionmentioning

confidence: 99%

Membrane-proximal α/β Stalk Interactions Differentially Regulate Integrin Activation

Kamata¹,

Handa²,

Sato³

et al. 2005

Journal of Biological Chemistry

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The affinity of integrin-ligand interaction is regulated extracellularly by divalent cations and intracellularly by inside-out signaling. We report here that the extracellular, membrane-proximal ␣/␤ stalk interactions not only regulate cation-induced integrin activation but also play critical roles in propagating inside-out signaling. Two closely related integrins, ␣IIb␤3 and ␣V␤3, share high structural homology and bind to similar ligands in an RGD-dependent manner. Despite these structural and functional similarities, they exhibit distinct responses to Mn 2؉ . Although ␣V␤3 showed robust ligand binding in the presence of Mn 2؉ , ␣IIb␤3 showed a limited increase but failed to achieve full activation. Swapping ␣ stalk regions between ␣IIb and ␣V revealed that the ␣ stalk, but not the ligand-binding head region, was responsible for the difference. A series of ␣IIb/␣V domain-swapping chimeras were constructed to identify the responsible domain. Surprisingly, the minimum component required to render ␣IIb␤3 susceptible to Mn 2؉ activation was the ␣V calf-2 domain, which does not contain any divalent cation-binding sites. The calf-2 domain makes interface with ␤ epidermal growth factor 4 and ␤ tail domain in three-dimensional structure. The effect of calf-2 domain swapping was partially reproduced by mutating the specific amino acid residues in the calf-2/epidermal growth factor 4-␤ tail domain interface. When this interface was constrained by an artificially introduced disulfide bridge, the Mn 2؉ -induced ␣V␤3-fibrinogen interaction was significantly impaired. Notably, a similar disulfide bridge completely abrogated fibrinogen binding to ␣IIb␤3 when ␣IIb␤3 was activated by cytoplasmic tail truncation to mimic inside-out signaling. Thus, disruption/formation of the membraneproximal ␣/␤ stalk interface may act as an on/off switch that triggers integrin-mediated bidirectional signaling.Integrins are a family of ␣/␤ heterodimeric transmembrane cell surface receptors that mediate cell-extracellular matrix and cell-cell interactions. The hallmark of integrin-dependent adhesive interaction is its regulation by intracellular signaling events (inside-out signaling) and by divalent cations. In addition to mediating adhesive interactions, liganded integrins initiate signals inside the cell to modify cell behavior (outside-in signaling) and thus play fundamental roles in numerous biological processes such as differentiation, cell survival, apoptosis, and cell motility (1). Integrin-mediated bidirectional signaling is accompanied by conformational change of the integrin structure. The crystal structure of ␣V␤3 extracellular domains revealed an unexpected bent conformer distinct from the extended conformer observed under electron microscope (2, 3). High-resolution electron microscopic observation on truncated recombinant ␣V␤3 has confirmed the presence of both conformers, suggesting that the transition from one conformer to another might take place under physiological conditions (4). However, integrin extension per se is not requ...

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Section: Discussionmentioning

confidence: 99%

Membrane-proximal α/β Stalk Interactions Differentially Regulate Integrin Activation

Kamata¹,

Handa²,

Sato³

et al. 2005

Journal of Biological Chemistry

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“…However, when neutrophils were mixed with platelets under conditions that induced degranulation, and in the presence of TRAP to activate platelets and cause P-selectin surface expression, we saw evidence of proteolysis of only PSGL-1. Several reports have demonstrated an ability of cathepsin G [40][41][42] and elastase 42,43 to act on platelets in washed platelet systems in a rapid proteolytic fashion; however, platelet P-selectin has not previously been shown to be a substrate for cathepsin G or elastase. Results presented here suggest that in purified systems, cathepsin G and elastase can both use PSGL-1 and P-selectin as substrates.…”

Section: Discussionmentioning

confidence: 99%

Regulation of P-selectin binding to the neutrophil P-selectin counter-receptor P-selectin glycoprotein ligand-1 by neutrophil elastase and cathepsin G

Gardiner

Luca

McNally

et al. 2001

Blood

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In the inflammatory response, leukocyte rolling before adhesion and transmigration through the blood vessel wall is mediated by specific cell surface adhesion receptors. Neutrophil rolling involves the interaction of P-selectin expressed on activated endothelium and its counter-receptor on neutrophils, P-selectin glycoprotein ligand-1 (PSGL-1). Here, it is reported that P-selectin binding to neutrophils is lost under conditions that cause the release of proteinases from neutrophil primary granules. Treatment of neutrophils with the purified neutrophil granule proteinases, cathepsin G and elastase, rapidly abolished their capacity to bind P-selectin. This inactivation corresponded to loss of the N-terminal domain of PSGL-1, as assessed by Western blot analysis. A loss of intact PSGL-1 protein from the surfaces of neutrophils after the induction of degranulation was also detected by Western blot analysis. Cathepsin G initially cleaved near the PSGL-1 N-terminus, whereas neutrophil elastase predominantly cleaved at a more C-terminal site within the protein mucin core. Consistent with this, cathepsin G cleaved a synthetic peptide based on the PSGL-1 N-terminus between Tyr-7/Leu-8. Under conditions producing neutrophil degranulation in incubations containing mixtures of platelets and neutrophils, the loss of PSGL-1, but not P-selectin, from plateletneutrophil lysates was detected. Cathepsin G-or neutrophil elastase-mediated PSGL-1 proteolysis may constitute a potential autocrine mechanism for downregulation of neutrophil adhesion to P-selectin. IntroductionRecruitment of neutrophils to inflammatory sites is initiated by rolling of circulating cells on activated endothelium before firmer adhesion and subsequent transmigration. [1][2][3][4] Neutrophil rolling is mediated predominantly by expression of adhesive receptors of the selectin family on activated endothelial cells. 5,6 P-selectin is stored on Weibel-Palade body membranes and rapidly expressed on the surface of activated endothelial cells; E-selectin expression is induced in response to inflammatory stimuli. The counter-receptor for P-selectin on neutrophils is P-selectin glycoprotein ligand-1 (PSGL-1), an approximately 220-kd glycoprotein homodimer. The mature protein consists of an extracellular N-terminal anionic sequence containing 1 to 3 sulfated tyrosine residues (Gln-1-Glu-20), a sialomucin domain, a transmembrane domain, and a cytoplasmic tail. 7,8 Several lines of evidence have shown that the sulfated N-terminal sequence of PSGL-1 is critical for P-selectin binding. We found that a cobra venom metalloproteinase, mocarhagin, abolished P-selectin binding to neutrophils by selectively cleaving P-selectin between Tyr-10 and Asp-11. 9 Further, P-selectin binding to recombinant PSGL-1 was dependent on coexpression with tyrosylsulfate sulfotransferase, whereas blocking sulfation of the recombinant receptor inhibited ligand binding. [10][11][12] After initial rolling, tight adhesion of arrested neutrophils is regulated by other adhesion receptors, in particul...

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“…In this respect, it is remarkable that, although the M3 epitope is always exposed, the epitope for PMI-1, an antibody directed against the very same end of the C terminus of ␣ IIbH , is fully exposed only after platelet aggregation and fibrinogen binding, after RGD peptide binding, or when the divalent ion concentration is Ͻ10 M (1). Similarly, selective removal of the C-terminal end of ␣ IIbH by ␣-chymotrypsin or neutrophil elastase seems to be related to the activation of platelets and fibrinogen binding (46).…”

Section: Immunoinhibition Of In Vitro Platelet Aggregation By Anti-␣ mentioning

confidence: 99%

Agonist-specific Structural Rearrangements of Integrin αIIbβ3

Calzada

Álvarez

2002

Journal of Biological Chemistry

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Concrete structural features of integrin ␣-287), demonstrate the existence of ␣ IIb ␤ 3 agonist-specific activation states, explain the specificity for ligand binding and functional inhibition for some agonists, and predict the existence of agonist-specific final effectors and receptor activation mechanisms. The distinct non-reciprocal competition patterns observed at rest and after activation support the agonist-specific activation states and the existence of intrasubunit and intersubunit allosteric effects, previously proposed as the mechanism for ␣ IIb ␤ 3 transmembrane activation.Integrin ␣ IIb ␤ 3 , a 230-kDa Ca 2ϩ -dependent heterodimeric protein peculiar to megakaryocytes and blood platelets, serves as the receptor for fibrinogen and other adhesive proteins upon platelet stimulation; also known as glycoprotein IIb/IIIa, it plays a crucial role in platelet adhesion to and spreading on the subendothelium, platelet aggregation, and clot retraction (1-3).The genetic, biochemical, immunochemical, molecular dynamic, functional, pathological, and pharmacological characterization of ␣ IIb ␤ 3 is more advanced than similar knowledge about any other member of the integrin family. To acquire the receptor capacity (viz. recognition and binding of adhesive proteins), ␣ IIb ␤ 3 requires some induction mechanism to take place, which is physiologically linked to platelet activation by a variety of agonists and whose final step consists most probably of a change in the quaternary structure of the integrin (4).At present, the best molecular picture of ␣ IIb ␤ 3 in solution is that derived from protein chemical analysis (5-10); x-ray crystallography of the extracellular domain of ␣ v ␤ 3 (11) and the NMR structure of the epidermal growth factor-3 domain of ␤ 2 (12); mapping of antibody epitopes (13), ligand-mimetic crosslinking sites (10,14), and natural and site-directed mutations (15, 16); electron microscopy (17); and molecular size and shape (18). Integrins in solution appear in electron micrographs as a globular head with two legs, with the total length from tip to tip including the globular head being ϳ40 nm. The legs of ␣ IIb ␤ 3 are flexible and emerge from the same side of the head, with their tips either separated but never reaching a diametrical disposition (the head-free tail shapes), touching (the empty oval shapes) or overlapping (the bilobular shapes) each other, or fully folded on themselves and on the head (the filled globular shapes) (18). This high degree of flexibility of the tails of the heterodimer, seen in electron micrographs and deduced from the crystallographic structure, accounts for the short rotational correlation times measured in Triton X-100 solutions by time-resolved fluorescence anisotropy.1 Given its high segmental mobility, ␣ IIb ␤ 3 should adopt a large variety of shapes also in the membrane, where its lateral and rotational mobility has been measured (19,20). The integrin model that locates the subunit N-terminal domains at the globular head and the transmembrane and cytoplasmic domains...

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Human Neutrophil Elastase Proteolytically Activates the Platelet Integrin αIIbβ3 through Cleavage of the Carboxyl Terminus of the αIIb Subunit Heavy Chain

Cited by 71 publications

References 60 publications

Membrane-proximal α/β Stalk Interactions Differentially Regulate Integrin Activation

Membrane-proximal α/β Stalk Interactions Differentially Regulate Integrin Activation

Regulation of P-selectin binding to the neutrophil P-selectin counter-receptor P-selectin glycoprotein ligand-1 by neutrophil elastase and cathepsin G

Agonist-specific Structural Rearrangements of Integrin αIIbβ3

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