Corinne de la Salle’s research while affiliated with French National Centre for Scientific Research and other places

Glycoprotein (GP) Ibalpha is a major adhesive receptor of platelets, surface expressed as part of the GPIb-IX-V complex. However, important questions about how the four gene products (Ibalpha, Ibbeta, IX, and V) composing this complex are processed remain. A deficiency of or nonfunctioning GPIb-IX-V is characteristic of the Bernard-Soulier syndrome (BSS), an inherited bleeding disease. We now report a BSS variant whose platelets have little or no GIbbeta or GPIX, but where residual GPIbalpha was selectively located in flow cytometry by monoclonal antibodies (WM23 and Bx-1) recognizing denatured epitopes. Whereas WM23 immunoprecipitated GPIbalpha (130 kDa), GPIX, and GPIbbeta from control platelets, a single surface protein of approximately 66 kDa was obtained for the patient. DNA sequencing revealed a homozygous Asn(64) --> Thr substitution in the GPIbbeta from the patient. This substitution modified a conserved residue in the COOH-terminal region flanking the single-copy leucine-rich domain of GPIbbeta. When GPIbbeta64Thr was coexpressed in a stable CHO cell line with wild-type GPIbalpha and GPIX, flow cytometry and confocal microscopy failed to show GPIb-IX complexes at the cell surface. Intracellular GPIbalpha and GPIbbeta were detected and largely confined to the endoplasmic reticulum, and little GPIX was seen. GPIbalpha was immunoprecipitated as a 66-70 kDa protein in (35)S metabolic studies and lacked O-glycosidic side chains. Also, it was not disulfide bound to the mutated GPIbbeta. Thus, a single amino acid substitution in the extracellular domain of GPIbbeta can affect both the maturation of GPIbalpha and GPIX stability. GPIbbeta has a pivotal role in regulating GPIb-IX-V biosynthesis.

This paper describes the molecular defect of the second case of Bernard-Soulier syndrome, initially reported in 1957. Analysis of the patient's platelets by flow cytometry and Western blotting failed to detect surface expression of any of the four subunits of the glycoprotein (GP)Ib-V-IX complex and revealed small amounts of intracellular GPIbalpha, GPIbbeta and GPV but no GPIX. DNA sequencing revealed a novel missense mutation in the GPIX gene which replaced Leu (CTG) by Pro (CCG) at position 7 of the signal peptide. This mutation is, to date, the only known example of a leader sequence defect in Bernard-Soulier syndrome. The change occurred in a prototypic alpha-helical hydrophobic core region, typically enriched in leucine and devoid of proline residues. Co-transfection of GPIXPro7 with normal GPIbalpha and GPIbbeta into Chinese hamster ovary cells reproduced the platelet phenotype, resulting in no detectable GPIX, low intracellular levels of GPIbalpha and GPIbbeta, and an absence of surface expression. This mutation presumably leads to an abnormal conformation and, hence, incorrect insertion of GPIX into the endoplasmic reticulum and/or to defective signal peptide cleavage, both of which are required for correct transport to the cell membrane. This provides further evidence for a critical role of GPIX in controlling biosynthesis of the GPIb-IX complex.

GPIbbeta is disulfide-linked to GPIbalpha to form GPIb, a platelet receptor for von Willebrand factor (vWF). GPIb is in turn non covalently linked to GPIX and GPV to form the GPIb/V/IX complex. Apart from its contribution to controlling surface expression of the complex, the exact function of GPIbbeta is not well established due to a lack of suitable ligands or antibodies. The present report describes a monoclonal antibody (RAM.1) that labeled the 26 kDa GPIbbeta subunit on western blots and coprecipitated the three subunits of the GPIb/IX complex from lysates of platelets and transfected CHO and K562 cells. RAM.1 bound to GPIbbeta deleted of its intracellular domain whereas Gi27, directed against intracellular GPIbbeta, did not. Using synthetic peptides, the RAM.1 epitope was mapped to a putative cysteine loop within the COOH-terminal leucine-rich flanking region. In functional assays, RAM.1 had no effect on platelet aggregation induced by ADP, collagen or thrombin, but inhibited ristocetin induced platelet agglutination and botrocetin induced vWF binding. RAM.1 inhibited adhesion of GPIb/V/IX transfected K562 cells to a vWF matrix under flow, increased their rolling velocity and decreased the resistance of cells to detachment at high shear. This study suggests a role of GPIbbeta in modulating the adhesive properties of GPIb/V/IX and describes a useful tool to analyze the exact functions of GPIbbeta.

The multisubunit leucine-rich glycoprotein (GP) Ib-IX-V complex mediates von Willebrand factor-dependent platelet adhesion at sites of blood-vessel injury. Molecular defects of this receptor are reported to cause the Bernard-Soulier haemorrhagic disorder. To gain insight into the mechanisms controlling expression of normal and defective receptors, we performed pulse-chase metabolic studies and detailed analysis of intracellular processing in GPIb-IX-transfected Chinese-hamster ovary cells. In the native complex, after early subunit association, sugars N-linked to the three subunits are trimmed and sialylated in the Golgi compartment and GPIbalpha undergoes extensive O-glycosylation. Surface biotinylation during chase demonstrated that only fully processed complexes reach the cell surface. Tunicamycin treatment revealed that early N-glycosylation is not required for O-glycosylation of GPIbalpha and surface expression of the complex. Biosynthetic studies were then performed on a Bernard-Soulier variant based on previous description of abnormal GPIbalpha size and decreased surface expression. The mutant complex associated normally, but displayed defective processing of its N-linked sugars and abnormal O-glycosylation of GPIbalpha. Confocal immunofluorescence microscopy revealed that the mutant complexes could reach the cell surface but also accumulated intracellularly, while use of compartment specific markers showed strong co-localization in the endoplasmic reticulum (ER) and ER-to-Golgi intermediate compartments ('ERGIC') and only slight labelling of the cis-Golgi. Blockade before the Golgi was confirmed by brefeldin A treatment, which restored O-glycosylation and processing of N-linked sugars. The present study has shown that transfer from the ER to the Golgi represents an important step for controlling post-translational processing and surface expression of normal GPIb-IX-V complex.

The multisubunit leucine-rich glycoprotein (GP) Ib–IX–V complex mediates von Willebrand factor-dependent platelet adhesion at sites of blood-vessel injury. Molecular defects of this receptor are reported to cause the Bernard–Soulier haemorrhagic disorder. To gain insight into the mechanisms controlling expression of normal and defective receptors, we performed pulse–chase metabolic studies and detailed analysis of intracellular processing in GPIb-IX-transfected Chinese-hamster ovary cells. In the native complex, after early subunit association, sugars N-linked to the three subunits are trimmed and sialylated in the Golgi compartment and GPIbα undergoes extensive O-glycosylation. Surface biotinylation during chase demonstrated that only fully processed complexes reach the cell surface. Tunicamycin treatment revealed that early N-glycosylation is not required for O-glycosylation of GPIbα and surface expression of the complex. Biosynthetic studies were then performed on a Bernard–Soulier variant based on previous description of abnormal GPIbα size and decreased surface expression. The mutant complex associated normally, but displayed defective processing of its N-linked sugars and abnormal O-glycosylation of GPIbα. Confocal immunofluorescence microscopy revealed that the mutant complexes could reach the cell surface but also accumulated intracellularly, while use of compartment specific markers showed strong co-localization in the endoplasmic reticulum (ER) and ER-to-Golgi intermediate compartments (‘ERGIC’) and only slight labelling of the cis-Golgi. Blockade before the Golgi was confirmed by brefeldin A treatment, which restored O-glycosylation and processing of N-linked sugars. The present study has shown that transfer from the ER to the Golgi represents an important step for controlling post-translational processing and surface expression of normal GPIb-IX-V complex.

Megakaryocytopoiesis is a complex multistep process involving cell division, endoreplication, and maturation and resulting in the release of platelets into the blood circulation. Megakaryocytes (MK) progressively express lineage-restricted proteins, some of which play essential roles in platelet physiology. Glycoprotein (GP)Ib-V-IX (CD42) and GPIIb (CD41) are examples of MK-specific proteins having receptor properties essential for platelet adhesion and aggregation. This study defined the progressive expression of the GPIb-V-IX complex during in vitro MK maturation and compared it to that of GPIIb, an early MK marker. Human cord blood CD34(+) progenitor cells were cultured in the presence of cytokines inducing megakaryocytic differentiation. GPIb-V-IX expression appeared at day 3 of culture and was strictly dependent on MK cytokine induction, whereas GPIIb was already present in immature CD34(+) cells. Analysis by flow cytometry and of the messenger RNA level both showed that GPV appeared 1 day later than GPIb-IX. Microscopy studies confirmed the late appearance of GPV, which was principally localized in the cytoplasm when GPIb-IX was found on the cell surface, suggesting a delayed program of GPV synthesis and trafficking. Cell sorting studies revealed that the CD41(+)GPV(+) population contained 4N and 8N cells at day 7, and was less effective than CD41(+)GPV(-) cells in generating burst-forming units of erythrocytes or MK colonies. This study shows that the subunits of the GPIb-V-IX complex represent unique surface markers of MK maturation. The genes coding for GPIb-IX and GPV are useful tools to study megakaryocytopoiesis and for tissue-specific or conditional expression in mature MK and platelets. (Blood. 2000;96:4169-4177)

Megakaryocytopoiesis is a complex multistep process involving cell division, endoreplication, and maturation and resulting in the release of platelets into the blood circulation. Megakaryocytes (MK) progressively express lineage-restricted proteins, some of which play essential roles in platelet physiology. Glycoprotein (GP)Ib-V-IX (CD42) and GPIIb (CD41) are examples of MK-specific proteins having receptor properties essential for platelet adhesion and aggregation. This study defined the progressive expression of the GPIb-V-IX complex during in vitro MK maturation and compared it to that of GPIIb, an early MK marker. Human cord blood CD34+ progenitor cells were cultured in the presence of cytokines inducing megakaryocytic differentiation. GPIb-V-IX expression appeared at day 3 of culture and was strictly dependent on MK cytokine induction, whereas GPIIb was already present in immature CD34+ cells. Analysis by flow cytometry and of the messenger RNA level both showed that GPV appeared 1 day later than GPIb-IX. Microscopy studies confirmed the late appearance of GPV, which was principally localized in the cytoplasm when GPIb-IX was found on the cell surface, suggesting a delayed program of GPV synthesis and trafficking. Cell sorting studies revealed that the CD41+GPV+ population contained 4N and 8N cells at day 7, and was less effective than CD41+GPV− cells in generating burst-forming units of erythrocytes or MK colonies. This study shows that the subunits of the GPIb-V-IX complex represent unique surface markers of MK maturation. The genes coding for GPIb-IX and GPV are useful tools to study megakaryocytopoiesis and for tissue-specific or conditional expression in mature MK and platelets.

The mechanisms governing the biosynthesis and surface expression of platelet adhesive receptors on parent megakaryocytes are as yet poorly understood. In particular, the assembly and processing of the multisubunit glycoprotein (GP) Ib-IX-V complex, a receptor for von Willebrand factor (vWf) is not fully understood. In the present work, these questions were addressed by reproducing a natural mutation of GPIbalpha found in a variant case of Bernard-Soulier syndrome (Nancy I), due to the deletion of leucine 179 in the seventh leucine-rich repeat of the polypeptide. Wild type and mutated GPIbalpha were transfected into CHO cells expressing GPlbbeta and GPIX. Flow cytometry showed surface expression of the three subunits of both GPIb-IX complexes, but GPlbalphadeltaLeu was present at lower levels (20-40%) and was recognized only by a sub class of monoclonal antibodies which epitopes were not modified by the mutation. These properties reproduce the defect found in the patient's platelets, demonstrating the causative nature of the mutation and validate the use of the CHO cells model. Biochemical studies were performed in an attempt to elucidate the mechanism of the conformational change of GPIbalphadeltaLeu. They unexpectedly revealed a major glycosylation deficiency of the mutated GPIbalpha leading to a 40% decrease in molecular weight. The other two subunits of the complex were however normal and present at the plasma membrane. The deletion led to complete functional deficiency with lack of vWf binding of CHOalphadeltaLeu transfected cells in the presence of botrocetin and defective adhesion to a vWf coated surface under static conditions. Finally, in contrast to normal CHOalphabetaIX cells, which displayed rolling and deceleration when perfused over a vWf surface, CHOalphadeltaLeubetaIX cells were unable to roll over or attach to a vWf substratum. These results show that the integrity of the leucine-rich region of GPIbalpha is essential for normal processing and function of the GPIb-IX complex. In addition, these results obtained in a cellular system supported the suspected role of the macroglycopeptide region of GPIbalpha in maintaining a suitable conformation of this multisubunit receptor to perform its adhesive function.

Platelet adhesion to sites of vascular injury is initiated by the binding of the platelet glycoprotein (GP) Ib-V-IX complex to matrix-bound von Willebrand factor (vWf). This receptor-ligand interaction is characterized by a rapid on-off rate that enables efficient platelet tethering and rolling under conditions of rapid blood flow. We demonstrate here that platelets adhering to immobilized vWf under flow conditions undergo rapid morphological conversion from flat discs to spiny spheres during surface translocation. Studies of Glanzmann thrombasthenic platelets (lacking integrin alpha(IIb)beta(3)) and Chinese hamster ovary (CHO) cells transfected with GPIb/IX (CHO-Ib/IX) confirmed that vWf binding to GPIb/IX was sufficient to induce actin polymerization and cytoskeletal reorganization independent of integrin alpha(IIb)beta(3). vWf-induced cytoskeletal reorganization occurred independently of several well characterized signaling processes linked to platelet activation, including calcium influx, prostaglandin metabolism, protein tyrosine phosphorylation, activation of protein kinase C or phosphatidylinositol 3-kinase but was critically dependent on the mobilization of intracellular calcium. Studies of Oregon Green 488 1, 2-bis(o-amino-5-fluorophenoxy)ethane-N,N,N',N-tetraacetic acid tetraacetoxymethyl ester-loaded platelets and CHO-Ib/IX cells demonstrated that these cells mobilize intracellular calcium in a shear-dependent manner during surface translocation on vWf. Taken together, these studies suggest that the vWf-GPIb interaction stimulates actin polymerization and cytoskeletal reorganization in rolling platelets via a shear-sensitive signaling pathway linked to intracellular calcium mobilization.