The GPIbα–thrombin interaction: far from crystal clear

Platelet-Activation Mechanisms and Vascular Remodeling

This overview article for the Comprehensive Physiology collection is focused on detailing platelets, how platelets respond to various stimuli, how platelets interact with their external biochemical environment, and the role of platelets in physiological and pathological processes. Specifically, we will discuss the four major functions of platelets: activation, adhesion, aggregation, and inflammation. We will extend this discussion to include various mechanisms that can induce these functional changes and a discussion of some of the salient receptors that are responsible for platelets interacting with their external environment. We will finish with a discussion of how platelets interact with their vascular environment, with a special focus on interactions with the extracellular matrix and endothelial cells, and finally how platelets can aid and possibly initiate the progression of various vascular diseases. Throughout this overview, we will highlight both the historical investigations into the role of platelets in health and disease as well as some of the more current work. Overall, the authors aim for the readers to gain an appreciation for the complexity of platelet functions and the multifaceted role of platelets in the vascular system. © 2017 American Physiological Society. Compr Physiol 8:1117-1156, 2018.

Molecular cloning and characterization of rhesus monkey platelet glycoprotein Ibα, a major ligand-binding subunit of GPIb-IX-V complex

INTRODUCTION

Through binding to von Willebrand factor (VWF), platelet glycoprotein (GP) Ibα, the major ligand-binding subunit of the GPIb-IX-V complex, initiates platelet adhesion and aggregation in response to exposed VWF or elevated fluid-shear stress. There is little data regarding non-human primate platelet GPIbα. This study cloned and characterized rhesus monkey (Macaca Mullatta) platelet GPIbα.

MATERIALS AND METHODS

DNAMAN software was used for sequence analysis and alignment. N/O-glycosylation sites and 3-D structure modelling were predicted by online OGPET v1.0, NetOGlyc 1.0 Server and SWISS-MODEL, respectively. Platelet function was evaluated by ADP- or ristocetin-induced platelet aggregation.

RESULTS

Rhesus monkey GPIbα contains 2,268 nucleotides with an open reading frame encoding 755 amino acids. Rhesus monkey GPIbα nucleotide and protein sequences share 93.27% and 89.20% homology respectively, with human. Sequences encoding the leucine-rich repeats of rhesus monkey GPIbα share strong similarity with human, whereas PEST sequences and N/O-glycosylated residues vary. The GPIbα-binding residues for thrombin, filamin A and 14-3-3ζ are highly conserved between rhesus monkey and human. Platelet function analysis revealed monkey and human platelets respond similarly to ADP, but rhesus monkey platelets failed to respond to low doses of ristocetin where human platelets achieved 76% aggregation. However, monkey platelets aggregated in response to higher ristocetin doses.

CONCLUSIONS

Monkey GPIbα shares strong homology with human GPIbα, however there are some differences in rhesus monkey platelet activation through GPIbα engagement, which need to be considered when using rhesus monkey platelet to investigate platelet GPIbα function.

Binding of alpha-thrombin to surface-anchored platelet glycoprotein Ib(alpha) sulfotyrosines through a two-site mechanism involving exosite I

The involvement of exosite I in α-thrombin (FIIa) binding to platelet glycoprotein Ibα (GPIbα), which could influence interactions with other substrates, remains undefined. To address the problem, we generated the GPIbα amino terminal domain (GPIbα-N) fully sulfated on three tyrosine residues and solved the structure of its complex with FIIa. We found that sulfotyrosine (Tys) 278 enhances the interaction mainly by establishing contacts with exosite I. We then evaluated how substituting tyrosine with phenylalanine, which cannot be sulfated, affects FIIa binding to soluble or surface-immobilized GPIbα-N. Mutating Tyr(276), which mostly contacts exosite II residues, markedly reduced FIIa interaction with both soluble and immobilized GPIbα-N; mutating Tyr(278) or Tyr(279), which mostly contact exosite I residues, reduced FIIa complexing in solution by 0-20% but affinity for immobilized GPIbα-N 2 to 6-fold, respectively. Moreover, three exosite I ligands--aptamer HD1, hirugen, and lepirudin--did not interfere with soluble FIIa complexing to GPIbα-N, excluding that their binding caused allosteric effects influencing the interaction; nonetheless, all impaired FIIa binding to immobilized GPIbα-N and platelet GPIb nearly as much as aptamer HD22 and heparin, both exosite II ligands. Bound HD1 and hirugen alter Trp(148) orientation in a loop near exosite I preventing contacts with the sulfate oxygen atoms of Tys(279). These results support a mechanism in which binding occurs when the two exosites of one FIIa molecule independently interact with two immobilized GPIbα molecules. Through exosite engagement, GPIbα may influence FIIa-dependent processes relevant to hemostasis and thrombosis.

Unravelling the mechanism and significance of thrombin binding to platelet glycoprotein Ib

The main question concerning the mechanism of a-thrombin binding to platelet membrane glycoprotein (GP)Ib is whether it involves both thrombin exosite I and exosite II. The solution of two independent crystal structures suggests alternative explanations that may actually reflect different modes of binding with distinct pathophysiological significance. With respect to function, it is still unclear whether thrombin binding to GPIb promotes procoagulant and prothrombotic pathways of response to vascular injury or limits such responses by sequestering, at least temporarily, the active enzyme. We review here published information on these topics and touch upon ongoing studies aimed at finding definitive answers to outstanding questions relevant for a better understanding of thrombosis and haemostasis.

Biophysical investigation of GpIbalpha binding to thrombin anion binding exosite II

Substrates and cofactors of the serine protease thrombin (IIa) employ two anion binding exosites (ABE-I and -II) to aid in binding. On the surface of platelets resides the GpIbalpha/beta-GpIX-GpV membrane-bound receptor complex. IIa's ABE-II is proposed to interact with an anionic portion of GpIbalpha which enhances IIa cleavage of PAR-1 and subsequent activation of platelets. In this work, one-dimensional (1D) and two-dimensional (2D) NMR, analytical ultracentrifugation (AUC), and hydrogen-deuterium exchange (HDX) coupled with MALDI-TOF MS were performed to further characterize the features of binding to IIa's ABEs. The described work builds upon investigations performed in a prior study with fibrin(ogen)'s gamma' peptide and IIa [Sabo, T. M., Farrell, D. H., and Maurer, M. C. (2006) Biochemistry 45, 7434-7445]. 1D line broadening NMR (1H and 31P) and 2D trNOESY NMR studies indicate that GpIbalpha residues D274-E285 interact extensively with the IIa surface in an extended conformation. AUC demonstrates that both GpIbalpha (269-286) and gamma' (410-427) peptides interact with IIa with a 1:1 stoichiometry. When the HDX results are compared to those for the ABE-I targeting peptide hirudin (54-65), the data imply that GpIbalpha (269-286), GpIbalpha (1-290), and gamma' (410-427) are indeed directed to ABE-II. The ABE-II binding fragments reduce HDX for sites distant from the interface, suggesting long-range conformational effects. These studies illustrate that GpIbalpha and gamma' target ABE-II with similar consequences on IIa dynamics, albeit with differing structural features.

Crystallography and protein–protein interactions: biological interfaces and crystal contacts

Crystallography is commonly used for studying the structures of protein–protein complexes. However, a crystal structure does not define a unique protein–protein interface, and distinguishing a ‘biological interface’ from ‘crystal contacts’ is often not straightforward. A number of computational approaches exist for distinguishing them, but their error rate is high, emphasizing the need to obtain further data on the biological interface using complementary structural and functional approaches. In addition to reviewing the computational and experimental approaches for addressing this problem, we highlight two relevant examples. The first example from our laboratory involves the structure of acyl-CoA thioesterase 7, where each domain of this two-domain protein was crystallized separately, but both yielded a non-functional assembly. The structure of the full-length protein was uncovered using a combination of complementary approaches including chemical cross-linking, analytical ultracentrifugation and mutagenesis. The second example involves the platelet glycoprotein Ibα–thrombin complex. Two groups reported the crystal structures of this complex, but all the interacting interfaces differed between the two structures. Our computational analysis did not fully resolve the reasons for the discrepancies, but provided interesting insights into the system. This review highlights the need to complement crystallographic studies with complementary experimental and computational approaches.

In vivo relevance for platelet glycoprotein Ibalpha residue Tyr276 in thrombus formation

BACKGROUND

Platelet glycoprotein (GP) Ib-IX-V supports platelet adhesion on damaged vascular walls by binding to von Willebrand factor (VWF). For several decades it has been recognized that the alpha-subunit of GP (GPIbalpha) also binds thrombin but the physiological relevance, if any, of this interaction was unknown. Previous studies have shown that a sulfated tyrosine 276 (Tyr276) is essential for thrombin binding to GPIbalpha.

OBJECTIVES

This study investigated the in vivo relevance of GPIbalpha residue Tyr276 in hemostasis and thrombosis.

METHODS

Transgenic mouse colonies expressing the normal human GPIbalpha subunit or a mutant human GPIbalpha containing a Phe substitution for Tyr276 (hTg(Y276F)) were generated. Both colonies were bred to mice devoid of murine GPIbalpha.

RESULTS

Surface-expressed GPIbalpha levels and platelet counts were similar in both colonies. hTg(Y276F) platelets were significantly impaired in binding alpha-thrombin but displayed normal binding to type I fibrillar collagen and human VWF in the presence of ristocetin. In vivo thrombus formation as a result of chemical damage (FeCl(3)) demonstrated that hTg(Y276F) mice have a delayed time to occlusion followed by unstable blood flow indicative of embolization. In models of laser-induced injury, thrombi developing in hTg(Y276F) animals were also less stable.

CONCLUSIONS

The results demonstrate that GPIbalpha residue Tyr276 is physiologically important, supporting stable thrombus formation in vivo.

Programmed autologous cleavage of platelet receptors

Platelet adhesion receptors play a critical role in vascular pathophysiology, and control platelet adhesion, activation and aggregation in hemostasis, thrombotic disease and atherogenesis. One of the key emerging mechanisms for regulating platelet function is the programmed autologous cleavage of platelet receptors. Induced by ligand binding or platelet activation, proteolysis at extracellular (ectodomain shedding) or intracellular (cytoplasmic domain deactivation) sites down-regulates the adheso-signaling function of receptors, thereby controlling not only platelet responsiveness, but in the case of ectodomain shedding, liberating soluble ectodomain fragments into plasma where they constitute potential modulators or markers. This review discusses the underlying mechanisms for dual proteolytic pathways of receptor regulation, and the impact of these pathways on thrombus formation and stability in vivo.

Platelet Receptor Proteolysis

The platelet plasma membrane is literally at the cutting-edge of recent research into proteolytic regulation of the function and surface expression of platelet receptors, revealing new mechanisms for how the thrombotic propensity of platelets is controlled in health and disease. Extracellular proteolysis of receptors irreversibly inactivates receptor-mediated adhesion and signaling, as well as releasing soluble fragments into the plasma where they act as potential markers or modulators. Platelet-surface sheddases, particularly of the metalloproteinase-disintegrin (ADAM) family, can be regulated by many of the same mechanisms that control receptor function, such as calmodulin association or activation of signaling pathways. This provides layers of regulation (proteinase and receptor), and a higher order of control of cellular function. Activation of pathways leading to extracellular shedding is concomitant with activation of intracellular proteinases such as calpain, which may also irreversibly deactivate receptors. In this review, platelet receptor shedding will be discussed in terms of (1) the identity of proteinases involved in receptor proteolysis, (2) key platelet receptors regulated by proteolytic pathways, and (3) how shedding might be regulated in normal physiology or future therapeutics. In particular, a focus on proteolytic regulation of the platelet collagen receptor, glycoprotein (GP)VI, illustrates many of the key biochemical, cellular, and clinical implications of current research in this area.

Thrombin induces GPIb-IX-mediated fibrin binding to alphaIIbbeta3 in a reconstituted Chinese hamster ovary cell model

BACKGROUND

The interaction of thrombin with platelet glycoprotein (GP) Ib-IX-V has been recently suggested to induce fibrin-dependent platelet aggregation associated with signaling events. The approaches used to avoid the protease-activated receptor (PAR) thrombin receptors in platelets have provided controversial conclusions regarding the precise mechanism and molecules involved in the response.

OBJECTIVES

In the present study, we developed a cellular model to investigate the functional consequences following the binding of thrombin to GPIb-IX.

METHODS

We used Chinese hamster ovary (CHO) cells stably expressing human alpha(IIb)beta(3) and/or GPIb-IX complexes (CHO-alpha(IIb)beta(3)-IbIX cells) to analyze the effect of thrombin on the binding of polymerizing fibrin by using fluorescein isothiocyanate-fibrinogen as precursor.

RESULTS

Thrombin induces, in a dose-dependent manner, the binding of polymerizing fibrin to CHO-alpha(IIb)beta(3)-IbIX cells. This response is not observed in cells expressing only one of the receptors, and it can be blocked by monoclonal antibodies against alpha(IIb)beta(3) and GPIbalpha. We show that the reaction is not due to simple cell trapping by the fibrin clot, and provide data supporting a role of a signaling pathway in which the 14-3-3zeta adaptor and calcium-calmodulin-dependent events are involved.

CONCLUSIONS

The present data support a significant role of GPIb-IX and alpha(IIb)beta(3) receptors in an alternative fibrin-mediated pathway of platelet activation induced by thrombin.

Glycoprotein Ibα–Mediated Platelet Adhesion and Aggregation to Immobilized Thrombin Under Conditions of Flow

OBJECTIVE

Thrombin interacts with platelets via the protease-activated receptors (PARs) 1 and 4, and via glycoprotein Ibalpha (GPIbalpha). Recently, it was shown that platelets are able to adhere to immobilized thrombin under static conditions via GPIbalpha.

METHODS AND RESULTS

Here, we show that platelets are also able to adhere to and form stable aggregates on immobilized thrombin under conditions of flow. Adhesion and aggregation to thrombin was dependent on the interaction with GPIbalpha, as addition of glycocalicin or an antibody blocking the interaction between thrombin and GPIbalpha inhibited platelet adhesion. Additionally, platelet adhesion to recombinant thrombin mutants, which are unable to bind GPIbalpha, was severely suppressed. Furthermore, platelet adhesion to thrombin was dependent on activation of PARs, and partly on granule secretion and thromboxane-A2 synthesis. Immobilization of thrombin on a fibrin network resulted in substantially increased adhesion compared with fibrin alone. The adhesion to fibrin alone was completely abolished by addition of dRGDW, whereas fibrin-bound thrombin still showed substantial platelet adhesion in the presence of dRGDW, indicating that fibrin-bound thrombin is able to directly capture platelets under flow.

CONCLUSIONS

These results indicate that platelets are able to adhere to thrombin under flow conditions, which is dependent on the interaction with GPIbalpha.

Structure and interaction modes of thrombin

Any vascular injury triggers the burst-like release of the trypsin-like serine proteinase alpha-thrombin. Thrombin, the main executioner of the coagulation cascade, exhibits procoagulant as well as anticoagulant and antifibrinolytic properties, very specifically interacting with a number of protein substrates, receptors, cofactors, inhibitors, carbohydrates, and modulators. A large number of crystal structures of alpha-thrombin have shown that the thrombin surface can be subdivided into several functional regions, which recognize different substrates, inhibitors, and mediators with high specificity.

Molecular recognition mechanisms of thrombin

Thrombin is the final protease generated in the blood coagulation cascade, and is the only factor capable of cleaving fibrinogen to create a fibrin clot. Unlike every other coagulation protease, thrombin is composed solely of its serine protease domain, so that once formed it can diffuse freely to encounter a large number of potential substrates. Thus thrombin serves many functions in hemostasis through the specific cleavage of at least a dozen substrates. The solution of the crystal structure of thrombin some 15 years ago revealed a deep active site cleft and two adjacent basic exosites, and it was clear that thrombin must utilize these unique features in recognizing its substrates. Just how this occurs is still being investigated, but recent data from thrombin mutant libraries and crystal structures combine to paint the clearest picture to date of the molecular determinants of substrate recognition by thrombin. In almost all cases, both thrombin exosites are involved, either through direct interaction with the substrate protein or through indirect interaction with a third cofactor molecule. The purpose of this article is to summarize recent biochemical and structural data in order to provide insight into the thrombin molecular recognition events at the heart of hemostasis.

How does agkicetin-C bind on platelet glycoprotein Ibalpha and achieve its platelet effects?

The platelet glycoprotein (GP) Ib-IX-V receptor complex has a central role in primary haemostasis and possesses binding sites for the plasmatic adhesive protein von Willebrand Factor (VWF) and thrombin. Several snake venom components have been identified in recent years that target this receptor complex and modulate its functionality. Among them, agkicetin-C is from Deinagkistrodon acutus and proved to be a potent antagonist of GPIb-IX-V. We further studied the structure-activity relationships of agkicetin-C in order to reveal the molecular mechanisms of its antagonistic effect. Agkicetin-C concentration-dependently inhibited botrocetin-, ristocetin- and low dose thrombin- (0.32-0.4nM) induced platelet aggregation. Moreover, it abolished platelet adhesion to collagen under high shear conditions (2600/s), while having only minor effects at low shear rate (650/s), which suggested it targets mainly GPIbalpha instead of other platelet glycoproteins. The interaction site of agkicetin-C was further refined: it recognizes a linear sequence in a recombinant GPIbalpha (AA1-289) fragment and inhibited completely the ristocetin-induced VWF binding to this fragment. Using cross-blocking studies with epitope-mapped anti-GPIbalpha monoclonal antibodies, the binding region of agkicetin-C was refined to the AA201-282 region. In conclusiong the C-type lectin agkicetin-C is a potent GPIb-IX-V antagonist, inhibiting both VWF and thrombin interaction through binding to the AA201-282 region in GPIbalpha. Another thing of interest is that, although agkicetin-C did not agglutinate platelets in all conditions tested in vitro, it caused a severe thrombocytopenia in rats, suggesting a different mechanism than with flavocetin-A or echicetin.

Platelet physiology and thrombosis

Glycoprotein (GP) Ibalpha of the GPIb-IX-V complex and GPVI bind von Willebrand factor (vWF) and collagen, respectively, and are critical for the initial interaction of circulating platelets with the injured vessel wall under high shear conditions. These interactions act together to facilitate stable thrombus formation in vivo. Ligand binding to GPIb-IX-V of the leucine-rich repeat family or GPVI of the immunoglobulin superfamily initiates platelet activation, and inside-out activation of the platelet integrin, alphaIIbbeta3, that binds vWF or fibrinogen and mediates platelet aggregation. The binding site for GPIbalpha on vWF resides in the conserved A1 domain, encompassing the disulfide bond at Cys509-Cys695. This domain may be activated to bind platelet GPIbalpha under shear stress by anchoring of the downstream A3 domain to collagen and conformational distortion of the intervening A2 domain. The N-terminal, 282 residues, of GPIbalpha contains the binding site for vWF-A1, as well as the conserved A-type domain of the leukocyte integrin alphaMbeta2 (alphaM I domain) and P-selectin expressed on activated platelets or endothelial cells. Endothelial P-selectin also supports surface expression of vWF multimers, enabling platelet vessel wall interaction by at least two mechanisms. Recent evidence suggests GPVI that binds collagen, and GPIb-IX-V that binds collagen-bound vWF are physically associated on the platelet surface. This review will focus on the structure-function of primary platelet adhesion receptors, GPIb-IX-V and GPVI, and how they act together to regulate platelet thrombus formation in pathophysiology.

Primary Platelet Adhesion Receptors

Thrombotic diseases such as heart attack and stroke remain a major health concern in the Western world despite existing anti-thrombotic drugs. Current studies are revealing structure-function relationships of primary platelet adhesion receptors mediating adhesion, activation and aggregation, and the molecular mechanisms underlying platelet thrombus formation. Platelet adhesion is relevant not only to thrombotic disease, but there is increasing evidence of a specific role for platelets in vascular processes such as inflammation and atherogenesis. This review focuses on recent advances in understanding the molecular basis for platelet thrombus formation, in particular the receptors, glycoprotein (GP)Ib-IX-V and GPVI, that initiate platelet adhesion and activation at high shear stress.