Haematologica, Vol 95, Issue 7, 1049-1051 doi:10.3324/haematol.2010.024893
Copyright © 2010 by Ferrata Storti Foundation

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Editorials and Perspectives

Regulation of platelet β3 integrins

Joel S. Bennett¹, David T. Moore²

¹ Hematology-Oncology Division, Department of Medicine and
² Department of Biochemistry/Biophysics, University of Pennsylvania School of Medicine, Philadelphia, PA, USA. E-mail: bennetts{at}mail.med.upenn.edu

In this issue of the journal, Jayo et al. report a heterozygous de novo L718P mutation in the β3 integrin cytoplasmic domain of a woman with a life-long history of severe mucocutaneous bleeding.¹ Although aspects of the patient’s platelet function differ from those of patients with classic Glanzmann’s thrombasthenia, the location of the mutation focuses attention on the importance of cytoplasmic domains in regulating IIbβ3 function.

Integrins are a family of heterodimeric adhesion receptors that reside on cell surfaces in a finely-tuned equilibrium between resting low affinity and active high affinity conformations.² This equilibrium is particularly important for platelets. When platelets encounter vascular damage, the integrin lIbβ3 is rapidly shifted from its inactive to its active conformation, enabling it to bind soluble ligands such as fibrinogen and von Willebrand factor and initiate platelet aggregation.³ However, on circulating platelets, IIbβ3 is maintained in its inactive conformation to prevent the spontaneous formation of intravascular platelet thrombi.

Crystal structures of the extracellular portion of IIbβ3,⁴ and of the homologous integrin vβ3,⁵ revealed that the molecules in the crystals were severely bent, whereas electron microscopy of the active molecules revealed extended structures, implying that large conformational changes occur upon IIbβ3 and vβ3 activation.^6,7 This global rearrangement is initiated by signals generated in the platelet cytoplasm. The signals are then transmitted across the platelet plasma membrane via the IIbβ3 and vβ3 transmembrane helices to extracellular ligand binding sites. Because integrins lacking transmembrane and cytoplasmic domains are constitutively active, these domains appear to constrain integrins in their resting conformations.

Two loci of protein-protein interaction which exert constraining effects on integrin activity have been identified. The first locus consists of a unique /β transmembrane domain heterodimer that results from the packing of complementary small and large side chains on neighboring helices.⁸ In the case of IIbβ3, this packing places the IIb transmembrane helix motif G---G---L in juxtaposition to the β3 transmembrane helix motif V---I---G (Figure 1). This transmembrane helix packing arrangement, conserved across the entire integrin family, results in helix-helix interactions whose strength is appropriate for a system that undergoes rapid conformational switching. Thus, single point mutations that disrupt the transmembrane heterodimer are sufficient to cause IIbβ3 activation.⁹

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Figure 1. Model of the reciprocal "large-small" integrin transmembrane heterodimer interface. The integrin heterodimer is represented as an idealized pair of helices with large spheres denoting large hydrophobic residues and small spheres representing small polar residues. G, glycine; L, leucine; V, valine; I, isoleucine; and W, tryptophan.

The second locus involves the integrin cytoplasmic domains. Because deletion of the conserved membrane-proximal IIb cytoplasmic domain sequence GFFKR or the conserved β3 cytoplasmic domain sequence LLITIHD causes IIbβ3 activation,¹⁰ it has been proposed that these sequences interact to form an activation-constraining ‘clasp’, a feature of which may be a stabilizing salt-bridge between R995 in IIb and D723 in β3.¹¹ However, under physiological circumstances, IIbβ3 activation occurs when intracellular proteins such as talin and kindlin-3 bind to highly conserved portions of the β3 cytoplasmic domain and cause cytoplasmic domain separation.¹²

To determine a structure for the activation-constraining clasp, Vinogradova et al. used nuclear magnetic resonance (NMR) to study interactions between IIb and β3 cytoplasmic domain peptides, either as full-length native peptides or as fusions with maltose-binding protein.^13,14 Calculated structures revealed an N-terminal /β interface containing both hydrophobic and electrostatic interactions, including an electrostatic interaction between the guanidyl of IIb R995 and the carboxyl of β3 D723. Subsequently, when NMR was performed in the presence of dodecylphosphocholine micelles to mimic a membranous environment, β3 residues 716–721 were found to be embedded in lipid. Lastly, NMR was performed using a mixture of β3 peptide and the talin FERM domain. The talin FERM domain binds to two regions of the β3 cytoplasmic domain centered on residues 739 and 747 and phenylalanine residues 727 and 730. Under these conditions, NMR chemical shifts for β3 residues T720-D723 were perturbed, suggesting that talin binding to the β3 cytoplasmic domain may physically disrupt the membrane-proximal clasp.

Surprisingly, it has been difficult to detect the IIb/β3 clasp experimentally. Thus, neither Ulmer et al. who used NMR to study the structure of the IIb and β3 cytoplasmic domains tethered by a coiled-coil¹⁵ nor Li et al. who analyzed the interaction of the IIb and β3 transmembrane and cytoplasmic domain polypeptides dissolved in detergent micelles detected their heteromeric association.¹⁶

To obtain a structure for the IIbβ3 cytosolic domain heterodimer as it might exist in resting IIbβ3, Metcalf et al. introduced cysteines at IIb residue 987 and β3 residue 712 and dissolved the resulting disulfide-crosslinked construct in dodecylphosphocholine micelles for NMR experiments (unpublished data). While the IIb cytoplasmic domain was found to be intrinsically disordered, the β3 cytoplasmic domain showed considerable structure, consisting of a proximal helix contiguous with the transmembrane helix and two distal helices (Figure 2). The proximal helix extended to residue D723 and was followed by a hinge at residue R724. This hinge allowed the proximal helix and the first distal helix to pack together at an angle of 110°, bringing the two distal helices into proximity to the membrane bilayer. Lys716 and Ile719, located on the same face of the proximal helix, interacted with the IIb cytoplasmic domain, perhaps allowing residue D723 to interact electrostatically with IIb R995. The first distal helix extended from residues K725 to A737 and was followed by a flexible linker spanning residues 738–743 and the second distal helix beginning at residue N744 through I757. The remainder of the cytoplasmic domain, consisting of its extreme C-terminus, was flexible and unstructured. It is noteworthy that the two distal helices are amphipathic and consequently, may interact with the membrane bilayer. However, they are also dynamic and likely available in the cytosolic compartment for binding to cytoplasmic signaling proteins such as talin and kindlin-3.

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Figure 2. Ribbon diagram of the β3 cytoplasmic domain. The regions of the domain that interact with IIb, talin, kindlin-3 and Src are indicated. The side chains of the residues that interact with IIb are shown in blue, green, and red. The side chains of the hydrophobic residues that are either embedded in the membrane or interact with talin are shown in yellow.

These structural studies provide a background for understanding the pathogenesis of the bleeding disorder of the patient reported by Jayo et al.¹ The mutated residue, L718, is located in the proximal β3 cytoplasmic domain helix. Replacing it with proline likely ‘breaks’ the helix at this point, leading to either of two diametrically opposed outcomes: either the mutation activates IIbβ3 by disrupting the interaction between IIb and β3 or it inhibits IIbβ3 activation by uncoupling talin and kindlin-3 binding to the β3 cytoplasmic domain and cytoplasmic domain separation. In Chinese hamster ovary cells, L718P did cause spontaneous IIbβ3 activity, enhanced IIbβ3 clustering, and disruption of ordered lipid domains. But, in platelets, where it was expressed heterozygously with normal β3, the mutation was associated with impaired platelet aggregation and decreased ligand binding to IIbβ3. Platelets from individuals heterozygous for Glanzmann’s thrombasthenia express 50% of the normal amount of IIbβ3 and aggregate normally.¹⁷ Thus, in this case, either IIbβ3 containing the L718P mutation impairs the function of the normal co-expressed IIbβ3 (a dominant-negative effect) or additional abnormalities contribute to the patient’s bleeding diathesis.

Previously, Peyruchaud et al. reported the case of a patient with an R995Q mutation in IIb that was predicted to cause constitutive IIbβ3 activation by disrupting the electrostatic interaction between IIb R995 and β3 D723.¹⁸ However, the mutant IIbβ3 was not constitutively active and the patient’s thrombasthenia-like phenotype was most likely due to a decreased amount of IIbβ3 on the platelet surface. Subsequently, Ruiz et al. described a patient with thrombasthenia whose C560R mutation in β3 locked IIbβ3 in its high affinity conformation.¹⁹ Although agonist-stimulated platelet aggregation was impaired, platelet microaggregates formed spontaneously in stirred platelet suspensions, ligands such as fibrinogen bound spontaneously to the mutant IIbβ3, and fibrinogen was present on the surface of circulating platelets. Nonetheless, the patient presented with a thrombasthenic phenotype because of a substantially reduced amount of platelet surface IIbβ3.

The patient Jayo et al. studied, unlike typical patients with thrombasthenia, was slightly thrombocytopenic and had platelets that were smaller than normal.¹ Consequently, although the amount of IIbβ3 on the platelet surface was slightly decreased, the density of IIbβ3 was likely normal or nearly so. Further, unlike typical thrombasthenic platelets, there was a marked decrease in IIbβ3-independent platelet secretion, suggesting that other platelet function abnormalities were contributing to the patient’s mucocutaneous bleeding. Thus, this case underscores the complexity of platelet function and the difficulty in extrapolating from effects seen in tissue culture cells expressing recombinant IIbβ3 to platelets where IIbβ3 is normally expressed.

Footnotes

Dr. Bennett is a Professor of Medicine in the Hematology-Oncology Division of the Department of Medicine of the University of Pennsylvania School of Medicine.

Mr. Moore is a graduate student in the Medical Student Training Program of the University of Pennsylvania School of Medicine.

(Related Original Article on page 1158)

No potential conflict of interest relevant to this article was reported.

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Related Article

L718P mutation in the membrane-proximal cytoplasmic tail of β3 promotes abnormal IIbβ3 clustering and lipid microdomain coalescence, and associates with a thrombasthenia-like phenotype

Asier Jayo, Isabel Conde, Pedro Lastres, Constantino Martínez, José Rivera, Vicente Vicente, Consuelo González-Manchón
Haematologica 2010 95: 1158-1166. [Abstract] [Full Text] [PDF]

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